cache-nx-buildjet v4.0.2

Cache Nix action

A GitHub Action to restore and save (not only) Nix store paths using GitHub Actions cache.

This action is based on actions/cache.

What it can

• Restore and save the Nix store on Linux and macOS runners.
• Restore and save other directories on Linux, macOS, and Windows runners.
• Collect garbage in the Nix store before saving a new cache.
• Merge caches produced by several jobs.
• Purge caches created or last accessed at least the given time ago.

A typical job

1. The nix-quick-install-action installs Nix in single-user mode.

2. Restore phase:

   1. The cache-nix-action tries to restore a cache whose key is the same as the primary key.

   2. When it can't restore, the cache-nix-action tries to restore a cache whose key matches a prefix in a given list of key prefixes.

   3. The cache-nix-action restores all caches whose keys match some of the prefixes in another given list of key prefixes.

3. Other job steps run.

4. Post Restore phase:

   1. The cache-nix-action purges caches whose keys are the same as the primary key and that were created more than a given time ago.

   2. When there's no cache whose key is the same as the primary key, the cache-nix-action collects garbage in the Nix store and saves a new cache.

   3. The cache-nix-action purges caches whose keys match some of the given prefixes in a given list of key prefixes and that were created more than a given time ago relative to the start of the Post Restore phase.

Limitations

• The action caches and restores /nix.
  • The action doesn't manage stores specified via the --store flag (link).
  • The action ignores existing /nix/store paths when restoring a cache.
  • The action ignores cached /nix/var except /nix/var/nix/db/db.sqlite.
  • The action merges existing and new databases when restoring a cache.
• The action requires nix-quick-install-action.
• The action supports only Linux and macOS runners for Nix store caching.
• The action purges caches scoped to the current GITHUB_REF.
• The action purges caches by keys without considering cache versions (see Cache version).
• GitHub allows only 10GB of caches and then removes the least recently used entries (see its eviction policy). Workarounds:
  • Purge old caches
  • Merge caches
• The Nix store size is limited by a runner storage size (link).
  • Workaround: the jlumbroso/free-disk-space action frees ~30GB of disk space in several minutes.
• Caches are isolated for restoring between refs (link).
  • Workaround: provide caches for PRs on default or base branches.
• For purging, a workflow must have the permission actions: write and the token must have a repo scope (link).

Comparison with alternative approaches

See Caching Approaches.

Additional actions

• Restore action
• Save action

Example steps

- uses: nixbuild/nix-quick-install-action@v27

- name: Restore and cache Nix store
  uses: nix-community/cache-nix-action@v5
  with:
    # restore and save a cache using this key
    primary-key: nix-${{ runner.os }}-${{ hashFiles('**/*.nix') }}
    # if there's no cache hit, restore a cache by this prefix
    restore-prefixes-first-match: nix-${{ runner.os }}-
    # collect garbage until Nix store size (in bytes) is at most this number
    # before trying to save a new cache
    gc-max-store-size-linux: 1073741824
    # do purge caches
    purge: true
    # purge all versions of the cache
    purge-prefixes: cache-${{ runner.os }}-
    # created more than this number of seconds ago relative to the start of the `Post Restore` phase
    purge-created: 0
    # except the version with the `primary-key`, if it exists
    purge-primary-key: never

• nix-quick-install-action loads nixConfig from flake.nix and writes to nix.conf (see action.yml in the nix-quick-install repo).
• Due to gc-max-store-size-linux: 1073741824, on Linux runners, garbage in the Nix store is collected until store size reaches 1GB or until there's no garbage to collect.
• Since gc-max-store-size-macos isn't set to a number, on macOS runners, no garbage is collected in the Nix store.
• The cache-nix-action purges caches:
  • (with a key prefix cache-${{ runner.os }}-) AND (created more than 42 seconds ago OR last accessed more than 42 seconds ago).

Example workflow

See ci.yaml and its runs.

Configuration

See action.yml.

Inputs

Outputs

Troubleshooting

• Use action-tmate to debug on a runner via SSH.

