11 KiB
Contribution Guide
If you want to hack on Miri yourself, great! Here are some resources you might find useful.
Getting started
Check out the issues on this GitHub repository for some ideas. In particular,
look for the green E-*
labels which mark issues that should be rather
well-suited for onboarding. For more ideas or help with hacking on Miri, you can
contact us (oli-obk
and RalfJ
) on the Rust Zulip.
Preparing the build environment
Miri heavily relies on internal and unstable rustc interfaces to execute MIR, which means it is important that you install a version of rustc that Miri actually works with.
The rust-version
file contains the commit hash of rustc that Miri is currently
tested against. Other versions will likely not work. After installing
rustup-toolchain-install-master
, you can run the following command to
install that exact version of rustc as a toolchain:
./rustup-toolchain
This will set up a rustup toolchain called miri
and set it as an override for
the current directory.
You can also create a .auto-everything
file (contents don't matter, can be empty), which
will cause any ./miri
command to automatically call rustup-toolchain
, clippy
and rustfmt
for you. If you don't want all of these to happen, you can add individual .auto-toolchain
,
.auto-clippy
and .auto-fmt
files respectively.
Building and testing Miri
Invoking Miri requires getting a bunch of flags right and setting up a custom
sysroot with xargo. The miri
script takes care of that for you. With the
build environment prepared, compiling Miri is just one command away:
./miri build
Run ./miri
without arguments to see the other commands our build tool
supports.
Testing the Miri driver
The Miri driver compiled from src/bin/miri.rs
is the "heart" of Miri: it is
basically a version of rustc
that, instead of compiling your code, runs it.
It accepts all the same flags as rustc
(though the ones only affecting code
generation and linking obviously will have no effect) and more.
For example, you can (cross-)run the driver on a particular file by doing
./miri run tests/pass/format.rs
./miri run tests/pass/hello.rs --target i686-unknown-linux-gnu
and you can (cross-)run the entire test suite using:
./miri test
MIRI_TEST_TARGET=i686-unknown-linux-gnu ./miri test
If your target doesn't support libstd, you can run miri with
MIRI_NO_STD=1 MIRI_TEST_TARGET=thumbv7em-none-eabihf ./miri test tests/fail/alloc/no_global_allocator.rs
MIRI_NO_STD=1 ./miri run tests/pass/no_std.rs --target thumbv7em-none-eabihf
to avoid attempting (and failing) to build libstd. Note that almost no tests will pass this way, but you can run individual tests.
./miri test FILTER
only runs those tests that contain FILTER
in their
filename (including the base directory, e.g. ./miri test fail
will run all
compile-fail tests).
You can get a trace of which MIR statements are being executed by setting the
MIRI_LOG
environment variable. For example:
MIRI_LOG=info ./miri run tests/pass/vec.rs
Setting MIRI_LOG
like this will configure logging for Miri itself as well as
the rustc_middle::mir::interpret
and rustc_mir::interpret
modules in rustc. You
can also do more targeted configuration, e.g. the following helps debug the
stacked borrows implementation:
MIRI_LOG=rustc_mir::interpret=info,miri::stacked_borrows ./miri run tests/pass/vec.rs
In addition, you can set MIRI_BACKTRACE=1
to get a backtrace of where an
evaluation error was originally raised.
UI testing
We use ui-testing in Miri, meaning we generate .stderr
and .stdout
files for the output
produced by Miri. You can use ./miri bless
to automatically (re)generate these files when
you add new tests or change how Miri presents certain output.
Note that when you also use MIRIFLAGS
to change optimizations and similar, the ui output
will change in unexpected ways. In order to still be able
to run the other checks while ignoring the ui output, use MIRI_SKIP_UI_CHECKS=1 ./miri test
.
For more info on how to configure ui tests see the documentation on the ui test crate
Testing cargo miri
Working with the driver directly gives you full control, but you also lose all the convenience provided by cargo. Once your test case depends on a crate, it is probably easier to test it with the cargo wrapper. You can install your development version of Miri using
./miri install
and then you can use it as if it was installed by rustup
. Make sure you use
the same toolchain when calling cargo miri
that you used when installing Miri!
Usually this means you have to write cargo +miri miri ...
to select the miri
toolchain that was installed by ./rustup-toolchain
.
There's a test for the cargo wrapper in the test-cargo-miri
directory; run
./run-test.py
in there to execute it. Like ./miri test
, this respects the
MIRI_TEST_TARGET
environment variable to execute the test for another target.
