# Bootstrapping the Compiler [*Bootstrapping*][boot] is the process of using a compiler to compile itself. More accurately, it means using an older compiler to compile a newer version of the same compiler. This raises a chicken-and-egg paradox: where did the first compiler come from? It must have been written in a different language. In Rust's case it was [written in OCaml][ocaml-compiler]. However it was abandoned long ago and the only way to build a modern version of rustc is a slightly less modern version. This is exactly how `x.py` works: it downloads the current beta release of rustc, then uses it to compile the new compiler. ## Stages of bootstrapping Compiling `rustc` is done in stages. ### Stage 0 The stage0 compiler is usually the current _beta_ `rustc` compiler and its associated dynamic libraries, which `x.py` will download for you. (You can also configure `x.py` to use something else.) The stage0 compiler is then used only to compile `rustbuild`, `std`, and `rustc`. When compiling `rustc`, the stage0 compiler uses the freshly compiled `std`. There are two concepts at play here: a compiler (with its set of dependencies) and its 'target' or 'object' libraries (`std` and `rustc`). Both are staged, but in a staggered manner. ### Stage 1 The rustc source code is then compiled with the stage0 compiler to produce the stage1 compiler. ### Stage 2 We then rebuild our stage1 compiler with itself to produce the stage2 compiler. In theory, the stage1 compiler is functionally identical to the stage2 compiler, but in practice there are subtle differences. In particular, the stage1 compiler itself was built by stage0 and hence not by the source in your working directory. This means that the symbol names used in the compiler source may not match the symbol names that would have been made by the stage1 compiler, which can cause problems for dynamic libraries and tests. The `stage2` compiler is the one distributed with `rustup` and all other install methods. However, it takes a very long time to build because one must first build the new compiler with an older compiler and then use that to build the new compiler with itself. For development, you usually only want the `stage1` compiler, which you can build with `./x.py build library`. See [Building the Compiler](./how-to-build-and-run.html#building-the-compiler). ### Stage 3 Stage 3 is optional. To sanity check our new compiler, we can build the libraries with the stage2 compiler. The result ought to be identical to before, unless something has broken. ### Building the stages `x.py` tries to be helpful and pick the stage you most likely meant for each subcommand. These defaults are as follows: - `check`: `--stage 0` - `doc`: `--stage 0` - `build`: `--stage 1` - `test`: `--stage 1` - `dist`: `--stage 2` - `install`: `--stage 2` - `bench`: `--stage 2` You can always override the stage by passing `--stage N` explicitly. For more information about stages, [see below](#understanding-stages-of-bootstrap). ## Complications of bootstrapping Since the build system uses the current beta compiler to build the stage-1 bootstrapping compiler, the compiler source code can't use some features until they reach beta (because otherwise the beta compiler doesn't support them). On the other hand, for [compiler intrinsics][intrinsics] and internal features, the features _have_ to be used. Additionally, the compiler makes heavy use of nightly features (`#![feature(...)]`). How can we resolve this problem? There are two methods used: 1. The build system sets `--cfg bootstrap` when building with `stage0`, so we can use `cfg(not(bootstrap))` to only use features when built with `stage1`. This is useful for e.g. features that were just stabilized, which require `#![feature(...)]` when built with `stage0`, but not for `stage1`. 2. The build system sets `RUSTC_BOOTSTRAP=1`. This special variable means to _break the stability guarantees_ of rust: Allow using `#![feature(...)]` with a compiler that's not nightly. This should never be used except when bootstrapping the compiler. [boot]: https://en.wikipedia.org/wiki/Bootstrapping_(compilers) [intrinsics]: ../appendix/glossary.md#intrinsic [ocaml-compiler]: https://github.com/rust-lang/rust/tree/ef75860a0a72f79f97216f8aaa5b388d98da6480/src/boot ## Contributing to bootstrap When you use the bootstrap system, you'll call it through `x.py`. However, most of the code lives in `src/bootstrap`. `bootstrap` has a difficult problem: it is written in Rust, but yet it is run before the Rust compiler is built! To work around this, there are two components of bootstrap: the main one written in rust, and `bootstrap.py`. `bootstrap.py` is what gets run by `x.py`. It takes care of downloading the `stage0` compiler, which will then build the bootstrap binary written in Rust. Because there are two separate codebases behind `x.py`, they need to be kept in sync. In particular, both `bootstrap.py` and the bootstrap binary parse `config.toml` and read the same command line arguments. `bootstrap.py` keeps these in sync by setting various environment variables, and the programs sometimes have to add arguments that are explicitly ignored, to be read by the other. ### Adding a setting to config.toml This section is a work in progress. In the meantime, you can see an example contribution [here][bootstrap-build]. [bootstrap-build]: https://github.com/rust-lang/rust/pull/71994 ## Understanding stages of bootstrap ### Overview This is a detailed look into the separate bootstrap stages. The convention `x.py` uses is that: - A `--stage N` flag means to run the stage N compiler (`stageN/rustc`). - A "stage N artifact" is a build artifact that is _produced_ by the stage N compiler. - The stage N+1 compiler is assembled from stage N *artifacts*. This process is called _uplifting_. #### Build artifacts Anything you can build with `x.py` is a _build artifact_. Build artifacts include, but are not limited to: - binaries, like `stage0-rustc/rustc-main` - shared objects, like `stage0-sysroot/rustlib/libstd-6fae108520cf72fe.so` - [rlib] files, like `stage0-sysroot/rustlib/libstd-6fae108520cf72fe.rlib` - HTML files generated by rustdoc, like `doc/std` [rlib]: ../serialization.md #### Examples - `./x.py build --stage 0` means to build with the beta `rustc`. - `./x.py doc --stage 0` means to document using the beta `rustdoc`. - `./x.py test --stage 0 library/std` means to run tests on the standard library without building `rustc` from source ('build with stage 0, then test the artifacts'). If you're working on the standard library, this is normally the test command you want. - `./x.py test src/test/ui` means to build the stage 1 compiler and run `compiletest` on it. If you're working on the compiler, this is normally the test command you want. #### Examples of what *not* to do - `./x.py test --stage 0 src/test/ui` is not useful: it runs tests on the _beta_ compiler and doesn't build `rustc` from source. Use `test src/test/ui` instead, which builds stage 1 from source. - `./x.py test --stage 0 compiler/rustc` builds the compiler but runs no tests: it's running `cargo test -p rustc`, but cargo doesn't understand Rust's tests. You shouldn't need to use this, use `test` instead (without arguments). - `./x.py build --stage 0 compiler/rustc` builds the compiler, but does not build libstd or even libcore. Most of the time, you'll want `./x.py build library` instead, which allows compiling programs without needing to define lang items. ### Building vs. running Note that `build --stage N compiler/rustc` **does not** build the stage N compiler: instead it builds the stage N+1 compiler _using_ the stage N compiler. In short, _stage 0 uses the stage0 compiler to create stage0 artifacts which will later be uplifted to be the stage1 compiler_. In each stage, two major steps are performed: 1. `std` is compiled by the stage N compiler. 2. That `std` is linked to programs built by the stage N compiler, including the stage N artifacts (stage N+1 compiler). This is somewhat intuitive if one thinks of the stage N artifacts as "just" another program we are building with the stage N compiler: `build --stage N compiler/rustc` is linking the stage N artifacts to the `std` built by the stage N compiler. Here is a chart of a full build using `x.py`: A diagram of the rustc compilation phases Keep in mind this diagram is a simplification, i.e. `rustdoc` can be built at different stages, the process is a bit different when passing flags such as `--keep-stage`, or if there are non-host targets. ### Stages and `std` Note that there are two `std` libraries in play here: 1. The library _linked_ to `stageN/rustc`, which was built by stage N-1 (stage N-1 `std`) 2. The library _used to compile programs_ with `stageN/rustc`, which was built by stage N (stage N `std`). Stage N `std` is pretty much necessary for any useful work with the stage N compiler. Without it, you can only compile programs with `#![no_core]` -- not terribly useful! The reason these need to be different is because they aren't necessarily ABI-compatible: there could be new layout optimizations, changes to MIR, or other changes to Rust metadata on nightly that aren't present in beta. This is also where `--keep-stage 1 library/std` comes into play. Since most changes to the compiler don't actually change the ABI, once you've produced a `std` in stage 1, you can probably just reuse it with a different compiler. If the ABI hasn't changed, you're