SoC-2022-Ideas.md

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This is the idea page for Summer of Code 2022 for Git.

Please completely read the general application information page before reading the idea list below.

Summer of code main project ideas

Students: Please consider these ideas as starting points for generating proposals. We are also more than happy to receive proposals for other ideas related to Git. Make sure you have read the "Note about refactoring projects versus projects that implement new features" in the general application information page though.

More Sparse Index Integrations

The spare index feature accelerates Git commands when using sparse-checkout in cone mode. This works by modifying the on-disk index file in a way that includes "sparse directory" entries instead of only file entries. This requires care when enabling the sparse index for different commands, as custom logic might be necessary. At minimum, interaction with the sparse index needs to be carefully tested in the Git test suite when enabling it.

The most-used commands have already been integrated with the sparse index feature. This process usually takes a few steps:

1. Add tests to t1092-sparse-checkout-compatibility.sh for the builtin, with a focus on what happens for paths outside of the sparse-checkout cone.
2. Disable the command_requires_full_index setting in the builtin and ensure the tests pass.
3. If the tests do not pass, then alter the logic to work with the sparse index.
4. Add tests to check that a sparse index stays sparse.
5. Add performance tests to demonstrate speedup.

Here is a list of builtins that could be integrated with the sparse index. They are generally organized in order of least-difficult to most-difficult. This allows the student to gain partial success early in the project and the student can complete as many as possible in the timeframe (without expectation that all will be completed during the project).

• git mv
• git rm
• git grep
• git rev-parse
• git fsck
• git check-attr
• git describe
• git diff-files
• git diff-index
• git diff-tree
• git worktree
• git write-tree
• git apply
• git am
• git checkout--worker (for parallel checkout)
• git merge-index
• git rerere

Expected Project Size: 175 hours or 350 hours

Difficulty: Medium

Languages: C, shell(bash)

Possible mentors:

• Derrick Stolee < derrickstolee@github.com >
• Victoria Dye < vdye@github.com >

Unify ref-filter formats with other pretty formats

Git has an old problem of duplicated implementations of some logic. For example, Git had at least 4 different implementations to format command output for different commands.

Our previous GSoC students and Outreachy interns unified some of the formating logic into ref-filter and got rid of similar logic in some command specific files. Current task is to continue this work and reuse ref-filter formatting logic in pretty.

See:

• this discussion https://lore.kernel.org/git/87pnsfkvk1.fsf@0x63.nu/T/#u
• Hariom Verma's GSoC 2020 final report https://harry-hov.github.io/blogs/posts/the-final-report

Expected Project Size: 175 hours or 350 hours

Difficulty: Medium

Languages: C, shell(bash)

Possible mentors:

• Christian Couder < christian.couder@gmail.com >
• Hariom Verma < hariom18599@gmail.com >

Reachability bitmap improvements

Reachability bitmaps allow Git to quickly answer queries about which objects are reachable from a given commit. Instead of a commits parents and its root tree recursively, we can use a precomputed set of objects encoded as a bit-string and stored in a .bitmap file to answer the query near instantaneously.

There are a couple of areas where bitmap performance itself could be improved:

• Individual bitmaps are stored compressed (with EWAH), but we have some sense that it can be slow to decompress individual bitmaps (which we have to do in order to read them, but also to do things like negate them, OR and AND them together, etc).

  One possible project could be to explore using an alternative compression scheme (like the more modern Roaring+Run technique) to see if we can improve overall bitmap performance by reducing the amount of time it takes to read an individual bitmap.

  This project would entail designing a suite of performance tests, along with any necessary changes to the .bitmap format necessary to accommodate the new compression scheme, making those changes, and then running the performance tests to measure the resulting speed-up.

• Loading a .bitmap file can be slow for large bitmaps. This is because we have to read the file sequentially in order to discover the offset of each bitmap within the file.

  It should be possible to shave off some time from this step by including a small "table of contents" that indicates which commits have bitmaps, and where to find them in the .bitmap file. In the past some efforts have been made to do this. But we should undertake more performance testing to prove whether this is or isn't a good idea before submitting a patch series in this area.

• Recent changes have made it possible to repack a repository's objects into a sequence of packs whose object count forms a geometric progression (e.g., if the first pack has N objects, the next pack will have at least 2N objects, then 4N objects and so on).

  But even when repacking a repository in this way, regenerating its bitmaps can still take a long time. One possible approach to this would be a new mode of generating bitmaps that is more "incremental" in nature. In other words, a mode which only adds new bitmaps for commits introduced between successive bitmap generations.

  Because of how individual bitmaps are generated, this will result in only having to traverse objects between the new bitmap tips and old ones, resulting in overall faster bitmap generation.

  Like the above, this project would involve designing a set of performance tests, implementing the changes required to introduce this new type of bitmap generation, and then running those tests against your new code.

• Other (larger, longer-term) ideas include: rethinking how we select which commits receive bitmaps (and/or having bitmaps represent multiple commits instead of just one to "summarize" small sets of commits), or improving how we handle queries that use a bitmap but do not have complete coverage. GSoC students should consider these projects more advanced, and thus they are not explained in as much detail here. Instead, this point serves to illustrate that there are opportunities to explore larger projects should we decide they are more interesting than the above or we have time to take them on.

This project will give GSoC students a broad overview of reachability bitmaps, with the goal of improving their performance in some way or another. Students can expect hands-on mentorship, but will have the agency to pick one or more of the above sub-projects (or create their own!) that interests them most.

Expected Project Size: 175 hours or 350 hours

Difficulty: Medium

Languages: C, shell

Possible mentors:

• Taylor Blau < me@ttaylorr.com >
• Kaartic Sivaraam < kaartic.sivaraam@gmail.com >