title: Dissecting Guix, Part 1: Derivations
date: TBC
author: (
tags: Dissecting Guix, Functional package management, Programming interfaces, Scheme API
---
To a new user, Guix's functional architecture can seem quite alien, and possibly
offputting.  With a combination of extensive `#guix`-querying, determined
manual-reading, and plenty of source-perusing, they may eventually figure out
how everything fits together by themselves, but this can be frustrating and
often takes a fairly long time.

However, once you peel back the layers, the "Nix way" is actually rather
elegant, if perhaps not as simple as the mutable, imperative style implemented
by the likes of [`dpkg`](https://wiki.debian.org/dpkg) and
[`pacman`](https://wiki.archlinux.org/title/pacman).
This series of blog posts will cover basic Guix concepts, taking a "ground-up"
approach by dealing with lower-level concepts first, and hopefully make those
months of information-gathering unnecessary.

Before we dig in to Guix-specific concepts, we'll need to learn about one
inherited from [Nix](https://nixos.org), the original functional package manager
and the inspiration for Guix; the idea of a _derivation_ and its corresponding
_store items_.

These concepts were originally described by Eelco Dolstra, the author of Nix, in
their [PhD thesis](https://edolstra.github.io/pubs/phd-thesis.pdf); see
_§ 2.1 The Nix store_ and _§ 2.4 Store Derivations_.

# Store Items

As you almost certainly know, everything that Guix builds is stored in the
_store_, which is almost always the `/gnu/store` directory.  It's the job of the
[`guix-daemon`](https://guix.gnu.org/manual/en/html_node/Invoking-guix_002ddaemon.html)
to manage the store and build things.  If you run
[`guix build PKG`](https://guix.gnu.org/manual/en/html_node/Invoking-guix-build.html),
`PKG` will be built or downloaded from a substitute server if available, and a
path to an item in the store will be displayed.

```
$ guix build irssi
/gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3
```

This item contains the final result of building [`irssi`](https://irssi.org).
Let's peek inside:

```
$ ls $(guix build irssi)
bin/  etc/  include/  lib/  share/
$ ls $(guix build irssi)/bin
irssi*
```

`irssi` is quite a simple package.  What about a more complex one, like
[`glib`](https://docs.gtk.org/glib)?

```
$ guix build glib
/gnu/store/bx8qq76idlmjrlqf1faslsq6zjc6f426-glib-2.73.3-bin
/gnu/store/j65bhqwr7qq7l77nj0ahmk1f1ilnjr3a-glib-2.73.3-debug
/gnu/store/3pn4ll6qakgfvfpc4mw89qrrbsgj3jf3-glib-2.73.3-doc
/gnu/store/dvsk6x7d26nmwsqhnzws4iirb6dhhr1d-glib-2.73.3
/gnu/store/4c8ycz501n2d0xdi4blahvnbjhd5hpa8-glib-2.73.3-static
```

`glib` produces five `/gnu/store` items, because it's possible for a package to
produce multiple [outputs](https://guix.gnu.org/manual/en/html_node/Packages-with-Multiple-Outputs.html).
Each output can be referred to separately, by prefixing a package's name with
`:OUTPUT` where supported.  For example, this
[`guix install`](https://guix.gnu.org/manual/en/html_node/Invoking-guix-package.html)
invocation will add `glib`'s `bin` output to your profile:

```
$ guix install glib:bin
```

The default output is `out`, so when you pass `glib` by itself to that command,
it will actually install `glib:out` to the profile.

`guix build` also provides the `--source` flag, which produces the store item
corresponding to the given package's downloaded source code.

```
$ guix build --source irssi
/gnu/store/cflbi4nbak0v9xbyc43lamzl4a539hhb-irssi-1.4.3.tar.xz
$ guix build --source glib
/gnu/store/d22wzjq3xm3q8hwnhbgk2xd3ph7lb6ay-glib-2.73.3.tar.xz
```

But how does Guix know how to build these store outputs in the first place?
That's where derivations come in.

