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Sorbet's runtime type checking component
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 Dependencies

Development

~> 5.11
~> 2.1
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 Project Readme

Sorbet logo

Sorbet

This repository contains Sorbet, a fast, powerful type checker designed for Ruby. It aims to be easy to add to existing codebases with gradual types, and fast to respond with errors and suggestions.

This README contains documentation specifically for contributing to Sorbet. You might also want to:

If you are at Stripe, you might also want to see http://go/types/internals for docs about Stripe-specific development workflows and historical Stripe context.

Table of Contents

  • Sorbet user-facing design principles
  • Quickstart
  • Learning how Sorbet works
  • Building Sorbet
    • Common Compilation Errors
  • Running Sorbet
  • Running the tests
  • Testing Sorbet against pay-server
  • Writing tests
    • test_corpus tests
    • Expectation tests
    • CLI tests
    • LSP tests
      • Testing "Find Definition" and "Find All References"
      • Testing "Go to Type Definition"
      • Testing hover
      • Testing completion
      • Testing workspace symbols (symbol search)
      • Testing incremental type checking
    • LSP recorded tests
    • Updating tests
  • Debugging
  • Writing docs
  • Editor and environment
    • Bazel
    • Multiple git worktrees
    • Shell
    • Formatting files
    • Editor setup for C++

Sorbet user-facing design principles

Early in our project, we've defined some guidelines for how working with sorbet should feel like.

  1. Explicit

    We're willing to write annotations, and in fact see them as beneficial; they make code more readable and predictable. We're here to help readers as much as writers.

  2. Feel useful, not burdensome

    While it is explicit, we are putting effort into making it concise. This shows in multiple ways:

    • error messages should be clear
    • verbosity should be compensated with more safety
  3. As simple as possible, but powerful enough

    Overall, we are not strong believers in super-complex type systems. They have their place, and we need a fair amount of expressive power to model (enough) real Ruby code, but all else being equal we want to be simpler. We believe that such a system scales better, and—most importantly—is easier for our users to learn & understand.

  4. Compatible with Ruby

    In particular, we don't want a new syntax. Existing Ruby syntax means we can leverage most of our existing tooling (editors, etc). Also, the point of Sorbet is to gradually improve an existing Ruby codebase. No new syntax makes it easier to be compatible with existing tools.

  5. Scales

    On all axes: execution speed, number of collaborators, lines of code, codebase age. We work in large Ruby codebases, and they will only get larger.

  6. Can be adopted gradually

    In order to make adoption possible at scale, we cannot require every team or project to adopt Sorbet all at once. Sorbet needs to support teams adopting it at different paces.

Quickstart

  1. Install the dependencies

    • brew install bazel autoconf coreutils parallel
  2. Clone this repository

    • git clone https://github.com/sorbet/sorbet.git
    • cd sorbet
  3. Build Sorbet

    • ./bazel build //main:sorbet --config=dbg
  4. Run Sorbet!

    • bazel-bin/main/sorbet -e "42 + 'hello'"

Learning how Sorbet works

We've documented the internals of Sorbet in a separate doc. Cross-reference between that doc and here to learn how Sorbet works and how to change it!

→ internals.md

There is also a talk online that describes Sorbet's high-level architecture and the reasons why it's fast:

→ Fast type checking for Ruby

Building Sorbet

There are multiple ways to build sorbet. This one is the most common:

./bazel build //main:sorbet --config=dbg

This will build an executable in bazel-bin/main/sorbet (see "Running Sorbet" below). There are many options you can pass when building sorbet:

  • --config=dbg
    • Most common build config for development.
    • Good stack traces, runs all ENFORCEs.
  • --config=sanitize
    • Link in extra sanitizers, in particular: UBSan and ASan.
    • Catches most memory and undefined-behavior errors.
    • Substantially larger and slower binary.
  • --config=debugsymbols
    • (Included by --config=dbg) debugging symbols, and nothing else.
  • --config=forcedebug
    • Use more memory, but report even more sanity checks.
  • --config=static-libs
    • Forcibly use static linking (Sorbet defaults to dynamic linking for faster build times).
    • Sorbet already uses this option in release builds (see below).
  • --config=release-mac and --config=release-linux
    • Exact release configuration that we ship to our users.

