Trivial build helpers
Nixpkgs provides a variety of wrapper functions that help build commonly useful derivations.
Like stdenv.mkDerivation
, each of these build helpers creates a derivation, but the arguments passed are different (usually simpler) from those required by stdenv.mkDerivation
.
runCommand
runCommand :: String -> AttrSet -> String -> Derivation
The result of runCommand name drvAttrs buildCommand
is a derivation that is built by running the specified shell commands.
By default runCommand
runs in a stdenv with no compiler environment, whereas runCommandCC
uses the default stdenv, pkgs.stdenv
.
name :: String
: The name that Nix will append to the store path in the same way that stdenv.mkDerivation
uses its name
attribute.
drvAttr :: AttrSet
: Attributes to pass to the underlying call to stdenv.mkDerivation
.
buildCommand :: String
: Shell commands to run in the derivation builder.
Note
You have to create a file or directory `$out` for Nix to be able to run the builder successfully.
Example
# Invocation of `runCommand`
(import <nixpkgs> {}).runCommand "my-example" {} ''
echo My example command is running
mkdir $out
echo I can write data to the Nix store > $out/message
echo I can also run basic commands like:
echo ls
ls
echo whoami
whoami
echo date
date
''
runCommandCC
This works just like runCommand
. The only difference is that it also provides a C compiler in buildCommand
's environment. To minimize your dependencies, you should only use this if you are sure you will need a C compiler as part of running your command.
runCommandLocal
Variant of runCommand
that forces the derivation to be built locally, it is not substituted. This is intended for very cheap commands (<1s execution time). It saves on the network round-trip and can speed up a build.
Note
This sets allowSubstitutes
to false
, so only use runCommandLocal
if you are certain the user will always have a builder for the system
of the derivation. This should be true for most trivial use cases (e.g., just copying some files to a different location or adding symlinks) because there the system
is usually the same as builtins.currentSystem
.
Writing text files
Nixpkgs provides the following functions for producing derivations which write text files or executable scripts into the Nix store.
They are useful for creating files from Nix expression, and are all implemented as convenience wrappers around writeTextFile
.
Each of these functions will cause a derivation to be produced.
When you coerce the result of each of these functions to a string with string interpolation or builtins.toString
, it will evaluate to the store path of this derivation.
:!!! note Some of these functions will put the resulting files within a directory inside the derivation output. If you need to refer to the resulting files somewhere else in a Nix expression, append their path to the derivation's store path.
For example, if the file destination is a directory:
{
my-file = writeTextFile {
name = "my-file";
text = ''
Contents of File
'';
destination = "/share/my-file";
};
}
Remember to append "/share/my-file" to the resulting store path when using it elsewhere:
writeShellScript "evaluate-my-file.sh" ''
cat ${my-file}/share/my-file
''
makeDesktopItem
Write an XDG desktop file to the Nix store.
This function is usually used to add desktop items to a package through the copyDesktopItems
hook.
makeDesktopItem
adheres to version 1.4 of the specification.
Inputs
makeDesktopItem
takes an attribute set that accepts most values from the XDG specification.
All recognised keys from the specification are supported with the exception of the "Hidden" field. The keys are converted into camelCase format, but correspond 1:1 to their equivalent in the specification: genericName
, noDisplay
, comment
, icon
, onlyShowIn
, notShowIn
, dbusActivatable
, tryExec
, exec
, path
, terminal
, mimeTypes
, categories
, implements
, keywords
, startupNotify
, startupWMClass
, url
, prefersNonDefaultGPU
.
The "Version" field is hardcoded to the version makeDesktopItem
currently adheres to.
The following fields are either required, are of a different type than in the specification, carry specific default values, or are additional fields supported by makeDesktopItem
:
name
(String)
: The name of the desktop file in the Nix store.
type
(String; optional)
: Default value: "Application"
desktopName
(String)
: Corresponds to the "Name" field of the specification.
actions
(List of Attribute set; optional)
: A list of attribute sets {name, exec?, icon?}
extraConfig
(Attribute set; optional)
: Additional key/value pairs to be added verbatim to the desktop file. Attributes need to be prefixed with 'X-'.
