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| | ;;; rx.el --- sexp notation for regular expressions -*- lexical-binding: t -*-
;; Copyright (C) 2001-2019 Free Software Foundation, Inc.
;; Author: Gerd Moellmann <gerd@gnu.org>
;; Maintainer: emacs-devel@gnu.org
;; Keywords: strings, regexps, extensions
;; This file is part of GNU Emacs.
;; GNU Emacs is free software: you can redistribute it and/or modify
;; it under the terms of the GNU General Public License as published by
;; the Free Software Foundation, either version 3 of the License, or
;; (at your option) any later version.
;; GNU Emacs is distributed in the hope that it will be useful,
;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
;; GNU General Public License for more details.
;; You should have received a copy of the GNU General Public License
;; along with GNU Emacs. If not, see <https://www.gnu.org/licenses/>.
;;; Commentary:
;; This is another implementation of sexp-form regular expressions.
;; It was unfortunately written without being aware of the Sregex
;; package coming with Emacs, but as things stand, Rx completely
;; covers all regexp features, which Sregex doesn't, doesn't suffer
;; from the bugs mentioned in the commentary section of Sregex, and
;; uses a nicer syntax (IMHO, of course :-).
;; This significantly extended version of the original, is almost
;; compatible with Sregex. The only incompatibility I (fx) know of is
;; that the `repeat' form can't have multiple regexp args.
;; Now alternative forms are provided for a degree of compatibility
;; with Olin Shivers' attempted definitive SRE notation. SRE forms
;; not catered for include: dsm, uncase, w/case, w/nocase, ,@<exp>,
;; ,<exp>, (word ...), word+, posix-string, and character class forms.
;; Some forms are inconsistent with SRE, either for historical reasons
;; or because of the implementation -- simple translation into Emacs
;; regexp strings. These include: any, word. Also, case-sensitivity
;; and greediness are controlled by variables external to the regexp,
;; and you need to feed the forms to the `posix-' functions to get
;; SRE's POSIX semantics. There are probably more difficulties.
;; Rx translates a sexp notation for regular expressions into the
;; usual string notation. The translation can be done at compile-time
;; by using the `rx' macro. The `regexp' and `literal' forms accept
;; non-constant expressions, in which case `rx' will translate to a
;; `concat' expression. Translation can be done fully at run-time by
;; calling function `rx-to-string'. See the documentation of `rx' for
;; a complete description of the sexp notation.
;;
;; Some examples of string regexps and their sexp counterparts:
;;
;; "^[a-z]*"
;; (rx (and line-start (0+ (in "a-z"))))
;;
;; "\n[^ \t]"
;; (rx (and "\n" (not (any " \t"))))
;;
;; "\\*\\*\\* EOOH \\*\\*\\*\n"
;; (rx "*** EOOH ***\n")
;;
;; "\\<\\(catch\\|finally\\)\\>[^_]"
;; (rx (and word-start (submatch (or "catch" "finally")) word-end
;; (not (any ?_))))
;;
;; "[ \t\n]*:\\([^:]+\\|$\\)"
;; (rx (and (zero-or-more (in " \t\n")) ":"
;; (submatch (or line-end (one-or-more (not (any ?:)))))))
;;
;; "^content-transfer-encoding:\\(\n?[\t ]\\)*quoted-printable\\(\n?[\t ]\\)*"
;; (rx (and line-start
;; "content-transfer-encoding:"
;; (+ (? ?\n)) (any " \t")
;; "quoted-printable"
;; (+ (? ?\n)) (any " \t"))
;;
;; (concat "^\\(?:" something-else "\\)")
;; (rx (and line-start (regexp something-else))), statically or
;; (rx-to-string `(and line-start ,something-else)), dynamically.
;;
;; (regexp-opt '(STRING1 STRING2 ...))
;; (rx (or STRING1 STRING2 ...)), or in other words, `or' automatically
;; calls `regexp-opt' as needed.
;;
;; "^;;\\s-*\n\\|^\n"
;; (rx (or (and line-start ";;" (0+ space) ?\n)
;; (and line-start ?\n)))
;;
;; "\\$[I]d: [^ ]+ \\([^ ]+\\) "
;; (rx (and "$Id: "
;; (1+ (not (in " ")))
;; " "
;; (submatch (1+ (not (in " "))))
;; " "))
;;
;; "\\\\\\\\\\[\\w+"
;; (rx (and ?\\ ?\\ ?\[ (1+ word)))
;;
;; etc.
;;; History:
;;
;;; Code:
(require 'cl-lib)
(require 'cl-extra)
;; FIXME: support macros.
(defvar rx-constituents ;Not `const' because some modes extend it.
'((and . (rx-and 0 nil))
(seq . and) ; SRE
(: . and) ; SRE
(sequence . and) ; sregex
(or . (rx-or 0 nil))
(| . or) ; SRE
(not-newline . ".")
