nixpkgs/doc/build-helpers/images/dockertools.section.md
Robert Hensing d2dfcfcfad
Merge pull request #289584 from athre0z/docker-zstd
dockerTools: configurable compression schema
2024-02-19 18:06:54 +01:00

66 KiB

pkgs.dockerTools

pkgs.dockerTools is a set of functions for creating and manipulating Docker images according to the Docker Image Specification v1.3.0. Docker itself is not used to perform any of the operations done by these functions.

buildImage

This function builds a Docker-compatible repository tarball containing a single image. As such, the result is suitable for being loaded in Docker with docker image load (see for how to do this).

This function will create a single layer for all files (and dependencies) that are specified in its argument. Only new dependencies that are not already in the existing layers will be copied. If you prefer to create multiple layers for the files and dependencies you want to add to the image, see or instead.

This function allows a script to be run during the layer generation process, allowing custom behaviour to affect the final results of the image (see the documentation of the runAsRoot and extraCommands attributes).

The resulting repository tarball will list a single image as specified by the name and tag attributes. By default, that image will use a static creation date (see documentation for the created attribute). This allows buildImage to produce reproducible images.

:::{.tip} When running an image built with buildImage, you might encounter certain errors depending on what you included in the image, especially if you did not start with any base image.

If you encounter errors similar to getProtocolByName: does not exist (no such protocol name: tcp), you may need to add the contents of pkgs.iana-etc in the copyToRoot attribute. Similarly, if you encounter errors similar to Error_Protocol ("certificate has unknown CA",True,UnknownCa), you may need to add the contents of pkgs.cacert in the copyToRoot attribute. :::

Inputs

buildImage expects an argument with the following attributes:

name (String)

The name of the generated image.

tag (String or Null; optional)

Tag of the generated image. If null, the hash of the nix derivation will be used as the tag.

Default value: null.

fromImage (Path or Null; optional)

The repository tarball of an image to be used as the base for the generated image. It must be a valid Docker image, such as one exported by docker image save, or another image built with the dockerTools utility functions. This can be seen as an equivalent of FROM fromImage in a Dockerfile. A value of null can be seen as an equivalent of FROM scratch.

If specified, the layer created by buildImage will be appended to the layers defined in the base image, resulting in an image with at least two layers (one or more layers from the base image, and the layer created by buildImage). Otherwise, the resulting image with contain the single layer created by buildImage.

Default value: null.

fromImageName (String or Null; optional)

Used to specify the image within the repository tarball in case it contains multiple images. A value of null means that buildImage will use the first image available in the repository.

:::{.note} This must be used with fromImageTag. Using only fromImageName without fromImageTag will make buildImage use the first image available in the repository. :::

Default value: null.

fromImageTag (String or Null; optional)

Used to specify the image within the repository tarball in case it contains multiple images. A value of null means that buildImage will use the first image available in the repository.

:::{.note} This must be used with fromImageName. Using only fromImageTag without fromImageName will make buildImage use the first image available in the repository :::

Default value: null.

copyToRoot (Path, List of Paths, or Null; optional)

Files to add to the generated image. Anything that coerces to a path (e.g. a derivation) can also be used. This can be seen as an equivalent of ADD contents/ / in a Dockerfile.

Default value: null.

keepContentsDirlinks (Boolean; optional)

When adding files to the generated image (as specified by copyToRoot), this attribute controls whether to preserve symlinks to directories. If false, the symlinks will be transformed into directories. This behaves the same as rsync -k when keepContentsDirlinks is false, and the same as rsync -K when keepContentsDirlinks is true.

Default value: false.

runAsRoot (String or Null; optional)

A bash script that will run as root inside a VM that contains the existing layers of the base image and the new generated layer (including the files from copyToRoot). The script will be run with a working directory of /. This can be seen as an equivalent of RUN ... in a Dockerfile. A value of null means that this step in the image generation process will be skipped.

See for how to work with this attribute.

:::{.caution} Using this attribute requires the kvm device to be available, see system-features. If the kvm device isn't available, you should consider using buildLayeredImage or streamLayeredImage instead. Those functions allow scripts to be run as root without access to the kvm device. :::

:::{.note} At the time the script in runAsRoot is run, the files specified directly in copyToRoot will be present in the VM, but their dependencies might not be there yet. Copying their dependencies into the generated image is a step that happens after runAsRoot finishes running. :::

Default value: null.

extraCommands (String; optional)

A bash script that will run before the layer created by buildImage is finalised. The script will be run on some (opaque) working directory which will become / once the layer is created. This is similar to runAsRoot, but the script specified in extraCommands is not run as root, and does not involve creating a VM. It is simply run as part of building the derivation that outputs the layer created by buildImage.

See for how to work with this attribute, and subtle differences compared to runAsRoot.

Default value: "".

config (Attribute Set or Null; optional)

Used to specify the configuration of the containers that will be started off the generated image. Must be an attribute set, with each attribute as listed in the Docker Image Specification v1.3.0.

Default value: null.

architecture (String; optional)

Used to specify the image architecture. This is useful for multi-architecture builds that don't need cross compiling. If specified, its value should follow the OCI Image Configuration Specification, which should still be compatible with Docker. According to the linked specification, all possible values for $GOARCH in the Go docs should be valid, but will commonly be one of 386, amd64, arm, or arm64.

Default value: the same value from pkgs.go.GOARCH.

diskSize (Number; optional)

Controls the disk size (in megabytes) of the VM used to run the script specified in runAsRoot. This attribute is ignored if runAsRoot is null.

Default value: 1024.

buildVMMemorySize (Number; optional)

Controls the amount of memory (in megabytes) provisioned for the VM used to run the script specified in runAsRoot. This attribute is ignored if runAsRoot is null.

Default value: 512.

created (String; optional)

Specifies the time of creation of the generated image. This should be either a date and time formatted according to ISO-8601 or "now", in which case buildImage will use the current date.

See for how to use "now".

:::{.caution} Using "now" means that the generated image will not be reproducible anymore (because the date will always change whenever it's built). :::

Default value: "1970-01-01T00:00:01Z".

uid (Number; optional)

The uid of the user that will own the files packed in the new layer built by buildImage.

Default value: 0.

gid (Number; optional)

The gid of the group that will own the files packed in the new layer built by buildImage.

Default value: 0.

compressor (String; optional)

Selects the algorithm used to compress the image.

Default value: "gz".
Possible values: "none", "gz", "zstd".

contents DEPRECATED

This attribute is deprecated, and users are encouraged to use copyToRoot instead.

Passthru outputs

buildImage defines a few passthru attributes:

buildArgs (Attribute Set)

The argument passed to buildImage itself. This allows you to inspect all attributes specified in the argument, as described above.

layer (Attribute Set)

The derivation with the layer created by buildImage. This allows easier inspection of the contents added by buildImage in the generated image.

imageTag (String)

The tag of the generated image. This is useful if no tag was specified in the attributes of the argument to buildImage, because an automatic tag will be used instead. imageTag allows you to retrieve the value of the tag used in this case.