Examples
Example
# Usage 1 of `makeDesktopItem`
Write a desktop file /nix/store/<store path>/my-program.desktop
to the Nix store.
{makeDesktopItem}:
makeDesktopItem {
name = "my-program";
desktopName = "My Program";
genericName = "Video Player";
noDisplay = false;
comment = "Cool video player";
icon = "/path/to/icon";
onlyShowIn = [ "KDE" ];
dbusActivatable = true;
tryExec = "my-program";
exec = "my-program --someflag";
path = "/some/working/path";
terminal = false;
actions.example = {
name = "New Window";
exec = "my-program --new-window";
icon = "/some/icon";
};
mimeTypes = [ "video/mp4" ];
categories = [ "Utility" ];
implements = [ "org.my-program" ];
keywords = [ "Video" "Player" ];
startupNotify = false;
startupWMClass = "MyProgram";
prefersNonDefaultGPU = false;
extraConfig.X-SomeExtension = "somevalue";
}
Example
# Usage 2 of `makeDesktopItem`
Override the hello
package to add a desktop item.
{ copyDesktopItems
, hello
, makeDesktopItem }:
hello.overrideAttrs {
nativeBuildInputs = [ copyDesktopItems ];
desktopItems = [(makeDesktopItem {
name = "hello";
desktopName = "Hello";
exec = "hello";
})];
}
writeTextFile
Write a text file to the Nix store.
writeTextFile
takes an attribute set with the following possible attributes:
name
(String)
: Corresponds to the name used in the Nix store path identifier.
text
(String)
: The contents of the file.
executable
(Bool, optional)
: Make this file have the executable bit set.
Default: false
destination
(String, optional)
: A subpath under the derivation's output path into which to put the file. Subdirectories are created automatically when the derivation is realised.
By default, the store path itself will be a file containing the text contents.
Default: ""
checkPhase
(String, optional)
: Commands to run after generating the file.
Default: ""
meta
(Attribute set, optional)
: Additional metadata for the derivation.
Default: {}
allowSubstitutes
(Bool, optional)
: Whether to allow substituting from a binary cache.
Passed through to allowSubsitutes
of the underlying call to builtins.derivation
.
It defaults to false
, as running the derivation's simple builder
executable locally is assumed to be faster than network operations.
Set it to true if the checkPhase
step is expensive.
Default: false
preferLocalBuild
(Bool, optional)
: Whether to prefer building locally, even if faster remote build machines are available.
Passed through to preferLocalBuild
of the underlying call to builtins.derivation
.
It defaults to true
for the same reason allowSubstitutes
defaults to false
.
Default: true
derivationArgs
(Attribute set, optional)
: Extra arguments to pass to the underlying call to stdenv.mkDerivation
.
Default: {}
The resulting store path will include some variation of the name, and it will be a file unless destination
is used, in which case it will be a directory.
Example
# Usage 1 of `writeTextFile`
Write my-file
to /nix/store/<store path>/some/subpath/my-cool-script
, making it executable.
Also run a check on the resulting file in a checkPhase
, and supply values for the less-used options.
writeTextFile {
name = "my-cool-script";
text = ''
#!/bin/sh
echo "This is my cool script!"
'';
executable = true;
destination = "/some/subpath/my-cool-script";
checkPhase = ''
${pkgs.shellcheck}/bin/shellcheck $out/some/subpath/my-cool-script
'';
meta = {
license = pkgs.lib.licenses.cc0;
};
allowSubstitutes = true;
preferLocalBuild = false;
}
Example
Usage 2 of writeTextFile
Write the string Contents of File
to /nix/store/<store path>
.
See also the helper function.
writeTextFile {
name = "my-file";
text = ''
Contents of File
'';
}
Example
Usage 3 of writeTextFile
Write an executable script my-script
to /nix/store/<store path>/bin/my-script
.
