Tree-sitter indentation for js-mode & cc-mode

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* Tree-sitter indentation for js-mode & cc-mode
@ 2022-10-27  1:43 Yuan Fu
  2022-10-27  9:11 ` Theodor Thornhill
  0 siblings, 1 reply; 14+ messages in thread
From: Yuan Fu @ 2022-10-27  1:43 UTC (permalink / raw)
  To: emacs-devel; +Cc: Theodor Thornhill

I did some work to allow tree-sitter indentation engine to plug in to c-offset-alist. Currently in a tree-sitter indent rule, we have

(MATCHER ANCHOR OFFSET)

OFFSET is normally an integer, but now it can also be a syntax symbol recognized by cc-mode’s indentation engine. In that case, tree-sitter indent calculates the indent using c-calc-offset, passing the syntax symbol and anchor position to it, and c-calc-offset will give us the integer offset based on c-offset-alist.

I’ve written indent rules for js-mode, they are in js-treesit-cc-indent-rules. Overall it works pretty well. Theo, could you give it a try? From my testing it is already an improvement from the original rules. I didn’t finish the JSX part and just copied your original rules for JSX. In the future I can probably port that to cc-style too.

I also added imenu support for js-mode and ts-mode, and navigation for python-mode.

Yuan

^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-27  1:43 Tree-sitter indentation for js-mode & cc-mode Yuan Fu
@ 2022-10-27  9:11 ` Theodor Thornhill
  2022-10-27  9:28   ` Theodor Thornhill
  2022-10-27 15:21   ` Yuan Fu
  0 siblings, 2 replies; 14+ messages in thread
From: Theodor Thornhill @ 2022-10-27  9:11 UTC (permalink / raw)
  To: Yuan Fu, emacs-devel; +Cc: Stefan Monnier

[-- Attachment #1: Type: text/plain, Size: 4017 bytes --]


Hi Yuan!

> I did some work to allow tree-sitter indentation engine to plug in to
> c-offset-alist. Currently in a tree-sitter indent rule, we have
>
> (MATCHER ANCHOR OFFSET)
>
> OFFSET is normally an integer, but now it can also be a syntax symbol
> recognized by cc-mode’s indentation engine. In that case, tree-sitter
> indent calculates the indent using c-calc-offset, passing the syntax
> symbol and anchor position to it, and c-calc-offset will give us the
> integer offset based on c-offset-alist.
>

This is cool, but do we really want/need this?  I mean, now we're really
binding these implementations together and allowing all the legacy of CC
mode to blend in.  We also need knowledge of how CC mode names their
syntactic definitions.  IMO one of the big selling points of tree sitter
is that you can look at other editors implementation and get inspired
immediately.  Now we need deep knowledge of cc mode, don't we?  Also,
why would we want cc mode to calculate this for us?  I see what you're
trying to do, but _I_ think this is a step in the wrong direction.


> I’ve written indent rules for js-mode, they are in
> js-treesit-cc-indent-rules. Overall it works pretty well. Theo, could
> you give it a try? From my testing it is already an improvement from
> the original rules. I didn’t finish the JSX part and just copied your
> original rules for JSX. In the future I can probably port that to
> cc-style too.
>

I don't think this is better, for example:

The old variant renders this snippet correctly:
```
const fooClient = new Foo({
  bucket: process.env.foo,
  region: process.env.foo,
});
```

But the new one renders it like this:
```
const fooClient = new Foo({
                            bucket: process.env.foo,
                          region: process.env.foo,
                          });
```

I know this is a matter of tweaking, but it immediately makes me
question the reasoning to blend them.

In addition I profiled indenting a 50k lines js file with messed up
indentation, and received some surprising results.  The pure cc mode
variant is slow, but MUCH faster than tree-sitter.  It seems we are
looking up way to much the root of the tree, but you know the internals
here better than me.  Is this something we can optimize away? See the
attached report at the bottom.


> I also added imenu support for js-mode and ts-mode, and navigation for
> python-mode.
>

Very cool - it seems to work pretty nicely!

Anyways - can we please revisit the idea that we init and/or use cc mode
in tandem with tree-sitter?  I know we want "feature parity", but I
think we lose too much of the simplicity gained by adding in the old
complexity.  My prediction for the future is that this will result in
numerous bug reports where it's hard to know whether this is a fix for
cc mode or treesitter.  And in the end people _will_ just skip these
modes altogether and put simpler ones in (m)elpa that only uses treesit,
to avoid this.  The cc mode won't go away at all, for the people that
considers that superior.  We can still use the treesit-settings as a
centralized variable to get most, if not all of the "auto-enabling"
benefits by just lifting it up:

```
  ;;....

  (cond
   ;; Tree-sitter.
   ((treesit-ready-p 'js-mode 'javascript)
    ;; init all treesitter relevant stuff - can add in _some_ other
    ;; non-cc-mode settinigs, such as comment-start, etc above this.
    ;; We don't need the cache, detection of js-jsx or any of the
    ;; before-change-functions
  
    (treesit-major-mode-setup))
   ;; Elisp.
   (t
     ;; enable in normal cc mode stuff
    )))

```

This way other hypothetical tree-sitter-v2 in the future is just a
simple cond, and no need to worry.