Independently of providing or omitting any of the above flags, you can turn on optimizations for any build:

  • -c opt
    • Enables clang optimizations (i.e., -O2)

These args are not mutually exclusive. For example, a common pairing when debugging is

--config=dbg --config=sanitize

In .bazelrc you can find out what all these options (and others) mean.

Common Compilation Errors

(Mac) Xcode version must be specified to use an Apple CROSSTOOL

This error typically occurs after an Xcode upgrade.

Developer tools must be installed, the Xcode license must be accepted, and your active Xcode command line tools directory must point to an installed version of Xcode.

The following commands should do the trick:

# Install command line tools
xcode-select --install
# Ensure that the system finds command line tools in an active Xcode directory
sudo xcode-select -s /Applications/Xcode.app/Contents/Developer
# Accept the Xcode license.
sudo xcodebuild -license
# Clear bazel's cache, which may contain files generated from a previous
# version of Xcode command line tools.
bazel clean --expunge

(Mac) fatal error: 'math.h' file not found (or some other system header)

This error can happen on Macs when the /usr/include folder is missing. The solution is to install macOS headers via the following package:

macOS Mojave:

open /Library/Developer/CommandLineTools/Packages/macOS_SDK_headers_for_macOS_10.14.pkg

macOS Catalina:

sudo ln -s /Library/Developer/CommandLineTools/SDKs/MacOSX.sdk/usr/include/* /usr/local/include/

Running Sorbet

Run Sorbet on an expression:

bazel-bin/main/sorbet -e "1 + false"

Run Sorbet on a file:

bazel-bin/main/sorbet foo.rb

Running bazel-bin/main/sorbet --help will show lots of options. These are the common ones for contributors:

  • -p <IR>
    • Asks sorbet to print out any given intermediate representation.
    • See --help for available values of <IR>.
  • --stop-after <phase>
    • Useful when there's a bug in a later phase, and you want to quit early to debug.
  • -v, -vv, -vvv
    • Show logger output (increasing verbosity)
  • --max-threads=1
    • Useful for determining if you're dealing with a concurrency bug or not.
  • --wait-for-dbg
    • Will freeze Sorbet on startup and wait for a debugger to attach
    • This is useful when you don't have control over launching the process (LSP)

Running the tests

To run all the tests:

bazel test //... --config=dbg

(The //... literally means "all targets".)

To run a subset of the tests curated for faster iteration and development speed, run:

bazel test test --config=dbg

Note that in bazel terms, the second test is an alias for //test:test, so we're being a bit cute here.

By default, all test output goes into files. To also print it to the screen:

bazel test //... --config=dbg --test_output=errors

If any test failed, you will see two pieces of information printed:

1. //test:test_testdata/resolver/optional_constant
2.   /private/var/tmp/.../test/test_testdata/resolver/optional_constant/test.log
  1. the test's target (in case you want to run just this test again with bazel test <target>)
  2. a (runnable) file containing the test's output

To see the failing output, either:

  • Re-run bazel test with the --test_output=errors flag
  • Copy/paste the *.log file and run it (the output will open in less)

Testing Sorbet against pay-server

This is specific to contributing to Sorbet at Stripe.

If you are at Stripe and want to test your branch against pay-server, see http://go/types/local-dev.

Writing tests

We write tests by adding files to subfolders of the test/ directory. Individual subfolders are "magic"; each contains specific types of tests. We aspire to have our tests be fully reproducible.

C++ note: In C++, hash functions are only required to produce the same result for the same input within a single execution of a program.

Thus, we expect all user-visible outputs to be explicitly sorted using a key stable from one run to the next.