Examples

:::{.example #ex-dockerTools-buildImage}

Building a Docker image

The following package builds a Docker image that runs the redis-server executable from the redis package. The Docker image will have name redis and tag latest.

{ dockerTools, buildEnv, redis }:
dockerTools.buildImage {
  name = "redis";
  tag = "latest";

  copyToRoot = buildEnv {
    name = "image-root";
    paths = [ redis ];
    pathsToLink = [ "/bin" ];
  };

  runAsRoot = ''
    mkdir -p /data
  '';

  config = {
    Cmd = [ "/bin/redis-server" ];
    WorkingDir = "/data";
    Volumes = { "/data" = { }; };
  };
}

The result of building this package is a .tar.gz file that can be loaded into Docker:

$ nix-build
(some output removed for clarity)
building '/nix/store/yw0adm4wpsw1w6j4fb5hy25b3arr9s1v-docker-image-redis.tar.gz.drv'...
Adding layer...
tar: Removing leading `/' from member names
Adding meta...
Cooking the image...
Finished.
/nix/store/p4dsg62inh9d2ksy3c7bv58xa851dasr-docker-image-redis.tar.gz

$ docker image load -i /nix/store/p4dsg62inh9d2ksy3c7bv58xa851dasr-docker-image-redis.tar.gz
(some output removed for clarity)
Loaded image: redis:latest

:::

:::{.example #ex-dockerTools-buildImage-runAsRoot}

Building a Docker image with runAsRoot

The following package builds a Docker image with the hello executable from the hello package. It uses runAsRoot to create a directory and a file inside the image.

This works the same as , but uses runAsRoot instead of extraCommands.

{ dockerTools, buildEnv, hello }:
dockerTools.buildImage {
  name = "hello";
  tag = "latest";

  copyToRoot = buildEnv {
    name = "image-root";
    paths = [ hello ];
    pathsToLink = [ "/bin" ];
  };

  runAsRoot = ''
    mkdir -p /data
    echo "some content" > my-file
  '';

  config = {
    Cmd = [ "/bin/hello" ];
    WorkingDir = "/data";
  };
}

:::

:::{.example #ex-dockerTools-buildImage-extraCommands}

Building a Docker image with extraCommands

The following package builds a Docker image with the hello executable from the hello package. It uses extraCommands to create a directory and a file inside the image.

This works the same as , but uses extraCommands instead of runAsRoot. Note that with extraCommands, we can't directly reference / and must create files and directories as if we were already on /.

{ dockerTools, buildEnv, hello }:
dockerTools.buildImage {
  name = "hello";
  tag = "latest";

  copyToRoot = buildEnv {
    name = "image-root";
    paths = [ hello ];
    pathsToLink = [ "/bin" ];
  };

  extraCommands = ''
    mkdir -p data
    echo "some content" > my-file
  '';

  config = {
    Cmd = [ "/bin/hello" ];
    WorkingDir = "/data";
  };
}

:::

:::{.example #ex-dockerTools-buildImage-creatednow}

Building a Docker image with a creation date set to the current time

Note that using a value of "now" in the created attribute will break reproducibility.

{ dockerTools, buildEnv, hello }:
dockerTools.buildImage {
  name = "hello";
  tag = "latest";

  created = "now";

  copyToRoot = buildEnv {
    name = "image-root";
    paths = [ hello ];
    pathsToLink = [ "/bin" ];
  };

  config.Cmd = [ "/bin/hello" ];
}

After importing the generated repository tarball with Docker, its CLI will display a reasonable date and sort the images as expected:

$ docker image ls
REPOSITORY   TAG      IMAGE ID       CREATED              SIZE
hello        latest   de2bf4786de6   About a minute ago   25.2MB

:::

buildLayeredImage

buildLayeredImage uses streamLayeredImage underneath to build a compressed Docker-compatible repository tarball. Basically, buildLayeredImage runs the script created by streamLayeredImage to save the compressed image in the Nix store. buildLayeredImage supports the same options as streamLayeredImage, see streamLayeredImage for details.

:::{.note} Despite the similar name, buildImage works completely differently from buildLayeredImage and streamLayeredImage.

Even though some of the arguments may seem related, they cannot be interchanged. :::

You can load the result of this function in Docker with docker image load. See to see how to do that.

Examples

:::{.example #ex-dockerTools-buildLayeredImage-hello}

Building a layered Docker image

The following package builds a layered Docker image that runs the hello executable from the hello package. The Docker image will have name hello and tag latest.

{ dockerTools, hello }:
dockerTools.buildLayeredImage {
  name = "hello";
  tag = "latest";

  contents = [ hello ];

  config.Cmd = [ "/bin/hello" ];
}

The result of building this package is a .tar.gz file that can be loaded into Docker:

$ nix-build
(some output removed for clarity)
building '/nix/store/bk8bnrbw10nq7p8pvcmdr0qf57y6scha-hello.tar.gz.drv'...
No 'fromImage' provided
Creating layer 1 from paths: ['/nix/store/i93s7xxblavsacpy82zdbn4kplsyq48l-libunistring-1.1']
Creating layer 2 from paths: ['/nix/store/ji01n9vinnj22nbrb86nx8a1ssgpilx8-libidn2-2.3.4']
Creating layer 3 from paths: ['/nix/store/ldrslljw4rg026nw06gyrdwl78k77vyq-xgcc-12.3.0-libgcc']
Creating layer 4 from paths: ['/nix/store/9y8pmvk8gdwwznmkzxa6pwyah52xy3nk-glibc-2.38-27']
Creating layer 5 from paths: ['/nix/store/zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1']
Creating layer 6 with customisation...
Adding manifests...
Done.
/nix/store/hxcz7snvw7f8rzhbh6mv8jq39d992905-hello.tar.gz

$ docker image load -i /nix/store/hxcz7snvw7f8rzhbh6mv8jq39d992905-hello.tar.gz
(some output removed for clarity)
Loaded image: hello:latest

:::

streamLayeredImage

streamLayeredImage builds a script which, when run, will stream to stdout a Docker-compatible repository tarball containing a single image, using multiple layers to improve sharing between images. This means that streamLayeredImage does not output an image into the Nix store, but only a script that builds the image, saving on IO and disk/cache space, particularly with large images.

You can load the result of this function in Docker with docker image load. See to see how to do that.

For this function, you specify a store path or a list of store paths to be added to the image, and the functions will automatically include any dependencies of those paths in the image. The function will attempt to create one layer per object in the Nix store that needs to be added to the image. In case there are more objects to include than available layers, the function will put the most "popular" objects in their own layers, and group all remaining objects into a single layer.