# `.drv` Files

You've probably seen these being printed by the Guix CLI now and again.
Derivations, represented in the daemon's eyes by `.drv` files, contain
instructions for building store items.  We can retrieve the paths of these
`.drv` files with the `guix build --derivations` command:

```
$ guix build --derivations irssi
/gnu/store/zcgmhac8r4kdj2s6bcvcmhh4k35qvihx-irssi-1.4.3.drv
```

`guix build` can actually also accept derivation paths as an argument, in lieu
of a package, like so:

```
$ guix build /gnu/store/zcgmhac8r4kdj2s6bcvcmhh4k35qvihx-irssi-1.4.3.drv
/gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3
```

Let's look inside this derivation file.

```
Derive([("out","/gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3","","")],[("/gnu/store/9mv9xg4kyj4h1cvsgrw7b9x34y8yppph-glib-2.70.2.drv",["out"]),("/gnu/store/baqpbl4wck7nkxrbyc9nlhma7kq5dyfl-guile-2.0.14.drv",["out"]),("/gnu/store/bfirgq65ndhf63nn4q6vlkbha9zd931q-openssl-1.1.1l.drv",["out"]),("/gnu/store/gjwpqzvfhz13shix6a6cs2hjc18pj7wy-module-import-compiled.drv",["out"]),("/gnu/store/ij8651x4yh53hhcn6qw2644nhh2s8kcn-glib-2.70.2.drv",["out"]),("/gnu/store/jg2vv6yc2yqzi3qzs82dxvqmi5k21lhy-irssi-1.4.3.drv",["out"]),("/gnu/store/qggpjl9g6ic3cq09qrwkm0dfsdjf7pyr-glibc-utf8-locales-2.33.drv",["out"]),("/gnu/store/zafabw13yyhz93jwrcz7axak1kn1f2cx-openssl-1.1.1s.drv",["out"])],["/gnu/store/af18nrrsk98c5a71h3fifnxg1zi5mx7y-module-import","/gnu/store/qnrwmby5cwqdqxyiv1ga6azvakmdvgl7-irssi-1.4.3-builder"],"x86_64-linux","/gnu/store/hnr4r2d0h0xarx52i6jq9gvsrlc3q81a-guile-2.0.14/bin/guile",["--no-auto-compile","-L","/gnu/store/af18nrrsk98c5a71h3fifnxg1zi5mx7y-module-import","-C","/gnu/store/6rkkvvb7pl1l9ng8vvywvwf357vhm3va-module-import-compiled","/gnu/store/qnrwmby5cwqdqxyiv1ga6azvakmdvgl7-irssi-1.4.3-builder"],[("allowSubstitutes","0"),("guix properties","((type . graft) (graft (count . 2)))"),("out","/gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3"),("preferLocalBuild","1")])
```

It's... not exactly human-readable.  We could try to format it and break it
down, but it'd still be pretty hard to understand, since `.drv` files contain no
labels for the fields or any other human-readable indicators. Instead, we're
going to explore derivations in a Guile REPL.

# Exploring Guix Interactively

Before we continue, we'll want to start a REPL, so that we can try out the Guix
Guile API interactively.  To run a REPL in the terminal, simply
[call `guix repl`](https://guix.gnu.org/manual/devel/en/html_node/Using-Guix-Interactively.html).

If you're using Emacs, you can instead install
[Geiser](https://nongnu.org/geiser), which provides a comfortable Emacs UI for
various Lisp REPLs, invoke `guix repl --listen=tcp:37146 &`, and type
`M-x geiser-connect RET RET RET` to connect to the running Guile instance.

Your `.guile` file may contain code for enabling colours and readline bindings
that Geiser will choke on.  The default Guix System `.guile` contains code to
suppress these features when `INSIDE_EMACS` is set, so you'll need to run
`guix repl` like this:

```sh
INSIDE_EMACS=1 guix repl --listen=tcp:37146 &
```

There are a few Guix modules we'll need.  Run this Scheme code to import them:

```scheme
(use-modules (guix derivations)
             (guix gexp)
             (guix packages)
             (guix store)
             (gnu packages glib)
             (gnu packages irc))
```

We now have access to the store, G-expression, package, and derivation APIs,
along with the `irssi` and `glib` `<package>` objects.

# Creating a `<derivation>`

The Guix API for derivations revolves around the `<derivation>` record, which is
the Scheme representation of that whole block of text surrounded by
`Derive(...)`.  If we look in `guix/derivations.scm`, we can see that it's
defined like this:

```scheme
(define-immutable-record-type <derivation>
  (make-derivation outputs inputs sources system builder args env-vars
                   file-name)
  derivation?
  (outputs  derivation-outputs)      ; list of name/<derivation-output> pairs
  (inputs   derivation-inputs)       ; list of <derivation-input>
  (sources  derivation-sources)      ; list of store paths
  (system   derivation-system)       ; string
  (builder  derivation-builder)      ; store path
  (args     derivation-builder-arguments)         ; list of strings
  (env-vars derivation-builder-environment-vars)  ; list of name/value pairs
  (file-name derivation-file-name))               ; the .drv file name
```

With the exception of `file-name`, each of those fields corresponds to a field
in the `Derive(...)` form.  Before we can examine them, though, we need to
figure out how to _lower_ that `irssi` `<package>` object into a derivation.