(nonl . not-newline) ; SRE
(anything . (rx-anything 0 nil))
(any . (rx-any 1 nil rx-check-any)) ; inconsistent with SRE
(any . ".") ; sregex
(in . any)
(char . any) ; sregex
(not-char . (rx-not-char 1 nil rx-check-any)) ; sregex
(not . (rx-not 1 1 rx-check-not))
(repeat . (rx-repeat 2 nil))
(= . (rx-= 2 nil)) ; SRE
(>= . (rx->= 2 nil)) ; SRE
(** . (rx-** 2 nil)) ; SRE
(submatch . (rx-submatch 1 nil)) ; SRE
(group . submatch) ; sregex
(submatch-n . (rx-submatch-n 2 nil))
(group-n . submatch-n)
(zero-or-more . (rx-kleene 1 nil))
(one-or-more . (rx-kleene 1 nil))
(zero-or-one . (rx-kleene 1 nil))
(\? . zero-or-one) ; SRE
(\?? . zero-or-one)
(* . zero-or-more) ; SRE
(*? . zero-or-more)
(0+ . zero-or-more)
(+ . one-or-more) ; SRE
(+? . one-or-more)
(1+ . one-or-more)
(optional . zero-or-one)
(opt . zero-or-one) ; sregex
(minimal-match . (rx-greedy 1 1))
(maximal-match . (rx-greedy 1 1))
(backref . (rx-backref 1 1 rx-check-backref))
(line-start . "^")
(bol . line-start) ; SRE
(line-end . "$")
(eol . line-end) ; SRE
(string-start . "\\`")
(bos . string-start) ; SRE
(bot . string-start) ; sregex
(string-end . "\\'")
(eos . string-end) ; SRE
(eot . string-end) ; sregex
(buffer-start . "\\`")
(buffer-end . "\\'")
(point . "\\=")
(word-start . "\\<")
(bow . word-start) ; SRE
(word-end . "\\>")
(eow . word-end) ; SRE
(word-boundary . "\\b")
(not-word-boundary . "\\B") ; sregex
(symbol-start . "\\_<")
(symbol-end . "\\_>")
(syntax . (rx-syntax 1 1))
(not-syntax . (rx-not-syntax 1 1)) ; sregex
(category . (rx-category 1 1 rx-check-category))
(eval . (rx-eval 1 1))
(literal . (rx-literal 1 1 stringp))
(regexp . (rx-regexp 1 1 stringp))
(regex . regexp) ; sregex
(digit . "[[:digit:]]")
(numeric . digit) ; SRE
(num . digit) ; SRE
(control . "[[:cntrl:]]") ; SRE
(cntrl . control) ; SRE
(hex-digit . "[[:xdigit:]]") ; SRE
(hex . hex-digit) ; SRE
(xdigit . hex-digit) ; SRE
(blank . "[[:blank:]]") ; SRE
(graphic . "[[:graph:]]") ; SRE
(graph . graphic) ; SRE
(printing . "[[:print:]]") ; SRE
(print . printing) ; SRE
(alphanumeric . "[[:alnum:]]") ; SRE
(alnum . alphanumeric) ; SRE
(letter . "[[:alpha:]]")
(alphabetic . letter) ; SRE
(alpha . letter) ; SRE
(ascii . "[[:ascii:]]") ; SRE
(nonascii . "[[:nonascii:]]")
(lower . "[[:lower:]]") ; SRE
(lower-case . lower) ; SRE
(punctuation . "[[:punct:]]") ; SRE
(punct . punctuation) ; SRE
(space . "[[:space:]]") ; SRE
(whitespace . space) ; SRE
(white . space) ; SRE
(upper . "[[:upper:]]") ; SRE
(upper-case . upper) ; SRE
(word . "[[:word:]]") ; inconsistent with SRE
(wordchar . word) ; sregex
(not-wordchar . "\\W"))
"Alist of sexp form regexp constituents.
Each element of the alist has the form (SYMBOL . DEFN).
SYMBOL is a valid constituent of sexp regular expressions.
If DEFN is a string, SYMBOL is translated into DEFN.
If DEFN is a symbol, use the definition of DEFN, recursively.
Otherwise, DEFN must be a list (FUNCTION MIN-ARGS MAX-ARGS PREDICATE).
FUNCTION is used to produce code for SYMBOL. MIN-ARGS and MAX-ARGS
are the minimum and maximum number of arguments the function-form
sexp constituent SYMBOL may have in sexp regular expressions.
MAX-ARGS nil means no limit. PREDICATE, if specified, means that
all arguments must satisfy PREDICATE.")
(defconst rx-syntax
'((whitespace . ?-)
(punctuation . ?.)
(word . ?w)
(symbol . ?_)
(open-parenthesis . ?\()
(close-parenthesis . ?\))
(expression-prefix . ?\')
(string-quote . ?\")
(paired-delimiter . ?$)
(escape . ?\\)
(character-quote . ?/)
(comment-start . ?<)
(comment-end . ?>)
(string-delimiter . ?|)
(comment-delimiter . ?!))
"Alist mapping Rx syntax symbols to syntax characters.
Each entry has the form (SYMBOL . CHAR), where SYMBOL is a valid
symbol in `(syntax SYMBOL)', and CHAR is the syntax character
corresponding to SYMBOL, as it would be used with \\s or \\S in
regular expressions.")
(defconst rx-categories
'((space-for-indent . ?\s)
(base . ?.)
(consonant . ?0)
(base-vowel . ?1)
(upper-diacritical-mark . ?2)
(lower-diacritical-mark . ?3)
(tone-mark . ?4)
(symbol . ?5)
(digit . ?6)
(vowel-modifying-diacritical-mark . ?7)
(vowel-sign . ?8)
(semivowel-lower . ?9)
(not-at-end-of-line . ?<)
(not-at-beginning-of-line . ?>)
(alpha-numeric-two-byte . ?A)
(chinese-two-byte . ?C)
(chinse-two-byte . ?C) ;; A typo in Emacs 21.1-24.3.
(greek-two-byte . ?G)
(japanese-hiragana-two-byte . ?H)
(indian-two-byte . ?I)
(japanese-katakana-two-byte . ?K)
(strong-left-to-right . ?L)
(korean-hangul-two-byte . ?N)
(strong-right-to-left . ?R)
(cyrillic-two-byte . ?Y)
(combining-diacritic . ?^)
(ascii . ?a)
(arabic . ?b)
(chinese . ?c)
(ethiopic . ?e)
(greek . ?g)
(korean . ?h)
(indian . ?i)
(japanese . ?j)
(japanese-katakana . ?k)
(latin . ?l)
(lao . ?o)
(tibetan . ?q)
(japanese-roman . ?r)
(thai . ?t)
(vietnamese . ?v)
(hebrew . ?w)
(cyrillic . ?y)
(can-break . ?|))
"Alist mapping symbols to category characters.