There are many ways to test Sorbet, some "better" than others. We've ordered them below in order from most preferable to least preferable. And we always prefer some tests to no tests!

test_corpus tests

The first kind of test can be called either test_corpus tests or testdata tests, based on the name of the test harness or the folder containing these tests, respectively.

To create a test_corpus test, add any file <name>.rb to test/testdata, in any folder depth. The file must either:

  • type check entirely, or
  • throw errors only on lines marked with a comment (see below).

To mark that a line should have errors, append # error: <message> (the <message> must match the raised error message). In case there are multiple errors on this line, add an # error: <message> on its own line just below.

Error checks can optionally point to a range of characters rather than a line:

1 + '' # error: `String` doesn't match `Integer`

rescue Foo, Bar => baz
     # ^^^ error: Unable to resolve constant `Foo`
          # ^^^ error: Unable to resolve constant `Bar`

You can run this test with:

bazel test //test:test_PosTests/testdata/path/to/<name>

Expectation tests

Each test_corpus test can be turned into an expectation test by optionally creating any number of <name>.rb.<phase>.exp files (where <name> matches the name of the ruby file for this test). These files contain pretty printed representations of internal data structures, according to what would be printed by -p <phase>. The snapshot must exactly match the output generated by running sorbet -p <phase> <name>.rb for the test to pass.

You can run this test with:

bazel test //test:test_PosTests/testdata/path/to/<name>

Files that begin with a prefix and __ will be run together. For example, foo__1.rb and foo__2.rb will be run together as test foo. If such sets of files have *.exp files associated with them, the *.exp files must instead follow the pattern <name>.<phase>.exp, where <name> does not include the __*.rb suffix. So foo__1.rb and foo__2.rb would have an exp file like foo.<pass>.exp.

Another exception: for package-tree exp tests, the filename is always pass.package-tree.exp, no matter the name of the test.

CLI tests

Any folder <name> that is added to test/cli/ becomes a test. This folder should have a file test.sh that is executable. When run, its output will be compared against test.out in that folder.

Our bazel setup will produce two targets:

  • bazel run //test/cli:test_<name> will execute the .sh file
  • bazel test //test/cli:test_<name> will execute the .sh and check it against what's in the .out file.

The scripts are run inside Bazel, so they will be executed from the top of the workspace and have access to source files and built targets using their path from the root. In particular, the compiled sorbet binary is available under main/sorbet.

LSP tests

Most LSP tests are expectation tests with additional LSP-specific annotations. They are primarily contained in test/testdata/lsp, but all files in test/testdata are tested in LSP mode. You can run a test test/testdata/lsp/<name>.rb like so:

bazel test //test:test_LSPTests/testdata/lsp/<name>

Testing "Find Definition" and "Find All References"

LSP tests have access to def and usage assertions that you can use to annotate definition and usage sites for a variable:

  a = 10
# ^ def: a
  b = a + 10
    # ^ usage: a

With these annotations, the test will check that "Find Definition" from the addition will lead to a = 10, and that "Find All References" from either location will return both the definition and usage.

If a variable is re-defined, it can be annotated with a version number:

  a = 10
# ^ def: a 1
  a = 20
# ^ def: a 2
  b = a + 10
    # ^ usage: a 2

usage annotations can accept multiple version numbers, separated by a ,. This is useful if you have variables that get re-defined through multiple-paths:

  if some_condition
    a = 10
  # ^ def a 1
  else
    a = 'hello'
  # ^ def: a 2
  end

  p a
  # ^ usage: a 1,2

If a location should not report any definition or usage, then use the magic label (nothing):

    a = 10
# ^ def: (nothing)

If a location should report multiple definitions (e.g., a class or module opened in multiple files), then you can add a second def with the same name:

class Foo
  #   ^^^ def: foo
end

class Foo
  #   ^^^ def: foo
end

When marking definitions that correspond to method arguments that have defaults, multiple definitions will need to be marked: one for the argument definition itself and one for its default value. The default value needs to be given a different version number, and also marked default-arg-value:

  def foo(a: 1)
        # ^ def: a 1
           # ^ def: a 2 default-arg-value
    p a
    # ^ usage: a 1,2
  end

This is due to the translation of defaults into the CFG: there is a synthetic conditional that chooses either to initialize the variable from the argument passed at the send, or to the default value when no value is present.