See also the helper function.
writeTextFile {
name = "my-script";
text = ''
echo "hi"
'';
executable = true;
destination = "/bin/my-script";
}
writeText
Write a text file to the Nix store
writeText
takes the following arguments:
a string.
name
(String)
: The name used in the Nix store path.
text
(String)
: The contents of the file.
The store path will include the name, and it will be a file.
Example
# Usage of `writeText`
Write the string Contents of File
to /nix/store/<store path>
:
writeText "my-file"
''
Contents of File
''
This is equivalent to:
writeTextFile {
name = "my-file";
text = ''
Contents of File
'';
}
writeTextDir
Write a text file within a subdirectory of the Nix store.
writeTextDir
takes the following arguments:
path
(String)
: The destination within the Nix store path under which to create the file.
text
(String)
: The contents of the file.
The store path will be a directory.
Example
# Usage of `writeTextDir`
Write the string Contents of File
to /nix/store/<store path>/share/my-file
:
writeTextDir "share/my-file"
''
Contents of File
''
This is equivalent to:
writeTextFile {
name = "my-file";
text = ''
Contents of File
'';
destination = "share/my-file";
}
writeScript
Write an executable script file to the Nix store.
writeScript
takes the following arguments:
name
(String)
: The name used in the Nix store path.
text
(String)
: The contents of the file.
The created file is marked as executable. The store path will include the name, and it will be a file.
Example
# Usage of `writeScript`
Write the string Contents of File
to /nix/store/<store path>
and make the file executable.
writeScript "my-file"
''
Contents of File
''
This is equivalent to:
writeTextFile {
name = "my-file";
text = ''
Contents of File
'';
executable = true;
}
writeScriptBin
Write a script within a bin
subirectory of a directory in the Nix store.
This is for consistency with the convention of software packages placing executables under bin
.
writeScriptBin
takes the following arguments:
name
(String)
: The name used in the Nix store path and within the file created under the store path.
text
(String)
: The contents of the file.
The created file is marked as executable.
The file's contents will be put into /nix/store/<store path>/bin/<name>
.
The store path will include the name, and it will be a directory.
Example
# Usage of `writeScriptBin`
writeScriptBin "my-script"
''
echo "hi"
''
This is equivalent to:
writeTextFile {
name = "my-script";
text = ''
echo "hi"
'';
executable = true;
destination = "bin/my-script";
}
writeShellScript
Write a Bash script to the store.
writeShellScript
takes the following arguments:
name
(String)
: The name used in the Nix store path.
text
(String)
: The contents of the file.
The created file is marked as executable. The store path will include the name, and it will be a file.
This function is almost exactly like , except that it prepends to the file a shebang line that points to the version of Bash used in Nixpkgs.
Example
# Usage of `writeShellScript`
writeShellScript "my-script"
''
echo "hi"
''
This is equivalent to:
writeTextFile {
name = "my-script";
text = ''
#! ${pkgs.runtimeShell}
echo "hi"
'';
executable = true;
}
writeShellScriptBin
Write a Bash script to a "bin" subdirectory of a directory in the Nix store.
writeShellScriptBin
takes the following arguments:
name
(String)
: The name used in the Nix store path and within the file generated under the store path.
text
(String)
: The contents of the file.
The file's contents will be put into /nix/store/<store path>/bin/<name>
.
The store path will include the the name, and it will be a directory.
This function is a combination of and .
Example
# Usage of `writeShellScriptBin`
writeShellScriptBin "my-script"
''
echo "hi"
''
This is equivalent to:
writeTextFile {
name = "my-script";
text = ''
#! ${pkgs.runtimeShell}
echo "hi"
'';
executable = true;
destination = "bin/my-script";
}
concatTextFile
, concatText
, concatScript
These functions concatenate files
to the Nix store in a single file. This is useful for configuration files structured in lines of text. concatTextFile
takes an attribute set and expects two arguments, name
and files
. name
corresponds to the name used in the Nix store path. files
will be the files to be concatenated. You can also set executable
to true to make this file have the executable bit set.
concatText
andconcatScript
are simple wrappers over concatTextFile
.