An additional layer will be created with symlinks to the store paths you specified to be included in the image. These symlinks are built with symlinkJoin, so they will be included in the root of the image. See to understand how these symlinks are laid out in the generated image.

streamLayeredImage allows scripts to be run when creating the additional layer with symlinks, allowing custom behaviour to affect the final results of the image (see the documentation of the extraCommands and fakeRootCommands attributes).

The resulting repository tarball will list a single image as specified by the name and tag attributes. By default, that image will use a static creation date (see documentation for the created attribute). This allows the function to produce reproducible images.

Inputs

streamLayeredImage expects one argument with the following attributes:

name (String)

The name of the generated image.

tag (String or Null; optional)

Tag of the generated image. If null, the hash of the nix derivation will be used as the tag.

Default value: null.

fromImage(Path or Null; optional)

The repository tarball of an image to be used as the base for the generated image. It must be a valid Docker image, such as one exported by docker image save, or another image built with the dockerTools utility functions. This can be seen as an equivalent of FROM fromImage in a Dockerfile. A value of null can be seen as an equivalent of FROM scratch.

If specified, the created layers will be appended to the layers defined in the base image.

Default value: null.

contents (Path or List of Paths; optional) []{#dockerTools-buildLayeredImage-arg-contents}

Directories whose contents will be added to the generated image. Things that coerce to paths (e.g. a derivation) can also be used. This can be seen as an equivalent of ADD contents/ / in a Dockerfile.

All the contents specified by contents will be added as a final layer in the generated image. They will be added as links to the actual files (e.g. links to the store paths). The actual files will be added in previous layers.

Default value: []

config (Attribute Set or Null; optional) []{#dockerTools-buildLayeredImage-arg-config}

Used to specify the configuration of the containers that will be started off the generated image. Must be an attribute set, with each attribute as listed in the Docker Image Specification v1.3.0.

If any packages are used directly in config, they will be automatically included in the generated image. See for an example.

Default value: null.

architecture (String; optional)

Used to specify the image architecture. This is useful for multi-architecture builds that don't need cross compiling. If specified, its value should follow the OCI Image Configuration Specification, which should still be compatible with Docker. According to the linked specification, all possible values for $GOARCH in the Go docs should be valid, but will commonly be one of 386, amd64, arm, or arm64.

Default value: the same value from pkgs.go.GOARCH.

created (String; optional)

Specifies the time of creation of the generated image. This should be either a date and time formatted according to ISO-8601 or "now", in which case the current date will be used.

:::{.caution} Using "now" means that the generated image will not be reproducible anymore (because the date will always change whenever it's built). :::

Default value: "1970-01-01T00:00:01Z".

maxLayers (Number; optional) []{#dockerTools-buildLayeredImage-arg-maxLayers}

The maximum number of layers that will be used by the generated image. If a fromImage was specified, the number of layers used by fromImage will be subtracted from maxLayers to ensure that the image generated will have at most maxLayers.

:::{.caution} Depending on the tool/runtime where the image will be used, there might be a limit to the number of layers that an image can have. For Docker, see this issue on GitHub. :::

Default value: 100.

extraCommands (String; optional)

A bash script that will run in the context of the layer created with the contents specified by contents. At the moment this script runs, only the contents directly specified by contents will be available as links.

Default value: "".

fakeRootCommands (String; optional)

A bash script that will run in the context of the layer created with the contents specified by contents. During the process to generate that layer, the script in extraCommands will be run first, if specified. After that, a {manpage}fakeroot(1) environment will be entered. The script specified in fakeRootCommands runs inside the fakeroot environment, and the layer is then generated from the view of the files inside the fakeroot environment.

This is useful to change the owners of the files in the layer (by running chown, for example), or performing any other privileged operations related to file manipulation (by default, all files in the layer will be owned by root, and the build environment doesn't have enough privileges to directly perform privileged operations on these files).

For more details, see the manpage for {manpage}fakeroot(1).

:::{.caution} Due to how fakeroot works, static binaries cannot perform privileged file operations in fakeRootCommands, unless enableFakechroot is set to true. :::

Default value: "".

enableFakechroot (Boolean; optional)

By default, the script specified in fakeRootCommands only runs inside a fakeroot environment. If enableFakechroot is true, a more complete chroot environment will be created using proot before running the script in fakeRootCommands. Files in the Nix store will be available. This allows scripts that perform installation in / to work as expected. This can be seen as an equivalent of RUN ... in a Dockerfile.

Default value: false

includeStorePaths (Boolean; optional)

The files specified in contents are put into layers in the generated image. If includeStorePaths is false, the actual files will not be included in the generated image, and only links to them will be added instead. It is not recommended to set this to false unless you have other tooling to insert the store paths via other means (such as bind mounting the host store) when running containers with the generated image. If you don't provide any extra tooling, the generated image won't run properly.

See to understand the impact of setting includeStorePaths to false.

Default value: true

passthru (Attribute Set; optional)

Use this to pass any attributes as passthru for the resulting derivation.

Default value: {}

Passthru outputs

streamLayeredImage also defines its own passthru attributes:

imageTag (String)

The tag of the generated image. This is useful if no tag was specified in the attributes of the argument to the function, because an automatic tag will be used instead. imageTag allows you to retrieve the value of the tag used in this case.

Examples

:::{.example #ex-dockerTools-streamLayeredImage-hello}

Streaming a layered Docker image

The following package builds a script which, when run, will stream a layered Docker image that runs the hello executable from the hello package. The Docker image will have name hello and tag latest.

{ dockerTools, hello }:
dockerTools.streamLayeredImage {
  name = "hello";
  tag = "latest";

  contents = [ hello ];

  config.Cmd = [ "/bin/hello" ];
}

The result of building this package is a script. Running this script and piping it into docker image load gives you the same image that was built in . Note that in this case, the image is never added to the Nix store, but instead streamed directly into Docker.

$ nix-build
(output removed for clarity)
/nix/store/wsz2xl8ckxnlb769irvq6jv1280dfvxd-stream-hello

$ /nix/store/wsz2xl8ckxnlb769irvq6jv1280dfvxd-stream-hello | docker image load
No 'fromImage' provided
Creating layer 1 from paths: ['/nix/store/i93s7xxblavsacpy82zdbn4kplsyq48l-libunistring-1.1']
Creating layer 2 from paths: ['/nix/store/ji01n9vinnj22nbrb86nx8a1ssgpilx8-libidn2-2.3.4']
Creating layer 3 from paths: ['/nix/store/ldrslljw4rg026nw06gyrdwl78k77vyq-xgcc-12.3.0-libgcc']
Creating layer 4 from paths: ['/nix/store/9y8pmvk8gdwwznmkzxa6pwyah52xy3nk-glibc-2.38-27']
Creating layer 5 from paths: ['/nix/store/zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1']
Creating layer 6 with customisation...
Adding manifests...
Done.
(some output removed for clarity)
Loaded image: hello:latest

:::

:::{.example #ex-dockerTools-streamLayeredImage-exploringlayers}

Exploring the layers in an image built with streamLayeredImage

Assume the following package, which builds a layered Docker image with the hello package.

