`pkgs.dockerTools` is a set of functions for creating and manipulating Docker images according to the [Docker Image Specification v1.3.0](https://github.com/moby/moby/blob/46f7ab808b9504d735d600e259ca0723f76fb164/image/spec/spec.md#image-json-field-descriptions).
Docker itself is not used to perform any of the operations done by these functions.
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 [](#ssec-pkgs-dockerTools-buildLayeredImage) or [](#ssec-pkgs-dockerTools-streamLayeredImage) 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).
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.
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`.
: 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 [](#ex-dockerTools-buildImage-runAsRoot) for how to work with this attribute.
:::{.caution}
Using this attribute requires the `kvm` device to be available, see [`system-features`](https://nixos.org/manual/nix/stable/command-ref/conf-file.html#conf-system-features).
If the `kvm` device isn't available, you should consider using [`buildLayeredImage`](#ssec-pkgs-dockerTools-buildLayeredImage) or [`streamLayeredImage`](#ssec-pkgs-dockerTools-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 [](#ex-dockerTools-buildImage-extraCommands) for how to work with this attribute, and subtle differences compared to `runAsRoot`.
: 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](https://github.com/moby/moby/blob/46f7ab808b9504d735d600e259ca0723f76fb164/image/spec/spec.md#image-json-field-descriptions).
_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](https://github.com/opencontainers/image-spec/blob/main/config.md#properties), which should still be compatible with Docker.
According to the linked specification, all possible values for `$GOARCH` in [the Go docs](https://go.dev/doc/install/source#environment) 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](https://en.wikipedia.org/wiki/ISO_8601) or `"now"`, in which case `buildImage` will use the current date.
See [](#ex-dockerTools-buildImage-creatednow) 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`.
: Populate the nix database in the image with the dependencies of `copyToRoot`.
The main purpose is to be able to use nix commands in the container.
:::{.caution}
Be careful since this doesn't work well in combination with `fromImage`. In particular, in a multi-layered image, only the Nix paths from the lower image will be in the database.
This also neglects to register the store paths that are pulled into the image as a dependency of one of the other values, but aren't a dependency of `copyToRoot`.
`buildLayeredImage` uses [`streamLayeredImage`](#ssec-pkgs-dockerTools-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`](#ssec-pkgs-dockerTools-streamLayeredImage) for details.
:::{.note}
Despite the similar name, [`buildImage`](#ssec-pkgs-dockerTools-buildImage) works completely differently from `buildLayeredImage` and `streamLayeredImage`.
Even though some of the arguments may seem related, they cannot be interchanged.
`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.
For this function, you specify a [store path](https://nixos.org/manual/nix/stable/store/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"](https://github.com/NixOS/nixpkgs/tree/release-23.11/pkgs/build-support/references-by-popularity) 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`](#trivial-builder-symlinkJoin), so they will be included in the root of the image.
See [](#ex-dockerTools-streamLayeredImage-exploringlayers) 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.
: 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](https://github.com/moby/moby/blob/46f7ab808b9504d735d600e259ca0723f76fb164/image/spec/spec.md#image-json-field-descriptions).
If any packages are used directly in `config`, they will be automatically included in the generated image.
See [](#ex-dockerTools-streamLayeredImage-configclosure) 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](https://github.com/opencontainers/image-spec/blob/main/config.md#properties), which should still be compatible with Docker.
According to the linked specification, all possible values for `$GOARCH` in [the Go docs](https://go.dev/doc/install/source#environment) 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](https://en.wikipedia.org/wiki/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).
: Specifies the time used for the modification timestamp of files within the layers of the generated image.
This should be either a date and time formatted according to [ISO-8601](https://en.wikipedia.org/wiki/ISO_8601) or `"now"`, in which case the current date will be used.
:::{.caution}
Using a non-constant date will cause built layers to have a different hash each time, preventing deduplication.
Using `"now"` also means that the generated image will not be reproducible anymore (because the date will always change whenever it's built).
Can be overridden to e.g. `1000` / `1000` / `"user"` / `"user"` to enable building a container where Nix can be used as an unprivileged user in single-user mode.
: 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`.
: 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).
Due to how fakeroot works, static binaries cannot perform privileged file operations in `fakeRootCommands`, unless `enableFakechroot` is set to `true`.
: 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`](https://proot-me.github.io/) 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`.
: 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.
: Populate the nix database in the image with the dependencies of `copyToRoot`.
The main purpose is to be able to use nix commands in the container.
:::{.caution}
Be careful since this doesn't work well in combination with `fromImage`. In particular, in a multi-layered image, only the Nix paths from the lower image will be in the database.
This also neglects to register the store paths that are pulled into the image as a dependency of one of the other values, but aren't a dependency of `copyToRoot`.
