//! Internal interface for communicating between a `proc_macro` client //! (a proc macro crate) and a `proc_macro` server (a compiler front-end). //! //! Serialization (with C ABI buffers) and unique integer handles are employed //! to allow safely interfacing between two copies of `proc_macro` built //! (from the same source) by different compilers with potentially mismatching //! Rust ABIs (e.g., stage0/bin/rustc vs stage1/bin/rustc during bootstrap). #![deny(unsafe_code)] pub use super::{Delimiter, Level, LineColumn, Spacing}; use std::fmt; use std::hash::Hash; use std::marker; use std::mem; use std::ops::Bound; use std::panic; use std::sync::atomic::AtomicUsize; use std::sync::Once; use std::thread; /// Higher-order macro describing the server RPC API, allowing automatic /// generation of type-safe Rust APIs, both client-side and server-side. /// /// `with_api!(MySelf, my_self, my_macro)` expands to: /// ```rust,ignore (pseudo-code) /// my_macro! { /// // ... /// Literal { /// // ... /// fn character(ch: char) -> MySelf::Literal; /// // ... /// fn span(my_self: &MySelf::Literal) -> MySelf::Span; /// fn set_span(my_self: &mut MySelf::Literal, span: MySelf::Span); /// }, /// // ... /// } /// ``` /// /// The first two arguments serve to customize the arguments names /// and argument/return types, to enable several different usecases: /// /// If `my_self` is just `self`, then each `fn` signature can be used /// as-is for a method. If it's anything else (`self_` in practice), /// then the signatures don't have a special `self` argument, and /// can, therefore, have a different one introduced. /// /// If `MySelf` is just `Self`, then the types are only valid inside /// a trait or a trait impl, where the trait has associated types /// for each of the API types. If non-associated types are desired, /// a module name (`self` in practice) can be used instead of `Self`. macro_rules! with_api { ($S:ident, $self:ident, $m:ident) => { $m! { FreeFunctions { fn drop($self: $S::FreeFunctions); fn track_env_var(var: &str, value: Option<&str>); fn track_path(path: &str); }, TokenStream { fn drop($self: $S::TokenStream); fn clone($self: &$S::TokenStream) -> $S::TokenStream; fn new() -> $S::TokenStream; fn is_empty($self: &$S::TokenStream) -> bool; fn expand_expr($self: &$S::TokenStream) -> Result<$S::TokenStream, ()>; fn from_str(src: &str) -> $S::TokenStream; fn to_string($self: &$S::TokenStream) -> String; fn from_token_tree( tree: TokenTree<$S::Group, $S::Punct, $S::Ident, $S::Literal>, ) -> $S::TokenStream; fn into_iter($self: $S::TokenStream) -> $S::TokenStreamIter; }, TokenStreamBuilder { fn drop($self: $S::TokenStreamBuilder); fn new() -> $S::TokenStreamBuilder; fn push($self: &mut $S::TokenStreamBuilder, stream: $S::TokenStream); fn build($self: $S::TokenStreamBuilder) -> $S::TokenStream; }, TokenStreamIter { fn drop($self: $S::TokenStreamIter); fn clone($self: &$S::TokenStreamIter) -> $S::TokenStreamIter; fn next( $self: &mut $S::TokenStreamIter, ) -> Option>; }, Group { fn drop($self: $S::Group); fn clone($self: &$S::Group) -> $S::Group; fn new(delimiter: Delimiter, stream: $S::TokenStream) -> $S::Group; fn delimiter($self: &$S::Group) -> Delimiter; fn stream($self: &$S::Group) -> $S::TokenStream; fn span($self: &$S::Group) -> $S::Span; fn span_open($self: &$S::Group) -> $S::Span; fn span_close($self: &$S::Group) -> $S::Span; fn set_span($self: &mut $S::Group, span: $S::Span); }, Punct { fn new(ch: char, spacing: Spacing) -> $S::Punct; fn as_char($self: $S::Punct) -> char; fn spacing($self: $S::Punct) -> Spacing; fn span($self: $S::Punct) -> $S::Span; fn with_span($self: $S::Punct, span: $S::Span) -> $S::Punct; }, Ident { fn new(string: &str, span: $S::Span, is_raw: bool) -> $S::Ident; fn