Garbage collection parameters

On Linux runners, when gc-max-store-size-linux is set to a number, the cache-nix-action will run nix store gc --max R before saving a cache. Here, R is max(0, S - gc-max-store-size-linux), where S is the current store size.

Respective conditions hold for macOS runners.

There are alternative approaches to garbage collection (see Garbage collection).

Purge old caches

The cache-nix-action allows to delete old caches after saving a new cache (see purge-* inputs in Inputs and the compare-run-times job in the Example workflow).

The purge-cache action allows to remove caches based on their last accessed or created time without branch limitations.

Alternatively, you can use the GitHub Actions Cache API.

Merge caches

GitHub evicts least recently used caches when their total size exceeds 10GB (see Limitations).

If you have multiple similar caches produced on runners with the same OS (Linux or macOS), you can merge them into a single cache and store just it to save space.

In short:

1. Matrix jobs produce similar individual caches.
2. The next job restores all of these individual caches, saves a common cache, and purges individual caches.
3. On subsequent runs, matrix jobs use the common cache.

See the make-similar-caches and merge-similar-caches jobs in the example workflow.

Pros: if N individual caches are very similar, a common cache will take approximately N times less space. Cons: if caches aren't very similar, run time may increase due to a bigger common cache.

Caching approaches

Discussed in more details here and here.

Caching approaches work at different "distances" from /nix/store of GitHub Actions runner. These distances affect the restore and save speed.

GitHub Actions

• DeterminateSystems/magic-nix-cache-action
• nix-community/cache-nix-action

cache-nix-action

Pros:

• Free.
• Easy to set up.
• Uses GitHub Actions Cache and works fast.
• Doesn't require repository secrets.
• Allows to save a store of at most a given size (see Garbage collection parameters).
• Allows to save outputs from garbage collection (see Garbage collection).
• When there's a cache hit, restoring from a GitHub Actions cache can be faster than downloading multiple paths from binary caches.
  • You can compare run times of jobs with and without store caching in Actions.
    • Open a run and click on the time under Total duration.

Cons: see Limitations

magic-nix-cache-action

Pros (link):

• Free.
• Easy to set up.
• Uses GitHub Actions Cache and works fast.
• Restores and saves paths selectively.

Cons:

• Collects telemetry (link)
• May trigger rate limit errors (link).
• Follows the GitHub Actions Cache semantics (link).
  • Caches are isolated between branches (link).
• Saves a cache for each path in a store and quickly litters Caches.

actions/cache

If used with nix-quick-install-action, it's similar to the cache-nix-action.

If used with install-nix-action and a chroot local store:

Pros:

• Quick restore and save /tmp/nix.

Cons:

• Slow nix copy from /tmp/nix to /nix/store.

If used with install-nix-action and this trick, it's similar to the cache-nix-action, but slower (link).

Hosted binary caches

See binary cache, HTTP Binary Cache Store.

• cachix
• attic

Pros:

• Restore and save paths selectively.
• Provide least recently used garbage collection strategies (cachix, attic).
• Don't cache paths available from the NixOS cache (cachix).
• Allow to share paths between projects (cachix).

Cons:

• Have limited free storage (cachix gives 5GB for open-source projects).
• Need good bandwidth for receiving and pushing paths over the Internet.
• Can be down.

Garbage collection

When restoring a Nix store from a cache, the store may contain old unnecessary paths. These paths should be removed sometimes to limit cache size and ensure the fastest restore/save steps.

Garbage collection approach 1

Produce a cache once, use it multiple times. Don't collect garbage.

Advantages:

• Unnecessary paths are saved to a cache only during a new save.

Disadvantages:

• Unnecessary paths can accumulate between new saves.
  • A job at the firs run produces a path A and saves a cache.
  • The job at the second run restores the cache, produces a path B, and saves a cache. The cache has both A and B.
  • etc.

Garbage collection approach 2

Collect garbage before saving a cache.

Advantages:

• Automatically keep cache at a minimal/limited size

Disadvantages:

• No standard way to gc only old paths.

Save a path from garbage collection

• Use nix profile install to save installables from garbage collection.
  • Get store paths of inputs via nix flake archive (see comment).
  • Get outputs via nix flake show --json | jq '.packages."x86_64-linux"|keys[]'| xargs -I {} on x86_64-linux (see this issue).
• Keep inputs (see this issue and this issue).
• Start direnv in background.