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`.
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:
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](https://distribution.github.io/distribution/spec/api/).
The image will be downloaded as an uncompressed Docker-compatible repository tarball, which is suitable for use with other `dockerTools` functions such as [`buildImage`](#ssec-pkgs-dockerTools-buildImage), [`buildLayeredImage`](#ssec-pkgs-dockerTools-buildLayeredImage), and [`streamLayeredImage`](#ssec-pkgs-dockerTools-streamLayeredImage).
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 [](#ex-dockerTools-pullImage-nixprefetchdocker) for a tool that can help gather these values.
**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`](https://nixos.org/manual/nix/stable/language/advanced-attributes#adv-attr-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](https://github.com/opencontainers/image-spec/blob/main/config.md#properties), which should still be compatible with Docker.
According to the linked specification, all possible values for `$GOOS` in [the Go docs](https://go.dev/doc/install/source#environment) should be valid, but will commonly be one of `darwin` or `linux`.
_Default value:_`"linux"`.
`arch` (String; _optional_)
: Specifies the architecture of the image to pull.
If specified, its value should follow the [OCI Image Configuration Specification](https://github.com/opencontainers/image-spec/blob/main/config.md#properties), which should still be compatible with Docker.
According to the linked specification, all possible values for `$GOARCH` in [the Go docs](https://go.dev/doc/install/source#environment) 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.
Since [`dockerTools.pullImage`](#ssec-pkgs-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`.
```shell
$ nix run nixpkgs#nix-prefetch-docker -- --image-name nixos/nix --image-tag 2.19.3 --arch amd64 --os linux
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:
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.
`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`](https://nixos.org/manual/nix/stable/command-ref/conf-file.html#conf-system-features).
`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 [](#ex-dockerTools-exportImage-naming) and [](#ex-dockerTools-exportImage-fromImagePath) 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.
# Exporting a Docker image with `dockerTools.exportImage`
This example first builds a layered image with [`dockerTools.buildLayeredImage`](#ssec-pkgs-dockerTools-buildLayeredImage), and then exports its filesystem with `dockerTools.exportImage`.
```nix
{ 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:
```shell
$ nix-build
(some output removed for clarity)
Unpacking base image...
From-image name or tag wasn't set. Reading the first ID.
However, since [`dockerTools.buildLayeredImage`](#ssec-pkgs-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:
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).
[](#ex-dockerTools-helpers-buildImage) and [](#ex-dockerTools-helpers-buildLayeredImage) 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.
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.
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>`).
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.
This is a string containing a script that sets up files needed for [`shadow`](https://github.com/shadow-maint/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 [](#ex-dockerTools-shadowSetup-buildImage) and [](#ex-dockerTools-shadowSetup-buildLayeredImage) to better understand how to use it.
`shadowSetup` achieves a result similar to [`fakeNss`](#sssec-pkgs-dockerTools-helpers-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](https://en.wikipedia.org/wiki/Linux_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`](#ssec-pkgs-dockerTools-buildLayeredImage) or [`streamLayeredImage`](#ssec-pkgs-dockerTools-streamLayeredImage), you will have to set the `enableFakechroot` attribute to `true`, or else the script in `shadowSetup` won't run properly.
See [](#ex-dockerTools-shadowSetup-buildLayeredImage).
# Using `dockerTools`'s environment helpers with `buildImage`
This example adds the [`binSh`](#sssec-pkgs-dockerTools-helpers-binSh) helper to a basic Docker image built with [`dockerTools.buildImage`](#ssec-pkgs-dockerTools-buildImage).
This helper makes it possible to enter a shell inside the container.
This is the `buildImage` equivalent of [](#ex-dockerTools-helpers-buildLayeredImage).
# Using `dockerTools`'s environment helpers with `buildLayeredImage`
This example adds the [`binSh`](#sssec-pkgs-dockerTools-helpers-binSh) helper to a basic Docker image built with [`dockerTools.buildLayeredImage`](#ssec-pkgs-dockerTools-buildLayeredImage).
This helper makes it possible to enter a shell inside the container.
This is the `buildLayeredImage` equivalent of [](#ex-dockerTools-helpers-buildImage).
`buildNixShellImage` uses [`streamNixShellImage`](#ssec-pkgs-dockerTools-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`](#ssec-pkgs-dockerTools-streamNixShellImage) for details.
`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 [](#ex-dockerTools-streamNixShellImage-hello) 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 [](#ex-dockerTools-streamNixShellImage-addingShellHook)) 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`).
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.
: 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](https://nixos.org/manual/nix/stable/command-ref/nix-shell.html#environment-variables) for {manpage}`nix-shell(1)`.