Each entry has the form (SYMBOL . CHAR), where SYMBOL is a valid
symbol in `(category SYMBOL)', and CHAR is the category character
corresponding to SYMBOL, as it would be used with `\\c' or `\\C' in
regular expression strings.")
(defvar rx-greedy-flag t
"Non-nil means produce greedy regular expressions for `zero-or-one',
`zero-or-more', and `one-or-more'. Dynamically bound.")
(defvar rx--compile-to-lisp nil
"Nil means return a regexp as a string.
Non-nil means we may return a lisp form which produces a
string (used for `rx' macro).")
(defun rx-info (op head)
"Return parsing/code generation info for OP.
If OP is the space character ASCII 32, return info for the symbol `?'.
If OP is the character `?', return info for the symbol `??'.
See also `rx-constituents'.
If HEAD is non-nil, then OP is the head of a sexp, otherwise it's
a standalone symbol."
(cond ((eq op ? ) (setq op '\?))
((eq op ??) (setq op '\??)))
(let (old-op)
(while (and (not (null op)) (symbolp op))
(setq old-op op)
(setq op (cdr (assq op rx-constituents)))
(when (if head (stringp op) (consp op))
;; We found something but of the wrong kind. Let's look for an
;; alternate definition for the other case.
(let ((new-op
(cdr (assq old-op (cdr (memq (assq old-op rx-constituents)
rx-constituents))))))
(if (and new-op (not (if head (stringp new-op) (consp new-op))))
(setq op new-op))))))
op)
(defun rx-check (form)
"Check FORM according to its car's parsing info."
(unless (listp form)
(error "rx `%s' needs argument(s)" form))
(let* ((rx (rx-info (car form) 'head))
(nargs (1- (length form)))
(min-args (nth 1 rx))
(max-args (nth 2 rx))
(type-pred (nth 3 rx)))
(when (and (not (null min-args))
(< nargs min-args))
(error "rx form `%s' requires at least %d args"
(car form) min-args))
(when (and (not (null max-args))
(> nargs max-args))
(error "rx form `%s' accepts at most %d args"
(car form) max-args))
(when type-pred
(dolist (sub-form (cdr form))
(unless (funcall type-pred sub-form)
(error "rx form `%s' requires args satisfying `%s'"
(car form) type-pred))))))
(defun rx-group-if (regexp group)
"Put shy groups around REGEXP if seemingly necessary when GROUP
is non-nil."
(cond
;; for some repetition
((eq group '*) (if (rx-atomic-p regexp) (setq group nil)))
;; for concatenation
((eq group ':)
(if (rx-atomic-p
(if (and (stringp regexp)
(string-match
"\\(?:[?*+]\\??\\|\\\\{[0-9]*,?[0-9]*\\\\}\\)\\'" regexp))
(substring regexp 0 (match-beginning 0))
regexp))
(setq group nil)))
;; for OR
((eq group '|) (setq group nil))
;; do anyway
((eq group t))
((rx-atomic-p regexp t) (setq group nil)))
(cond ((and group (stringp regexp))
(concat "\\(?:" regexp "\\)"))
(group `("\\(?:" ,@regexp "\\)"))
(t regexp)))
(defvar rx-parent)
;; dynamically bound in some functions.
(defun rx-and (form)
"Parse and produce code from FORM.
FORM is of the form `(and FORM1 ...)'."
(rx-check form)
(rx-group-if
(rx-subforms (cdr form) ':)
(and (memq rx-parent '(* t)) rx-parent)))
(defun rx-or (form)
"Parse and produce code from FORM, which is `(or FORM1 ...)'."
(rx-check form)
(rx-group-if
(cond
((null (cdr form)) regexp-unmatchable)
((cl-every #'stringp (cdr form))
(regexp-opt (cdr form) nil t))
(t (rx-subforms (cdr form) '| "\\|")))
(and (memq rx-parent '(: * t)) rx-parent)))
(defun rx-anything (form)
"Match any character."
(if (consp form)
(error "rx `anything' syntax error: %s" form))
(rx-or (list 'or 'not-newline ?\n)))
(defun rx-any-delete-from-range (char ranges)
"Delete by side effect character CHAR from RANGES.
Only both edges of each range is checked."
(let (m)
(cond
((memq char ranges) (setq ranges (delq char ranges)))
((setq m (assq char ranges))
(if (eq (1+ char) (cdr m))
(setcar (memq m ranges) (1+ char))
(setcar m (1+ char))))
((setq m (rassq char ranges))
(if (eq (1- char) (car m))
(setcar (memq m ranges) (1- char))
(setcdr m (1- char)))))
ranges))
(defun rx-any-condense-range (args)
"Condense by side effect ARGS as range for Rx `any'."
(let (str
l)
;; set STR list of all strings
;; set L list of all ranges
(mapc (lambda (e) (cond ((stringp e) (push e str))
((numberp e) (push (cons e e) l))
;; Ranges between ASCII and raw bytes are split,
;; to prevent accidental inclusion of Unicode
;; characters later on.
((and (<= (car e) #x7f)
(>= (cdr e) #x3fff80))
(push (cons (car e) #x7f) l)
(push (cons #x3fff80 (cdr e)) l))
(t (push e l))))
args)
;; condense overlapped ranges in L
(let ((tail (setq l (sort l #'car-less-than-car)))
d)
(while (setq d (cdr tail))
(if (>= (cdar tail) (1- (caar d)))
(progn
(setcdr (car tail) (max (cdar tail) (cdar d)))
(setcdr tail (cdr d)))
(setq tail d))))
;; Separate small ranges to single number, and delete dups.
(nconc
(apply #'nconc
(mapcar (lambda (e)
(cond
((= (car e) (cdr e)) (list (car e)))
((= (1+ (car e)) (cdr e)) (list (car e) (cdr e)))
((list e))))
l))
(delete-dups str))))
(defun rx-check-any-string (str)
"Turn the `any' argument string STR into a list of characters.
