Functions reference The nixpkgs repository has several utility functions to manipulate Nix expressions.
Overriding Sometimes one wants to override parts of nixpkgs, e.g. derivation attributes, the results of derivations or even the whole package set.
<pkg>.override The function override is usually available for all the derivations in the nixpkgs expression (pkgs). It is used to override the arguments passed to a function. Example usages: pkgs.foo.override { arg1 = val1; arg2 = val2; ... } import pkgs.path { overlays = [ (self: super: { foo = super.foo.override { barSupport = true ; }; })]}; mypkg = pkgs.callPackage ./mypkg.nix { mydep = pkgs.mydep.override { ... }; } In the first example, pkgs.foo is the result of a function call with some default arguments, usually a derivation. Using pkgs.foo.override will call the same function with the given new arguments.
<pkg>.overrideAttrs The function overrideAttrs allows overriding the attribute set passed to a stdenv.mkDerivation call, producing a new derivation based on the original one. This function is available on all derivations produced by the stdenv.mkDerivation function, which is most packages in the nixpkgs expression pkgs. Example usage: helloWithDebug = pkgs.hello.overrideAttrs (oldAttrs: rec { separateDebugInfo = true; }); In the above example, the separateDebugInfo attribute is overridden to be true, thus building debug info for helloWithDebug, while all other attributes will be retained from the original hello package. The argument oldAttrs is conventionally used to refer to the attr set originally passed to stdenv.mkDerivation. Note that separateDebugInfo is processed only by the stdenv.mkDerivation function, not the generated, raw Nix derivation. Thus, using overrideDerivation will not work in this case, as it overrides only the attributes of the final derivation. It is for this reason that overrideAttrs should be preferred in (almost) all cases to overrideDerivation, i.e. to allow using sdenv.mkDerivation to process input arguments, as well as the fact that it is easier to use (you can use the same attribute names you see in your Nix code, instead of the ones generated (e.g. buildInputs vs nativeBuildInputs, and involves less typing.
<pkg>.overrideDerivation You should prefer overrideAttrs in almost all cases, see its documentation for the reasons why. overrideDerivation is not deprecated and will continue to work, but is less nice to use and does not have as many abilities as overrideAttrs. Do not use this function in Nixpkgs as it evaluates a Derivation before modifying it, which breaks package abstraction and removes error-checking of function arguments. In addition, this evaluation-per-function application incurs a performance penalty, which can become a problem if many overrides are used. It is only intended for ad-hoc customisation, such as in ~/.config/nixpkgs/config.nix. The function overrideDerivation creates a new derivation based on an existing one by overriding the original's attributes with the attribute set produced by the specified function. This function is available on all derivations defined using the makeOverridable function. Most standard derivation-producing functions, such as stdenv.mkDerivation, are defined using this function, which means most packages in the nixpkgs expression, pkgs, have this function. Example usage: mySed = pkgs.gnused.overrideDerivation (oldAttrs: { name = "sed-4.2.2-pre"; src = fetchurl { url = ftp://alpha.gnu.org/gnu/sed/sed-4.2.2-pre.tar.bz2; sha256 = "11nq06d131y4wmf3drm0yk502d2xc6n5qy82cg88rb9nqd2lj41k"; }; patches = []; }); In the above example, the name, src, and patches of the derivation will be overridden, while all other attributes will be retained from the original derivation. The argument oldAttrs is used to refer to the attribute set of the original derivation. A package's attributes are evaluated *before* being modified by the overrideDerivation function. For example, the name attribute reference in url = "mirror://gnu/hello/${name}.tar.gz"; is filled-in *before* the overrideDerivation function modifies the attribute set. This means that overriding the name attribute, in this example, *will not* change the value of the url attribute. Instead, we need to override both the name *and* url attributes.
lib.makeOverridable The function lib.makeOverridable is used to make the result of a function easily customizable. This utility only makes sense for functions that accept an argument set and return an attribute set. Example usage: f = { a, b }: { result = a+b; }; c = lib.makeOverridable f { a = 1; b = 2; }; The variable c is the value of the f function applied with some default arguments. Hence the value of c.result is 3, in this example. The variable c however also has some additional functions, like c.override which can be used to override the default arguments. In this example the value of (c.override { a = 4; }).result is 6.