The procedure we use to turn a high-level object like `<package>` into a
derivation is called `lower-object`; more on that in a future post.  However,
this doesn't produce a derivation:

```scheme
(pk (lower-object irssi))
;;; (#<procedure 7fe17c7af540 at guix/store.scm:1994:2 (state)>)
```

`pk` is an abbreviation for the procedure `peek`, which takes the given object,
writes a representation of it to the output, and returns it.  It's especially
handy when you want to view an intermediate value in a complex expression.

The returned object is a procedure that needs to be evaluated in the context of
a store connection.  We do this by first using `with-store` to connect to the
store and bind the connection to a name, then wrapping the `lower-object` call
with `run-with-store`:

```scheme
(define irssi-drv
  (pk (with-store %store
        (run-with-store %store
          (lower-object irssi)))))
;;; (#<derivation /gnu/store/zcgmhac8r4kdj2s6bcvcmhh4k35qvihx-irssi-1.4.3.drv => /gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3 7fe1902b6140>)

(define glib-drv
  (pk (with-store %store
        (run-with-store %store
          (lower-object glib)))))
;;; (#<derivation /gnu/store/81qqs7xah2ln39znrji4r6xj85zi15bi-glib-2.70.2.drv => /gnu/store/lp7k9ygvpwxgxjvmf8bix8d2aar0azr7-glib-2.70.2-bin /gnu/store/22mkp8cr6rxg6w8br9q8dbymf51b44m8-glib-2.70.2-debug /gnu/store/a6qb5arvir4vm1zlkp4chnl7d8qzzd7x-glib-2.70.2 /gnu/store/y4ak268dcdwkc6lmqfk9g1dgk2jr9i34-glib-2.70.2-static 7fe17ca13b90>)
```

And we have liftoff!  Now we've got two `<derivation>` records to play with.

# Exploring `<derivation>`

## `<derivation-output>`

The first "argument" in the `.drv` file is `outputs`, which tells the Guix
daemon about the outputs that this build can produce:

```scheme
(define irssi-outputs
  (pk (derivation-outputs irssi-drv)))
;;; ((("out" . #<<derivation-output> path: "/gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3" hash-algo: #f hash: #f recursive?: #f>)))

(pk (assoc-ref irssi-outputs "out"))

(define glib-outputs
  (pk (derivation-outputs glib-drv)))
;;; ((("bin" . #<<derivation-output> path: "/gnu/store/lp7k9ygvpwxgxjvmf8bix8d2aar0azr7-glib-2.70.2-bin" hash-algo: #f hash: #f recursive?: #f>) ("debug" . #<<derivation-output> path: "/gnu/store/22mkp8cr6rxg6w8br9q8dbymf51b44m8-glib-2.70.2-debug" hash-algo: #f hash: #f recursive?: #f>) ("out" . #<<derivation-output> path: "/gnu/store/a6qb5arvir4vm1zlkp4chnl7d8qzzd7x-glib-2.70.2" hash-algo: #f hash: #f recursive?: #f>) ("static" . #<<derivation-output> path: "/gnu/store/y4ak268dcdwkc6lmqfk9g1dgk2jr9i34-glib-2.70.2-static" hash-algo: #f hash: #f recursive?: #f>)))

(pk (assoc-ref glib-outputs "bin"))
;;; (#<<derivation-output> path: "/gnu/store/lp7k9ygvpwxgxjvmf8bix8d2aar0azr7-glib-2.70.2-bin" hash-algo: #f hash: #f recursive?: #f>)
```

It's a simple association list mapping output names to `<derivation-output>`
records, and it's equivalent to the first "argument" in the `.drv` file:

```
[ ("out", "/gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3", "", "")
]
```

