rust-analyzer/docs/dev
2021-02-16 19:22:09 +03:00
..
architecture.md Use track caller in test documentation 2021-02-10 11:26:48 +03:00
debugging.md Do not overwrite lock file 2021-02-05 10:57:36 -05:00
guide.md Rename ra_ide -> ide 2020-08-13 17:58:27 +02:00
lsp-extensions.md document offsets 2021-02-16 19:22:09 +03:00
README.md Include a commit log summary in the changelog 2021-02-12 19:53:58 +02:00
style.md Document config pattern 2021-02-12 18:10:16 +03:00
syntax.md Fix spelling mistakes in docs/dev 2021-02-03 13:46:51 +01:00

Contributing Quick Start

Rust Analyzer is an ordinary Rust project, which is organized as a Cargo workspace, builds on stable and doesn't depend on C libraries. So, just

$ cargo test

should be enough to get you started!

To learn more about how rust-analyzer works, see ./architecture.md document. It also explains the high-level layout of the source code. Do skim through that document.

We also publish rustdoc docs to pages:

https://rust-analyzer.github.io/rust-analyzer/ide/

Various organizational and process issues are discussed in this document.

Getting in Touch

Rust Analyzer is a part of RLS-2.0 working group. Discussion happens in this Zulip stream:

https://rust-lang.zulipchat.com/#narrow/stream/185405-t-compiler.2Fwg-rls-2.2E0

Issue Labels

  • good-first-issue are good issues to get into the project.
  • E-has-instructions issues have links to the code in question and tests.
  • E-easy, E-medium, E-hard, E-unknown, labels are estimates for how hard would be to write a fix. Each triaged issue should have one of these labels.
  • S-actionable and S-unactionable specify if there are concrete steps to resolve or advance an issue. Roughly, actionable issues need only work to be fixed, while unactionable ones are effectively wont-fix. Each triaged issue should have one of these labels.
  • fun is for cool, but probably hard stuff.
  • Design is for moderate/large scale architecture discussion. Also a kind of fun. These issues should generally include a link to a Zulip discussion thread.

CI

We use GitHub Actions for CI. Most of the things, including formatting, are checked by cargo test so, if cargo test passes locally, that's a good sign that CI will be green as well. The only exception is that some long-running tests are skipped locally by default. Use env RUN_SLOW_TESTS=1 cargo test to run the full suite.

We use bors-ng to enforce the not rocket science rule.

You can run cargo xtask install-pre-commit-hook to install git-hook to run rustfmt on commit.

Launching rust-analyzer

Debugging the language server can be tricky. LSP is rather chatty, so driving it from the command line is not really feasible, driving it via VS Code requires interacting with two processes.

For this reason, the best way to see how rust-analyzer works is to find a relevant test and execute it. VS Code & Emacs include an action for running a single test.

Launching a VS Code instance with a locally built language server is also possible. There's "Run Extension (Debug Build)" launch configuration for this in VS Code.

In general, I use one of the following workflows for fixing bugs and implementing features:

If the problem concerns only internal parts of rust-analyzer (i.e. I don't need to touch the rust-analyzer crate or TypeScript code), there is a unit-test for it. So, I use Rust Analyzer: Run action in VS Code to run this single test, and then just do printf-driven development/debugging. As a sanity check after I'm done, I use cargo xtask install --server and Reload Window action in VS Code to verify that the thing works as I expect.

If the problem concerns only the VS Code extension, I use Run Installed Extension launch configuration from launch.json. Notably, this uses the usual rust-analyzer binary from PATH. For this, it is important to have the following in your settings.json file:

{
    "rust-analyzer.server.path": "rust-analyzer"
}

After I am done with the fix, I use cargo xtask install --client to try the new extension for real.

If I need to fix something in the rust-analyzer crate, I feel sad because it's on the boundary between the two processes, and working there is slow. I usually just cargo xtask install --server and poke changes from my live environment. Note that this uses --release, which is usually faster overall, because loading stdlib into debug version of rust-analyzer takes a lot of time. To speed things up, sometimes I open a temporary hello-world project which has "rust-analyzer.withSysroot": false in .code/settings.json. This flag causes rust-analyzer to skip loading the sysroot, which greatly reduces the amount of things rust-analyzer needs to do, and makes printf's more useful. Note that you should only use the eprint! family of macros for debugging: stdout is used for LSP communication, and print! would break it.

If I need to fix something simultaneously in the server and in the client, I feel even more sad. I don't have a specific workflow for this case.

