Contributing.md

Contributing to LLPC

Introduction

This file documents best practices for use when making changes to the LLPC project.

Where the Coding Standards are concerned with the quality of the source code of LLPC at any point in time, this document is concerned with the quality of the process by which the source code evolves over time.

LLPC uses pull requests on GitHub for code review. We maintain a linear history, that is, pull requests are rebased on top of the dev branch.

Commits as the logical atomic unit of change

Adapted from the Linux kernel guide on submitting patches, which really says it best:

Separate each logical change into a separate commit.

For example, if your changes include both a bug fix and a performance enhancement, separate those changes into two commits. If your change includes a cleanup that extracts common functionality into a new function and a bug fix in that common functionality, separate those into two commits.

On the other hand, if you make a single change to numerous files, such as adopting a new API provided by LLVM, group those changes into a single commit. Thus a single logical change is contained within a single commit.

The point to remember is that each commit should make an easily understood change that can be verified by reviewers. Each commit should be justifiable on its own merits.

Each commit must be a strict improvement. When submitting a series of commits, make a reasonable effort to ensure that there are no regressions in the middle of the series. This allows us to use git bisect when regressions do occur.

Exercise judgment as to whether a series of commits should be submitted as multiple pull requests or as a single one. GitHub makes it difficult to review individual commits in a pull request, but having many pull requests is confusing for reviewers as well, because their relationship, if any, is not clear in the UI. Some rules of thumb:

• If your changes are entirely separate, such as a new feature and an unrelated bug fix that you happened to make while developing the feature, put the commits onto separate branches and submit them as separate pull requests.
• If your changes are related, such as a sequence of refactorings and enhancements towards implementing a larger feature, consider submitting them as a single pull requests. Reviewers can still look at individual commits via GitHub's UI or by downloading your branch and examining it locally.

Having multiple incomplete commits locally and rewriting them using git rebase is normal and encouraged as part of the process of shaping a series of logically self-contained commits. The guidelines above only apply once you send out your changes via a pull request.

Write useful commit messages

[Parts of this section are also adapted from the Linux kernel guide on submitting patches.]

Commit messages should describe the "why" of a change: What does the change solve? Where does it lead? Convince the reviewer that there is a problem worth fixing.

Follow best practices for commit messages:

• The first line must be a short summary of the commit. The second line must be blank.

• When the commit is contained entirely within a logical module, prefix the summary with the module name, e.g. "builder: Add CreateUnicornSample".

• Generally keep lines shorter than 75 characters. Exceeding this limit slightly for the summary is okay, and don't break lines where it would hurt searchability, e.g. don't break URLs and CTS test names. Don't break footer lines, as tools should be able to parse them mechanically.

• Use common practice footer lines to provide more information where applicable.

• The most important footer line is a "Fixes:" line. They allow a quick identification of relevant bug fix commits, for example for cherry-picking onto release branches. Common forms are:

  • Indicate the fix of a regression that was introduced by an earlier commit, using both the hash and the summary title of the commit in the following format:

    Fixes: 123456789a ("patch: Change the default order of userdata SGPRs")
    

  • Refer to an issue that was fixed:

    Fixes: https://github.com/GPUOpen-Drivers/llpc/issues/1234
    

    Caution: We still need to clarify how/whether to refer to internal tickets.

  • Refer to a CTS test that was fixed:

    Fixes: dEQP-VK.shader.unicorns.horn_winding.ccw.*
    

• Provide further explanation as necessary in paragraphs between the summary and the footer.

• Describe your changes in imperative mood, as if you are giving orders to the codebase to change its behaviour, e.g. "make xyzzy do frotz" instead of "[This patch] makes xyzzy do frotz" or "[I] changed xyzzy to do frotz".

Quote the relevant specifications (Vulkan, SPIR-V, or other) to provide justification for your changes. For example:

Section "Validation Rules within a Module" of the Vulkan Environment
for SPIR-V appendix (version 1.2.345) says:

    "If OpControlBarrier is used in fragment, vertex, tessellation
    evaluation, or geometry shaders, the execution Scope must be
    Subgroup."