The `hash-algo` and `hash` fields are for storing the content hash and the
algorithm used with that hash for what we term a _fixed-output derivation_,
which is essentially a derivation where we know what the hash of the content
will be in advance.  For instance, `origin`s produce fixed-output derivations:

```scheme
(define irssi-src-drv
  (pk (with-store %store
        (run-with-store %store
          (lower-object (package-source irssi))))))
;;; (#<derivation /gnu/store/mcz3vzq7lwwaqjb8dy7cd69lvmi6d241-irssi-1.4.3.tar.xz.drv => /gnu/store/cflbi4nbak0v9xbyc43lamzl4a539hhb-irssi-1.4.3.tar.xz 7fe17b3c8d70>)

(define irssi-src-outputs
  (pk (derivation-outputs irssi-src-drv)))
;;; ((("out" . #<<derivation-output> path: "/gnu/store/cflbi4nbak0v9xbyc43lamzl4a539hhb-irssi-1.4.3.tar.xz" hash-algo: sha256 hash: #vu8(185 63 113 82 35 163 34 230 127 66 182 26 8 165 18 174 41 227 75 212 165 61 127 34 55 102 102 10 170 90 4 52) recursive?: #f>)))
  
(pk (assoc-ref irssi-src-outputs "out"))
;;; (#<<derivation-output> path: "/gnu/store/cflbi4nbak0v9xbyc43lamzl4a539hhb-irssi-1.4.3.tar.xz" hash-algo: sha256 hash: #vu8(185 63 113 82 35 163 34 230 127 66 182 26 8 165 18 174 41 227 75 212 165 61 127 34 55 102 102 10 170 90 4 52) recursive?: #f>)
```

Note how the `hash` and `hash-algo` now have values.

Perceptive readers may note that the `<derivation-output>` has four fields,
whereas the tuple in the `.drv` file only has three (minus the label).  The
serialisation of `recursive?` is done by adding the prefix `r:` to the
`hash-algo` field, though its actual purpose is difficult to explain, and is out
of scope for this post.

## `<derivation-input>`

The next field is `inputs`, which corresponds to the second field in the `.drv`
file format:

```
[ ("/gnu/store/9mv9xg4kyj4h1cvsgrw7b9x34y8yppph-glib-2.70.2.drv", ["out"]),
  ("/gnu/store/baqpbl4wck7nkxrbyc9nlhma7kq5dyfl-guile-2.0.14.drv", ["out"]),
  ("/gnu/store/bfirgq65ndhf63nn4q6vlkbha9zd931q-openssl-1.1.1l.drv", ["out"]),
  ("/gnu/store/gjwpqzvfhz13shix6a6cs2hjc18pj7wy-module-import-compiled.drv", ["out"]),
  ("/gnu/store/ij8651x4yh53hhcn6qw2644nhh2s8kcn-glib-2.70.2.drv", ["out"]),
  ("/gnu/store/jg2vv6yc2yqzi3qzs82dxvqmi5k21lhy-irssi-1.4.3.drv", ["out"]),
  ("/gnu/store/qggpjl9g6ic3cq09qrwkm0dfsdjf7pyr-glibc-utf8-locales-2.33.drv", ["out"]),
  ("/gnu/store/zafabw13yyhz93jwrcz7axak1kn1f2cx-openssl-1.1.1s.drv", ["out"])
]
```

Here, each tuple specifies a derivation that needs to be built before this
derivation can be built, and the outputs of the derivation that the build
process of this derivation uses.  Let's grab us the Scheme equivalent:

```scheme
(define irssi-inputs
  (pk (derivation-inputs irssi-drv)))
;;; [a fairly large amount of output]

(pk (car irssi-inputs))
;;; (#<<derivation-input> drv: #<derivation /gnu/store/9mv9xg4kyj4h1cvsgrw7b9x34y8yppph-glib-2.70.2.drv => /gnu/store/2jj2mxn6wfrcw7i85nywk71mmqbnhzps-glib-2.70.2 7fe1902b6640> sub-derivations: ("out")>)
```

Unlike `derivation-outputs`, `derivation-inputs` maps 1:1 to the `.drv`
form; the `drv` field is a `<derivation>` to be built, and the
`sub-derivations` field is a list of outputs.

## Builder Configuration

The other fields are simpler; none of them involve new records.  The third is
`derivation-sources`, which contains a list of all store items used in the build
which aren't themselves built using derivations, whereas `derivation-inputs`
contains the dependencies which are.

This list usually just contains the path to the Guile _build script_ that
realises the store items when run, which we'll examine in a later post, and
the path to a directory containing extra modules to add to the build script's
`%load-path`, called `/gnu/store/...-module-import`.