Generators Generators are functions that create file formats from nix data structures, e. g. for configuration files. There are generators available for: INI, JSON and YAML All generators follow a similar call interface: generatorName configFunctions data, where configFunctions is an attrset of user-defined functions that format nested parts of the content. They each have common defaults, so often they do not need to be set manually. An example is mkSectionName ? (name: libStr.escape [ "[" "]" ] name) from the INI generator. It receives the name of a section and sanitizes it. The default mkSectionName escapes [ and ] with a backslash. Generators can be fine-tuned to produce exactly the file format required by your application/service. One example is an INI-file format which uses : as separator, the strings "yes"/"no" as boolean values and requires all string values to be quoted: with lib; let customToINI = generators.toINI { # specifies how to format a key/value pair mkKeyValue = generators.mkKeyValueDefault { # specifies the generated string for a subset of nix values mkValueString = v: if v == true then ''"yes"'' else if v == false then ''"no"'' else if isString v then ''"${v}"'' # and delegats all other values to the default generator else generators.mkValueStringDefault {} v; } ":"; }; # the INI file can now be given as plain old nix values in customToINI { main = { pushinfo = true; autopush = false; host = "localhost"; port = 42; }; mergetool = { merge = "diff3"; }; } This will produce the following INI file as nix string: [main] autopush:"no" host:"localhost" port:42 pushinfo:"yes" str\:ange:"very::strange" [mergetool] merge:"diff3" Nix store paths can be converted to strings by enclosing a derivation attribute like so: "${drv}". Detailed documentation for each generator can be found in lib/generators.nix.
Debugging Nix Expressions Nix is a unityped, dynamic language, this means every value can potentially appear anywhere. Since it is also non-strict, evaluation order and what ultimately is evaluated might surprise you. Therefore it is important to be able to debug nix expressions. In the lib/debug.nix file you will find a number of functions that help (pretty-)printing values while evaluation is runnnig. You can even specify how deep these values should be printed recursively, and transform them on the fly. Please consult the docstrings in lib/debug.nix for usage information.
buildFHSUserEnv buildFHSUserEnv provides a way to build and run FHS-compatible lightweight sandboxes. It creates an isolated root with bound /nix/store, so its footprint in terms of disk space needed is quite small. This allows one to run software which is hard or unfeasible to patch for NixOS -- 3rd-party source trees with FHS assumptions, games distributed as tarballs, software with integrity checking and/or external self-updated binaries. It uses Linux namespaces feature to create temporary lightweight environments which are destroyed after all child processes exit, without root user rights requirement. Accepted arguments are: name Environment name. targetPkgs Packages to be installed for the main host's architecture (i.e. x86_64 on x86_64 installations). Along with libraries binaries are also installed. multiPkgs Packages to be installed for all architectures supported by a host (i.e. i686 and x86_64 on x86_64 installations). Only libraries are installed by default. extraBuildCommands Additional commands to be executed for finalizing the directory structure. extraBuildCommandsMulti Like extraBuildCommands, but executed only on multilib architectures. extraOutputsToInstall Additional derivation outputs to be linked for both target and multi-architecture packages. extraInstallCommands Additional commands to be executed for finalizing the derivation with runner script. runScript A command that would be executed inside the sandbox and passed all the command line arguments. It defaults to bash. One can create a simple environment using a shell.nix like that: {} }: (pkgs.buildFHSUserEnv { name = "simple-x11-env"; targetPkgs = pkgs: (with pkgs; [ udev alsaLib ]) ++ (with pkgs.xorg; [ libX11 libXcursor libXrandr ]); multiPkgs = pkgs: (with pkgs; [ udev alsaLib ]); runScript = "bash"; }).env ]]> Running nix-shell would then drop you into a shell with these libraries and binaries available. You can use this to run closed-source applications which expect FHS structure without hassles: simply change runScript to the application path, e.g. ./bin/start.sh -- relative paths are supported.