If I'm missing something important here, please let me know, but I
_really_ don't understand the reason for merging these implementations.

Anyway, thanks for your continued hard work!

Theo


[-- Attachment #2: indent-report.txt --]
[-- Type: text/plain, Size: 32301 bytes --]

      528085  99% - command-execute
      527969  99%  - funcall-interactively
      527969  99%   - execute-extended-command
      527969  99%    - command-execute
      527969  99%     - funcall-interactively
      527969  99%      - foo2
      527969  99%       - indent-for-tab-command
      527969  99%        - indent-region
      527965  99%         - indent-region-line-by-line
      527901  99%          - indent-according-to-mode
      527893  99%           - treesit-indent
      527825  99%            - let*
      482649  91%             - cond
      482636  91%              - treesit-node-at
      482512  91%               - let*
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           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b4f78e>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b400cd>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b40307>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b403c1>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b40307>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b4f78e>
           4   0%                             string-match-p
           4   0%                          - #<lambda 0xb2f0a20b4f78e>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b403c1>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b40307>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b40307>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b40756>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b40756>
           4   0%                             string-match-p
           4   0%                          - #<lambda 0xb2f0a20b400cd>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                            #<lambda 0xb2f0a20b40307>
           4   0%                          - #<lambda 0xb2f0a20b403c1>
           4   0%                             string-match-p
           4   0%                          - #<lambda 0xb2f0a20b4f78e>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b403c1>
           4   0%                             string-match-p
           4   0%                          - #<lambda 0xb2f0a20b4f78e>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b403c1>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b403c1>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b403c1>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b40756>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b40307>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b403c1>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b4f78e>
           4   0%                             string-match-p
           4   0%                          - #<lambda 0xb2f0a20b40756>
           4   0%                           - string-match-p
           4   0%                              or
           4   0%                          - #<lambda 0xb2f0a20b40756>
           4   0%                           - string-match-p
           4   0%                              or
          20   0%                         - and
           4   0%                            not
          28   0%                        setq
           4   0%                    treesit-node-language
        4073   0%              - progn
        4053   0%               - let*
        4049   0%                - let
        4041   0%                 - if
        4033   0%                  - let
        3721   0%                   - if
        1611   0%                    - indent-line-to
         620   0%                       jit-lock-after-change
          38   0%                     - #<compiled -0x1b08287213a66ec>
          38   0%                      - filter-buffer-substring
          38   0%                       - buffer-substring--filter
          38   0%                        - #<compiled -0xf7269c39310322>
          38   0%                           apply
          16   0%                       syntax-ppss-flush-cache
           8   0%                     - js--flush-caches
           4   0%                        setq
           4   0%                       undo-auto--undoable-change
         300   0%                   - +
         132   0%                      save-excursion
         404   0%              - cond
         116   0%               - treesit-node-at
         116   0%                - let*
         116   0%                 - if
          84   0%                  - progn
          84   0%                   - while
          80   0%                      setq
         582   0%             - treesit-parent-while
         564   0%              - let
         564   0%               - while
         528   0%                - progn
         520   0%                   setq
          32   0%                - and
          28   0%                 - funcall
           4   0%                    #<lambda 0x13e697510aa41905>
          40   0%               save-excursion
          20   0%            - treesit-update-ranges
           4   0%               let
         116   0%  - byte-code
         116   0%   - read-extended-command
         116   0%    - read-extended-command-1
         116   0%     - completing-read-default
         116   0%      - apply
         116   0%       - vertico--advice
          92   0%        - #<subr completing-read-default>
          58   0%         - vertico--exhibit
          40   0%          - vertico--update
          40   0%           - vertico--recompute
          32   0%            - vertico--all-completions
          32   0%             - completion-all-completions
          32   0%              - completion--nth-completion
          32   0%               - completion--some
          32   0%                - #<compiled -0x14947987a33baafc>
          32   0%                 - completion-basic-all-completions
          32   0%                  - completion-pcm--all-completions
          32   0%                   - #<subr F616e6f6e796d6f75732d6c616d626461_anonymous_lambda_54>
          32   0%                    - complete-with-action
          20   0%                     - all-completions
           8   0%                      - #<compiled 0xcb35081dde22255>
           4   0%                         #<compiled -0x12b7891def632ea6>
           4   0%              vertico-sort-history-length-alpha
          18   0%          - vertico--arrange-candidates
          15   0%           - vertico--affixate
          15   0%              read-extended-command--affixation
           3   0%           - #<compiled 0x26aef75ebef866b>
           3   0%            - completion-hilit-commonality
           3   0%             - #<compiled 0x1ae5721236d6a985>
           3   0%                font-lock-prepend-text-property
           5   0%         - timer-event-handler
           2   0%          - apply
           2   0%             #<subr F616e6f6e796d6f75732d6c616d626461_anonymous_lambda_9>
        1189   0% + ...
          95   0% + timer-event-handler