{ dockerTools, hello }:
dockerTools.streamLayeredImage {
  name = "hello";
  contents = [ hello ];
}

The hello package depends on 4 other packages:

$ nix-store --query -R $(nix-build -A hello)
/nix/store/i93s7xxblavsacpy82zdbn4kplsyq48l-libunistring-1.1
/nix/store/ji01n9vinnj22nbrb86nx8a1ssgpilx8-libidn2-2.3.4
/nix/store/ldrslljw4rg026nw06gyrdwl78k77vyq-xgcc-12.3.0-libgcc
/nix/store/9y8pmvk8gdwwznmkzxa6pwyah52xy3nk-glibc-2.38-27
/nix/store/zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1

This means that all these packages will be included in the image generated by streamLayeredImage. It will put each package in its own layer, for a total of 5 layers with actual files in them. A final layer will be created only with symlinks for the hello package.

The image generated will have the following directory structure (some directories were collapsed for readability):

├── bin
│   └── hello → /nix/store/zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1/bin/hello
├── nix
│   └── store
│       ├─⊕ 9y8pmvk8gdwwznmkzxa6pwyah52xy3nk-glibc-2.38-27
│       ├─⊕ i93s7xxblavsacpy82zdbn4kplsyq48l-libunistring-1.1
│       ├─⊕ ji01n9vinnj22nbrb86nx8a1ssgpilx8-libidn2-2.3.4
│       ├─⊕ ldrslljw4rg026nw06gyrdwl78k77vyq-xgcc-12.3.0-libgcc
│       └─⊕ zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1
└── share
    ├── info
    │   └── hello.info → /nix/store/zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1/share/info/hello.info
    ├─⊕ locale
    └── man
        └── man1
            └── hello.1.gz → /nix/store/zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1/share/man/man1/hello.1.gz

Each of the packages in /nix/store comes from a layer in the image. The final layer adds the /bin and /share directories, but they only contain links to the actual files in /nix/store.

If our package sets includeStorePaths to false, we'll end up with only the final layer with the links, but the actual files won't exist in the image:

{ dockerTools, hello }:
dockerTools.streamLayeredImage {
  name = "hello";
  contents = [ hello ];
  includeStorePaths = false;
}

After building this package, the image will have the following directory structure:

├── bin
│   └── hello → /nix/store/zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1/bin/hello
└── share
    ├── info
    │   └── hello.info → /nix/store/zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1/share/info/hello.info
    ├─⊕ locale
    └── man
        └── man1
            └── hello.1.gz → /nix/store/zhl06z4lrfrkw5rp0hnjjfrgsclzvxpm-hello-2.12.1/share/man/man1/hello.1.gz

Note how the links point to paths in /nix/store, but they're not included in the image itself. This is why you need extra tooling when using includeStorePaths: a container created from such image won't find any of the files it needs to run otherwise. :::

::: {.example #ex-dockerTools-streamLayeredImage-configclosure}

Building a layered Docker image with packages directly in config

The closure of config is automatically included in the generated image. The following package shows a more compact way to create the same output generated in .

{ dockerTools, hello, lib }:
dockerTools.streamLayeredImage {
  name = "hello";
  tag = "latest";
  config.Cmd = [ "${lib.getExe hello}" ];
}

:::

[]{#ssec-pkgs-dockerTools-fetchFromRegistry}

pullImage

This function is similar to the docker image pull command, which means it can be used to pull a Docker image from a registry that implements the Docker Registry HTTP API V2. By default, the docker.io registry is used.

The image will be downloaded as an uncompressed Docker-compatible repository tarball, which is suitable for use with other dockerTools functions such as buildImage, buildLayeredImage, and streamLayeredImage.

This function requires two different types of hashes/digests to be specified:

  • One of them is used to identify a unique image within the registry (see the documentation for the imageDigest attribute).
  • The other is used by Nix to ensure the contents of the output haven't changed (see the documentation for the sha256 attribute).

Both hashes are required because they must uniquely identify some content in two completely different systems (the Docker registry and the Nix store), but their values will not be the same. See for a tool that can help gather these values.

Inputs

pullImage expects a single argument with the following attributes:

imageName (String)

Specifies the name of the image to be downloaded, as well as the registry endpoint. By default, the docker.io registry is used. To specify a different registry, prepend the endpoint to imageName, separated by a slash (/). See for how to do that.

imageDigest (String)

Specifies the digest of the image to be downloaded.

:::{.tip} Why can't I specify a tag to pull from, and have to use a digest instead?

Tags are often updated to point to different image contents. The most common example is the latest tag, which is usually updated whenever a newer image version is available.

An image tag isn't enough to guarantee the contents of an image won't change, but a digest guarantees this. Providing a digest helps ensure that you will still be able to build the same Nix code and get the same output even if newer versions of an image are released. :::

sha256 (String)

The hash of the image after it is downloaded. Internally, this is passed to the outputHash attribute of the resulting derivation. This is needed to provide a guarantee to Nix that the contents of the image haven't changed, because Nix doesn't support the value in imageDigest.

finalImageName (String; optional)

Specifies the name that will be used for the image after it has been downloaded. This only applies after the image is downloaded, and is not used to identify the image to be downloaded in the registry. Use imageName for that instead.

Default value: the same value specified in imageName.

finalImageTag (String; optional)

Specifies the tag that will be used for the image after it has been downloaded. This only applies after the image is downloaded, and is not used to identify the image to be downloaded in the registry.

Default value: "latest".

os (String; optional)

Specifies the operating system of the image to pull. If specified, its value should follow the OCI Image Configuration Specification, which should still be compatible with Docker. According to the linked specification, all possible values for $GOOS in the Go docs should be valid, but will commonly be one of darwin or linux.

Default value: "linux".

arch (String; optional)

Specifies the architecture of the image to pull. If specified, its value should follow the OCI Image Configuration Specification, which should still be compatible with Docker. According to the linked specification, all possible values for $GOARCH in the Go docs should be valid, but will commonly be one of 386, amd64, arm, or arm64.

Default value: the same value from pkgs.go.GOARCH.

tlsVerify (Boolean; optional)

Used to enable or disable HTTPS and TLS certificate verification when communicating with the chosen Docker registry. Setting this to false will make pullImage connect to the registry through HTTP.

Default value: true.

name (String; optional)

The name used for the output in the Nix store path.

Default value: a value derived from finalImageName and finalImageTag, with some symbols replaced. It is recommended to treat the default as an opaque value.