Garbage collection approaches

• Use nix-heuristic-gc for cache eviction via atime.
• gc via gc roots nix-cache-cut.
• gc based on time cache-gc.

Contribute

• Improve README.
• Report errors, suggest improvements in issues.
• Upgrade code.
  • Read about JavaScript actions
  • See main files:
    • restoreImpl.ts
    • saveImpl.ts

• Upgrade docs.

  • Edit action.nix.

  • Update action.yml-s and README.md-s:

    nix run .#write

• Update the actions-toolkit branch.

• Ask for new releases of github-actions.cache-buildjet if there are changes on the actions-toolkit branch.

Cache action

Documentation

See "Caching dependencies to speed up workflows".

What's New

v4

• Updated to node 20
• Added a save-always flag to save the cache even if a prior step fails

v3

• Added support for caching in GHES 3.5+.
• Fixed download issue for files > 2GB during restore.
• Updated the minimum runner version support from node 12 -> node 16.
• Fixed avoiding empty cache save when no files are available for caching.
• Fixed tar creation error while trying to create tar with path as ~/ home folder on ubuntu-latest.
• Fixed zstd failing on amazon linux 2.0 runners.
• Fixed cache not working with github workspace directory or current directory.
• Fixed the download stuck problem by introducing a timeout of 1 hour for cache downloads.
• Fix zstd not working for windows on gnu tar in issues.
• Allowing users to provide a custom timeout as input for aborting download of a cache segment using an environment variable SEGMENT_DOWNLOAD_TIMEOUT_MINS. Default is 10 minutes.
• New actions are available for granular control over caches - restore and save.
• Added option to fail job on cache miss. See Exit workflow on cache miss for more info.
• Fix zstd not being used after zstd version upgrade to 1.5.4 on hosted runners
• Added option to lookup cache without downloading it.
• Reduced segment size to 128MB and segment timeout to 10 minutes to fail fast in case the cache download is stuck.

See the v2 README.md for older updates.

Usage

Pre-requisites

Create a workflow .yml file in your repository's .github/workflows directory. An example workflow is available below. For more information, see the GitHub Help Documentation for Creating a workflow file.

If you are using this inside a container, a POSIX-compliant tar needs to be included and accessible from the execution path.

If you are using a self-hosted Windows runner, GNU tar and zstd are required for Cross-OS caching to work. They are also recommended to be installed in general so the performance is on par with hosted Windows runners.

Environment Variables

• SEGMENT_DOWNLOAD_TIMEOUT_MINS - Segment download timeout (in minutes, default 10) to abort download of the segment if not completed in the defined number of minutes. Read more

Cache scopes

The cache is scoped to the key, version, and branch. The default branch cache is available to other branches.

See Matching a cache key for more info.

Example cache workflow

Restoring and saving cache using a single action

name: Caching Primes

on: push

jobs:
  build:
    runs-on: ubuntu-latest

    steps:
      - uses: actions/checkout@v4

      - name: Cache Primes
        id: cache-primes
        uses: actions/cache@v4
        with:
          primary-key: ${{ runner.os }}-primes
          paths: prime-numbers

      - name: Generate Prime Numbers
        if: steps.cache-primes.outputs.cache-hit != 'true'
        run: /generate-primes.sh -d prime-numbers

      - name: Use Prime Numbers
        run: /primes.sh -d prime-numbers

The cache action provides a cache-hit output which is set to true when the cache is restored using the primary key and false when the cache is restored using restore-keys or no cache is restored.

Using a combination of restore and save actions

name: Caching Primes

on: push

jobs:
  build:
    runs-on: ubuntu-latest

    steps:
      - uses: actions/checkout@v4

      - name: Restore cached Primes
        id: cache-primes-restore
        uses: nix-community/cache-nix-action/restore@v5
        with:
          primary-key: ${{ runner.os }}-primes
          paths: |
            path/to/dependencies
            some/other/dependencies

      # other steps

      - name: Save Primes
        id: cache-primes-save
        uses: nix-community/cache-nix-action/save@v5
        with:
          primary-key: ${{ steps.cache-primes-restore.outputs.cache-primary-key }}
          paths: |
            path/to/dependencies
            some/other/dependencies

Note You must use the cache or restore action in your workflow before you need to use the files that might be restored from the cache. If the provided key matches an existing cache, a new cache is not created and if the provided key doesn't match an existing cache, a new cache is automatically created provided the job completes successfully.