^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-27  9:11 ` Theodor Thornhill
@ 2022-10-27  9:28   ` Theodor Thornhill
  2022-10-27  9:58     ` Theodor Thornhill
  2022-10-27 15:21   ` Yuan Fu
  1 sibling, 1 reply; 14+ messages in thread
From: Theodor Thornhill @ 2022-10-27  9:28 UTC (permalink / raw)
  To: Yuan Fu, emacs-devel

[-- Attachment #1: Type: text/plain, Size: 108 bytes --]

Theodor Thornhill <theo@thornhill.no> writes:

BTW, I fixed ts-mode.  See attached patch :-)

Thanks,
Theo


[-- Warning: decoded text below may be mangled, UTF-8 assumed --]
[-- Attachment #2: 0001-Ensure-we-have-a-treesit-parser-in-mode-init.patch --]
[-- Type: text/x-diff, Size: 863 bytes --]

From f1d9d6f004b16885efd127fa074537028a3805f8 Mon Sep 17 00:00:00 2001
From: Theodor Thornhill <theo@thornhill.no>
Date: Thu, 27 Oct 2022 11:26:44 +0200
Subject: [PATCH] Ensure we have a treesit-parser in mode init

* lisp/progmodes/ts-mode.el (ts-mode): Create a parser.
---
 lisp/progmodes/ts-mode.el | 4 ++--
 1 file changed, 2 insertions(+), 2 deletions(-)

diff --git a/lisp/progmodes/ts-mode.el b/lisp/progmodes/ts-mode.el
index 28800e378a..61235608c6 100644
--- a/lisp/progmodes/ts-mode.el
+++ b/lisp/progmodes/ts-mode.el
@@ -261,8 +261,8 @@ ts-mode
   :syntax-table ts-mode--syntax-table
 
   (cond
-   ((treesit-ready-p nil 'tsx)
-    ;; Tree-sitter.
+   ((treesit-ready-p 'ts-mode 'tsx)
+    (treesit-parser-create 'tsx)
     ;; Comments.
     (setq-local comment-start "// ")
     (setq-local comment-start-skip "\\(?://+\\|/\\*+\\)\\s *")
-- 
2.34.1


^ permalink raw reply related	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-27  9:28   ` Theodor Thornhill
@ 2022-10-27  9:58     ` Theodor Thornhill
  0 siblings, 0 replies; 14+ messages in thread
From: Theodor Thornhill @ 2022-10-27  9:58 UTC (permalink / raw)
  To: Yuan Fu, emacs-devel

Theodor Thornhill <theo@thornhill.no> writes:

> Theodor Thornhill <theo@thornhill.no> writes:
>
> BTW, I fixed ts-mode.  See attached patch :-)
>
> Thanks,
> Theo


Never mind this patch.  Added it as well as some other small tweaks in a
separate bugreport.

Thanks,
Theo



^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-27  9:11 ` Theodor Thornhill
  2022-10-27  9:28   ` Theodor Thornhill
@ 2022-10-27 15:21   ` Yuan Fu
  2022-10-27 18:36     ` Theodor Thornhill
  1 sibling, 1 reply; 14+ messages in thread
From: Yuan Fu @ 2022-10-27 15:21 UTC (permalink / raw)
  To: Theodor Thornhill; +Cc: emacs-devel, Stefan Monnier



> On Oct 27, 2022, at 2:11 AM, Theodor Thornhill <theo@thornhill.no> wrote:
> 
> 
> Hi Yuan!
> 
>> I did some work to allow tree-sitter indentation engine to plug in to
>> c-offset-alist. Currently in a tree-sitter indent rule, we have
>> 
>> (MATCHER ANCHOR OFFSET)
>> 
>> OFFSET is normally an integer, but now it can also be a syntax symbol
>> recognized by cc-mode’s indentation engine. In that case, tree-sitter
>> indent calculates the indent using c-calc-offset, passing the syntax
>> symbol and anchor position to it, and c-calc-offset will give us the
>> integer offset based on c-offset-alist.
>> 
> 
> This is cool, but do we really want/need this?  I mean, now we're really
> binding these implementations together and allowing all the legacy of CC
> mode to blend in.  We also need knowledge of how CC mode names their
> syntactic definitions.  IMO one of the big selling points of tree sitter
> is that you can look at other editors implementation and get inspired
> immediately.  Now we need deep knowledge of cc mode, don't we?  Also,
> why would we want cc mode to calculate this for us?  I see what you're
> trying to do, but _I_ think this is a step in the wrong direction.

You have a point. I tried to blend in cc-mode because that’ll allow us support “styles” and existing user customization. (Also I started out thinking it will be easier to write indentation rules this way which turns out to be not true.) Perhaps it’s better to come up with a new system for customizing indentation style. I’ll revert this change.