Finding all references works differently in package specification (__package.rb) files. Consider the following:

class Foo < PackageSpec
  import Bar

Calling "find all references" on Bar in this file will return only references to Bar in the Foo package. LSP tests have access to import and importusage assertions that you can use to test this functionality.

class Foo < PackageSpec
  import Bar
  #      ^^^ import: bar
  class Foo::Baz
    Bar.new
 #  ^^^ importusage: bar
  end

With these annotations, the LSP test will check if "find all references" on Bar in import Bar statement returns the Bar.new usage.

Note that an import assertion is dissimilar to a def assertion, in that it is in fact a subclass of a usage assertion. In this case, the def corresponding to an import is the PackageSpec declaration of the imported package. Calling "find all references" on a PackageSpec declaration will return all imports of the package.

class Bar < PackageSpec
  #   ^^^ def: bar
  import Bar
class Foo < PackageSpec
  import Bar
  #      ^^^ import: bar
class Baz < PackageSpec
  import Bar
  #      ^^^ import: bar

With these annotations, the LSP test will check if "find all references" on Bar from the class Bar < PackageSpec declaration returns the declaration itself plus the imports.

Testing "Go to Type Definition"

This is somewhat similar to "Find Definition" above, but also slightly different because there's no analogue of "Find All Type Definitions."

class A; end
#     ^ type-def: some-label

aaa = A.new
# ^ type: some-label

The type: some-label assertion says "please simulate a Go to Type Definition here, named some-label" and the type-def: some-label assertion says "assert that the results for some-label are exactly these locations."

That means if the type definition could return multiple locs, the assertions will have to cover all results:

class A; end
#     ^ type-def: AorB
class B; end
#     ^ type-def: AorB

aaa = T.let(A.new, T.any(A, B))
# ^ type: AorB

If a location should not report any definition or usage, then use the magic label (nothing):

# typed: false
class A; end
aaa = A.new
# ^ def: (nothing)

Testing hover

LSP tests can also assert the contents of hover responses with hover assertions:

  a = 10
# ^ hover: Integer(10)

If a location should report the empty string, use the special label (nothing):

     a = 10
# ^ hover: (nothing)

Assert the contents of a specific line of the hover response with hover-line assertions:

  a = 10
# ^ hover-line: 1 Integer(10)

Testing completion

LSP tests can also assert the contents of completion responses with completion assertions.

class A
  def self.foo_1; end
  def self.foo_2; end

  foo
#    ^ completion: foo_1, foo_2
end

The ^ corresponds to the position of the cursor. So in the above example, it's as if the cursor is like this: foo│. If the ^ had been directly under the last o, it would have been like this: fo|o. Only the first ^ is used. If you use ^^^ in the assertion, the test harness will send a completion assertion at the position of the first caret.

You can also write a test for a partial prefix of the completion results:

class A
  def self.foo_1; end
  def self.foo_2; end

  foo
#    ^ completion: foo_1, ...
end

Add the , ... suffix to the end of a partial list of completion results, and the test harness will ensure that the listed identifiers match a prefix of the completion items. This prefix must still be listed in order.

If a location should report zero completion items, use the special message (nothing):

class A
  def self.foo_1; end
  def self.foo_2; end

  zzz
#    ^ completion: (nothing)
end

To write a test for the snippet that would be inserted into the document if a particular completion item was selected, you can make two files:

# -- test/testdata/lsp/completion/mytest.rb --
class A
  def self.foo_1; end
end

A.foo_
#     ^ apply-completion: [A] item: 0

The apply-completion assertion says "make sure the file mytest.A.rbedited contains the result of inserting the completion snippet for the 0th completion item into the file."