Examples

::: {.example #ex-dockerTools-pullImage-niximage}

Pulling the nixos/nix Docker image from the default registry

This example pulls the nixos/nix image and saves it in the Nix store.

{ dockerTools }:
dockerTools.pullImage {
  imageName = "nixos/nix";
  imageDigest = "sha256:b8ea88f763f33dfda2317b55eeda3b1a4006692ee29e60ee54ccf6d07348c598";
  finalImageName = "nix";
  finalImageTag = "2.19.3";
  sha256 = "zRwlQs1FiKrvHPaf8vWOR/Tlp1C5eLn1d9pE4BZg3oA=";
}

:::

::: {.example #ex-dockerTools-pullImage-differentregistry}

Pulling the nixos/nix Docker image from a specific registry

This example pulls the coreos/etcd image from the quay.io registry.

{ dockerTools }:
dockerTools.pullImage {
  imageName = "quay.io/coreos/etcd";
  imageDigest = "sha256:24a23053f29266fb2731ebea27f915bb0fb2ae1ea87d42d890fe4e44f2e27c5d";
  finalImageName = "etcd";
  finalImageTag = "v3.5.11";
  sha256 = "Myw+85f2/EVRyMB3axECdmQ5eh9p1q77FWYKy8YpRWU=";
}

:::

::: {.example #ex-dockerTools-pullImage-nixprefetchdocker}

Finding the digest and hash values to use for dockerTools.pullImage

Since dockerTools.pullImage requires two different hashes, one can run the nix-prefetch-docker tool to find out the values for the hashes. The tool outputs some text for an attribute set which you can pass directly to pullImage.

$ nix run nixpkgs#nix-prefetch-docker -- --image-name nixos/nix --image-tag 2.19.3 --arch amd64 --os linux
(some output removed for clarity)
Writing manifest to image destination
-> ImageName: nixos/nix
-> ImageDigest: sha256:498fa2d7f2b5cb3891a4edf20f3a8f8496e70865099ba72540494cd3e2942634
-> FinalImageName: nixos/nix
-> FinalImageTag: latest
-> ImagePath: /nix/store/4mxy9mn6978zkvlc670g5703nijsqc95-docker-image-nixos-nix-latest.tar
-> ImageHash: 1q6cf2pdrasa34zz0jw7pbs6lvv52rq2aibgxccbwcagwkg2qj1q
{
  imageName = "nixos/nix";
  imageDigest = "sha256:498fa2d7f2b5cb3891a4edf20f3a8f8496e70865099ba72540494cd3e2942634";
  sha256 = "1q6cf2pdrasa34zz0jw7pbs6lvv52rq2aibgxccbwcagwkg2qj1q";
  finalImageName = "nixos/nix";
  finalImageTag = "latest";
}

It is important to supply the --arch and --os arguments to nix-prefetch-docker to filter to a single image, in case there are multiple architectures and/or operating systems supported by the image name and tags specified. By default, nix-prefetch-docker will set os to linux and arch to amd64.

Run nix-prefetch-docker --help for a list of all supported arguments:

$ nix run nixpkgs#nix-prefetch-docker -- --help
(output removed for clarity)

:::

exportImage

This function is similar to the docker container export command, which means it can be used to export an image's filesystem as an uncompressed tarball archive. The difference is that docker container export is applied to containers, but dockerTools.exportImage applies to Docker images. The resulting archive will not contain any image metadata (such as command to run with docker container run), only the filesystem contents.

You can use this function to import an archive in Docker with docker image import. See to understand how to do that.

:::{.caution} exportImage works by unpacking the given image inside a VM. Because of this, using this function requires the kvm device to be available, see system-features. :::

Inputs

exportImage expects an argument with the following attributes:

fromImage (Attribute Set or String)

The repository tarball of the image whose filesystem will be exported. It must be a valid Docker image, such as one exported by docker image save, or another image built with the dockerTools utility functions.

If name is not specified, fromImage must be an Attribute Set corresponding to a derivation, i.e. it can't be a path to a tarball. If name is specified, fromImage can be either an Attribute Set corresponding to a derivation or simply a path to a tarball.

See and to understand the connection between fromImage, name, and the name used for the output of exportImage.

fromImageName (String or Null; optional)

Used to specify the image within the repository tarball in case it contains multiple images. A value of null means that exportImage will use the first image available in the repository.

:::{.note} This must be used with fromImageTag. Using only fromImageName without fromImageTag will make exportImage use the first image available in the repository. :::

Default value: null.

fromImageTag (String or Null; optional)

Used to specify the image within the repository tarball in case it contains multiple images. A value of null means that exportImage will use the first image available in the repository.

:::{.note} This must be used with fromImageName. Using only fromImageTag without fromImageName will make exportImage use the first image available in the repository :::

Default value: null.

diskSize (Number; optional)

Controls the disk size (in megabytes) of the VM used to unpack the image.

Default value: 1024.

name (String; optional)

The name used for the output in the Nix store path.

Default value: the value of fromImage.name.

Examples

:::{.example #ex-dockerTools-exportImage-hello}

Exporting a Docker image with dockerTools.exportImage

This example first builds a layered image with dockerTools.buildLayeredImage, and then exports its filesystem with dockerTools.exportImage.

{ dockerTools, hello }:
dockerTools.exportImage {
  name = "hello";
  fromImage = dockerTools.buildLayeredImage {
    name = "hello";
    contents = [ hello ];
  };
}

When building the package above, we can see the layers of the Docker image being unpacked to produce the final output:

$ nix-build
(some output removed for clarity)
Unpacking base image...
From-image name or tag wasn't set. Reading the first ID.
Unpacking layer 5731199219418f175d1580dbca05677e69144425b2d9ecb60f416cd57ca3ca42/layer.tar
tar: Removing leading `/' from member names
Unpacking layer e2897bf34bb78c4a65736510204282d9f7ca258ba048c183d665bd0f3d24c5ec/layer.tar
tar: Removing leading `/' from member names
Unpacking layer 420aa5876dca4128cd5256da7dea0948e30ef5971712f82601718cdb0a6b4cda/layer.tar
tar: Removing leading `/' from member names
Unpacking layer ea5f4e620e7906c8ecbc506b5e6f46420e68d4b842c3303260d5eb621b5942e5/layer.tar
tar: Removing leading `/' from member names
Unpacking layer 65807b9abe8ab753fa97da8fb74a21fcd4725cc51e1b679c7973c97acd47ebcf/layer.tar
tar: Removing leading `/' from member names
Unpacking layer b7da2076b60ebc0ea6824ef641978332b8ac908d47b2d07ff31b9cc362245605/layer.tar
Executing post-mount steps...
Packing raw image...
[    1.660036] reboot: Power down
/nix/store/x6a5m7c6zdpqz1d8j7cnzpx9glzzvd2h-hello