> 
> 
>> I’ve written indent rules for js-mode, they are in
>> js-treesit-cc-indent-rules. Overall it works pretty well. Theo, could
>> you give it a try? From my testing it is already an improvement from
>> the original rules. I didn’t finish the JSX part and just copied your
>> original rules for JSX. In the future I can probably port that to
>> cc-style too.
>> 
> 
> I don't think this is better, for example:
> 
> The old variant renders this snippet correctly:
> ```
> const fooClient = new Foo({
>  bucket: process.env.foo,
>  region: process.env.foo,
> });
> ```
> 
> But the new one renders it like this:
> ```
> const fooClient = new Foo({
>                            bucket: process.env.foo,
>                          region: process.env.foo,
>                          });
> ```
> 
> I know this is a matter of tweaking, but it immediately makes me
> question the reasoning to blend them.

It’s largely my slip-up rather than inherit defect of the system, but I agree with your opinion above.

> 
> In addition I profiled indenting a 50k lines js file with messed up
> indentation, and received some surprising results.  The pure cc mode
> variant is slow, but MUCH faster than tree-sitter.  It seems we are
> looking up way to much the root of the tree, but you know the internals
> here better than me.  Is this something we can optimize away? See the
> attached report at the bottom.

This is very strange, I need to look into it.

> 
>> I also added imenu support for js-mode and ts-mode, and navigation for
>> python-mode.
>> 
> 
> Very cool - it seems to work pretty nicely!

Nice.

> 
> Anyways - can we please revisit the idea that we init and/or use cc mode
> in tandem with tree-sitter?  I know we want "feature parity", but I
> think we lose too much of the simplicity gained by adding in the old
> complexity.  My prediction for the future is that this will result in
> numerous bug reports where it's hard to know whether this is a fix for
> cc mode or treesitter.  And in the end people _will_ just skip these
> modes altogether and put simpler ones in (m)elpa that only uses treesit,
> to avoid this.  The cc mode won't go away at all, for the people that
> considers that superior.  We can still use the treesit-settings as a
> centralized variable to get most, if not all of the "auto-enabling"
> benefits by just lifting it up:
> 
> ```
>  ;;....
> 
>  (cond
>   ;; Tree-sitter.
>   ((treesit-ready-p 'js-mode 'javascript)
>    ;; init all treesitter relevant stuff - can add in _some_ other
>    ;; non-cc-mode settinigs, such as comment-start, etc above this.
>    ;; We don't need the cache, detection of js-jsx or any of the
>    ;; before-change-functions
> 
>    (treesit-major-mode-setup))
>   ;; Elisp.
>   (t
>     ;; enable in normal cc mode stuff
>    )))
> 
> ```
> 
> This way other hypothetical tree-sitter-v2 in the future is just a
> simple cond, and no need to worry.
> 
> If I'm missing something important here, please let me know, but I
> _really_ don't understand the reason for merging these implementations.

I don’t have an educated opinion on this. If no one has objections I’ll follow your professional advice ;-)

> Anyway, thanks for your continued hard work!

Many thanks to you, too!

> 
> Theo
> 
> <indent-report.txt>




^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-27 15:21   ` Yuan Fu
@ 2022-10-27 18:36     ` Theodor Thornhill
  2022-10-28  8:15       ` Yuan Fu
  0 siblings, 1 reply; 14+ messages in thread
From: Theodor Thornhill @ 2022-10-27 18:36 UTC (permalink / raw)
  To: Yuan Fu; +Cc: emacs-devel, Stefan Monnier




>> This is cool, but do we really want/need this?  I mean, now we're really
>> binding these implementations together and allowing all the legacy of CC
>> mode to blend in.  We also need knowledge of how CC mode names their
>> syntactic definitions.  IMO one of the big selling points of tree sitter
>> is that you can look at other editors implementation and get inspired
>> immediately.  Now we need deep knowledge of cc mode, don't we?  Also,
>> why would we want cc mode to calculate this for us?  I see what you're
>> trying to do, but _I_ think this is a step in the wrong direction.
>
>You have a point. I tried to blend in cc-mode because that’ll allow us support “styles” and existing user customization. (Also I started out thinking it will be easier to write indentation rules this way which turns out to be not true.) Perhaps it’s better to come up with a new system for customizing indentation style. I’ll revert this change.

I think we can do something similar to the font lock features, can't we? 

>> 
>> But the new one renders it like this:
>> ```
>> const fooClient = new Foo({
>>                            bucket: process.env.foo,
>>                          region: process.env.foo,
>>                          });
>> ```
>> 
>> I know this is a matter of tweaking, but it immediately makes me
>> question the reasoning to blend them.
>
>It’s largely my slip-up rather than inherit defect of the system, but I agree with your opinion above.

Yes, absolutely. My intention was just to make the point with confusion in mixing semantics etc. By the way - I think adding more helpers and anchors like you've done is nice, so don't just revert blindly, unless you have to :-) 

>> looking up way to much the root of the tree, but you know the internals
>> here better than me.  Is this something we can optimize away? See the
>> attached report at the bottom.
>
>This is very strange, I need to look into it.
>

I'm happy to provide more info and profiling, as well as testing if need be! 