The original order is not preserved. Ranges, \"A-Z\", become pairs, (?A . ?Z)."
(let ((decode-char
;; Make sure raw bytes are decoded as such, to avoid confusion with
;; U+0080..U+00FF.
(if (multibyte-string-p str)
#'identity
(lambda (c) (if (<= #x80 c #xff)
(+ c #x3fff00)
c))))
(len (length str))
(i 0)
(ret nil))
(if (= 0 len)
(error "String arg for Rx `any' must not be empty"))
(while (< i len)
(cond ((and (< i (- len 2))
(= (aref str (+ i 1)) ?-))
;; Range.
(let ((start (funcall decode-char (aref str i)))
(end (funcall decode-char (aref str (+ i 2)))))
(cond ((< start end) (push (cons start end) ret))
((= start end) (push start ret))
(t
(error "Rx character range `%c-%c' is reversed"
start end)))
(setq i (+ i 3))))
(t
;; Single character.
(push (funcall decode-char (aref str i)) ret)
(setq i (+ i 1)))))
ret))
(defun rx-check-any (arg)
"Check arg ARG for Rx `any'."
(cond
((integerp arg) (list arg))
((symbolp arg)
(let ((translation (condition-case nil
(rx-form arg)
(error nil))))
(if (or (null translation)
(null (string-match "\\`\\[\\[:[-a-z]+:\\]\\]\\'" translation)))
(error "Invalid char class `%s' in Rx `any'" arg))
(list (substring translation 1 -1)))) ; strip outer brackets
((and (characterp (car-safe arg)) (characterp (cdr-safe arg)))
(unless (<= (car arg) (cdr arg))
(error "Rx character range `%c-%c' is reversed"
(car arg) (cdr arg)))
(list arg))
((stringp arg) (rx-check-any-string arg))
((error
"rx `any' requires string, character, char pair or char class args"))))
(defun rx-any (form)
"Parse and produce code from FORM, which is `(any ARG ...)'.
ARG is optional."
(rx-check form)
(let* ((args (rx-any-condense-range
(apply
#'nconc
(mapcar #'rx-check-any (cdr form)))))
m
s)
(cond
;; single close bracket
;; => "[]...-]" or "[]...--.]"
((memq ?\] args)
;; set ] at the beginning
(setq args (cons ?\] (delq ?\] args)))
;; set - at the end
(if (or (memq ?- args) (assq ?- args))
(setq args (nconc (rx-any-delete-from-range ?- args)
(list ?-)))))
;; close bracket starts a range
;; => "[]-....-]" or "[]-.--....]"
((setq m (assq ?\] args))
;; bring it to the beginning
(setq args (cons m (delq m args)))
(cond ((memq ?- args)
;; to the end
(setq args (nconc (delq ?- args) (list ?-))))
((setq m (assq ?- args))
;; next to the bracket's range, make the second range
(setcdr args (cons m (delq m (cdr args)))))))
;; bracket in the end range
;; => "[]...-]"
((setq m (rassq ?\] args))
;; set ] at the beginning
(setq args (cons ?\] (rx-any-delete-from-range ?\] args)))
;; set - at the end
(if (or (memq ?- args) (assq ?- args))
(setq args (nconc (rx-any-delete-from-range ?- args)
(list ?-)))))
;; {no close bracket appears}
;;
;; bring single bar to the beginning
((memq ?- args)
(setq args (cons ?- (delq ?- args))))
;; bar start a range, bring it to the beginning
((setq m (assq ?- args))
(setq args (cons m (delq m args))))
;;
;; hat at the beginning?
((or (eq (car args) ?^) (eq (car-safe (car args)) ?^))
(setq args (if (cdr args)
`(,(cadr args) ,(car args) ,@(cddr args))
(nconc (rx-any-delete-from-range ?^ args)
(list ?^))))))
;; some 1-char?
(if (and (null (cdr args)) (numberp (car args))
(or (= 1 (length
(setq s (regexp-quote (string (car args))))))
(and (equal (car args) ?^) ;; unnecessary predicate?
(null (eq rx-parent '!)))))
s
(concat "["
(mapconcat
(lambda (e) (cond
((numberp e) (string e))
((consp e)
(if (and (= (1+ (car e)) (cdr e))
;; rx-any-condense-range should
;; prevent this case from happening.
(null (memq (car e) '(?\] ?-)))
(null (memq (cdr e) '(?\] ?-))))
(string (car e) (cdr e))
(string (car e) ?- (cdr e))))
(e)))
args
nil)
"]"))))
(defun rx-check-not (arg)
"Check arg ARG for Rx `not'."
(unless (or (and (symbolp arg)
(string-match "\\`\\[\\[:[-a-z]+:\\]\\]\\'"
(condition-case nil
(rx-form arg)
(error ""))))
(eq arg 'word-boundary)
(and (consp arg)
(memq (car arg) '(not any in syntax category))))
(error "rx `not' syntax error: %s" arg))
t)
(defun rx-not (form)
"Parse and produce code from FORM. FORM is `(not ...)'."
(rx-check form)
(let ((result (rx-form (cadr form) '!))
case-fold-search)
(cond ((string-match "\\`\\[\\^" result)
(cond
((equal result "[^]") "[^^]")
((and (= (length result) 4) (null (eq rx-parent '!)))
(regexp-quote (substring result 2 3)))
((concat "[" (substring result 2)))))
((eq ?\[ (aref result 0))
(concat "[^" (substring result 1)))
((string-match "\\`\\\\[scbw]" result)
(concat (upcase (substring result 0 2))
(substring result 2)))
((string-match "\\`\\\\[SCBW]" result)
(concat (downcase (substring result 0 2))
(substring result 2)))
(t
(concat "[^" result "]")))))
(defun rx-not-char (form)
"Parse and produce code from FORM. FORM is `(not-char ...)'."