Caching Strategies

With the introduction of the restore and save actions, a lot of caching use cases can now be achieved. Please see the caching strategies document for understanding how you can use the actions strategically to achieve the desired goal.

Implementation Examples

Every programming language and framework has its own way of caching.

See Examples for a list of actions/cache implementations for use with:

• C# - NuGet
• Clojure - Lein Deps
• D - DUB
• Deno
• Elixir - Mix
• Go - Modules
• Haskell - Cabal
• Haskell - Stack
• Java - Gradle
• Java - Maven
• Node - npm
• Node - Lerna
• Node - Yarn
• OCaml/Reason - esy
• PHP - Composer
• Python - pip
• Python - pipenv
• R - renv
• Ruby - Bundler
• Rust - Cargo
• Scala - SBT
• Swift, Objective-C - Carthage
• Swift, Objective-C - CocoaPods
• Swift - Swift Package Manager
• Swift - Mint

Creating a cache key

A cache key can include any of the contexts, functions, literals, and operators supported by GitHub Actions.

For example, using the hashFiles function allows you to create a new cache when dependencies change.

- uses: nix-community/cache-nix-action@v5
  with:
    primary-key: ${{ runner.os }}-${{ hashFiles('**/lockfiles') }}
    paths: |
      path/to/dependencies
      some/other/dependencies

Additionally, you can use arbitrary command output in a cache key, such as a date or software version:

# http://man7.org/linux/man-pages/man1/date.1.html
- name: Get Date
  id: get-date
  run: echo "date=$(/bin/date -u "+%Y%m%d")" >> $GITHUB_OUTPUT
  shell: bash

- uses: nix-community/cache-nix-action@v5
  with:
    primary-key: ${{ runner.os }}-${{ steps.get-date.outputs.date }}-${{ hashFiles('**/lockfiles') }}
    paths: path/to/dependencies

See Using contexts to create cache keys

Cache Limits

A repository can have up to 10GB of caches. Once the 10GB limit is reached, older caches will be evicted based on when the cache was last accessed. Caches that are not accessed within the last week will also be evicted.

Skipping steps based on cache hit

Using the hit-primary-key output, subsequent steps (such as install or build) can be skipped when a cache hit occurs on the primary key. It is recommended to install missing/updated dependencies in case of a partial key match when the key is dependent on the hash of the package file.

Example:

steps:
  - uses: actions/checkout@v4

  - uses: nix-community/cache-nix-action@v5
    id: cache
    with:
      primary-key: ${{ runner.os }}-${{ hashFiles('**/lockfiles') }}
      path: path/to/dependencies

  - name: Install Dependencies
    if: steps.cache.outputs.hit-primary-key != true
    run: /install.sh

Note The id defined in nix-community/cache-nix-action must match the [id] in the if statement (i.e. steps.[id].outputs.hit-primary-key)

Cache Version

Cache version is a hash generated for a combination of compression tool used (Gzip, Zstd, etc. based on the runner OS) and the path of directories being cached. If two caches have different versions, they are identified as unique caches while matching. This, for example, means that a cache created on a windows-latest runner can't be restored on ubuntu-latest as cache Versions are different.

Pro tip: The list caches API can be used to get the version of a cache. This can be helpful to troubleshoot cache miss due to version.

