- Fork it!
- Create your feature branch:
git checkout -b my-new-feature - Test it:
cargo test - Lint it:
cargo +nightly clippy --all --all-targets -- -D warnings - Commit your changes:
git commit -am 'Add some feature' - Push to the branch:
git push origin my-new-feature - Submit a pull request :D
For developing on rustup itself, you may want to install into a temporary
directory, with a series of commands similar to this:
cargo build
mkdir home
RUSTUP_HOME=home CARGO_HOME=home target/debug/rustup-init --no-modify-path -yYou can then try out rustup with your changes by running home/bin/rustup, without
affecting any existing installation. Remember to keep those two environment variables
set when running your compiled rustup-init or the toolchains it installs, but unset
when rebuilding rustup itself.
If you wish to install your new build to try out longer term in your home directory
then you can run cargo dev-install which is an alias in .cargo/config which
runs cargo run -- --no-modify-path -y to install your build into your homedir.
We use rustfmt to keep our codebase consistently formatted. Please ensure that
you have correctly formatted your code (most editors will do this automatically
when saving) or it may not pass the CI tests.
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as in the README, without any additional terms or conditions.
These are requirements we have that we have not yet lifted to the level of automatic enforcement.
In each file the imports should be grouped into at most 4 groups in the following order:
- stdlib
- non-repository local crates
- repository local other crates
- this crate
Separate each group with a blank line, and rustfmt will sort into a canonical order. Any file that is not grouped like this can be rearranged whenever the file is touched - we're not precious about having it done in a separate commit, though that is helpful.
The rustup::currentprocess module abstracts the global state that is
std::env::args, std::env::vars, std::io::std*, std::process::id,
std::env::current_dir and std::process::exit permitting threaded tests of
the CLI logic; use process() rather than those APIs directly.
We do not enforce lint status in the checks done by GitHub Actions, because clippy is a moving target that can make it hard to merge for little benefit.
We do ask that contributors keep the clippy status clean themselves.
Minimally, run cargo +nightly clippy --all --all-targets -- -D warnings before
submitting code.
If possible, adding --all-features to the command is useful, but will require
additional dependencies like libcurl-dev.
Regular contributors or contributors to particularly OS-specific code should also make sure that their clippy checking is done on at least Linux and Windows, as OS-conditional code is a common source of unused imports and other small lints, which can build up over time.
For developers using BSD/Linux/Mac OS, there are Windows VM's suitable for such development tasks for use with virtualbox and other hypervisors are downloadable from Microsoft. Similarly, there are many Linux and Unix operating systems images available for developers whose usual operating system is Windows. Currently Rustup has no Mac OS specific code, so there should be no need to worry about Mac VM images.
Clippy is also run in GitHub Actions, in the General Checks / Checks build
task, but not currently run per-platform, which means there is no way to find
out the status of clippy per platform without running it on that platform as a
developer.
If you ever see a released version of rustup which has :: in its version string
then something went wrong with the CI and that needs to be addressed.
We use git-testament to construct our version strings. This records, as a
struct, details of the git commit, tag description, and also an indication
of modifications to the working tree present when the binary was compiled.
During normal development you may get information from invoking rustup --version
which looks like rustup-init 1.18.3+15 (a54051502 2019-05-26) or even
rustup-init 1.18.3+15 (a54051502 2019-05-26) dirty 1 modification.
The first part is always the binary name as per clap's normal operation. The
version number is a combination of the most recent tag in the git repo, and the
number of commits since that tag. The parenthesised information is, naturally,
the SHA of the most recent commit and the date of that commit. If the indication
of a dirty tree is present, the number of changes is indicated. This combines
adds, deletes, modifies, and unknown entries.
You can request further information of a rustup binary with the
rustup dump-testament hidden command. It produces output of the form:
$ rustup dump-testament
Rustup version renders as: 1.18.3+15 (a54051502 2019-05-26) dirty 1 modification
Current crate version: 1.18.3
Built from branch: kinnison/version-strings
Commit info: 1.18.3+15 (a54051502 2019-05-26)
Modified: CONTRIBUTING.mdThis can be handy when you are testing development versions on your PC and cannot remember exactly which version you had installed, or if you have given a development copy (or instruction to build such) to a user, and wish to have them confirm exactly what they are using.
Finally, we tell git-testament that we trust the stable branch to carry
releases. If the build is being performed when not on the stable branch, and
the tag and CARGO_PKG_VERSION differ, then the short version string will include
both, in the form rustup-init 1.18.3 :: 1.18.2+99 (a54051502 2019-05-26) which
indicates the crate version before the rest of the commit.
On the other hand, if the build was on the stable branch then regardless
of the tag information, providing the commit was clean, the version is
always replaced by the crate version. The dump-testament hidden command can
reveal the truth however.
Before making a release, ensure that rustup-init.sh is behaving correctly,
and that you're satisfied that nothing in the ecosystem is breaking because
of the update. A useful set of things to check includes verifying that
real-world toolchains install okay, and that rls-vscode isn't broken by
the release. While it's not our responsibility if they depend on non-stable
APIs, we should behave well if we can.