>> 

>> centralized variable to get most, if not all of the "auto-enabling"
>> benefits by just lifting it up:
>> 
>> ```
>>  ;;....
>> 
>>  (cond
>>   ;; Tree-sitter.
>>   ((treesit-ready-p 'js-mode 'javascript)
>>    ;; init all treesitter relevant stuff - can add in _some_ other
>>    ;; non-cc-mode settinigs, such as comment-start, etc above this.
>>    ;; We don't need the cache, detection of js-jsx or any of the
>>    ;; before-change-functions
>> 
>>    (treesit-major-mode-setup))
>>   ;; Elisp.
>>   (t
>>     ;; enable in normal cc mode stuff
>>    )))
>> 
>> ```
>> 
>> This way other hypothetical tree-sitter-v2 in the future is just a
>> simple cond, and no need to worry.
>> 
>> If I'm missing something important here, please let me know, but I
>> _really_ don't understand the reason for merging these implementations.
>
>I don’t have an educated opinion on this. If no one has objections I’ll follow your professional advice ;-)
>

Hah - no professionalism here, but I've spent quite some time in the cc mode machinery. 

>> Anyway, thanks for your continued hard work!
>
>Many thanks to you, too!
>
>

My pleasure! 

Theo



^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-27 18:36     ` Theodor Thornhill
@ 2022-10-28  8:15       ` Yuan Fu
  2022-10-28  8:59         ` Theodor Thornhill
  2022-10-28  9:10         ` Theodor Thornhill
  0 siblings, 2 replies; 14+ messages in thread
From: Yuan Fu @ 2022-10-28  8:15 UTC (permalink / raw)
  To: Theodor Thornhill; +Cc: emacs-devel, Stefan Monnier

> 
>>> looking up way to much the root of the tree, but you know the internals
>>> here better than me.  Is this something we can optimize away? See the
>>> attached report at the bottom.
>> 
>> This is very strange, I need to look into it.
>> 
> 
> I'm happy to provide more info and profiling, as well as testing if need be! 

I just tried running treesit-buffer-root-node and treesit-node-at 10000 times in the end of buffer and they are pretty fast, so I don’t know why the benchmark says 99% time is spent in treesit-buffer-root-node. Could you share the benchmark code and test file? Thanks!

Yuan


^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-28  8:15       ` Yuan Fu
@ 2022-10-28  8:59         ` Theodor Thornhill
  2022-10-28  9:10         ` Theodor Thornhill
  1 sibling, 0 replies; 14+ messages in thread
From: Theodor Thornhill @ 2022-10-28  8:59 UTC (permalink / raw)
  To: Yuan Fu; +Cc: emacs-devel, Stefan Monnier

[-- Attachment #1: Type: text/plain, Size: 1436 bytes --]

Yuan Fu <casouri@gmail.com> writes:

>> 
>>>> looking up way to much the root of the tree, but you know the internals
>>>> here better than me.  Is this something we can optimize away? See the
>>>> attached report at the bottom.
>>> 
>>> This is very strange, I need to look into it.
>>> 
>> 
>> I'm happy to provide more info and profiling, as well as testing if
>> need be!
>
> I just tried running treesit-buffer-root-node and treesit-node-at
> 10000 times in the end of buffer and they are pretty fast, so I don’t
> know why the benchmark says 99% time is spent in
> treesit-buffer-root-node. Could you share the benchmark code and test
> file? Thanks!

Absolutely.  I ran the test again - see test file and new report in
attachments.

You need to `M-x eval-buffer` in `treesit.el` to avoid the compiled
functions to get better profile report, then in the testfile:

M-x profiler-start
C-x h ;; (mark-whole-buffer)
C-i   ;; (indent-for-tab-command)
;; --- waaaaait
M-x profiler-stop
M-x profiler-report

There's no test code for this, just running the commands sequentially
and get the report :-)

Are we parsing the whole file over and over in treesit-buffer-root-node?
Do we for some reason not hit the early return?

Code is taken from [0] and duplicated and messed up indentation.

Theo

[0] https://raw.githubusercontent.com/TheAlgorithms/JavaScript/master/Search/BinarySearch.js


[-- Warning: decoded text below may be mangled, UTF-8 assumed --]
[-- Attachment #2: foo.js --]
[-- Type: text/javascript, Size: 1653341 bytes --]


function binarySearchRecursive (arr, x, low = 0, high = arr.length - 1) {
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
const mid = Math.floor(low + (high - low) / 2)

if (high >= low) {
if (arr[mid] === x) {
// item found => return its index
return mid
}

if (x < arr[mid]) {
// arr[mid] is an upper bound for x, so if x is in arr => low <= x < mid
return binarySearchRecursive(arr, x, low, mid - 1)
} else {
// arr[mid] is a lower bound for x, so if x is in arr => mid < x <= high
return binarySearchRecursive(arr, x, mid + 1, high)
}
} else {
// if low > high => we have searched the whole array without finding the item
return -1
}
}