The following command lists some of the contents of the output to verify that the structure of the archive is as expected:

$ tar --exclude '*/share/*' --exclude 'nix/store/*/*' -tvf /nix/store/x6a5m7c6zdpqz1d8j7cnzpx9glzzvd2h-hello
drwxr-xr-x root/0            0 1979-12-31 16:00 ./
drwxr-xr-x root/0            0 1979-12-31 16:00 ./bin/
lrwxrwxrwx root/0            0 1979-12-31 16:00 ./bin/hello -> /nix/store/h92a9jd0lhhniv2q417hpwszd4jhys7q-hello-2.12.1/bin/hello
dr-xr-xr-x root/0            0 1979-12-31 16:00 ./nix/
dr-xr-xr-x root/0            0 1979-12-31 16:00 ./nix/store/
dr-xr-xr-x root/0            0 1979-12-31 16:00 ./nix/store/05zbwhz8a7i2v79r9j21pl6m6cj0xi8k-libunistring-1.1/
dr-xr-xr-x root/0            0 1979-12-31 16:00 ./nix/store/ayg5rhjhi9ic73hqw33mjqjxwv59ndym-xgcc-13.2.0-libgcc/
dr-xr-xr-x root/0            0 1979-12-31 16:00 ./nix/store/h92a9jd0lhhniv2q417hpwszd4jhys7q-hello-2.12.1/
dr-xr-xr-x root/0            0 1979-12-31 16:00 ./nix/store/m59xdgkgnjbk8kk6k6vbxmqnf82mk9s0-libidn2-2.3.4/
dr-xr-xr-x root/0            0 1979-12-31 16:00 ./nix/store/p3jshbwxiwifm1py0yq544fmdyy98j8a-glibc-2.38-27/
drwxr-xr-x root/0            0 1979-12-31 16:00 ./share/

:::

:::{.example #ex-dockerTools-exportImage-importingDocker}

Importing an archive built with dockerTools.exportImage in Docker

We will use the same package from and import it into Docker.

{ dockerTools, hello }:
dockerTools.exportImage {
  name = "hello";
  fromImage = dockerTools.buildLayeredImage {
    name = "hello";
    contents = [ hello ];
  };
}

Building and importing it into Docker:

$ nix-build
(output removed for clarity)
/nix/store/x6a5m7c6zdpqz1d8j7cnzpx9glzzvd2h-hello
$ docker image import /nix/store/x6a5m7c6zdpqz1d8j7cnzpx9glzzvd2h-hello
sha256:1d42dba415e9b298ea0decf6497fbce954de9b4fcb2984f91e307c8fedc1f52f
$ docker image ls
REPOSITORY                              TAG                IMAGE ID       CREATED         SIZE
<none>                                  <none>             1d42dba415e9   4 seconds ago   32.6MB

:::

:::{.example #ex-dockerTools-exportImage-naming}

Exploring output naming with dockerTools.exportImage

exportImage does not require a name attribute if fromImage is a derivation, which means that the following works:

{ dockerTools, hello }:
dockerTools.exportImage {
  fromImage = dockerTools.buildLayeredImage {
    name = "hello";
    contents = [ hello ];
  };
}

However, since dockerTools.buildLayeredImage's output ends with .tar.gz, the output of exportImage will also end with .tar.gz, even though the archive created with exportImage is uncompressed:

$ nix-build
(output removed for clarity)
/nix/store/by3f40xvc4l6bkis74l0fj4zsy0djgkn-hello.tar.gz
$ file /nix/store/by3f40xvc4l6bkis74l0fj4zsy0djgkn-hello.tar.gz
/nix/store/by3f40xvc4l6bkis74l0fj4zsy0djgkn-hello.tar.gz: POSIX tar archive (GNU)

If the archive was actually compressed, the output of file would've mentioned that fact. Because of this, it may be important to set a proper name attribute when using exportImage with other functions from dockerTools. :::

:::{.example #ex-dockerTools-exportImage-fromImagePath}

Using dockerTools.exportImage with a path as fromImage

It is possible to use a path as the value of the fromImage attribute when calling dockerTools.exportImage. However, when doing so, a name attribute MUST be specified, or you'll encounter an error when evaluating the Nix code.

For this example, we'll assume a Docker tarball image named image.tar.gz exists in the same directory where our package is defined:

{ dockerTools }:
dockerTools.exportImage {
  name = "filesystem.tar";
  fromImage = ./image.tar.gz;
}

Building this will give us the expected output:

$ nix-build
(output removed for clarity)
/nix/store/w13l8h3nlkg0zv56k7rj0ai0l2zlf7ss-filesystem.tar

If you don't specify a name attribute, you'll encounter an evaluation error and the package won't build. :::

Environment Helpers

When building Docker images with Nix, you might also want to add certain files that are expected to be available globally by the software you're packaging. Simple examples are the env utility in /usr/bin/env, or trusted root TLS/SSL certificates. Such files will most likely not be included if you're building a Docker image from scratch with Nix, and they might also not be included if you're starting from a Docker image that doesn't include them. The helpers in this section are packages that provide some of these commonly-needed global files.

Most of these helpers are packages, which means you have to add them to the list of contents to be included in the image (this changes depending on the function you're using to build the image). and show how to include these packages on dockerTools functions that build an image. For more details on how that works, see the documentation for the function you're using.

usrBinEnv

This provides the env utility at /usr/bin/env. This is currently implemented by linking to the env binary from the coreutils package, but is considered an implementation detail that could change in the future.

binSh

This provides a /bin/sh link to the bash binary from the bashInteractive package. Because of this, it supports cases such as running a command interactively in a container (for example by running docker container run -it <image_name>).

caCertificates

This adds trusted root TLS/SSL certificates from the cacert package in multiple locations in an attempt to be compatible with binaries built for multiple Linux distributions. The locations currently used are:

  • /etc/ssl/certs/ca-bundle.crt
  • /etc/ssl/certs/ca-certificates.crt
  • /etc/pki/tls/certs/ca-bundle.crt

[]{#ssec-pkgs-dockerTools-fakeNss}

fakeNss

This is a re-export of the fakeNss package from Nixpkgs. See .

shadowSetup

This is a string containing a script that sets up files needed for shadow to work (using the shadow package from Nixpkgs), and alters PATH to make all its utilities available in the same script. It is intended to be used with other dockerTools functions in attributes that expect scripts. After the script in shadowSetup runs, you'll then be able to add more commands that make use of the utilities in shadow, such as adding any extra users and/or groups. See and to better understand how to use it.

shadowSetup achieves a result similar to fakeNss, but only sets up a root user with different values for the home directory and the shell to use, in addition to setting up files for PAM and a {manpage}login.defs(5) file.