Producing the final release artifacts is a bit involved because of the way Rustup is distributed. The steps for a release are:
- Update all
Cargo.tomlto have the new version (optionally make a commit) - Run
cargo buildand reviewCargo.lockchanges if all looks well, make a commit - Update
rustup-init.shversion to match the commit details forCargo.lock - Push this to the
stablebranch (git push origin HEAD:stable) - While you wait for green CI, double-check the
rustup-init.shfunctionality andrustup-initjust in case. - Ensure all of CI is green on the
stablebranch. Once it is, check through a representative proportion of the builds looking for the reported version statements to ensure that we definitely built something cleanly which reports as the right version number when run--version. - Ping someone in the release team to perform the actual release.
They can find instructions in
ci/sync-dist.pyNote: Some manual testing occurs here, so hopefully they'll catch anything egregious in which case abort the change and roll back. - Once the official release has happened, prepare and push a tag
of that commit, and also push the content to master
git tag -as $VER_NUM -m $VER_NUM(optionally without -s if not GPG signing the tag)git push origin HEAD:mastergit push origin $VER_NUM
The environment variable RUSTUP_FORCE_ARG0 can be used to get rustup to think
its a particular binary, rather than e.g. copying it, symlinking it or other
tricks with exec. This is handy when testing particular code paths from cargo
run.
RUSTUP_FORCE_ARG0=rustup cargo run -- uninstall nightlyIf it's necessary to alter the backtracking limit from the default of half
a release cycle for some reason, you can set the RUSTUP_BACKTRACK_LIMIT
environment variable. If this is unparseable as an i32 or if it's absent
then the default of 21 days (half a cycle) is used. If it parses and is less
than 1, it is clamped to 1 at minimum.
This is not meant for use by users, but can be suggested in diagnosing an issue should one arise with the backtrack limits.
When downloading a file, rustup will retry the download a number of times. The
default is 3 times, but if this variable is set to a valid usize then it is the
max retry count. A value of 0 means no retries, thus the default of 3 will
mean a download is tried a total of four times before failing out.
By default while running tests, we unset some environment variables that will
break our testing (like RUSTUP_TOOLCHAIN, SHELL, ZDOTDIR, RUST_BACKTRACE).
But if you want to debug locally, you may need backtrace. RUSTUP_BACKTRACE
is used like RUST_BACKTRACE to enable backtraces of failed tests.
NOTE: This is a backtrace for the test, not for any rustup process running in the test
$ RUSTUP_BACKTRACE=1 cargo test --release --test cli-v1 -- remove_toolchain_then_add_again
Finished release [optimized] target(s) in 0.38s
Running target\release\deps\cli_v1-1f29f824792f6dc1.exe
running 1 test
test remove_toolchain_then_add_again ... FAILED
failures:
---- remove_toolchain_then_add_again stdout ----
thread 'remove_toolchain_then_add_again' panicked at 'called `Result::unwrap()` on an `Err` value: Os { code: 1142, kind: Other, message: "An attempt was made to create more links on a file than the file system supports." }', src\libcore\result.rs:999:5
stack backtrace:
0: backtrace::backtrace::trace_unsynchronized
at C:\Users\appveyor\.cargo\registry\src\github.com-1ecc6299db9ec823\backtrace-0.3.29\src\backtrace\mod.rs:66
1: std::sys_common::backtrace::_print
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libstd\sys_common\backtrace.rs:47
2: std::sys_common::backtrace::print
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libstd\sys_common\backtrace.rs:36
3: std::panicking::default_hook::{{closure}}
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libstd\panicking.rs:198
4: std::panicking::default_hook
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libstd\panicking.rs:209
5: std::panicking::rust_panic_with_hook
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libstd\panicking.rs:475
6: std::panicking::continue_panic_fmt
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libstd\panicking.rs:382
7: std::panicking::rust_begin_panic
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libstd\panicking.rs:309
8: core::panicking::panic_fmt
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libcore\panicking.rs:85
9: core::result::unwrap_failed
10: cli_v1::mock::clitools::setup
11: alloc::boxed::{{impl}}::call_once<(),FnOnce<()>>
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\src\liballoc\boxed.rs:746
12: panic_unwind::__rust_maybe_catch_panic
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libpanic_unwind\lib.rs:82
13: std::panicking::try
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\src\libstd\panicking.rs:273
14: std::panic::catch_unwind
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\src\libstd\panic.rs:388
15: test::run_test::run_test_inner::{{closure}}
at /rustc/de02101e6d949c4a9040211e9ce8c488a997497e\/src\libtest\lib.rs:1466
note: Some details are omitted, run with `RUST_BACKTRACE=full` for a verbose backtrace.
failures:
remove_toolchain_then_add_again
test result: FAILED. 0 passed; 1 failed; 0 ignored; 0 measured; 26 filtered out
error: test failed, to rerun pass '--test cli-v1'