good to go, no need to spend time recompiling that `std`. `--keep-stage` simply assumes the previous compile is fine and copies those artifacts into the appropriate place, skipping the cargo invocation. ### Cross-compiling rustc *Cross-compiling* is the process of compiling code that will run on another architecture. For instance, you might want to build an ARM version of rustc using an x86 machine. Building stage2 `std` is different when you are cross-compiling. This is because `x.py` uses a trick: if `HOST` and `TARGET` are the same, it will reuse stage1 `std` for stage2! This is sound because stage1 `std` was compiled with the stage1 compiler, i.e. a compiler using the source code you currently have checked out. So it should be identical (and therefore ABI-compatible) to the `std` that `stage2/rustc` would compile. However, when cross-compiling, stage1 `std` will only run on the host. So the stage2 compiler has to recompile `std` for the target. (See in the table how stage2 only builds non-host `std` targets). ### Why does only libstd use `cfg(bootstrap)`? The `rustc` generated by the stage0 compiler is linked to the freshly-built `std`, which means that for the most part only `std` needs to be cfg-gated, so that `rustc` can use features added to std immediately after their addition, without need for them to get into the downloaded beta. Note this is different from any other Rust program: stage1 `rustc` is built by the _beta_ compiler, but using the _master_ version of libstd! The only time `rustc` uses `cfg(bootstrap)` is when it adds internal lints that use diagnostic items. This happens very rarely. ### What is a 'sysroot'? When you build a project with cargo, the build artifacts for dependencies are normally stored in `target/debug/deps`. This only contains dependencies cargo knows about; in particular, it doesn't have the standard library. Where do `std` or `proc_macro` come from? It comes from the **sysroot**, the root of a number of directories where the compiler loads build artifacts at runtime. The sysroot doesn't just store the standard library, though - it includes anything that needs to be loaded at runtime. That includes (but is not limited to): - `libstd`/`libtest`/`libproc_macro` - The compiler crates themselves, when using `rustc_private`. In-tree these are always present; out of tree, you need to install `rustc-dev` with rustup. - `libLLVM.so`, the shared object file for the LLVM project. In-tree this is either built from source or downloaded from CI; out-of-tree, you need to install `llvm-tools-preview` with rustup. All the artifacts listed so far are *compiler* runtime dependencies. You can see them with `rustc --print sysroot`: ``` $ ls $(rustc --print sysroot)/lib libchalk_derive-0685d79833dc9b2b.so libstd-25c6acf8063a3802.so libLLVM-11-rust-1.50.0-nightly.so libtest-57470d2aa8f7aa83.so librustc_driver-4f0cc9f50e53f0ba.so libtracing_attributes-e4be92c35ab2a33b.so librustc_macros-5f0ec4a119c6ac86.so rustlib ``` There are also runtime dependencies for the standard library! These are in `lib/rustlib`, not `lib/` directly. ``` $ ls $(rustc --print sysroot)/lib/rustlib/x86_64-unknown-linux-gnu/lib | head -n 5 libaddr2line-6c8e02b8fedc1e5f.rlib libadler-9ef2480568df55af.rlib liballoc-9c4002b5f79ba0e1.rlib libcfg_if-512eb53291f6de7e.rlib libcompiler_builtins-ef2408da76957905.rlib ``` `rustlib` includes libraries like `hashbrown` and `cfg_if`, which are not part of the public API of the standard library, but are used to implement it. `rustlib` is part of the search path for linkers, but `lib` will never be part of the search path. #### -Z force-unstable-if-unmarked Since `rustlib` is part of the search path, it means we have to be careful about which crates are included in it. In particular, all crates except for the standard library are built with the flag `-Z force-unstable-if-unmarked`, which means that you have to use `#![feature(rustc_private)]` in order to load it (as opposed to the standard library, which is always available). The `-Z force-unstable-if-unmarked` flag has a variety of purposes to help enforce that the correct crates are marked as unstable. It was introduced primarily to allow rustc and the standard library to link to arbitrary crates on crates.io which do not themselves use `staged_api`. `rustc` also relies on this flag to mark all of its crates as unstable with the `rustc_private` feature so that each crate does not need to be carefully marked with `unstable`. This flag is automatically applied to all of `rustc` and the standard library by the bootstrap scripts. This is needed because the compiler and all of its dependencies are shipped in the sysroot to all users. This flag has the following effects: - Marks the