span($self: $S::Ident) -> $S::Span; fn with_span($self: $S::Ident, span: $S::Span) -> $S::Ident; }, Literal { fn drop($self: $S::Literal); fn clone($self: &$S::Literal) -> $S::Literal; fn from_str(s: &str) -> Result<$S::Literal, ()>; fn to_string($self: &$S::Literal) -> String; fn debug_kind($self: &$S::Literal) -> String; fn symbol($self: &$S::Literal) -> String; fn suffix($self: &$S::Literal) -> Option; fn integer(n: &str) -> $S::Literal; fn typed_integer(n: &str, kind: &str) -> $S::Literal; fn float(n: &str) -> $S::Literal; fn f32(n: &str) -> $S::Literal; fn f64(n: &str) -> $S::Literal; fn string(string: &str) -> $S::Literal; fn character(ch: char) -> $S::Literal; fn byte_string(bytes: &[u8]) -> $S::Literal; fn span($self: &$S::Literal) -> $S::Span; fn set_span($self: &mut $S::Literal, span: $S::Span); fn subspan( $self: &$S::Literal, start: Bound, end: Bound, ) -> Option<$S::Span>; }, SourceFile { fn drop($self: $S::SourceFile); fn clone($self: &$S::SourceFile) -> $S::SourceFile; fn eq($self: &$S::SourceFile, other: &$S::SourceFile) -> bool; fn path($self: &$S::SourceFile) -> String; fn is_real($self: &$S::SourceFile) -> bool; }, MultiSpan { fn drop($self: $S::MultiSpan); fn new() -> $S::MultiSpan; fn push($self: &mut $S::MultiSpan, span: $S::Span); }, Diagnostic { fn drop($self: $S::Diagnostic); fn new(level: Level, msg: &str, span: $S::MultiSpan) -> $S::Diagnostic; fn sub( $self: &mut $S::Diagnostic, level: Level, msg: &str, span: $S::MultiSpan, ); fn emit($self: $S::Diagnostic); }, Span { fn debug($self: $S::Span) -> String; fn def_site() -> $S::Span; fn call_site() -> $S::Span; fn mixed_site() -> $S::Span; fn source_file($self: $S::Span) -> $S::SourceFile; fn parent($self: $S::Span) -> Option<$S::Span>; fn source($self: $S::Span) -> $S::Span; fn start($self: $S::Span) -> LineColumn; fn end($self: $S::Span) -> LineColumn; fn before($self: $S::Span) -> $S::Span; fn after($self: $S::Span) -> $S::Span; fn join($self: $S::Span, other: $S::Span) -> Option<$S::Span>; fn resolved_at($self: $S::Span, at: $S::Span) -> $S::Span; fn source_text($self: $S::Span) -> Option; fn save_span($self: $S::Span) -> usize; fn recover_proc_macro_span(id: usize) -> $S::Span; }, } }; } // FIXME(eddyb) this calls `encode` for each argument, but in reverse, // to avoid borrow conflicts from borrows started by `&mut` arguments. macro_rules! reverse_encode { ($writer:ident;) => {}; ($writer:ident; $first:ident $(, $rest:ident)*) => { reverse_encode!($writer; $($rest),*); $first.encode(&mut $writer, &mut ()); } } // FIXME(eddyb) this calls `decode` for each argument, but in reverse, // to avoid borrow conflicts from borrows started by `&mut` arguments. macro_rules! reverse_decode { ($reader:ident, $s:ident;) => {}; ($reader:ident, $s:ident; $first:ident: $first_ty:ty $(, $rest:ident: $rest_ty:ty)*) => { reverse_decode!($reader, $s; $($rest: $rest_ty),*); let $first = <$first_ty>::decode(&mut $reader, $s); } } #[allow(unsafe_code)] mod buffer; #[forbid(unsafe_code)] pub mod client; #[allow(unsafe_code)] mod closure; #[forbid(unsafe_code)] mod handle; #[macro_use] #[forbid(unsafe_code)] mod rpc; #[allow(unsafe_code)] mod scoped_cell; #[forbid(unsafe_code)] pub mod server; use buffer::Buffer; pub use rpc::PanicMessage; use rpc::{Decode, DecodeMut, Encode, Reader, Writer}; /// An active connection between a server and a client. /// The server creates the bridge (`Bridge::run_server` in `server.rs`), /// then passes it to the client through the function pointer in the `run` /// field of `client::Client`. The client holds its copy of the `Bridge` /// in TLS during its execution (`Bridge::{enter, with}` in `client.rs`). #[repr(C)] pub struct Bridge<'a> { /// Reusable buffer (only `clear`-ed, never shrunk), primarily /// used for making requests, but also for passing input to client. cached_buffer: Buffer, /// Server-side function that the client uses to make requests. dispatch: closure::Closure<'a, Buffer, Buffer>, /// If 'true', always invoke the default panic hook force_show_panics: bool, } #[forbid(unsafe_code)] #[allow(non_camel_case_types)] mod api_tags { use super::rpc::{DecodeMut, Encode, Reader, Writer}; macro_rules! declare_tags { ($($name:ident { $(fn $method:ident($($arg:ident: $arg_ty:ty),* $(,)?) $(-> $ret_ty:ty)*;)* }),* $(,)?) => { $( pub(super) enum $name { $($method),* } rpc_encode_decode!(enum $name { $($method),* }); )* pub(super) enum Method { $($name($name)),* } rpc_encode_decode!(enum Method { $($name(m)),* }); } } with_api!(self, self, declare_tags); } /// Helper to wrap associated types to allow trait impl dispatch. /// That is, normally a pair of impls for `T::Foo` and `T::Bar` /// can overlap, but if the impls are, instead, on types like /// `Marked` and `Marked`, they can't. trait Mark { type Unmarked; fn mark(unmarked: Self::Unmarked) -> Self; } /// Unwrap types wrapped by `Mark::mark` (see `Mark` for details). trait Unmark { type Unmarked; fn unmark(self) -> Self::Unmarked; } #[derive(Copy, Clone, PartialEq, Eq, Hash)] struct Marked { value: T, _marker: marker::PhantomData, } impl Mark for Marked { type Unmarked = T; fn mark(unmarked: Self::Unmarked) -> Self { Marked { value: unmarked, _marker: marker::PhantomData } } } impl Unmark for Marked { type Unmarked = T; fn unmark(self) -> Self::Unmarked { self.value } } impl<'a, T, M> Unmark for &'a Marked { type Unmarked = &'a T; fn unmark(self) -> Self::Unmarked { &self.value } } impl<'a, T, M> Unmark for &'a mut Marked { type Unmarked = &'a mut T; fn unmark(self) -> Self::Unmarked { &mut self.value } } impl Mark for Option { type Unmarked = Option; fn mark(unmarked: Self::Unmarked) -> Self { unmarked.map(T::mark) } } impl Unmark for Option { type Unmarked = Option; fn unmark(self) -> Self::Unmarked { self.map(T::unmark) } } impl Mark for Result { type Unmarked = Result; fn mark(unmarked: Self::Unmarked) -> Self { unmarked.map(T::mark).map_err(E::mark) } } impl Unmark for Result { type Unmarked = Result; fn unmark(self) -> Self::Unmarked { self.map(T::unmark).map_err(E::unmark) } } macro_rules! mark_noop { ($($ty:ty),* $(,)?) => { $( impl Mark for $ty { type Unmarked = Self; fn mark(unmarked: Self::Unmarked) -> Self { unmarked } } impl Unmark for $ty { type Unmarked = Self; fn unmark(self) -> Self::Unmarked { self } } )* } } mark_noop! { (), bool, char, &'_ [u8], &'_ str, String, usize, Delimiter, Level, LineColumn, Spacing, Bound, } rpc_encode_decode!( enum Delimiter { Parenthesis, Brace, Bracket, None, } ); rpc_encode_decode!( enum Level { Error, Warning, Note, Help, } ); rpc_encode_decode!(struct LineColumn { line, column }); rpc_encode_decode!( enum Spacing { Alone, Joint, } ); #[derive(Clone)] pub enum TokenTree { Group(G), Punct(P), Ident(I), Literal(L), } impl Mark for TokenTree { type Unmarked = TokenTree; fn mark(unmarked: Self::Unmarked) -> Self { match unmarked { TokenTree::Group(tt) => TokenTree::Group(G::mark(tt)), TokenTree::Punct(tt) => TokenTree::Punct(P::mark(tt)), TokenTree::Ident(tt) => TokenTree::Ident(I::mark(tt)), TokenTree::Literal(tt) => TokenTree::Literal(L::mark(tt)), } } } impl Unmark for TokenTree { type Unmarked = TokenTree; fn unmark(self) -> Self::Unmarked { match self { TokenTree::Group(tt) => TokenTree::Group(tt.unmark()), TokenTree::Punct(tt) => TokenTree::Punct(tt.unmark()), TokenTree::Ident(tt) => TokenTree::Ident(tt.unmark()), TokenTree::Literal(tt) => TokenTree::Literal(tt.unmark()), } } } rpc_encode_decode!( enum TokenTree { Group(tt), Punct(tt), Ident(tt), Literal(tt), } );