[-- Attachment #3: cpu.txt --]
[-- Type: text/plain, Size: 18577 bytes --]

      177699  99% - command-execute
      177652  99%  - funcall-interactively
      177652  99%   - indent-for-tab-command
      177652  99%    - indent-region
      177628  99%     - indent-region-line-by-line
      177516  99%      - indent-according-to-mode
      177504  99%       - treesit-indent
      177484  99%        - let*
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      174125  97%          - treesit-node-at
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           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                         string-match-p
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           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d77c1>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d77c1>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d7356>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                        #<lambda 0xb2d191f7cc38e>
           4   0%                      - #<lambda 0xb2d191f7d7356>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                        #<lambda 0xb2d191f7cc38e>
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7d77c1>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d77c1>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d7707>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d77c1>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d7707>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                        #<lambda 0xb2d191f7cc38e>
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                        #<lambda 0xb2d191f7cc38e>
           4   0%                      - #<lambda 0xb2d191f7d7356>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d7707>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7d77c1>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d77c1>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d7707>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7cc38e>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d77c1>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d77c1>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d7356>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                         string-match-p
           4   0%                      - #<lambda 0xb2d191f7d7356>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d7707>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d74cd>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d7356>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                      - #<lambda 0xb2d191f7d7356>
           4   0%                       - string-match-p
           4   0%                          or
           4   0%                       and
         292   0%                   - progn
         288   0%                    - progn
         276   0%                     - setq
         252   0%                      - let
         232   0%                       - treesit--simple-indent-eval
         224   0%                        - cond
         212   0%                         - apply
         140   0%                          - #<lambda 0x86706eb2bdc1d3>
          96   0%                           - save-excursion
           4   0%                              goto-char
          40   0%                          - mapcar
          24   0%                           - treesit--simple-indent-eval
          24   0%                              cond
          16   0%                          - treesit--simple-indent-eval
           8   0%                             cond
           4   0%                           and
           8   0%                         cons
          32   0%                    setq
           4   0%                  setq
           4   0%                treesit-node-language
         643   0%          - progn
         631   0%           - let*
         623   0%            - let
         623   0%             - if
         623   0%              - let
         483   0%               - if
          67   0%                - indent-line-to
          39   0%                 - #<compiled -0x18b4777d062e6ec>
          39   0%                  - filter-buffer-substring
          39   0%                   - buffer-substring--filter
          39   0%                    - #<compiled -0xf7ff5b55e48322>
          39   0%                       apply
         132   0%               - +
         120   0%                  save-excursion
          32   0%            cond
         104   0%         - treesit-parent-while
          80   0%          - let
          76   0%           - while
          48   0%            - progn
          44   0%               setq
          16   0%            - and
           8   0%             - funcall
           8   0%              - #<lambda 0x126956a6393a5198>
           4   0%                 eq
          20   0%           save-excursion
          47   0%  - byte-code
          47   0%   - read-extended-command
          47   0%    - read-extended-command-1
          47   0%     - completing-read-default
          47   0%      - apply
          47   0%       - vertico--advice
          31   0%        - #<subr completing-read-default>
          20   0%         - vertico--exhibit
          20   0%          - vertico--update
          20   0%           - vertico--recompute
          16   0%            - vertico--all-completions
          16   0%             - completion-all-completions
          16   0%              - completion--nth-completion
          16   0%               - completion--some
          16   0%                - #<compiled -0x1183ac11f303aafc>
          16   0%                 - completion-basic-all-completions
          16   0%                  - completion-pcm--all-completions
          16   0%                   - #<subr F616e6f6e796d6f75732d6c616d626461_anonymous_lambda_54>
          16   0%                    - complete-with-action
           8   0%                     - all-completions
           8   0%                      - #<compiled 0x21876cdf4622255>
           8   0%                         #<compiled 0x85106f9909cd18a>
           4   0%              vertico-sort-history-length-alpha
           7   0%         - frame-windows-min-size
           7   0%          - window-min-size
           7   0%           - window--min-size-1
           7   0%              window--min-size-1
        1298   0% + ...
          35   0% + #<compiled -0x18b4777d062e6ec>
          28   0% + timer-event-handler
          23   0% + redisplay_internal (C function)

^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-28  8:15       ` Yuan Fu
  2022-10-28  8:59         ` Theodor Thornhill
@ 2022-10-28  9:10         ` Theodor Thornhill
  2022-10-28 19:43           ` Yuan Fu
  1 sibling, 1 reply; 14+ messages in thread
From: Theodor Thornhill @ 2022-10-28  9:10 UTC (permalink / raw)
  To: Yuan Fu; +Cc: emacs-devel, Stefan Monnier

Yuan Fu <casouri@gmail.com> writes:

>> 
>>>> looking up way to much the root of the tree, but you know the internals
>>>> here better than me.  Is this something we can optimize away? See the
>>>> attached report at the bottom.
>>> 
>>> This is very strange, I need to look into it.
>>> 
>> 
>> I'm happy to provide more info and profiling, as well as testing if need be! 
>
> I just tried running treesit-buffer-root-node and treesit-node-at
> 10000 times in the end of buffer and they are pretty fast, so I don’t
> know why the benchmark says 99% time is spent in
> treesit-buffer-root-node. Could you share the benchmark code and test
> file? Thanks!
>
> Yuan


Absolutely.  I ran the test again - see test file and new report in
attachments.