crate as "unstable" with the `rustc_private` feature if it is not itself marked as stable or unstable. - Allows these crates to access other forced-unstable crates without any need for attributes. Normally a crate would need a `#![feature(rustc_private)]` attribute to use other unstable crates. However, that would make it impossible for a crate from crates.io to access its own dependencies since that crate won't have a `feature(rustc_private)` attribute, but *everything* is compiled with `-Z force-unstable-if-unmarked`. Code which does not use `-Z force-unstable-if-unmarked` should include the `#![feature(rustc_private)]` crate attribute to access these force-unstable crates. This is needed for things that link `rustc`, such as `miri`, `rls`, or `clippy`. You can find more discussion about sysroots in: - The [rustdoc PR] explaining why it uses `extern crate` for dependencies loaded from sysroot - [Discussions about sysroot on Zulip](https://rust-lang.zulipchat.com/#narrow/stream/182449-t-compiler.2Fhelp/topic/deps.20in.20sysroot/) - [Discussions about building rustdoc out of tree](https://rust-lang.zulipchat.com/#narrow/stream/182449-t-compiler.2Fhelp/topic/How.20to.20create.20an.20executable.20accessing.20.60rustc_private.60.3F) [rustdoc PR]: https://github.com/rust-lang/rust/pull/76728 ### Directories and artifacts generated by `x.py` The following tables indicate the outputs of various stage actions: | Stage 0 Action | Output | |-----------------------------------------------------------|----------------------------------------------| | `beta` extracted | `build/HOST/stage0` | | `stage0` builds `bootstrap` | `build/bootstrap` | | `stage0` builds `test`/`std` | `build/HOST/stage0-std/TARGET` | | copy `stage0-std` (HOST only) | `build/HOST/stage0-sysroot/lib/rustlib/HOST` | | `stage0` builds `rustc` with `stage0-sysroot` | `build/HOST/stage0-rustc/HOST` | | copy `stage0-rustc` (except executable) | `build/HOST/stage0-sysroot/lib/rustlib/HOST` | | build `llvm` | `build/HOST/llvm` | | `stage0` builds `codegen` with `stage0-sysroot` | `build/HOST/stage0-codegen/HOST` | | `stage0` builds `rustdoc`, `clippy`, `miri`, with `stage0-sysroot` | `build/HOST/stage0-tools/HOST` | `--stage=0` stops here. | Stage 1 Action | Output | |-----------------------------------------------------|---------------------------------------| | copy (uplift) `stage0-rustc` executable to `stage1` | `build/HOST/stage1/bin` | | copy (uplift) `stage0-codegen` to `stage1` | `build/HOST/stage1/lib` | | copy (uplift) `stage0-sysroot` to `stage1` | `build/HOST/stage1/lib` | | `stage1` builds `test`/`std` | `build/HOST/stage1-std/TARGET` | | copy `stage1-std` (HOST only) | `build/HOST/stage1/lib/rustlib/HOST` | | `stage1` builds `rustc` | `build/HOST/stage1-rustc/HOST` | | copy `stage1-rustc` (except executable) | `build/HOST/stage1/lib/rustlib/HOST` | | `stage1` builds `codegen` | `build/HOST/stage1-codegen/HOST` | `--stage=1` stops here. | Stage 2 Action | Output | |--------------------------------------------------------|-----------------------------------------------------------------| | copy (uplift) `stage1-rustc` executable | `build/HOST/stage2/bin` | | copy (uplift) `stage1-sysroot` | `build/HOST/stage2/lib and build/HOST/stage2/lib/rustlib/HOST` | | `stage2` builds `test`/`std` (not HOST targets) | `build/HOST/stage2-std/TARGET` | | copy `stage2-std` (not HOST targets) | `build/HOST/stage2/lib/rustlib/TARGET` | | `stage2` builds `rustdoc`, `clippy`, `miri` | `build/HOST/stage2-tools/HOST` | | copy `rustdoc` | `build/HOST/stage2/bin` | `--stage=2` stops here. ## Passing stage-specific flags to `rustc` `x.py` allows you to pass stage-specific flags to `rustc` when bootstrapping. The `RUSTFLAGS_BOOTSTRAP` environment variable is passed as RUSTFLAGS to the bootstrap stage (stage0), and `RUSTFLAGS_NOT_BOOTSTRAP` is passed when building artifacts for later stages. ## Environment Variables During bootstrapping, there are a bunch of compiler-internal environment variables that are used. If you are trying to run an intermediate version of `rustc`, sometimes you may need to set some of these environment variables manually. Otherwise, you get an error like the following: ```text thread 'main' panicked at 'RUSTC_STAGE was not set: NotPresent', library/core/src/result.rs:1165:5 ``` If `./stageN/bin/rustc` gives an error about environment variables, that usually means something is quite wrong -- or you're trying to compile e.g. `rustc` or `std` or something that depends on environment variables. In the unlikely case that you actually need to invoke rustc in such a situation, you can find the environment variable values by adding the following flag to your `x.py` command: `--on-fail=print-env`.