pkgs.dockerTools pkgs.dockerTools is a set of functions for creating and manipulating Docker images according to the Docker Image Specification v1.2.0 . Docker itself is not used to perform any of the operations done by these functions. The dockerTools API is unstable and may be subject to backwards-incompatible changes in the future.
buildImage This function is analogous to the docker build command, in that can used to build a Docker-compatible repository tarball containing a single image with one or multiple layers. As such, the result is suitable for being loaded in Docker with docker load. The parameters of buildImage with relative example values are described below: Docker build buildImage { name = "redis"; tag = "latest"; fromImage = someBaseImage; fromImageName = null; fromImageTag = "latest"; contents = pkgs.redis; runAsRoot = '' #!${stdenv.shell} mkdir -p /data ''; config = { Cmd = [ "/bin/redis-server" ]; WorkingDir = "/data"; Volumes = { "/data" = {}; }; }; } The above example will build a Docker image redis/latest from the given base image. Loading and running this image in Docker results in redis-server being started automatically. name specifies the name of the resulting image. This is the only required argument for buildImage. tag specifies the tag of the resulting image. By default it's null, which indicates that the nix output hash will be used as tag. fromImage is the repository tarball containing the base image. It must be a valid Docker image, such as exported by docker save. By default it's null, which can be seen as equivalent to FROM scratch of a Dockerfile. fromImageName can be used to further specify the base image within the repository, in case it contains multiple images. By default it's null, in which case buildImage will peek the first image available in the repository. fromImageTag can be used to further specify the tag of the base image within the repository, in case an image contains multiple tags. By default it's null, in which case buildImage will peek the first tag available for the base image. contents is a derivation that will be copied in the new layer of the resulting image. This can be similarly seen as ADD contents/ / in a Dockerfile. By default it's null. runAsRoot is a bash script that will run as root in an environment that overlays the existing layers of the base image with the new resulting layer, including the previously copied contents derivation. This can be similarly seen as RUN ... in a Dockerfile. Using this parameter requires the kvm device to be available. config is used to specify the configuration of the containers that will be started off the built image in Docker. The available options are listed in the Docker Image Specification v1.2.0 . After the new layer has been created, its closure (to which contents, config and runAsRoot contribute) will be copied in the layer itself. Only new dependencies that are not already in the existing layers will be copied. At the end of the process, only one new single layer will be produced and added to the resulting image. The resulting repository will only list the single image image/tag. In the case of it would be redis/latest. It is possible to inspect the arguments with which an image was built using its buildArgs attribute. If you see errors similar to getProtocolByName: does not exist (no such protocol name: tcp) you may need to add pkgs.iana-etc to contents. If you see errors similar to Error_Protocol ("certificate has unknown CA",True,UnknownCa) you may need to add pkgs.cacert to contents. Impurely Defining a Docker Layer's Creation Date By default buildImage will use a static date of one second past the UNIX Epoch. This allows buildImage to produce binary reproducible images. When listing images with docker list images, the newly created images will be listed like this: You can break binary reproducibility but have a sorted, meaningful CREATED column by setting created to now. and now the Docker CLI will display a reasonable date and sort the images as expected: however, the produced images will not be binary reproducible.