:::{.caution} Using both fakeNss and shadowSetup at the same time will either cause your build to break or produce unexpected results. Use either fakeNss or shadowSetup depending on your use case, but avoid using both. :::

:::{.note} When used with buildLayeredImage or streamLayeredImage, you will have to set the enableFakechroot attribute to true, or else the script in shadowSetup won't run properly. See . :::

Examples

:::{.example #ex-dockerTools-helpers-buildImage}

Using dockerTools's environment helpers with buildImage

This example adds the binSh helper to a basic Docker image built with dockerTools.buildImage. This helper makes it possible to enter a shell inside the container. This is the buildImage equivalent of .

{ dockerTools, hello }:
dockerTools.buildImage {
  name = "env-helpers";
  tag = "latest";

  copyToRoot = [
    hello
    dockerTools.binSh
  ];

After building the image and loading it in Docker, we can create a container based on it and enter a shell inside the container. This is made possible by binSh.

$ nix-build
(some output removed for clarity)
/nix/store/2p0i3i04cgjlk71hsn7ll4kxaxxiv4qg-docker-image-env-helpers.tar.gz
$ docker image load -i /nix/store/2p0i3i04cgjlk71hsn7ll4kxaxxiv4qg-docker-image-env-helpers.tar.gz
(output removed for clarity)
$ docker container run --rm -it env-helpers:latest /bin/sh
sh-5.2# help
GNU bash, version 5.2.21(1)-release (x86_64-pc-linux-gnu)
(rest of output removed for clarity)

:::

:::{.example #ex-dockerTools-helpers-buildLayeredImage}

Using dockerTools's environment helpers with buildLayeredImage

This example adds the binSh helper to a basic Docker image built with dockerTools.buildLayeredImage. This helper makes it possible to enter a shell inside the container. This is the buildLayeredImage equivalent of .

{ dockerTools, hello }:
dockerTools.buildLayeredImage {
  name = "env-helpers";
  tag = "latest";

  contents = [
    hello
    dockerTools.binSh
  ];

  config = {
    Cmd = [ "/bin/hello" ];
  };
}

After building the image and loading it in Docker, we can create a container based on it and enter a shell inside the container. This is made possible by binSh.

$ nix-build
(some output removed for clarity)
/nix/store/rpf47f4z5b9qr4db4ach9yr4b85hjhxq-env-helpers.tar.gz
$ docker image load -i /nix/store/rpf47f4z5b9qr4db4ach9yr4b85hjhxq-env-helpers.tar.gz
(output removed for clarity)
$ docker container run --rm -it env-helpers:latest /bin/sh
sh-5.2# help
GNU bash, version 5.2.21(1)-release (x86_64-pc-linux-gnu)
(rest of output removed for clarity)

:::

:::{.example #ex-dockerTools-shadowSetup-buildImage}

Using dockerTools.shadowSetup with dockerTools.buildImage

This is an example that shows how to use shadowSetup with dockerTools.buildImage. Note that the extra script in runAsRoot uses groupadd and useradd, which are binaries provided by the shadow package. These binaries are added to the PATH by the shadowSetup script, but only for the duration of runAsRoot.

{ dockerTools, hello }:
dockerTools.buildImage {
  name = "shadow-basic";
  tag = "latest";

  copyToRoot = [ hello ];

  runAsRoot = ''
    ${dockerTools.shadowSetup}
    groupadd -r hello
    useradd -r -g hello hello
    mkdir /data
    chown hello:hello /data
  '';

  config = {
    Cmd = [ "/bin/hello" ];
    WorkingDir = "/data";
  };
}

:::

:::{.example #ex-dockerTools-shadowSetup-buildLayeredImage}

Using dockerTools.shadowSetup with dockerTools.buildLayeredImage

It accomplishes the same thing as , but using buildLayeredImage instead.

Note that the extra script in fakeRootCommands uses groupadd and useradd, which are binaries provided by the shadow package. These binaries are added to the PATH by the shadowSetup script, but only for the duration of fakeRootCommands.

{ dockerTools, hello }:
dockerTools.buildLayeredImage {
  name = "shadow-basic";
  tag = "latest";

  contents = [ hello ];

  fakeRootCommands = ''
    ${dockerTools.shadowSetup}
    groupadd -r hello
    useradd -r -g hello hello
    mkdir /data
    chown hello:hello /data
  '';
  enableFakechroot = true;

  config = {
    Cmd = [ "/bin/hello" ];
    WorkingDir = "/data";
  };
}

:::

[]{#ssec-pkgs-dockerTools-buildNixShellImage-arguments}

buildNixShellImage

buildNixShellImage uses streamNixShellImage underneath to build a compressed Docker-compatible repository tarball of an image that sets up an environment similar to that of running nix-shell on a derivation. Basically, buildNixShellImage runs the script created by streamNixShellImage to save the compressed image in the Nix store.

buildNixShellImage supports the same options as streamNixShellImage, see streamNixShellImage for details.

[]{#ssec-pkgs-dockerTools-buildNixShellImage-example}

Examples

:::{.example #ex-dockerTools-buildNixShellImage-hello}

Building a Docker image with buildNixShellImage with the build environment for the hello package

This example shows how to build the hello package inside a Docker container built with buildNixShellImage. The Docker image generated will have a name like hello-<version>-env and tag latest. This example is the buildNixShellImage equivalent of .

{ dockerTools, hello }:
dockerTools.buildNixShellImage {
  drv = hello;
  tag = "latest";
}

The result of building this package is a .tar.gz file that can be loaded into Docker:

$ nix-build
(some output removed for clarity)
/nix/store/pkj1sgzaz31wl0pbvbg3yp5b3kxndqms-hello-2.12.1-env.tar.gz

$ docker image load -i /nix/store/pkj1sgzaz31wl0pbvbg3yp5b3kxndqms-hello-2.12.1-env.tar.gz
(some output removed for clarity)
Loaded image: hello-2.12.1-env:latest

After starting an interactive container, the derivation can be built by running buildDerivation, and the output can be executed as expected:

$ docker container run -it hello-2.12.1-env:latest
[nix-shell:~]$ buildDerivation
Running phase: unpackPhase
unpacking source archive /nix/store/pa10z4ngm0g83kx9mssrqzz30s84vq7k-hello-2.12.1.tar.gz
source root is hello-2.12.1
(some output removed for clarity)
Running phase: fixupPhase
shrinking RPATHs of ELF executables and libraries in /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1
shrinking /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1/bin/hello
checking for references to /build/ in /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1...
gzipping man pages under /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1/share/man/
patching script interpreter paths in /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1
stripping (with command strip and flags -S -p) in  /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1/bin

[nix-shell:~]$ $out/bin/hello
Hello, world!

:::

streamNixShellImage

streamNixShellImage builds a script which, when run, will stream to stdout a Docker-compatible repository tarball of an image that sets up an environment similar to that of running nix-shell on a derivation. This means that streamNixShellImage does not output an image into the Nix store, but only a script that builds the image, saving on IO and disk/cache space, particularly with large images. See to understand how to load in Docker the image generated by this script.