# -- test/testdata/lsp/completion/mytest.A.rbedited --
class A
  def self.foo_1; end
end

A.foo_1${0}
#     ^ apply-completion: [A] item: 0

As you can see, the fancy ${...} (tabstop placeholders) show up verbatim in the output if they were sent in the completion response.

It's not currently possible to test these parts of a completion response:

  • completion kind
  • documentation
  • detail

For these, your best bet is to test manually in VS Code / your preferred editor and verify that you're seeing your changes. For documentation specifically, nearly all the code paths are shared with hover, so you can alternatively write a hover test.

Testing workspace symbols (symbol search)

LSP tests can assert that a specific item appears in a symbol search (the textDocument/workspaceSymbols request) using the symbol-search assertion:

class Project::Foo
#     ^^^ symbol-search: "Foo"
end

The symbol-search can optionally specify how that item should appear in search results:

class Project::Foo
#     ^^^ symbol-search: "Foo", name = "Foo", container = "Project"
end

In the above, container can also be the special string "(nothing)" to indicate that the item has no container.

symbol-search can also specify the item's relative rank in the ordered search results:

class Project::Foo
#     ^^^ symbol-search: "Foo", rank = 1
end

Testing "Go to Implementation"

Testing the "Go to Implementation" feature is really similar to the testing techniques of the "Go to Type Definition".

module A
#      ^ find-implementation: A
  extend T::Sig
  extend T::Helpers
  interface!
end

 class B
#^^^^^^^ implementation: A
  extend T::Sig
  include A
#         ^ find-implementation: A
end

There are two types of assertions:

  1. find-implementation: <symbol> means make a "Go to Implementation" request here. <symbol> marks the symbol name we are looking for.
  2. implementation: <symbol> marks the location which should be returned for the "Go to Implementation" call for a given <symbol>

If the request returns multiple locations, you should mark all of them with implementation: <symbol>

Testing rename constant

To write a test for renaming constants, you need to make at least two files:

# -- test/testdata/lsp/refactor/mytest.rb --

# typed: true
# frozen_string_literal: true

class Foo
  class Foo
  end
end

foo = Foo.new
#     ^ apply-rename: [A] newName: Bar

The apply-rename assertion here says "simulate a user starting a rename from the position of this caret." You'll need to add an .rbedited file that reflects what the result of the changes should look like. In this case, the file would look like this:

# -- test/testdata/lsp/refactor/mytest.A.rbedited --

# typed: true
# frozen_string_literal: true

class Bar
  class Foo
  end
end

foo = Bar.new
#     ^ apply-rename: [A] newName: Bar

You can test that invalid renames aren't applied by adding invalid: true to your test, like so:

# -- test/testdata/lsp/refactor/mytest.rb --

# typed: true
# frozen_string_literal: true

class Foo
  class Foo
  end
end

foo = Foo.new
#     ^ apply-rename: [A] newName: foo invalid:true

To test for a specific error message, add an expectedErrorMessage argument to the test:

# typed: true
# frozen_string_literal: true

require_relative './constant__class_definition.rb'

sig { params(foo: Foo::Foo).returns(Foo::Foo) }
def foo(foo); end

class Baz
#     ^ apply-rename: [D] newName: Bar invalid: true expectedErrorMessage: Renaming constants defined in .rbi files is not supported; symbol Baz is defined at test/testdata/lsp/rename/constant__rbi_class_reference.rbi

end

You can add more files that reference the constant you're renaming, just make sure to add a matching .rbedited file with the same version.

Testing incremental type checking

In LSP mode, Sorbet runs file updates on a fast path or a slow path. It checks the structure of the file before and after the update to determine if the change is covered under the fast path. If it is, it performs further processing to determine the set of files that need to be type checked.

LSP tests can define file updates in <name>.<version>.rbupdate files which contain the contents of <name>.rb after the update occurs. For example, the file foo.1.rbupdate contains the updated contents of foo.rb.

If the test contains multiple files by using a __ suffixed prefix, then all rbupdates with the same version will be applied in the same update. For example, foo__bar.1.rbupdate and foo__baz.1.rbupdate will be applied simultaneously to update foo__bar.rb and foo__baz.rb.

