How Git object deduplication works in GitLab

When a GitLab user forks a project, GitLab creates a new Project with an associated Git repository that is a copy of the original project at the time of the fork. If a large project gets forked often, this can lead to a quick increase in Git repository storage disk use. To counteract this problem, we are adding Git object deduplication for forks to GitLab. In this document, we describe how GitLab implements Git object deduplication.

Pool repositories

Understanding Git alternates

At the Git level, we achieve deduplication by using Git alternates. Git alternates is a mechanism that lets a repository borrow objects from another repository on the same machine.

To make repository A borrow from repository B:

  1. Establish the alternates link in the special file A.git/objects/info/alternates by writing a path that resolves to B.git/objects.
  2. In repository A, run git repack to remove all objects in repository A that also exist in repository B.

After the repack, repository A is no longer self-contained, but still contains its own refs and configuration. Objects in A that are not in B remain in A. For this configuration to work, objects must not be deleted from repository B because repository A might need them.

caution
Do not run git prune or git gc in object pool repositories, which are stored in the @pools directory. This can cause data loss in the regular repositories that depend on the object pool.

The danger lies in git prune, and git gc calls git prune. The problem is that git prune, when running in a pool repository, cannot reliably decide if an object is no longer needed.

Git alternates in GitLab: pool repositories

GitLab organizes this object borrowing by creating special pool repositories which are hidden from the user. We then use Git alternates to let a collection of project repositories borrow from a single pool repository. We call such a collection of project repositories a pool. Pools form star-shaped networks of repositories that borrow from a single pool, which resemble (but are not identical to) the fork networks that get formed when users fork projects.

At the Git level, pool repositories are created and managed using Gitaly RPC calls. Just like with typical repositories, the authority on which pool repositories exist, and which repositories borrow from them, lies at the Rails application level in SQL.

In conclusion, we need three things for effective object deduplication across a collection of GitLab project repositories at the Git level:

  1. A pool repository must exist.
  2. The participating project repositories must be linked to the pool repository via their respective objects/info/alternates files.
  3. The pool repository must contain Git object data common to the participating project repositories.

Deduplication factor

The effectiveness of Git object deduplication in GitLab depends on the amount of overlap between the pool repository and each of its participants. Each time garbage collection runs on the source project, Git objects from the source project are migrated to the pool repository. One by one, as garbage collection runs, other member projects benefit from the new objects that got added to the pool.

SQL model

Project repositories in GitLab do not have their own SQL table. They are indirectly identified by columns on the projects table. In other words, the only way to look up a project repository is to first look up its project, and then call project.repository.

With pool repositories we made a fresh start. These live in their own pool_repositories SQL table. The relations between these two tables are as follows:

  • a Project belongs to at most one PoolRepository (project.pool_repository)
  • as an automatic consequence of the above, a PoolRepository has many Projects
  • a PoolRepository has exactly one “source Project” (pool.source_project)

Assumptions

  • All repositories in a pool must be on the same Gitaly storage shard. The Git alternates mechanism relies on direct disk access across multiple repositories, and we can only assume direct disk access to be possible within a Gitaly storage shard.
  • The only two ways to remove a member project from a pool are (1) to delete the project or (2) to move the project to another Gitaly storage shard.

Creating pools and pool memberships

  • When a pool gets created, it must have a source project. The initial contents of the pool repository are a Git clone of the source project repository.
  • The occasion for creating a pool is when an existing eligible (non-private, hashed storage, non-forked) GitLab project gets forked and this project does not belong to a pool repository yet. The fork parent project becomes the source project of the new pool, and both the fork parent and the fork child project become members of the new pool.
  • Once project A has become the source project of a pool, all future eligible forks of A become pool members.
  • If the fork source is itself a fork, the resulting repository will neither join the repository nor is a new pool repository seeded.

    Such as:

    Suppose fork A is part of a pool repository, any forks created off of fork A are not a part of the pool repository that fork A is a part of.

    Suppose B is a fork of A, and A does not belong to an object pool. Now C gets created as a fork of B. C is not part of a pool repository.

Consequences

  • If a typical Project participating in a pool gets moved to another Gitaly storage shard, its “belongs to PoolRepository” relation will be broken. Because of the way moving repositories between shard is implemented, we get a fresh self-contained copy of the project’s repository on the new storage shard.
  • If the source project of a pool gets moved to another Gitaly storage shard or is deleted the “source project” relation is not broken. However, a pool does not fetch from a source unless the source is on the same Gitaly shard.

Consistency between the SQL pool relation and Gitaly

As far as Gitaly is concerned, the SQL pool relations make two types of claims about the state of affairs on the Gitaly server: pool repository existence, and the existence of an alternates connection between a repository and a pool.

Pool existence

If GitLab thinks a pool repository exists (that is, it exists according to SQL), but it does not on the Gitaly server, then it is created on the fly by Gitaly.

Pool relation existence

There are three different things that can go wrong here.

1. SQL says repository A belongs to pool P but Gitaly says A has no alternate objects

In this case, we miss out on disk space savings but all RPCs on A itself function fine. The next time garbage collection runs on A, the alternates connection gets established in Gitaly. This is done by Projects::GitDeduplicationService in GitLab Rails.

2. SQL says repository A belongs to pool P1 but Gitaly says A has alternate objects in pool P2

In this case Projects::GitDeduplicationService throws an exception.

3. SQL says repository A does not belong to any pool but Gitaly says A belongs to P

In this case Projects::GitDeduplicationService tries to “re-duplicate” the repository A using the DisconnectGitAlternates RPC.

Git object deduplication and GitLab Geo

When a pool repository record is created in SQL on a Geo primary, this eventually triggers an event on the Geo secondary. The Geo secondary then creates the pool repository in Gitaly. This leads to an “eventually consistent” situation because as each pool participant gets synchronized, Geo eventually triggers garbage collection in Gitaly on the secondary, at which stage Git objects are deduplicated.