The workflow will create 3 unique caches with same keys. Linux and Windows runners will use different compression technique and hence create two different caches. And build-linux will create two different caches as the paths are different.

jobs:
  build-linux:
    runs-on: ubuntu-latest
    steps:
      - uses: actions/checkout@v4

      - name: Cache Primes
        id: cache-primes
        uses: nix-community/cache-nix-action@v5
        with:
          primary-key: primes
          paths: prime-numbers

      - name: Generate Prime Numbers
        if: steps.cache-primes.outputs.cache-hit != 'true'
        run: ./generate-primes.sh -d prime-numbers

      - name: Cache Numbers
        id: cache-numbers
        uses: nix-community/cache-nix-action@v5
        with:
          primary-key: primes
          paths: numbers

      - name: Generate Numbers
        if: steps.cache-numbers.outputs.cache-hit != 'true'
        run: ./generate-primes.sh -d numbers

  build-windows:
    runs-on: windows-latest
    steps:
      - uses: actions/checkout@v4

      - name: Cache Primes
        id: cache-primes
        uses: nix-community/cache-nix-action@v5
        with:
          primary-key: primes
          paths: prime-numbers

      - name: Generate Prime Numbers
        if: steps.cache-primes.outputs.cache-hit != 'true'
        run: ./generate-primes -d prime-numbers

Known practices and workarounds

There are a number of community practices/workarounds to fulfill specific requirements. You may choose to use them if they suit your use case. Note these are not necessarily the only solution or even a recommended solution.

Cache segment restore timeout

A cache gets downloaded in multiple segments of fixed sizes (1GB for a 32-bit runner and 2GB for a 64-bit runner). Sometimes, a segment download gets stuck which causes the workflow job to be stuck forever and fail. Version v3.0.8 of actions/cache introduces a segment download timeout. The segment download timeout will allow the segment download to get aborted and hence allow the job to proceed with a cache miss.

Default value of this timeout is 10 minutes and can be customized by specifying an environment variable named SEGMENT_DOWNLOAD_TIMEOUT_MINS with timeout value in minutes.

Update a cache

A cache today is immutable and cannot be updated. But some use cases require the cache to be saved even though there was a hit during the Restore phase. To do so, always purge old versions of that cache:

- name: update cache on every commit
  uses: actions/cache@v4
  with:
    primary-key: primes-${{ runner.os }}
    paths: prime-numbers
    purge: true
    purge-primary-key: always

Please note that this will create a new cache on every run and hence will consume the cache quota.

Use cache across feature branches

Reusing cache across feature branches is not allowed today to provide cache isolation. However if both feature branches are from the default branch, a good way to achieve this is to ensure that the default branch has a cache. This cache will then be consumable by both feature branches.

Force deletion of caches overriding default cache eviction policy

Caches have branch scope restriction in place. This means that if caches for a specific branch are using a lot of storage quota, it may result into more frequently used caches from default branch getting thrashed. For example, if there are many pull requests happening on a repo and are creating caches, these cannot be used in default branch scope but will still occupy a lot of space till they get cleaned up by eviction policy. But sometime we want to clean them up on a faster cadence so as to ensure default branch is not thrashing. In order to achieve this, gh-actions-cache cli can be used to delete caches for specific branches.

This workflow uses gh-actions-cache to delete all the caches created by a branch.

name: cleanup caches by a branch
on:
  pull_request:
    types:
      - closed
  workflow_dispatch:

jobs:
  cleanup:
    runs-on: ubuntu-latest
    permissions:
      # `actions:write` permission is required to delete caches
      #   See also: https://docs.github.com/en/rest/actions/cache?apiVersion=2022-11-28#delete-a-github-actions-cache-for-a-repository-using-a-cache-id
      actions: write
      contents: read
    steps:
      - name: Check out code
        uses: actions/checkout@v4

      - name: Cleanup
        run: |
          gh extension install actions/gh-actions-cache

          REPO=${{ github.repository }}
          BRANCH=refs/pull/${{ github.event.pull_request.number }}/merge

          echo "Fetching list of cache key"
          cacheKeysForPR=$(gh actions-cache list -R $REPO -B $BRANCH | cut -f 1 )

          ## Setting this to not fail the workflow while deleting cache keys. 
          set +e
          echo "Deleting caches..."
          for cacheKey in $cacheKeysForPR
          do
              gh actions-cache delete $cacheKey -R $REPO -B $BRANCH --confirm
          done
          echo "Done"
        env:
          GH_TOKEN: ${{ secrets.GITHUB_TOKEN }}

License

The scripts and documentation in this project are released under the MIT License