(rx-check form)
(rx-not `(not (in ,@(cdr form)))))
(defun rx-not-syntax (form)
"Parse and produce code from FORM. FORM is `(not-syntax SYNTAX)'."
(rx-check form)
(rx-not `(not (syntax ,@(cdr form)))))
(defun rx-trans-forms (form &optional skip)
"If FORM's length is greater than two, transform it to length two.
A form (HEAD REST ...) becomes (HEAD (and REST ...)).
If SKIP is non-nil, allow that number of items after the head, i.e.
`(= N REST ...)' becomes `(= N (and REST ...))' if SKIP is 1."
(unless skip (setq skip 0))
(let ((tail (nthcdr (1+ skip) form)))
(if (= (length tail) 1)
form
(let ((form (copy-sequence form)))
(setcdr (nthcdr skip form) (list (cons 'and tail)))
form))))
(defun rx-= (form)
"Parse and produce code from FORM `(= N ...)'."
(rx-check form)
(setq form (rx-trans-forms form 1))
(unless (and (integerp (nth 1 form))
(> (nth 1 form) 0))
(error "rx `=' requires positive integer first arg"))
(let ((subform (rx-form (nth 2 form) '*)))
(if (stringp subform)
(format "%s\\{%d\\}" subform (nth 1 form))
`(,@subform ,(format "\\{%d\\}" (nth 1 form))))))
(defun rx->= (form)
"Parse and produce code from FORM `(>= N ...)'."
(rx-check form)
(setq form (rx-trans-forms form 1))
(unless (and (integerp (nth 1 form))
(> (nth 1 form) 0))
(error "rx `>=' requires positive integer first arg"))
(let ((subform (rx-form (nth 2 form) '*)))
(if (stringp subform)
(format "%s\\{%d,\\}" subform (nth 1 form))
`(,@subform ,(format "\\{%d,\\}" (nth 1 form))))))
(defun rx-** (form)
"Parse and produce code from FORM `(** N M ...)'."
(rx-check form)
(rx-form (cons 'repeat (cdr (rx-trans-forms form 2))) '*))
(defun rx-repeat (form)
"Parse and produce code from FORM.
FORM is either `(repeat N FORM1)' or `(repeat N M FORMS...)'."
(rx-check form)
(if (> (length form) 4)
(setq form (rx-trans-forms form 2)))
(if (null (nth 2 form))
(setq form (cons (nth 0 form) (cons (nth 1 form) (nthcdr 3 form)))))
(cond ((= (length form) 3)
(unless (and (integerp (nth 1 form))
(> (nth 1 form) 0))
(error "rx `repeat' requires positive integer first arg"))
(let ((subform (rx-form (nth 2 form) '*)))
(if (stringp subform)
(format "%s\\{%d\\}" subform (nth 1 form))
`(,@subform ,(format "\\{%d\\}" (nth 1 form))))))
((or (not (integerp (nth 2 form)))
(< (nth 2 form) 0)
(not (integerp (nth 1 form)))
(< (nth 1 form) 0)
(< (nth 2 form) (nth 1 form)))
(error "rx `repeat' range error"))
(t
(let ((subform (rx-form (nth 3 form) '*)))
(if (stringp subform)
(format "%s\\{%d,%d\\}" subform (nth 1 form) (nth 2 form))
`(,@subform ,(format "\\{%d,%d\\}" (nth 1 form) (nth 2 form))))))))
(defun rx-submatch (form)
"Parse and produce code from FORM, which is `(submatch ...)'."
(let ((subforms (rx-subforms (cdr form) ':)))
(if (stringp subforms)
(concat "\\(" subforms "\\)")
`("\\(" ,@subforms "\\)"))))
(defun rx-submatch-n (form)
"Parse and produce code from FORM, which is `(submatch-n N ...)'."
(let ((n (nth 1 form))
(subforms (rx-subforms (cddr form) ':)))
(if (stringp subforms)
(concat "\\(?" (number-to-string n) ":" subforms "\\)")
`("\\(?" ,(number-to-string n) ":" ,@subforms "\\)"))))
(defun rx-backref (form)
"Parse and produce code from FORM, which is `(backref N)'."
(rx-check form)
(format "\\%d" (nth 1 form)))
(defun rx-check-backref (arg)
"Check arg ARG for Rx `backref'."
(or (and (integerp arg) (>= arg 1) (<= arg 9))
(error "rx `backref' requires numeric 1<=arg<=9: %s" arg)))
(defun rx-kleene (form)
"Parse and produce code from FORM.
FORM is `(OP FORM1)', where OP is one of the `zero-or-one',
`zero-or-more' etc. operators.
If OP is one of `*', `+', `?', produce a greedy regexp.
If OP is one of `*?', `+?', `??', produce a non-greedy regexp.
If OP is anything else, produce a greedy regexp if `rx-greedy-flag'
is non-nil."
(rx-check form)
(setq form (rx-trans-forms form))
(let ((suffix (cond ((memq (car form) '(* + \? ?\s)) "")
((memq (car form) '(*? +? \?? ??)) "?")
(rx-greedy-flag "")
(t "?")))
(op (cond ((memq (car form) '(* *? 0+ zero-or-more)) "*")
((memq (car form) '(+ +? 1+ one-or-more)) "+")
(t "?")))
(subform (rx-form (cadr form) '*)))
(rx-group-if
(if (stringp subform)
(concat subform op suffix)
`(,@subform ,(concat op suffix)))
(and (memq rx-parent '(t *)) rx-parent))))
(defun rx-atomic-p (r &optional lax)
"Return non-nil if regexp string R is atomic.
An atomic regexp R is one such that a suffix operator
appended to R will apply to all of R. For example, \"a\"
\"[abc]\" and \"\\(ab\\|ab*c\\)\" are atomic and \"ab\",
\"[ab]c\", and \"ab\\|ab*c\" are not atomic.