Here are a few examples:
```nix "Writes my-file to /nix/store/
See also the concatText
helper function below. "Writes executable my-file to /nix/store//bin/my-file
concatTextFile { name = "my-file"; files = [ drv1 "${drv2}/path/to/file" ]; executable = true; destination = "/bin/my-file"; }
Writes contents of files to /nix/store/
concatText "my-file" [ file1 file2 ] "Writes contents of files to /nix/store/## `writeShellApplication` {#trivial-builder-writeShellApplication}
`writeShellApplication` is similar to `writeShellScriptBin` and `writeScriptBin` but supports runtime dependencies with `runtimeInputs`.
Writes an executable shell script to `/nix/store/<store path>/bin/<name>` and checks its syntax with [`shellcheck`](https://github.com/koalaman/shellcheck) and the `bash`'s `-n` option.
Some basic Bash options are set by default (`errexit`, `nounset`, and `pipefail`), but can be overridden with `bashOptions`.
Extra arguments may be passed to `stdenv.mkDerivation` by setting `derivationArgs`; note that variables set in this manner will be set when the shell script is _built,_ not when it's run.
Runtime environment variables can be set with the `runtimeEnv` argument.
For example, the following shell application can refer to `curl` directly, rather than needing to write `${curl}/bin/curl`:
```nix
writeShellApplication {
name = "show-nixos-org";
runtimeInputs = [ curl w3m ];
text = ''
curl -s 'https://nixos.org' | w3m -dump -T text/html
'';
}
symlinkJoin
This can be used to put many derivations into the same directory structure. It works by creating a new derivation and adding symlinks to each of the paths listed. It expects two arguments, name
, and paths
. name
is the name used in the Nix store path for the created derivation. paths
is a list of paths that will be symlinked. These paths can be to Nix store derivations or any other subdirectory contained within.
Here is an example:
# adds symlinks of hello and stack to current build and prints "links added"
symlinkJoin { name = "myexample"; paths = [ pkgs.hello pkgs.stack ]; postBuild = "echo links added"; }
/nix/store/sglsr5g079a5235hy29da3mq3hv8sjmm-myexample
|-- bin
| |-- hello -> /nix/store/qy93dp4a3rqyn2mz63fbxjg228hffwyw-hello-2.10/bin/hello
| `-- stack -> /nix/store/6lzdpxshx78281vy056lbk553ijsdr44-stack-2.1.3.1/bin/stack
`-- share
|-- bash-completion
| `-- completions
| `-- stack -> /nix/store/6lzdpxshx78281vy056lbk553ijsdr44-stack-2.1.3.1/share/bash-completion/completions/stack
|-- fish
| `-- vendor_completions.d
| `-- stack.fish -> /nix/store/6lzdpxshx78281vy056lbk553ijsdr44-stack-2.1.3.1/share/fish/vendor_completions.d/stack.fish
...
writeReferencesToFile
Deprecated. Use writeClosure
instead.
writeClosure
Given a list of store paths (or string-like expressions coercible to store paths), write their collective closure to a text file.
The result is equivalent to the output of nix-store -q --requisites
.
For example,
writeClosure [ (writeScriptBin "hi" ''${hello}/bin/hello'') ]
produces an output path /nix/store/<hash>-runtime-deps
containing
/nix/store/<hash>-hello-2.10
/nix/store/<hash>-hi
/nix/store/<hash>-libidn2-2.3.0
/nix/store/<hash>-libunistring-0.9.10
/nix/store/<hash>-glibc-2.32-40
You can see that this includes hi
, the original input path,
hello
, which is a direct reference, but also
the other paths that are indirectly required to run hello
.
writeDirectReferencesToFile
Writes the set of references to the output file, that is, their immediate dependencies.
This produces the equivalent of nix-store -q --references
.
For example,
writeDirectReferencesToFile (writeScriptBin "hi" ''${hello}/bin/hello'')
produces an output path /nix/store/<hash>-runtime-references
containing
/nix/store/<hash>-hello-2.10
but none of hello
's dependencies because those are not referenced directly
by hi
's output.