The next field is `derivation-system`, which specifies the Nix system we're
building for.  Then we have `derivation-builder`, pointing to the `guile`
executable that runs the build script; and the second-to-last is
`derivation-builder-arguments`, which is a list of arguments to pass to
`derivation-builder`. Note how we use `-L` and `-C` to extend the Guile
`%load-path` and `%load-compiled-path` to include the `module-import` and
`module-import-compiled` directories:

```scheme
(pk (derivation-system irssi-drv))
;;; ("x86_64-linux")

(pk (derivation-builder irrsi-drv))
;;; ("/gnu/store/hnr4r2d0h0xarx52i6jq9gvsrlc3q81a-guile-2.0.14/bin/guile")

(pk (derivation-builder-arguments irrsi-drv))
;;; (("--no-auto-compile" "-L" "/gnu/store/af18nrrsk98c5a71h3fifnxg1zi5mx7y-module-import" "-C" "/gnu/store/6rkkvvb7pl1l9ng8vvywvwf357vhm3va-module-import-compiled" "/gnu/store/qnrwmby5cwqdqxyiv1ga6azvakmdvgl7-irssi-1.4.3-builder"))
```

The final field contains a list of environment variables to set before we start
the build process:

```scheme
(pk (derivation-builder-environment-vars irssi-drv))
;;; ((("allowSubstitutes" . "0") ("guix properties" . "((type . graft) (graft (count . 2)))") ("out" . "/gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3") ("preferLocalBuild" . "1")))
```

The last record field, `derivation-file-name` contains the path to the `.drv`
file, and so isn't represented in a serialised derivation.

# Utilising `<derivation>`

Speaking of serialisation, to convert between the `.drv` text format and the
Scheme `<derivation>` record, you can use `write-derivation`, `read-derivation`,
and `read-derivation-from-file`:

```scheme
(define manual-drv
  (with-store %store
    (derivation %store "manual"
                "/bin/sh" '())))

(write-derivation drv (current-output-port))
;;; -| Derive([("out","/gnu/store/kh7fais2zab22fd8ar0ywa4767y6xyak-example","","")],[],[],"x86_64-linux","/bin/sh",[],[("out","/gnu/store/kh7fais2zab22fd8ar0ywa4767y6xyak-example")])

(pk (read-derivation-from-file (derivation-file-name irssi-drv)))
;;; (#<derivation /gnu/store/zcgmhac8r4kdj2s6bcvcmhh4k35qvihx-irssi-1.4.3.drv => /gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3 7fb3798788c0>)

(call-with-input-file (derivation-file-name irssi-drv)
  read-derivation)
;;; (#<derivation /gnu/store/zcgmhac8r4kdj2s6bcvcmhh4k35qvihx-irssi-1.4.3.drv => /gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3 7fb37ad19e10>)
```

You can realise `<derivation>`s as store items using the `build-derivations`
procedure:

```scheme
(use-modules (ice-9 ftw))

(define irssi-drv-out
  (pk (derivation-output-path
       (assoc-ref (derivation-outputs irssi-drv) "out"))))
;;; ("/gnu/store/v5pd69j3hjs1fck4b5p9hd91wc8yf5qx-irssi-1.4.3")

(pk (scandir irssi-drv-out))
;;; (#f)

(pk (with-store %store (build-derivations %store (list irssi-drv))))
;;; (#t)

(pk (scandir irssi-drv-out))
;;; (("." ".." "bin" "etc" "include" "lib" "share"))
```

# Conclusion

Derivations are one of Guix's most important concepts, but are fairly easy to
understand once you get past the obtuse `.drv` file format.  They provide the
Guix daemon with the initial instructions that it uses to build store items
like packages, origins, and other file-likes such as `computed-file` and
`local-file`, which will be discussed in a future post!

To recap, a derivation contains the following fields:

1. `derivation-outputs`, describing the various output paths that the derivation
   builds
2. `derivation-inputs`, describing the other derivations that need to be built
   before this one is
3. `derivation-sources`, listing the non-derivation store items that the
   derivation depends on
4. `derivation-system`, specifying the Nix system a derivation will be compiled
   for
5. `derivation-builder`, the executable to run the build script with
6. `derivation-builder-arguments`, arguments to pass to the builder
7. `derivation-builder-environment-vars`, variables to set in the builder's
   environment

#### About GNU Guix

[GNU Guix](https://guix.gnu.org) is a transactional package manager and
an advanced distribution of the GNU system that [respects user
freedom](https://www.gnu.org/distros/free-system-distribution-guidelines.html).
Guix can be used on top of any system running the Hurd or the Linux
kernel, or it can be used as a standalone operating system distribution
for i686, x86_64, ARMv7, AArch64 and POWER9 machines.

In addition to standard package management features, Guix supports
transactional upgrades and roll-backs, unprivileged package management,
per-user profiles, and garbage collection.  When used as a standalone
GNU/Linux distribution, Guix offers a declarative, stateless approach to
operating system configuration management.  Guix is highly customizable
and hackable through [Guile](https://www.gnu.org/software/guile)
programming interfaces and extensions to the
[Scheme](http://schemers.org) language.