Using a modified standard library
Miri re-builds the standard library into a custom sysroot, so it is fairly easy
to test Miri against a modified standard library -- you do not even have to
build Miri yourself, the Miri shipped by rustup
will work. All you have to do
is set the MIRI_LIB_SRC
environment variable to the library
folder of a
rust-lang/rust
repository checkout. Note that changing files in that directory
does not automatically trigger a re-build of the standard library; you have to
clear the Miri build cache manually (on Linux, rm -rf ~/.cache/miri
;
and on Windows, rmdir /S "%LOCALAPPDATA%\rust-lang\miri\cache"
).
Benchmarking
Miri comes with a few benchmarks; you can run ./miri bench
to run them with the locally built
Miri. Note: this will run ./miri install
as a side-effect. Also requires hyperfine
to be
installed (cargo install hyperfine
).
Configuring rust-analyzer
To configure rust-analyzer
and VS Code for working on Miri, save the following
to .vscode/settings.json
in your local Miri clone:
{
"rust-analyzer.rustc.source": "discover",
"rust-analyzer.linkedProjects": [
"./Cargo.toml",
"./cargo-miri/Cargo.toml"
],
"rust-analyzer.checkOnSave.overrideCommand": [
"env",
"AUTO_OPS=42",
"./miri",
"check",
"--message-format=json"
],
"rust-analyzer.buildScripts.overrideCommand": [
"env",
"AUTO_OPS=42",
"./miri",
"check",
"--message-format=json",
],
"rust-analyzer.rustfmt.extraArgs": [
"+nightly"
],
}
Note
If you are building Miri with a locally built rustc, set
rust-analyzer.rustcSource
to the relative path from your Miri clone to the rootCargo.toml
of the locally built rustc. For example, the path might look like../rust/Cargo.toml
.
See the rustc-dev-guide's docs on "Configuring rust-analyzer
for rustc
"
for more information about configuring VS Code and rust-analyzer
.
Advanced topic: other build environments
We described above the simplest way to get a working build environment for Miri,
which is to use the version of rustc indicated by rustc-version
. But
sometimes, that is not enough.
Updating rustc-version
The rustc-version
file is regularly updated to keep Miri close to the latest
version of rustc. Usually, new contributors do not have to worry about this. But
sometimes a newer rustc is needed for a patch, and sometimes Miri needs fixing
for changes in rustc. In both cases, rustc-version
needs updating.
To update the rustc-version
file and install the latest rustc, you can run:
./rustup-toolchain HEAD
Now edit Miri until ./miri test
passes, and submit a PR. Generally, it is
preferred to separate updating rustc-version
and doing what it takes to get
Miri working again, from implementing new features that rely on the updated
rustc. This avoids blocking all Miri development on landing a big PR.
Building Miri with a locally built rustc
A big part of the Miri driver lives in rustc, so working on Miri will sometimes require using a locally built rustc. The bug you want to fix may actually be on the rustc side, or you just need to get more detailed trace of the execution than what is possible with release builds -- in both cases, you should develop Miri against a rustc you compiled yourself, with debug assertions (and hence tracing) enabled.
The setup for a local rustc works as follows:
# Clone the rust-lang/rust repo.
git clone https://github.com/rust-lang/rust rustc
cd rustc
# Create a config.toml with defaults for working on Miri.
./x.py setup compiler
# Now edit `config.toml` and under `[rust]` set `debug-assertions = true`.
# Build a stage 2 rustc, and build the rustc libraries with that rustc.
# This step can take 30 minutes or more.
./x.py build --stage 2 compiler/rustc
# If you change something, you can get a faster rebuild by doing
./x.py build --keep-stage 0 --stage 2 compiler/rustc
# You may have to change the architecture in the next command
rustup toolchain link stage2 build/x86_64-unknown-linux-gnu/stage2
# Now cd to your Miri directory, then configure rustup
rustup override set stage2
Note: When you are working with a locally built rustc or any other toolchain that
is not the same as the one in rust-version
, you should not have .auto-everything
or
.auto-toolchain
as that will keep resetting your toolchain.
rm -f .auto-everything .auto-toolchain
Important: You need to delete the Miri cache when you change the stdlib; otherwise the
old, chached version will be used. On Linux, the cache is located at ~/.cache/miri
,
and on Windows, it is located at %LOCALAPPDATA%\rust-lang\miri\cache
; the exact
location is printed after the library build: "A libstd for Miri is now available in ...".
Note: ./x.py --stage 2 compiler/rustc
currently errors with thread 'main' panicked at 'fs::read(stamp) failed with No such file or directory (os error 2)
,
you can simply ignore that error; Miri will build anyway.
For more information about building and configuring a local compiler, see https://rustc-dev-guide.rust-lang.org/building/how-to-build-and-run.html.
With this, you should now have a working development setup! See above for how to proceed working on Miri.