Inside *.rbupdate files, you can assert that the slow path ran by adding a line with # assert-slow-path: true. You can assert that the fast path ran on foo__bar.rb and foo__baz.rb with #assert-fast-path: foo__bar.rb,foo__baz.rb.

Note that the default behavior when testing multi-file updates (e.g., *__1.1.rbupdate + *__2.1.rbupdate) is to include all the files in the file update that is created and sent to the LSP server. When testing changes that assert whether the right files were typechecked on the fast path with assert-fast-path, you also likely want to declare which files should not be included in the file edit, leaving Sorbet to figure out the subset of files to be typechecked. But regardless of whether a file was included in the update set, you likely want to assert that error occur at certain points inside the file. For this, you can use # exclude-from-file-update: true inside an rbupdate file. Note that when using this, the act of adding the exclude-from-file-update assertion in the rbupdate will have the effect of shifting all the error assertions off by one line compared to where the LSP server will be reporting those errors. To work around this, you should leave a spacer line in the previous file, so that the exclude-from-file-update assertion replaces the spacer line, instead of being inserted into the file as a completely new line. Search for spacer in some of the fast_path tests to see an example.

To craft an update to an RBI file, use .rbiupdate instead of .rbupdate, unless you mean to simulate the effect of converting an RBI file to an RB file.

LSP recorded tests

It is possible to record an LSP session and use it as a test. We are attempting to move away from this form of testing, as these tests are hard to update and understand. If at all possible, try to add your test case as a regular LSP test.

Any folder <name> that is added to test/lsp/ will become a test. This folder should contain a file named <folderName>.rec that contains a recorded LSP session.

  • Lines that start with "Read:" will be sent to sorbet as input.
  • Lines that start with "Write:" will be expected from sorbet as output.

Updating tests

Frequently when a test is failing, it's because something inconsequential changed in the captured output, rather than there being a bug in your code.

To recapture the traces, you can run

tools/scripts/update_exp_files.sh

You will probably want to look through the changes and git checkout any files with changes that you believe are actually bugs in your code and fix your code.

update_exp_files.sh updates every snapshot file kind known to Sorbet. This can be slow, depending on what needs to be recompiled and updated. Some faster commands:

# Only update the `*.exp` files in `test/testdata`
tools/scripts/update_testdata_exp.sh

# Only update the `*.exp` files in `test/testdata/cfg`
tools/scripts/update_testdata_exp.sh test/testdata/cfg

# Only update a single exp file's test:
tools/scripts/update_testdata_exp.sh test/testdata/cfg/next.rb

# Only update the `*.out` files in `test/cli`
bazel test //test/cli:update

Debugging

In general,

  • to debug a normal build of sorbet?
    • lldb bazel-bin/main/sorbet -- <args> ...
    • (Consider using --config=static-libs for better debug symbols)
    • If you see weird Python errors on macOS, try PATH=/usr/bin lldb.
  • to debug an existing Sorbet process (i.e., LSP)
    • launch Sorbet with the --wait-for-dbg flag
    • lldb -p <pid>
    • set breakpoints and then continue

Also, it’s good to get in the practice of fixing bugs by first adding an ENFORCE (assertion) that would have caught the bug before actually fixing the bug. It’s far easier to fix bugs when there’s a nice error message stating what invariant you’ve violated. ENFORCEs are free in the release build.

Writing docs

The sources for Sorbet's documentation website live in the website/ folder. Specifically, the docs live in website/docs/, are all authored with Markdown, and are built using Docusaurus.

→ website/README.md

^ See here for how to work with the documentation site locally.