The environment set up by streamNixShellImage somewhat resembles the Nix sandbox typically used by nix-build, with a major difference being that access to the internet is allowed. It also behaves like an interactive nix-shell, running things like shellHook (see ) and setting an interactive prompt. If the derivation is buildable (i.e. nix-build can be used on it), running buildDerivation in the container will build the derivation, with all its outputs being available in the correct /nix/store paths, pointed to by the respective environment variables (e.g. $out).

::: {.caution} The environment in the image doesn't match nix-shell or nix-build exactly, and this function is known not to work correctly for fixed-output derivations, content-addressed derivations, impure derivations and other special types of derivations. :::

Inputs

streamNixShellImage expects one argument with the following attributes:

drv (Attribute Set)

The derivation for which the environment in the image will be set up. Adding packages to the Docker image is possible by extending the list of nativeBuildInputs of this derivation. See for how to do that. Similarly, you can extend the image initialization script by extending shellHook. shows how to do that.

name (String; optional)

The name of the generated image.

Default value: the value of drv.name + "-env".

tag (String or Null; optional)

Tag of the generated image. If null, the hash of the nix derivation that builds the Docker image will be used as the tag.

Default value: null.

uid (Number; optional)

The user ID to run the container as. This can be seen as a nixbld build user.

Default value: 1000.

gid (Number; optional)

The group ID to run the container as. This can be seen as a nixbld build group.

Default value: 1000.

homeDirectory (String; optional)

The home directory of the user the container is running as.

Default value: /build.

shell (String; optional)

The path to the bash binary to use as the shell. This shell is started when running the image. This can be seen as an equivalent of the NIX_BUILD_SHELL environment variable for {manpage}nix-shell(1).

Default value: the bash binary from the bashInteractive package.

command (String or Null; optional)

If specified, this command will be run in the environment of the derivation in an interactive shell. A call to exit will be added after the command if it is specified, so the shell will exit after it's finished running. This can be seen as an equivalent of the --command option in {manpage}nix-shell(1).

Default value: null.

run (String or Null; optional)

Similar to the command attribute, but runs the command in a non-interactive shell instead. A call to exit will be added after the command if it is specified, so the shell will exit after it's finished running. This can be seen as an equivalent of the --run option in {manpage}nix-shell(1).

Default value: null.

Examples

:::{.example #ex-dockerTools-streamNixShellImage-hello}

Building a Docker image with streamNixShellImage with the build environment for the hello package

This example shows how to build the hello package inside a Docker container built with streamNixShellImage. The Docker image generated will have a name like hello-<version>-env and tag latest. This example is the streamNixShellImage equivalent of .

{ dockerTools, hello }:
dockerTools.streamNixShellImage {
  drv = hello;
  tag = "latest";
}

The result of building this package is a script. Running this script and piping it into docker image load gives you the same image that was built in .

$ nix-build
(some output removed for clarity)
/nix/store/8vhznpz2frqazxnd8pgdvf38jscdypax-stream-hello-2.12.1-env

$ /nix/store/8vhznpz2frqazxnd8pgdvf38jscdypax-stream-hello-2.12.1-env | docker image load
(some output removed for clarity)
Loaded image: hello-2.12.1-env:latest

After starting an interactive container, the derivation can be built by running buildDerivation, and the output can be executed as expected:

$ docker container run -it hello-2.12.1-env:latest
[nix-shell:~]$ buildDerivation
Running phase: unpackPhase
unpacking source archive /nix/store/pa10z4ngm0g83kx9mssrqzz30s84vq7k-hello-2.12.1.tar.gz
source root is hello-2.12.1
(some output removed for clarity)
Running phase: fixupPhase
shrinking RPATHs of ELF executables and libraries in /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1
shrinking /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1/bin/hello
checking for references to /build/ in /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1...
gzipping man pages under /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1/share/man/
patching script interpreter paths in /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1
stripping (with command strip and flags -S -p) in  /nix/store/f2vs29jibd7lwxyj35r9h87h6brgdysz-hello-2.12.1/bin

[nix-shell:~]$ $out/bin/hello
Hello, world!

:::

:::{.example #ex-dockerTools-streamNixShellImage-extendingBuildInputs}

Adding extra packages to a Docker image built with streamNixShellImage

This example shows how to add extra packages to an image built with streamNixShellImage. In this case, we'll add the cowsay package. The Docker image generated will have a name like hello-<version>-env and tag latest. This example uses as a starting point.

{ dockerTools, cowsay, hello }:
dockerTools.streamNixShellImage {
  tag = "latest";
  drv = hello.overrideAttrs (old: {
    nativeBuildInputs = old.nativeBuildInputs or [] ++ [
      cowsay
    ];
  });
}

The result of building this package is a script which can be run and piped into docker image load to load the generated image.

$ nix-build
(some output removed for clarity)
/nix/store/h5abh0vljgzg381lna922gqknx6yc0v7-stream-hello-2.12.1-env

$ /nix/store/h5abh0vljgzg381lna922gqknx6yc0v7-stream-hello-2.12.1-env | docker image load
(some output removed for clarity)
Loaded image: hello-2.12.1-env:latest

After starting an interactive container, we can verify the extra package is available by running cowsay:

$ docker container run -it hello-2.12.1-env:latest
[nix-shell:~]$ cowsay "Hello, world!"
 _______________
< Hello, world! >
 ---------------
        \   ^__^
         \  (oo)\_______
            (__)\       )\/\
                ||----w |
                ||     ||

:::

:::{.example #ex-dockerTools-streamNixShellImage-addingShellHook}

Adding a shellHook to a Docker image built with streamNixShellImage

This example shows how to add a shellHook command to an image built with streamNixShellImage. In this case, we'll simply output the string Hello, world!. The Docker image generated will have a name like hello-<version>-env and tag latest. This example uses as a starting point.

{ dockerTools, hello }:
dockerTools.streamNixShellImage {
  tag = "latest";
  drv = hello.overrideAttrs (old: {
    shellHook = ''
      ${old.shellHook or ""}
      echo "Hello, world!"
    '';
  });
}

The result of building this package is a script which can be run and piped into docker image load to load the generated image.

$ nix-build
(some output removed for clarity)
/nix/store/iz4dhdvgzazl5vrgyz719iwjzjy6xlx1-stream-hello-2.12.1-env

$ /nix/store/iz4dhdvgzazl5vrgyz719iwjzjy6xlx1-stream-hello-2.12.1-env | docker image load
(some output removed for clarity)
Loaded image: hello-2.12.1-env:latest

After starting an interactive container, we can see the result of the shellHook:

$ docker container run -it hello-2.12.1-env:latest
Hello, world!

[nix-shell:~]$

:::