Remove the unused code for the Workgroup case and guard with an
assertion instead.

This is particularly important when your change affects a subtle or uncommonly used corner of the specification.

For optimizations, provide numbers you have obtained in testing.

Remember that some of these additional explanations fit better as comments in the code itself. Exercise judgment when deciding whether to put the explanation in a comment or in the commit message. Ask yourself: is this useful as a comment when reading the code? Or does it only distract? Is the explanation independent of the current context and is it likely to stand the test of time?

Write useful tests

New code requires new tests to be written that will exercise that code. This applies to bug fixes as well as new features. The tests serve two purposes: ensure that the new code does not regress if it needs to be changed and to give an example of what the new code does.

Test cases should be reduced as much as possible. You can use Spir-V reduce to help reduce the size of test cases, or do it manually. This helps other developers understand the tests better, and allows the tests to run faster.

The tests must exist in the LLPC repository. They can be

• a shaderdb test,
• an LGC test,
• an LLPC unit test, or
• an LGC unit test.

We do not want to rely on the Vulkan CTS. Running the Vulkan CTS takes a long time, putting a time-to-test burden on all developers. The Vulkan CTS tests are also harder to debug because more components are involved and require a GPU.

LIT tests (tests that are run using the llvm-lit tool) should provide good and reliable coverage, e.g. using CHECK-NEXT lines, while still being easy to maintain. Where reasonably possible, try to:

• For passes in LGC, write an .lgc test that invokes lgc with the -passes option to run a single pass. Use LLVM's update_test_checks.py with the --tool option to automatically generate the check lines.
• For frontend code, write a GLSL or .spvasm test (either standalone file or inlined in a .pipe file) that invokes amdllpc with the -emit-lgc option or with -o - -filetype=asm. Use our update_llpc_test_checks.py tool to automatically generate the check lines. Where necessary, use options like --check-globals to auto-generate additional checks.

To help developers know if their tests are covering their code change, a code coverage analysis will be run on all PR before they are submitted. The PR should only be merged if the new code is covered. Exceptions can be made if there is a good reason like the PR adds error handling code for an error that cannot be reproduced consistently. Note that this is just a minimum requirement and does not mean that the tests are effective. If an existing test already covers the new code, that test should be updated to test for the new behaviour or a new test should be added.

Avoid binary data

Git does not handle binary files well. Binary data is difficult to review, modify, and may mask licensing issues. For these reasons, we avoid adding binary data to the repository. We also prefer textual data representations over arrays of raw bytes/words in the source code.

If your test requires binary inputs, replace them with textual inputs, or explain why the binary form is absolutely necessary. For example, you can store .spvasm inputs and assemble them at runtime instead of .spv binaries. Similarly, msgpack document inputs can stored as YAML strings and converted to msgpack objects at runtime.

Useful things to know about Git

Not all projects that use Git aim for commits as the logical unit of change, so it is expected that you may not be aware of all useful functionality in Git. This document is not a Git tutorial, but here is a brief list of tools that are useful to know of for this workflow:

• git gui to interactively commit only a subset of local changes, and to amend the most recent commit.
• git add -p to achieve the same via the command line.
• git commit --amend to amend the most recent commit from the command line.
• git stash to temporarily undo an uncommitted change and re-apply it later.
• git commit --squash=<commit> and git commit --fixup=<commit> to mark changes to be added to an earlier commit.
• git rebase -i <commit> and the rebase.autoSquash option to rework a series of commits.
• git rebase -i <commit> -x "..." to execute a command after each commit; you can use this to verify that LLPC compiles and passes lit tests after each commit.
• git cherry-pick for moving a commit from one branch to another.
• gitk and tig to browse the repository's history.
• git reflog to find old states of the repository that may seem lost; once you commit something, Git will not lose it -- at least not for the next 30 days.

Read Git's documentation or search online to learn more about them. Similar functionality is available in some GUI tools.

Additional sources

• Patch submission guidelines of the Linux kernel
• Blog post: They want to be small, they want to be big: thoughts on code reviews and the power of patch series