This function may return false negatives, but it will not
return false positives. It is nevertheless useful in
situations where an efficiency shortcut can be taken only if a
regexp is atomic. The function can be improved to detect
more cases of atomic regexps. Presently, this function
detects the following categories of atomic regexp;
a group or shy group: \\(...\\)
a character class: [...]
a single character: a
On the other hand, false negatives will be returned for
regexps that are atomic but end in operators, such as
\"a+\". I think these are rare. Probably such cases could
be detected without much effort. A guarantee of no false
negatives would require a theoretic specification of the set
of all atomic regexps."
(if (and rx--compile-to-lisp
(not (stringp r)))
nil ;; Runtime value, we must assume non-atomic.
(let ((l (length r)))
(cond
((<= l 1))
((= l 2) (= (aref r 0) ?\\))
((= l 3) (string-match "\\`\\(?:\\\\[cCsS_]\\|\\[[^^]\\]\\)" r))
((null lax)
(cond
((string-match "\\`\\[\\^?]?\\(?:\\[:[a-z]+:]\\|[^]]\\)*]\\'" r))
((string-match "\\`\\\\(\\(?:[^\\]\\|\\\\[^)]\\)*\\\\)\\'" r))))))))
(defun rx-syntax (form)
"Parse and produce code from FORM, which is `(syntax SYMBOL)'."
(rx-check form)
(let* ((sym (cadr form))
(syntax (cdr (assq sym rx-syntax))))
(unless syntax
;; Try sregex compatibility.
(cond
((characterp sym) (setq syntax sym))
((symbolp sym)
(let ((name (symbol-name sym)))
(if (= 1 (length name))
(setq syntax (aref name 0))))))
(unless syntax
(error "Unknown rx syntax `%s'" sym)))
(format "\\s%c" syntax)))
(defun rx-check-category (form)
"Check the argument FORM of a `(category FORM)'."
(unless (or (integerp form)
(cdr (assq form rx-categories)))
(error "Unknown category `%s'" form))
t)
(defun rx-category (form)
"Parse and produce code from FORM, which is `(category SYMBOL)'."
(rx-check form)
(let ((char (if (integerp (cadr form))
(cadr form)
(cdr (assq (cadr form) rx-categories)))))
(format "\\c%c" char)))
(defun rx-eval (form)
"Parse and produce code from FORM, which is `(eval FORM)'."
(rx-check form)
(rx-form (eval (cadr form)) rx-parent))
(defun rx-greedy (form)
"Parse and produce code from FORM.
If FORM is `(minimal-match FORM1)', non-greedy versions of `*',
`+', and `?' operators will be used in FORM1. If FORM is
`(maximal-match FORM1)', greedy operators will be used."
(rx-check form)
(let ((rx-greedy-flag (eq (car form) 'maximal-match)))
(rx-form (cadr form) rx-parent)))
(defun rx-regexp (form)
"Parse and produce code from FORM, which is `(regexp STRING)'."
(cond ((stringp form)
(rx-group-if (cadr form) rx-parent))
(rx--compile-to-lisp
;; Always group non string forms, since we can't be sure they
;; are atomic.
(rx-group-if (cdr form) t))
(t (rx-check form))))
(defun rx-literal (form)
"Parse and produce code from FORM, which is `(literal STRING-EXP)'."
(cond ((stringp form)
;; This is allowed(?), but makes little sense, you could just
;; use STRING directly.
(rx-group-if (regexp-quote (cadr form)) rx-parent))
(rx--compile-to-lisp
(rx-group-if `((regexp-quote ,(cadr form))) rx-parent))
(t (rx-check form))))
(defun rx-form (form &optional parent)
"Parse and produce code for regular expression FORM.
FORM is a regular expression in sexp form.
PARENT shows which type of expression calls and controls putting of
shy groups around the result and some more in other functions."
(let ((rx-parent parent))
(cond
((stringp form)
(rx-group-if (regexp-quote form)
(if (and (eq parent '*) (< 1 (length form)))
parent)))
((integerp form)
(regexp-quote (char-to-string form)))
((symbolp form)
(let ((info (rx-info form nil)))
(cond ((stringp info)
info)
((null info)
(error "Unknown rx form `%s'" form))
(t
(funcall (nth 0 info) form)))))
((consp form)
(let ((info (rx-info (car form) 'head)))
(unless (consp info)
(error "Unknown rx form `%s'" (car form)))
(funcall (nth 0 info) form)))
(t
(error "rx syntax error at `%s'" form)))))
(defun rx-subforms (subforms &optional parent regexp-op)
(let ((listify (lambda (x)
(if (listp x) (copy-sequence x)
(list x))))
(subregexps (cond ((cdr subforms)
(mapcar (lambda (x) (rx-form x parent)) subforms))
(subforms
;; Single form, no need for grouping.
(list (rx-form (car subforms))))
;; Zero forms.
(t ""))))
(cond ((or (not rx--compile-to-lisp)
(cl-every #'stringp subregexps))
(mapconcat #'identity subregexps regexp-op))
(regexp-op
(nconc (funcall listify (car subregexps))
(cl-mapcan (lambda (x)
(cons regexp-op (funcall listify x)))
(cdr subregexps))))
(t (cl-mapcan listify subregexps)))))
;;;###autoload
(defun rx-to-string (form &optional no-group)
"Parse and produce code for regular expression FORM.
FORM is a regular expression in sexp form.
NO-GROUP non-nil means don't put shy groups around the result.
Note that unlike for the `rx' macro, subforms `literal' and
`regexp' will not accept non-string arguments (so (literal
STRING) becomes just a more verbose version of STRING)."
(rx-group-if (rx-form form) (null no-group)))
;;;###autoload
(defmacro rx (&rest regexps)
"Translate regular expressions REGEXPS in sexp form to a regexp string.
REGEXPS is a non-empty sequence of forms of the sort listed below.