You need to `M-x eval-buffer` in `treesit.el` to avoid the compiled
functions to get better profile report, then in the testfile:

M-x profiler-start
C-x h ;; (mark-whole-buffer)
C-i   ;; (indent-for-tab-command)
;; --- waaaaait
M-x profiler-stop
M-x profiler-report

There's no test code for this, just running the commands sequentially
and get the report :-)

Are we parsing the whole file over and over in treesit-buffer-root-node?
Do we for some reason not hit the early return?

The js-file [0] is taken from [1] and duplicated and messed up
indentation. Report [2] was messed up by dpaste it seems.  Gmail didn't
want the files as attachments, so paste it is :-)

Hope this is useful!

Theo


[0]: https://dpaste.org/dwj3Q
[1]: https://raw.githubusercontent.com/TheAlgorithms/JavaScript/master/Search/BinarySearch.js
[2]: https://dpaste.org/aogkm
Theo



^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-28  9:10         ` Theodor Thornhill
@ 2022-10-28 19:43           ` Yuan Fu
  2022-10-28 19:49             ` Theodor Thornhill
  2022-10-29  5:53             ` Eli Zaretskii
  0 siblings, 2 replies; 14+ messages in thread
From: Yuan Fu @ 2022-10-28 19:43 UTC (permalink / raw)
  To: Theodor Thornhill; +Cc: emacs-devel, Stefan Monnier



> On Oct 28, 2022, at 2:10 AM, Theodor Thornhill <theo@thornhill.no> wrote:
> 
> Yuan Fu <casouri@gmail.com> writes:
> 
>>> 
>>>>> looking up way to much the root of the tree, but you know the internals
>>>>> here better than me.  Is this something we can optimize away? See the
>>>>> attached report at the bottom.
>>>> 
>>>> This is very strange, I need to look into it.
>>>> 
>>> 
>>> I'm happy to provide more info and profiling, as well as testing if need be! 
>> 
>> I just tried running treesit-buffer-root-node and treesit-node-at
>> 10000 times in the end of buffer and they are pretty fast, so I don’t
>> know why the benchmark says 99% time is spent in
>> treesit-buffer-root-node. Could you share the benchmark code and test
>> file? Thanks!
>> 
>> Yuan
> 
> 
> Absolutely.  I ran the test again - see test file and new report in
> attachments.
> 
> You need to `M-x eval-buffer` in `treesit.el` to avoid the compiled
> functions to get better profile report, then in the testfile:
> 
> M-x profiler-start
> C-x h ;; (mark-whole-buffer)
> C-i   ;; (indent-for-tab-command)
> ;; --- waaaaait
> M-x profiler-stop
> M-x profiler-report
> 
> There's no test code for this, just running the commands sequentially
> and get the report :-)
> 
> Are we parsing the whole file over and over in treesit-buffer-root-node?
> Do we for some reason not hit the early return?
> 
> The js-file [0] is taken from [1] and duplicated and messed up
> indentation. Report [2] was messed up by dpaste it seems.  Gmail didn't
> want the files as attachments, so paste it is :-)
> 
> Hope this is useful!
> 
> Theo
> 

Ok, I’m fairly certain this is due to tree-sitter reparsing after we indenting each line: treesit-buffer-root-node asks for the root node of the parser, which triggers a reparse, because last indent modified the buffer. We are basically reparsing as many time as there are lines in the buffer.

Indenting a similarly sized buffer where all indent are good is much faster, because there is no reparse due to change to the buffer.

Tree-sitter indent should add an implementation for indent-for-region function which precomputes indent for each line and indent lines in batch. That ought to fix it. Added to TODO :-)

Yuan


^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-28 19:43           ` Yuan Fu
@ 2022-10-28 19:49             ` Theodor Thornhill
  2022-10-29  1:05               ` Yuan Fu
  2022-10-29  5:53             ` Eli Zaretskii
  1 sibling, 1 reply; 14+ messages in thread
From: Theodor Thornhill @ 2022-10-28 19:49 UTC (permalink / raw)
  To: Yuan Fu; +Cc: emacs-devel, Stefan Monnier


>> 
>
> Ok, I’m fairly certain this is due to tree-sitter reparsing after we
> indenting each line: treesit-buffer-root-node asks for the root node
> of the parser, which triggers a reparse, because last indent modified
> the buffer. We are basically reparsing as many time as there are lines
> in the buffer.
>
> Indenting a similarly sized buffer where all indent are good is much
> faster, because there is no reparse due to change to the buffer.

Yeah, that's what I was seeing as well. I think this is correct.
>
> Tree-sitter indent should add an implementation for indent-for-region
> function which precomputes indent for each line and indent lines in
> batch. That ought to fix it. Added to TODO :-)

Hehe, sorry!

