rustc-driver.md

The Rustc Driver

The rustc_driver is essentially rustc's main() function. It acts as the glue for running the various phases of the compiler in the correct order, managing state such as the CodeMap (maps AST nodes to source code), Session (general build context and error messaging) and the TyCtxt (the "typing context", allowing you to query the type system and other cool stuff). The rustc_driver crate also provides external users with a method for running code at particular times during the compilation process, allowing third parties to effectively use rustc's internals as a library for analysing a crate or emulating the compiler in-process (e.g. the RLS).

For those using rustc as a library, the run_compiler() function is the main entrypoint to the compiler. Its main parameters are a list of command-line arguments and a reference to something which implements the CompilerCalls trait. A CompilerCalls creates the overall CompileController, letting it govern which compiler passes are run and attach callbacks to be fired at the end of each phase.

From rustc_driver's perspective, the main phases of the compiler are:

1. Parse Input: Initial crate parsing
2. Configure and Expand: Resolve #[cfg] attributes, name resolution, and expand macros
3. Run Analysis Passes: Run trait resolution, typechecking, region checking and other miscellaneous analysis passes on the crate
4. Translate to LLVM: Translate to the in-memory form of LLVM IR and turn it into an executable/object files

The CompileController then gives users the ability to inspect the ongoing compilation process

• after parsing
• after AST expansion
• after HIR lowering
• after analysis, and
• when compilation is done

The CompileState's various state_after_*() constructors can be inspected to determine what bits of information are available to which callback.

For a more detailed explanation on using rustc_driver, check out the stupid-stats guide by @nrc (attached as Appendix A).

Warning: By its very nature, the internal compiler APIs are always going to be unstable. That said, we do try not to break things unnecessarily.

A Note On Lifetimes

The Rust compiler is a fairly large program containing lots of big data structures (e.g. the AST, HIR, and the type system) and as such, arenas and references are heavily relied upon to minimize unnecessary memory use. This manifests itself in the way people can plug into the compiler, preferring a "push"-style API (callbacks) instead of the more Rust-ic "pull" style (think the Iterator trait).

For example the CompileState, the state passed to callbacks after each phase, is essentially just a box of optional references to pieces inside the compiler. The lifetime bound on the CompilerCalls trait then helps to ensure compiler internals don't "escape" the compiler (e.g. if you tried to keep a reference to the AST after the compiler is finished), while still letting users record some state for use after the run_compiler() function finishes.

Thread-local storage and interning are used a lot through the compiler to reduce duplication while also preventing a lot of the ergonomic issues due to many pervasive lifetimes. The rustc::ty::tls module is used to access these thread-locals, although you should rarely need to touch it.