Note that `rx' is a Lisp macro; when used in a Lisp program being
compiled, the translation is performed by the compiler. The
`literal' and `regexp' forms accept subforms that will evaluate
to strings, in addition to constant strings. If REGEXPS include
such forms, then the result is an expression which returns a
regexp string, rather than a regexp string directly. See
`rx-to-string' for performing translation completely at run-time.
The following are valid subforms of regular expressions in sexp
notation.
STRING
matches string STRING literally.
`(literal STRING)'
matches STRING literally, where STRING is any lisp
expression that evaluates to a string.
CHAR
matches character CHAR literally.
`not-newline', `nonl'
matches any character except a newline.
`anything'
matches any character
`(any SET ...)'
`(in SET ...)'
`(char SET ...)'
matches any character in SET .... SET may be a character or string.
Ranges of characters can be specified as `A-Z' in strings.
Ranges may also be specified as conses like `(?A . ?Z)'.
Reversed ranges like `Z-A' and `(?Z . ?A)' are not permitted.
SET may also be the name of a character class: `digit',
`control', `hex-digit', `blank', `graph', `print', `alnum',
`alpha', `ascii', `nonascii', `lower', `punct', `space', `upper',
`word', or one of their synonyms.
`(not (any SET ...))'
matches any character not in SET ...
`line-start', `bol'
matches the empty string, but only at the beginning of a line
in the text being matched
`line-end', `eol'
is similar to `line-start' but matches only at the end of a line
`string-start', `bos', `bot'
matches the empty string, but only at the beginning of the
string being matched against.
`string-end', `eos', `eot'
matches the empty string, but only at the end of the
string being matched against.
`buffer-start'
matches the empty string, but only at the beginning of the
buffer being matched against. Actually equivalent to `string-start'.
`buffer-end'
matches the empty string, but only at the end of the
buffer being matched against. Actually equivalent to `string-end'.
`point'
matches the empty string, but only at point.
`word-start', `bow'
matches the empty string, but only at the beginning of a word.
`word-end', `eow'
matches the empty string, but only at the end of a word.
`word-boundary'
matches the empty string, but only at the beginning or end of a
word.
`(not word-boundary)'
`not-word-boundary'
matches the empty string, but not at the beginning or end of a
word.
`symbol-start'
matches the empty string, but only at the beginning of a symbol.
`symbol-end'
matches the empty string, but only at the end of a symbol.
`digit', `numeric', `num'
matches 0 through 9.
`control', `cntrl'
matches any character whose code is in the range 0-31.
`hex-digit', `hex', `xdigit'
matches 0 through 9, a through f and A through F.
`blank'
matches horizontal whitespace, as defined by Annex C of the
Unicode Technical Standard #18. In particular, it matches
spaces, tabs, and other characters whose Unicode
`general-category' property indicates they are spacing
separators.
`graphic', `graph'
matches graphic characters--everything except whitespace, ASCII
and non-ASCII control characters, surrogates, and codepoints
unassigned by Unicode.
`printing', `print'
matches whitespace and graphic characters.
`alphanumeric', `alnum'
matches alphabetic characters and digits. For multibyte characters,
it matches characters whose Unicode `general-category' property
indicates they are alphabetic or decimal number characters.
`letter', `alphabetic', `alpha'
matches alphabetic characters. For multibyte characters,
it matches characters whose Unicode `general-category' property
indicates they are alphabetic characters.
`ascii'
matches ASCII (unibyte) characters.
`nonascii'
matches non-ASCII (multibyte) characters.
`lower', `lower-case'
matches anything lower-case, as determined by the current case
table. If `case-fold-search' is non-nil, this also matches any
upper-case letter.
`upper', `upper-case'
matches anything upper-case, as determined by the current case
table. If `case-fold-search' is non-nil, this also matches any
lower-case letter.
`punctuation', `punct'
matches punctuation. (But at present, for multibyte characters,
it matches anything that has non-word syntax.)
`space', `whitespace', `white'
matches anything that has whitespace syntax.
`word', `wordchar'
matches anything that has word syntax.
`not-wordchar'
matches anything that has non-word syntax.
`(syntax SYNTAX)'
matches a character with syntax SYNTAX. SYNTAX must be one
of the following symbols, or a symbol corresponding to the syntax
character, e.g. `\\.' for `\\s.'.
`whitespace' (\\s- in string notation)
`punctuation' (\\s.)
`word' (\\sw)
`symbol' (\\s_)
`open-parenthesis' (\\s()
`close-parenthesis' (\\s))
`expression-prefix' (\\s')
`string-quote' (\\s\")
`paired-delimiter' (\\s$)
`escape' (\\s\\)
`character-quote' (\\s/)
`comment-start' (\\s<)
`comment-end' (\\s>)
`string-delimiter' (\\s|)
`comment-delimiter' (\\s!)
`(not (syntax SYNTAX))'
matches a character that doesn't have syntax SYNTAX.
`(category CATEGORY)'
matches a character with category CATEGORY. CATEGORY must be
either a character to use for C, or one of the following symbols.
`space-for-indent' (\\c\\s in string notation)
`base' (\\c.)
`consonant' (\\c0)
`base-vowel' (\\c1)
`upper-diacritical-mark' (\\c2)
`lower-diacritical-mark' (\\c3)
`tone-mark' (\\c4)
`symbol' (\\c5)
`digit' (\\c6)
`vowel-modifying-diacritical-mark' (\\c7)
`vowel-sign' (\\c8)
`semivowel-lower' (\\c9)
`not-at-end-of-line' (\\c<)
`not-at-beginning-of-line' (\\c>)
`alpha-numeric-two-byte' (\\cA)
`chinese-two-byte' (\\cC)
`greek-two-byte' (\\cG)
`japanese-hiragana-two-byte' (\\cH)
`indian-two-byte' (\\cI)
`japanese-katakana-two-byte' (\\cK)
`strong-left-to-right' (\\cL)
`korean-hangul-two-byte' (\\cN)
`strong-right-to-left' (\\cR)
`cyrillic-two-byte' (\\cY)
`combining-diacritic' (\\c^)
`ascii' (\\ca)
`arabic' (\\cb)
`chinese' (\\cc)
`ethiopic' (\\ce)
`greek' (\\cg)
`korean' (\\ch)
`indian' (\\ci)
`japanese' (\\cj)
`japanese-katakana' (\\ck)
`latin' (\\cl)
`lao' (\\co)
`tibetan' (\\cq)
`japanese-roman' (\\cr)
`thai' (\\ct)
`vietnamese' (\\cv)
`hebrew' (\\cw)
`cyrillic' (\\cy)
`can-break' (\\c|)
`(not (category CATEGORY))'
matches a character that doesn't have category CATEGORY.