Theo





^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-28 19:49             ` Theodor Thornhill
@ 2022-10-29  1:05               ` Yuan Fu
  0 siblings, 0 replies; 14+ messages in thread
From: Yuan Fu @ 2022-10-29  1:05 UTC (permalink / raw)
  To: Theodor Thornhill; +Cc: emacs-devel, Stefan Monnier



> On Oct 28, 2022, at 12:49 PM, Theodor Thornhill <theo@thornhill.no> wrote:
> 
> 
>>> 
>> 
>> Ok, I’m fairly certain this is due to tree-sitter reparsing after we
>> indenting each line: treesit-buffer-root-node asks for the root node
>> of the parser, which triggers a reparse, because last indent modified
>> the buffer. We are basically reparsing as many time as there are lines
>> in the buffer.
>> 
>> Indenting a similarly sized buffer where all indent are good is much
>> faster, because there is no reparse due to change to the buffer.
> 
> Yeah, that's what I was seeing as well. I think this is correct.
>> 
>> Tree-sitter indent should add an implementation for indent-for-region
>> function which precomputes indent for each line and indent lines in
>> batch. That ought to fix it. Added to TODO :-)
> 
> Hehe, sorry!

Now done. Tree-sitter’s indentation is now slightly faster than cc-mode’s. There are certainly still room for improvement, around 70% time are spent in evaluating each indentation rules. In the future we could introduce a preprocessor for indentation rules like the one for font-lock rules which can pro-compile the rules’s higher order functions. And maybe we can optimize the way we layout the rules slightly.

Yuan


^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-28 19:43           ` Yuan Fu
  2022-10-28 19:49             ` Theodor Thornhill
@ 2022-10-29  5:53             ` Eli Zaretskii
  2022-10-29  6:54               ` Yuan Fu
  1 sibling, 1 reply; 14+ messages in thread
From: Eli Zaretskii @ 2022-10-29  5:53 UTC (permalink / raw)
  To: Yuan Fu; +Cc: theo, emacs-devel, monnier

> From: Yuan Fu <casouri@gmail.com>
> Date: Fri, 28 Oct 2022 12:43:31 -0700
> Cc: emacs-devel <emacs-devel@gnu.org>,
>  Stefan Monnier <monnier@iro.umontreal.ca>
> 
> Tree-sitter indent should add an implementation for indent-for-region function which precomputes indent for each line and indent lines in batch. That ought to fix it. Added to TODO :-)

I think this conclusion should be also in the manual, where we
describe how to provide indentation capabilities based on tree-sitter?



^ permalink raw reply	[flat|nested] 14+ messages in thread

* Re: Tree-sitter indentation for js-mode & cc-mode
  2022-10-29  5:53             ` Eli Zaretskii
@ 2022-10-29  6:54               ` Yuan Fu
  0 siblings, 0 replies; 14+ messages in thread
From: Yuan Fu @ 2022-10-29  6:54 UTC (permalink / raw)
  To: Eli Zaretskii; +Cc: Theodor Thornhill, emacs-devel, monnier



> On Oct 28, 2022, at 10:53 PM, Eli Zaretskii <eliz@gnu.org> wrote:
> 
>> From: Yuan Fu <casouri@gmail.com>
>> Date: Fri, 28 Oct 2022 12:43:31 -0700
>> Cc: emacs-devel <emacs-devel@gnu.org>,
>> Stefan Monnier <monnier@iro.umontreal.ca>
>> 
>> Tree-sitter indent should add an implementation for indent-for-region function which precomputes indent for each line and indent lines in batch. That ought to fix it. Added to TODO :-)
> 
> I think this conclusion should be also in the manual, where we
> describe how to provide indentation capabilities based on tree-sitter?

Ah, yes, thanks for reminding me. I have some new things to add to the major modes section (and some to remove).

Yuan


^ permalink raw reply	[flat|nested] 14+ messages in thread

end of thread, other threads:[~2022-10-29  6:54 UTC | newest]

Thread overview: 14+ messages (download: mbox.gz follow: Atom feed
-- links below jump to the message on this page --
2022-10-27  1:43 Tree-sitter indentation for js-mode & cc-mode Yuan Fu
2022-10-27  9:11 ` Theodor Thornhill
2022-10-27  9:28   ` Theodor Thornhill
2022-10-27  9:58     ` Theodor Thornhill
2022-10-27 15:21   ` Yuan Fu
2022-10-27 18:36     ` Theodor Thornhill
2022-10-28  8:15       ` Yuan Fu
2022-10-28  8:59         ` Theodor Thornhill
2022-10-28  9:10         ` Theodor Thornhill
2022-10-28 19:43           ` Yuan Fu
2022-10-28 19:49             ` Theodor Thornhill
2022-10-29  1:05               ` Yuan Fu
2022-10-29  5:53             ` Eli Zaretskii
2022-10-29  6:54               ` Yuan Fu

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