buildLayeredImage Create a Docker image with many of the store paths being on their own layer to improve sharing between images. name The name of the resulting image. tag optional Tag of the generated image. Default: the output path's hash contents optional Top level paths in the container. Either a single derivation, or a list of derivations. Default: [] config optional Run-time configuration of the container. A full list of the options are available at in the Docker Image Specification v1.2.0 . Default: {} created optional Date and time the layers were created. Follows the same now exception supported by buildImage. Default: 1970-01-01T00:00:01Z maxLayers optional Maximum number of layers to create. Default: 24
Behavior of <varname>contents</varname> in the final image Each path directly listed in contents will have a symlink in the root of the image. For example: will create symlinks for all the paths in the hello package: /nix/store/h1zb1padqbbb7jicsvkmrym3r6snphxg-hello-2.10/bin/hello /share/info/hello.info -> /nix/store/h1zb1padqbbb7jicsvkmrym3r6snphxg-hello-2.10/share/info/hello.info /share/locale/bg/LC_MESSAGES/hello.mo -> /nix/store/h1zb1padqbbb7jicsvkmrym3r6snphxg-hello-2.10/share/locale/bg/LC_MESSAGES/hello.mo ]]>
Automatic inclusion of <varname>config</varname> references The closure of config is automatically included in the closure of the final image. This allows you to make very simple Docker images with very little code. This container will start up and run hello:
Adjusting <varname>maxLayers</varname> Increasing the maxLayers increases the number of layers which have a chance to be shared between different images. Modern Docker installations support up to 128 layers, however older versions support as few as 42. If the produced image will not be extended by other Docker builds, it is safe to set maxLayers to 128. However it will be impossible to extend the image further. The first (maxLayers-2) most "popular" paths will have their own individual layers, then layer #maxLayers-1 will contain all the remaining "unpopular" paths, and finally layer #maxLayers will contain the Image configuration. Docker's Layers are not inherently ordered, they are content-addressable and are not explicitly layered until they are composed in to an Image.
pullImage This function is analogous to the docker pull command, in that can be used to pull a Docker image from a Docker registry. By default Docker Hub is used to pull images. Its parameters are described in the example below: Docker pull pullImage { imageName = "nixos/nix"; imageDigest = "sha256:20d9485b25ecfd89204e843a962c1bd70e9cc6858d65d7f5fadc340246e2116b"; finalImageTag = "1.11"; sha256 = "0mqjy3zq2v6rrhizgb9nvhczl87lcfphq9601wcprdika2jz7qh8"; os = "linux"; arch = "x86_64"; } imageName specifies the name of the image to be downloaded, which can also include the registry namespace (e.g. nixos). This argument is required. imageDigest specifies the digest of the image to be downloaded. Skopeo can be used to get the digest of an image, with its inspect subcommand. Since a given imageName may transparently refer to a manifest list of images which support multiple architectures and/or operating systems, supply the `--override-os` and `--override-arch` arguments to specify exactly which image you want. By default it will match the OS and architecture of the host the command is run on. $ nix-shell --packages skopeo jq --command "skopeo --override-os linux --override-arch x86_64 inspect docker://docker.io/nixos/nix:1.11 | jq -r '.Digest'" sha256:20d9485b25ecfd89204e843a962c1bd70e9cc6858d65d7f5fadc340246e2116b This argument is required. finalImageTag, if specified, this is the tag of the image to be created. Note it is never used to fetch the image since we prefer to rely on the immutable digest ID. By default it's latest. sha256 is the checksum of the whole fetched image. This argument is required. os, if specified, is the operating system of the fetched image. By default it's linux. arch, if specified, is the cpu architecture of the fetched image. By default it's x86_64.
exportImage This function is analogous to the docker export command, in that can used to flatten a Docker image that contains multiple layers. It is in fact the result of the merge of all the layers of the image. As such, the result is suitable for being imported in Docker with docker import. Using this function requires the kvm device to be available. The parameters of exportImage are the following: Docker export exportImage { fromImage = someLayeredImage; fromImageName = null; fromImageTag = null; name = someLayeredImage.name; } The parameters relative to the base image have the same synopsis as described in , except that fromImage is the only required argument in this case. The name argument is the name of the derivation output, which defaults to fromImage.name.
shadowSetup This constant string is a helper for setting up the base files for managing users and groups, only if such files don't exist already. It is suitable for being used in a runAsRoot script for cases like in the example below: Shadow base files buildImage { name = "shadow-basic"; runAsRoot = '' #!${stdenv.shell} ${shadowSetup} groupadd -r redis useradd -r -g redis redis mkdir /data chown redis:redis /data ''; } Creating base files like /etc/passwd or /etc/login.defs are necessary for shadow-utils to manipulate users and groups.