`(and SEXP1 SEXP2 ...)'
`(: SEXP1 SEXP2 ...)'
`(seq SEXP1 SEXP2 ...)'
`(sequence SEXP1 SEXP2 ...)'
matches what SEXP1 matches, followed by what SEXP2 matches, etc.
Without arguments, matches the empty string.
`(submatch SEXP1 SEXP2 ...)'
`(group SEXP1 SEXP2 ...)'
like `and', but makes the match accessible with `match-end',
`match-beginning', and `match-string'.
`(submatch-n N SEXP1 SEXP2 ...)'
`(group-n N SEXP1 SEXP2 ...)'
like `group', but make it an explicitly-numbered group with
group number N.
`(or SEXP1 SEXP2 ...)'
`(| SEXP1 SEXP2 ...)'
matches anything that matches SEXP1 or SEXP2, etc. If all
args are strings, use `regexp-opt' to optimize the resulting
regular expression. Without arguments, never matches anything.
`(minimal-match SEXP)'
produce a non-greedy regexp for SEXP. Normally, regexps matching
zero or more occurrences of something are \"greedy\" in that they
match as much as they can, as long as the overall regexp can
still match. A non-greedy regexp matches as little as possible.
`(maximal-match SEXP)'
produce a greedy regexp for SEXP. This is the default.
Below, `SEXP ...' represents a sequence of regexp forms, treated as if
enclosed in `(and ...)'.
`(zero-or-more SEXP ...)'
`(0+ SEXP ...)'
matches zero or more occurrences of what SEXP ... matches.
`(* SEXP ...)'
like `zero-or-more', but always produces a greedy regexp, independent
of `rx-greedy-flag'.
`(*? SEXP ...)'
like `zero-or-more', but always produces a non-greedy regexp,
independent of `rx-greedy-flag'.
`(one-or-more SEXP ...)'
`(1+ SEXP ...)'
matches one or more occurrences of SEXP ...
`(+ SEXP ...)'
like `one-or-more', but always produces a greedy regexp.
`(+? SEXP ...)'
like `one-or-more', but always produces a non-greedy regexp.
`(zero-or-one SEXP ...)'
`(optional SEXP ...)'
`(opt SEXP ...)'
matches zero or one occurrences of A.
`(? SEXP ...)'
like `zero-or-one', but always produces a greedy regexp.
`(?? SEXP ...)'
like `zero-or-one', but always produces a non-greedy regexp.
`(repeat N SEXP)'
`(= N SEXP ...)'
matches N occurrences.
`(>= N SEXP ...)'
matches N or more occurrences.
`(repeat N M SEXP)'
`(** N M SEXP ...)'
matches N to M occurrences.
`(backref N)'
matches what was matched previously by submatch N.
`(eval FORM)'
evaluate FORM and insert result. If result is a string,
`regexp-quote' it.
`(regexp REGEXP)'
include REGEXP in string notation in the result."
(let* ((rx--compile-to-lisp t)
(re (cond ((null regexps)
(error "No regexp"))
((cdr regexps)
(rx-to-string `(and ,@regexps) t))
(t
(rx-to-string (car regexps) t)))))
(if (stringp re)
re
`(concat ,@re))))
(pcase-defmacro rx (&rest regexps)
"Build a `pcase' pattern matching `rx' REGEXPS in sexp form.
The REGEXPS are interpreted as in `rx'. The pattern matches any
string that is a match for the regular expression so constructed,
as if by `string-match'.
In addition to the usual `rx' constructs, REGEXPS can contain the
following constructs:
(let REF SEXP...) creates a new explicitly named reference to
a submatch that matches regular expressions
SEXP, and binds the match to REF.
(backref REF) creates a backreference to the submatch
introduced by a previous (let REF ...)
construct. REF can be the same symbol
in the first argument of the corresponding
(let REF ...) construct, or it can be a
submatch number. It matches the referenced
submatch.
The REFs are associated with explicitly named submatches starting
from 1. Multiple occurrences of the same REF refer to the same
submatch.
If a case matches, the match data is modified as usual so you can
use it in the case body, but you still have to pass the correct
string as argument to `match-string'."
(let* ((vars ())
(rx-constituents
`((let
,(lambda (form)
(rx-check form)
(let ((var (cadr form)))
(cl-check-type var symbol)
(let ((i (or (cl-position var vars :test #'eq)
(prog1 (length vars)
(setq vars `(,@vars ,var))))))
(rx-form `(submatch-n ,(1+ i) ,@(cddr form))))))
1 nil)
(backref
,(lambda (form)
(rx-check form)
(rx-backref
`(backref ,(let ((var (cadr form)))
(if (integerp var) var
(1+ (cl-position var vars :test #'eq)))))))
1 1
,(lambda (var)
(cond ((integerp var) (rx-check-backref var))
((memq var vars) t)
(t (error "rx `backref' variable must be one of %s: %s"
vars var)))))
,@rx-constituents))
(regexp (rx-to-string `(seq ,@regexps) :no-group)))
`(and (pred (string-match ,regexp))
,@(cl-loop for i from 1
for var in vars
collect `(app (match-string ,i) ,var)))))
\f
(provide 'rx)
;;; rx.el ends here
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