Editor and environment

Bazel

Bazel supports having a persistent cache of previous build results so that rebuilds for the same input files are fast. To enable this feature, run this script to create a ./.bazelrc.local and cache folder:

tools/create_local_bazelrc.sh

Multiple git worktrees

Sometimes it can be nice to have multiple working trees in Git. This allows you to have multiple active checkouts Sorbet, sharing the same .git/ folder. To set up a new worktree with Sorbet:

tools/scripts/make_worktree.sh <worktree_name>

Shell

Many of the build commands are very long. You might consider shortening the common ones with shell aliases of your choice:

# mnemonic: 's' for sorbet
alias sb="bazel build //main:sorbet --config=dbg"
alias st="bazel test //... --config=dbg --test_output=errors"

Formatting files

We ensure that C++ files are formatted with clang-format and that Bazel BUILD files are formatted with buildifier. To avoid inconsistencies between different versions of these tools, we have scripts which download and run these tools through bazel:

tools/scripts/format_cxx.sh
tools/scripts/format_build_files.sh

CI will fail if there are any unformatted files, so you might want to set up your files to be formatted automatically with one of these options:

  1. Set up a pre-commit / pre-push hook which runs these scripts.
  2. Set up your editor to run these scripts. See below.

Editor setup for C++

The clang suite of tools has a pretty great story around editor tooling: you can build a compile_commands.json using Clang's Compilation Database format.

Many clang-based tools consume this file to provide language-aware features in, for example, editor integrations.

To build a compile_commands.json file for Sorbet with bazel:

tools/scripts/build_compilation_db.sh

This builds a ./compile_commands.json file (that is gitignored). This file hard-codes some paths into the Bazel sandbox. These files can get stale, especially when they're generated by Bazel genrule's. In particular, the ./compile_commands.json references files in Bazel's opt configuration (e.g., whatever was last built with -c opt / --compilation_mode=opt). If you're seeing stale errors, consider running a command like ./bazel build //main:sorbet -c opt.

You are encouraged to play around with various clang-based tools which use the compile_commands.json database. Some suggestions:

  • rtags -- Clang aware jump-to-definition / find references / etc.

    brew install rtags
    
    # Have the rtags daemon be automatically launched by macOS on demand
    brew services start rtags
    
    # cd into sorbet
    # ensure that ./compile_commands.json exists
    
    # Tell rtags to index sorbet using our compile_commands.json file
    rc -J .

    There are rtags editor plugins for most text editors.

  • clangd -- Clang-based language server implementation

    clangd supports more features than rtags (specifically, reporting Diagnostics), but can be somewhat slower at times because it does not pre-index all your code like rtags does.

    After successfully compiling Sorbet, point your editor to use the clangd executable located in bazel-sorbet/external/llvm_toolchain_15_0_7/bin/clangd.

  • clang-format -- Clang-based source code formatter

    We build clang-format in Bazel to ensure that everyone uses the same version. Here's how you can get clang-format out of Bazel to use it in your editor:

    # Build clang-format with bazel
    ./bazel build //tools:clang-format
    
    # Once bazel runs again, this symlink to clang-format will go away.
    # We need to copy it out of bazel so our editor can use it:
    mkdir -p "$HOME/bin"
    cp bazel-bin/tools/clang-format $HOME/bin
    
    # (Be sure that $HOME/bin is on your PATH, or use a path that is)

    With clang-format on your path, you should be able to find an editor plugin that uses it to format your code on save.

    Note: our format script passes some extra options to clang-format. Configure your editor to pass these options along to clang-format:

    -style=file -assume-filename=<CURRENT_FILE>
  • CLion -- JetBrains C/C++ IDE

    CLion can be made aware of the compile_commands.json database. Replaces your entire text editing workflow (full-fledged IDE).

  • vscode-clangd -- Clangd extension for VS Code

    This extension integrates clangd (see above) with VS Code. It will also run clang-format whenever you save. Note: Microsoft's C/C++ extension does not work properly with Sorbet's compile_commands.json.

    The settings for this repository automatically configure vscode-clangd to run the clangd executable in the bazel-sorbet directory. Note that you will need to compile Sorbet once before it will work.

    clangd operates on compile_commands.json, so make sure you run the ./tools/scripts/build_compilation_db.sh script.

Here are some sample config setups: