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LinuxKit packages

A LinuxKit package is a container image which can be used to assemble a bootable Linux image. The LinuxKit project has a number of core packages, but users can create their own packages, as it's very easy. Packages are the unit of customisation in a LinuxKit-based project, if you know how to build a container, you should be able to build a LinuxKit package.

All official LinuxKit packages are:

  • Enabled with multi-arch indexes to work on multiple architectures.
  • Derived from well-known sources for repeatable builds.
  • Built with multi-stage builds to minimise their size.

CI and Package Builds

When building and merging packages, it is important to note that our CI process builds packages. The targets make ci and make ci-pr execute make -C pkg build. These in turn execute linuxkit pkg build for each package under pkg/. This in turn will try to pull the image whose tag matches the tree hash or, failing that, to build it.

Any released image, i.e. any package under pkg/ that has not changed as part of a pull request, already will be released to Docker Hub. This will cause it to download that image, rather than try to build it.

Any non-releaed image, i.e. any package under pkg/ that has changed as part of a pull request, will not be in Docker Hub until the PR has merged. This will cause the download to fail, leading linuxkit pkg build to try and build the image and save it in the cache.

This does have two downsides:

  1. It is slower to do a package build than to just pull the latest image.
  2. If any of the steps of the build fails, e.g. a curl download that depends on an intermittent target, it can cause all of CI to fail.

In the past, each PR required a maintainer to build, and push to Docker Hub, every changed package in pkg/. This placed the maintainer in the PR cycle, with the following downsides:

  1. A maintainer had to be involved in every PR, not just reviewing but actually building and pushing. This reduces the ability for others to contribute.
  2. The actual package is pushed out by a person, violating good supply-chain practice.

Package source

A package source consists of a directory containing at least two files:

  • build.yml: contains metadata associated with the package
  • Dockerfile: contains the steps to build the package.

build.yml contains the following fields:

  • image (string): (mandatory) The name of the image to build
  • org (string): The hub/registry organisation to which this package belongs
  • arches (list of string): The architectures which this package should be built for (valid entries are GOARCH names)
  • extra-sources (list of strings): Additional sources for the package outside the package directory. The format is src:dst, where src can be relative to the package directory and dst is the destination in the build context. This is useful for sharing files, such as vendored go code, between packages.
  • gitrepo (string): The git repository where the package source is kept.
  • network (bool): Allow network access during the package build (default: no)
  • disable-cache (bool): Disable build cache for this package (default: no)
  • buildArgs will forward a list of build arguments down to docker. As if --build-arg was specified during docker build
  • config: (struct github.com/moby/tool/src/moby.ImageConfig): Image configuration, marshalled to JSON and added as org.mobyproject.config label on image (default: no label)
  • depends: Contains information on prerequisites which must be satisfied in order to build the package. Has subfields:
    • docker-images: Docker images to be made available (as tar files via docker image save) within the package build context. Contains the following nested fields:
      • from-file and list: (string and string list respectively). Mutually exclusive fields specifying the list of images to include. Each image must include a valid digest (sha256:...) in order to maintain determinism. If from-file is used then it is a path relative to (and within) the package directory with one image per line (lines with # in column 0 and blank lines are ignore). If list is used then each entry is an image.
      • target and target-dir: (string) Mutually exclusive fields specifying the target location, if target is used then it is a path relative to (and within) the package dir which names a tar file into which all of the listed images will be saved. If target-dir then it is a path relative to (and within) the package directory which names a directory into which each image will be saved (as «image name»@«digest».tar). NB: The path referenced by target-dir will be removed prior to populating (to avoid issues with stale files).

Building packages

Prerequisites

Before you can build packages you need:

  • Docker version 19.03 or newer.
  • If you are on a Mac you also need docker-credential-osxkeychain.bin, which comes with Docker for Mac.
  • make, base64, jq, and expect
  • A recent version of manifest-tool which you can build with make bin/manifest-tool, or go get github.com:estesp/manifest-tool, or via the LinuxKit homebrew tap with brew install --HEAD manifest-tool. manifest-tool must be in your path.
  • The LinuxKit tool linuxkit which must be in your path.

Further, when building packages you need to be logged into hub with docker login as some of the tooling extracts your hub credentials during the build.

Build Targets

LinuxKit builds packages as docker images. It deposits the built package as a docker image in one or both of two targets:

  • the linuxkit cache, which is at ~/.linuxkit/cache/ (configurable)
  • the docker image cache (optional)

The package always is built and saved in the linuxkit cache. However, you also can load the package for the current architecture, if available, into the docker image cache.

If you want to build images and test and run them in a standalone fashion locally, then you should add the docker image cache. Otherwise, you don't need anything more than the default linuxkit cache. LinuxKit defaults to building OS images using docker images from this cache, only looking in the docker cache if instructed to via linuxkit build --docker.

In the linuxkit cache, it creates all of the layers, the manifest that can be uploaded to a registry, and the multi-architecture index. If an image already exists for a different architecture in the cache, it updates the index to include additional manifests created.

The order of building is as follows:

  1. Build the image to the linuxkit cache
  2. If --docker is provided, load the image into the docker image cache

For example:

linuxkit pkg build pkg/foo           # builds pkg/foo and places it in the linuxkit cache
linuxkit pkg build pkg/foo --docker  # builds pkg/foo and places it in the linuxkit cache and also loads it into docker

Build Platforms

By default, linuxkit pkg build builds for all supported platforms in the package's build.yml, whose syntax is available [here][Package source]. If no platforms are provided in the build.yml, it builds for all platforms that linuxkit supports. As of this writing, those are:

  • linux/amd64
  • linux/arm64
  • linux/s390x

You can choose to skip one of the platforms from build.yml or those selected by default using the --skip-platforms flag.

For example:

linuxkit pkg build --skip-platforms linux/s390x ...

You can override the target build platform by passing it the --platforms option:

linuxkit pkg build --platforms <platform1,platform2,...platformN>

The options for --platforms are identical to those for docker build. An example is available in the official buildx documentation.

Given that this is linuxkit, i.e. all builds are for linux, the OS part would seem redundant, and it should be sufficient to pass --platform arm64. However, for complete consistency, the entire platform, e.g. --platforms linux/amd64,linux/arm64, must be provided.

Where it builds

You are running the linuxkit pkg build command on a single platform, e.g. your local linux cloud instance running on amd64, or a MacBook with Apple Silicon running on arm64.

How does linuxkit determine where to build the target images?

linuxkit uses buildkit directly to build all images. It uses docker contexts to determine where to run those buildkit containers, based on the target architecture.

When running a package build, linuxkit looks for a container named linuxkit-builder, running the appropriate version of buildkit. If it cannot find a container with that name, it creates it. If the container already exists but is not running buildkit, or if the version is incorrect, linuxkit stops and removes the existing linuxkit-builder container and creates one running the correct version of buildkit.

When linuxkit needs to build a package for a particular architecture:

  1. If a context for that architecture was provided, use that context, looking for and/or starting a buildkit container named linuxkit-builder.
  2. If no context for that architecture was provided, use the default context.

The actual building then will be one of:

  1. native, if the provided context has the same architecture as the target build architecture; else
  2. cross-build, if the provided context has a different architecture, but the package's Dockerfile supports cross-building; else
  3. emulated build, using docker's qemu binfmt capabilities

Cross-building, i.e. building on one platform using that platform's binaries to create outputs for a different platform, depends on the package's Dockerfile. Details are available in the official Docker buildx docs.

  • if the image is just FROM something, then it runs it under qemu using binfmt
  • if the image is FROM --platform=$BUILDPLATFORM something, then it runs it using the local architecture, invoking cross-builders

Read the official docs to learn more how to leverage cross-building with buildx.

Important: When building, if the local architecture is not one of those being build, selecting --docker to load the images into the docker image cache will result in an error. You must be building for the local architecture - optionally for others as well - in order to pass the --docker option.

Providing native builder nodes

linuxkit is capable of using native build nodes to do the build, even remotely. To do so, you must:

  1. Create a docker context that references the build node
  2. Tell linuxkit to use that context for that architecture

linuxkit will then use that provided context to look for and/or start a container in which to run buildkit for that architecture.

linuxkit looks for contexts in the following descending order of priority:

  1. CLI option --builders <platform>=<context>,<platform>=<context>, e.g. --builders linux/arm64=linuxkit-arm64,linux/amd64=default
  2. Environment variable LINUXKIT_BUILDERS=<platform>=<context>,<platform>=<context>, e.g. LINUXKIT_BUILDERS=linux/arm64=linuxkit-arm64,linux/amd64=default
  3. Existing context named linuxkit-<platform>, e.g. linuxkit-linux-arm64 or linuxkit-linux-s390x, with "/" replaced by "-", as "/" is an invalid character.
  4. Default context

If a builder name is provided for a specific platform, and it doesn't exist, it will be treated as a fatal error.

Examples

Simple build

There are no contexts starting with linuxkit-, no environment variable LINUXKIT_BUILDERS, no command-line argument --builders.

linuxkit will build any requested packages using default context on the local platform, with a container (created, if necessary) named linuxkit-builder. Builds for the same architecture will be native, builds for other platforms will use either qemu or cross-building.

Specified target

You create a context named my-remote-arm64 and then run:

linuxkit pkg build --platforms=linux/arm64,linux/amd64 --builders linux/arm64=my-remote-arm64

linuxkit will build:

  • for arm64 using the context my-remote-arm64, since you specified in --builders to use my-remote-arm64 for linux/arm64
  • for amd64 using the context default, as that is the default fallback

The same would happen if you used LINUXKIT_BUILDERS=linux/arm64=my-remote-arm64 instead of the --builders flag.

In both cases - the remote context my-remote-arm64 and the local default context - it will do the build inside a container named linuxkit-builder.

Named context

You create a context named linuxkit-linux-arm64 and then run:

linuxkit pkg build --platforms=linux/arm64,linux/amd64

linuxkit will build:

  • for arm64 using the context linuxkit-linux-arm64, since there is a context with the name linuxkit-<platform>, and you did not override it using --builders or the environment variable LINUXKIT_BUILDERS
  • for amd64 using the context default and the linuxkit builder, as that is the default fallback
Combination

You create a context named linuxkit-linux-arm64, and another named my-remote-builder-amd64 and then run:

linuxkit pkg build --platforms=linux/arm64,linux/amd64 --builders linux/amd64=my-remote-builder-amd64

linuxkit will build:

  • for arm64 using the context linuxkit-linux-arm64, since there is a context with the name linuxkit-<platform>, and you did not override that particular architecture using --builders or the environment variable LINUXKIT_BUILDERS
  • for amd64 using the context my-remote-builder-amd64, since you specified for that architecture using --builders

The same would happen if you used LINUXKIT_BUILDERS=linux/arm64=my-remote-builder-amd64 instead of the --builders flag.

Missing context

You do not have a context named my-remote-arm64, and run:

linuxkit pkg build --platforms=linux/arm64 --builders linux/arm64=my-remote-arm64

linuxkit will try to build for linux/arm64 using the context my-remote-arm64. Since that context does not exist, you will get an error.

Build packages as a maintainer

All official LinuxKit packages are multi-arch manifests and most of them are available for the following platforms:

  • linux/amd64
  • linux/arm64
  • linux/s390x

Official images must be built for all architectures for which they are available.

Pushing out a package as a maintainer involves two stages:

  1. Building and pushing out the platform-specific images
  2. Creating and pushing out the multi-arch manifest, a.k.a. OCI image index

The linuxkit pkg command contains automation which performs all of the steps. Note that «path-to-package» is the path to the package's source directory (containing at least build.yml and Dockerfile). It can be . if the package is in the current directory.

linuxkit pkg push «path-to-package»

This will do the following:

  1. Determine the name and tag for the image as follows:
    • The tag is from the hash of the git tree for that package. You can see it by doing linuxkit pkg show-tag «path-to-package».
    • The name for the image is from «path-to-package»/build.yml
    • The organization for the package is given on the command-line, default to linuxkit.
  2. Build the package in the given path using your local docker instance for all the platforms in «path-to-package»/build.yml
  3. Save the built image in the linuxkit cache
  4. Tag each built image as «image-name»:«hash»-«arch»
  5. Create a multi-arch manifest called «image-name»:«hash» (note no -«arch»)
  6. Push the manifest and all of the images to the hub

Note that for actual release images, these steps normally are performed as part of CI, by the merge-to-master process.

Prerequisites

  • For all of the steps, you must be logged into hub (docker login).

Build packages as a developer

linuxkit pkg build -org=wombat «path-to-package»

This will create a local image: wombat/<image>:<hash>-<arch> which you can use in your local YAML files for testing. If you need to test on other systems you can push the image to your hub account and pull from a different system by issuing:

linuxkit pkg build -org=wombat push

This will push both wombat/<image>:<hash>-<arch> and wombat/<image>:<hash> to hub.

Finally, if you are tired of the long hashes you can override the hash with:

linuxkit pkg build -org=wombat -hash=foo push

and this will create wombat/<image>:foo-<arch> and wombat/<image>:foo for use in your YAML files.

Proxies

If you are building packages from behind a proxy, linuxkit pkg build respects the following environment variables, and will set them as --build-arg to docker build when building a package.

  • http_proxy / HTTP_PROXY
  • https_proxy / HTTPS_PROXY
  • ftp_proxy / FTP_PROXY
  • no_proxy / NO_PROXY
  • all_proxy / ALL_PROXY

Note that the first four of these are the standard built-in build-arg options available for docker build; see the docker build documentation. The last, all_proxy, is a standard var used for socks proxying. Since it is not built into docker build, if you want to use it, you will need to add the following line to the dockerfile:

ARG all_proxy

LinuxKit does not judge between lower-cased or upper-cased variants of these options, e.g. http_proxy vs HTTP_PROXY, as docker build does not either. It just passes them through "as-is".