Additionally, I use cargo run --release -p rust-analyzer -- analysis-stats path/to/some/rust/crate to run a batch analysis. This is primarily useful for performance optimizations, or for bug minimization.

TypeScript Tests

If you change files under editors/code and would like to run the tests and linter, install npm and run:

cd editors/code
npm ci
npm run lint

Code Style & Review Process

Do see ./style.md.

How to ...

  • ... add an assist? #7535
  • ... add a new protocol extension? #4569
  • ... add a new configuration option? #7451
  • ... add a new completion? #6964
  • ... allow new syntax in the parser? #7338

Logging

Logging is done by both rust-analyzer and VS Code, so it might be tricky to figure out where logs go.

Inside rust-analyzer, we use the standard log crate for logging, and env_logger for logging frontend. By default, log goes to stderr, but the stderr itself is processed by VS Code.

To see stderr in the running VS Code instance, go to the "Output" tab of the panel and select rust-analyzer. This shows eprintln! as well. Note that stdout is used for the actual protocol, so println! will break things.

To log all communication between the server and the client, there are two choices:

  • you can log on the server side, by running something like

    env RA_LOG=lsp_server=debug code .
    
  • you can log on the client side, by enabling "rust-analyzer.trace.server": "verbose" workspace setting. These logs are shown in a separate tab in the output and could be used with LSP inspector. Kudos to @DJMcNab for setting this awesome infra up!

There are also two VS Code commands which might be of interest:

  • Rust Analyzer: Status shows some memory-usage statistics.

  • Rust Analyzer: Syntax Tree shows syntax tree of the current file/selection.

  • Rust Analyzer: View Hir shows the HIR expressions within the function containing the cursor.

    You can hover over syntax nodes in the opened text file to see the appropriate rust code that it refers to and the rust editor will also highlight the proper text range.

    If you trigger Go to Definition in the inspected Rust source file, the syntax tree read-only editor should scroll to and select the appropriate syntax node token.

    demo

Profiling

We have a built-in hierarchical profiler, you can enable it by using RA_PROFILE env-var:

RA_PROFILE=*             // dump everything
RA_PROFILE=foo|bar|baz   // enabled only selected entries
RA_PROFILE=*@3>10        // dump everything, up to depth 3, if it takes more than 10 ms

In particular, I have export RA_PROFILE='*>10' in my shell profile.

We also have a "counting" profiler which counts number of instances of popular structs. It is enabled by RA_COUNT=1.

To measure time for from-scratch analysis, use something like this:

$ cargo run --release -p rust-analyzer -- analysis-stats ../chalk/

For measuring time of incremental analysis, use either of these:

$ cargo run --release -p rust-analyzer -- analysis-bench ../chalk/ --highlight ../chalk/chalk-engine/src/logic.rs
$ cargo run --release -p rust-analyzer -- analysis-bench ../chalk/ --complete ../chalk/chalk-engine/src/logic.rs:94:0

Release Process

Release process is handled by release, dist and promote xtasks, release being the main one.

release assumes that you have checkouts of rust-analyzer, rust-analyzer.github.io, and rust-lang/rust in the same directory:

./rust-analyzer
./rust-analyzer.github.io
./rust-rust-analyzer  # Note the name!

Additionally, it assumes that remote for rust-analyzer is called upstream (I use origin to point to my fork).

Release steps:

  1. Inside rust-analyzer, run cargo xtask release. This will:
    • checkout the release branch
    • reset it to upstream/nightly
    • push it to upstream. This triggers GitHub Actions which:
      • runs cargo xtask dist to package binaries and VS Code extension
      • makes a GitHub release
      • pushes VS Code extension to the marketplace
    • create new changelog in rust-analyzer.github.io
  2. While the release is in progress, fill in the changelog
  3. Commit & push the changelog
  4. Tweet
  5. Inside rust-analyzer, run cargo xtask promote -- this will create a PR to rust-lang/rust updating rust-analyzer's submodule. Self-approve the PR.

If the GitHub Actions release fails because of a transient problem like a timeout, you can re-run the job from the Actions console. If it fails because of something that needs to be fixed, remove the release tag (if needed), fix the problem, then start over. Make sure to remove the new changelog post created when running cargo xtask release a second time.

Permissions

There are three sets of people with extra permissions:

  • rust-analyzer GitHub organization admins (which include current t-compiler leads). Admins have full access to the org.
  • review team in the organization. Reviewers have r+ access to all of organization's repositories and publish rights on crates.io. They also have direct commit access, but all changes should via bors queue. It's ok to self-approve if you think you know what you are doing! bors should automatically sync the permissions.
  • triage team in the organization. This team can label and close issues.