//! The main parser interface. #![feature(bool_to_option)] #![feature(crate_visibility_modifier)] #![feature(bindings_after_at)] #![feature(try_blocks)] #![feature(or_patterns)] use rustc_ast as ast; use rustc_ast::token::{self, DelimToken, Nonterminal, Token, TokenKind}; use rustc_ast::tokenstream::{self, Spacing, TokenStream, TokenTree}; use rustc_ast_pretty::pprust; use rustc_data_structures::sync::Lrc; use rustc_errors::{Diagnostic, FatalError, Level, PResult}; use rustc_session::parse::ParseSess; use rustc_span::{symbol::kw, FileName, SourceFile, Span, DUMMY_SP}; use smallvec::SmallVec; use std::mem; use std::path::Path; use std::str; use tracing::{debug, info}; pub const MACRO_ARGUMENTS: Option<&'static str> = Some("macro arguments"); #[macro_use] pub mod parser; use parser::{emit_unclosed_delims, make_unclosed_delims_error, Parser}; pub mod lexer; pub mod validate_attr; // A bunch of utility functions of the form `parse__from_` // where includes crate, expr, item, stmt, tts, and one that // uses a HOF to parse anything, and includes file and // `source_str`. /// A variant of 'panictry!' that works on a Vec instead of a single DiagnosticBuilder. macro_rules! panictry_buffer { ($handler:expr, $e:expr) => {{ use rustc_errors::FatalError; use std::result::Result::{Err, Ok}; match $e { Ok(e) => e, Err(errs) => { for e in errs { $handler.emit_diagnostic(&e); } FatalError.raise() } } }}; } pub fn parse_crate_from_file<'a>(input: &Path, sess: &'a ParseSess) -> PResult<'a, ast::Crate> { let mut parser = new_parser_from_file(sess, input, None); parser.parse_crate_mod() } pub fn parse_crate_attrs_from_file<'a>( input: &Path, sess: &'a ParseSess, ) -> PResult<'a, Vec> { let mut parser = new_parser_from_file(sess, input, None); parser.parse_inner_attributes() } pub fn parse_crate_from_source_str( name: FileName, source: String, sess: &ParseSess, ) -> PResult<'_, ast::Crate> { new_parser_from_source_str(sess, name, source).parse_crate_mod() } pub fn parse_crate_attrs_from_source_str( name: FileName, source: String, sess: &ParseSess, ) -> PResult<'_, Vec> { new_parser_from_source_str(sess, name, source).parse_inner_attributes() } pub fn parse_stream_from_source_str( name: FileName, source: String, sess: &ParseSess, override_span: Option, ) -> TokenStream { let (stream, mut errors) = source_file_to_stream(sess, sess.source_map().new_source_file(name, source), override_span); emit_unclosed_delims(&mut errors, &sess); stream } /// Creates a new parser from a source string. pub fn new_parser_from_source_str(sess: &ParseSess, name: FileName, source: String) -> Parser<'_> { panictry_buffer!(&sess.span_diagnostic, maybe_new_parser_from_source_str(sess, name, source)) } /// Creates a new parser from a source string. Returns any buffered errors from lexing the initial /// token stream. pub fn maybe_new_parser_from_source_str( sess: &ParseSess, name: FileName, source: String, ) -> Result, Vec> { maybe_source_file_to_parser(sess, sess.source_map().new_source_file(name, source)) } /// Creates a new parser, handling errors as appropriate if the file doesn't exist. /// If a span is given, that is used on an error as the source of the problem. pub fn new_parser_from_file<'a>(sess: &'a ParseSess, path: &Path, sp: Option) -> Parser<'a> { source_file_to_parser(sess, file_to_source_file(sess, path, sp)) } /// Creates a new parser, returning buffered diagnostics if the file doesn't exist, /// or from lexing the initial token stream. pub fn maybe_new_parser_from_file<'a>( sess: &'a ParseSess, path: &Path, ) -> Result, Vec> { let file = try_file_to_source_file(sess, path, None).map_err(|db| vec![db])?; maybe_source_file_to_parser(sess, file) } /// Given a `source_file` and config, returns a parser. fn source_file_to_parser(sess: &ParseSess, source_file: Lrc) -> Parser<'_> { panictry_buffer!(&sess.span_diagnostic, maybe_source_file_to_parser(sess, source_file)) } /// Given a `source_file` and config, return a parser. Returns any buffered errors from lexing the /// initial token stream. fn maybe_source_file_to_parser( sess: &ParseSess, source_file: Lrc, ) -> Result, Vec> { let end_pos = source_file.end_pos; let (stream, unclosed_delims) = maybe_file_to_stream(sess, source_file, None)?; let mut parser = stream_to_parser(sess, stream, None); parser.unclosed_delims = unclosed_delims; if parser.token == token::Eof { parser.token.span = Span::new(end_pos, end_pos, parser.token.span.ctxt()); } Ok(parser) } // Must preserve old name for now, because `quote!` from the *existing* // compiler expands into it. pub fn new_parser_from_tts(sess: &ParseSess, tts: Vec) -> Parser<'_> { stream_to_parser(sess, tts.into_iter().collect(), crate::MACRO_ARGUMENTS) } // Base abstractions /// Given a session and a path and an optional span (for error reporting), /// add the path to the session's source_map and return the new source_file or /// error when a file can't be read. fn try_file_to_source_file( sess: &ParseSess, path: &Path, spanopt: Option, ) -> Result, Diagnostic> { sess.source_map().load_file(path).map_err(|e| { let msg = format!("couldn't read {}: {}", path.display(), e); let mut diag = Diagnostic::new(Level::Fatal, &msg); if let Some(sp) = spanopt { diag.set_span(sp); } diag }) } /// Given a session and a path and an optional span (for error reporting), /// adds the path to the session's `source_map` and returns the new `source_file`. fn file_to_source_file(sess: &ParseSess, path: &Path, spanopt: Option) -> Lrc { match try_file_to_source_file(sess, path, spanopt) { Ok(source_file) => source_file, Err(d) => { sess.span_diagnostic.emit_diagnostic(&d); FatalError.raise(); } } } /// Given a `source_file`, produces a sequence of token trees. pub fn source_file_to_stream( sess: &ParseSess, source_file: Lrc, override_span: Option, ) -> (TokenStream, Vec) { panictry_buffer!(&sess.span_diagnostic, maybe_file_to_stream(sess, source_file, override_span)) } /// Given a source file, produces a sequence of token trees. Returns any buffered errors from /// parsing the token stream. pub fn maybe_file_to_stream( sess: &ParseSess, source_file: Lrc, override_span: Option, ) -> Result<(TokenStream, Vec), Vec> { let src = source_file.src.as_ref().unwrap_or_else(|| { sess.span_diagnostic .bug(&format!("cannot lex `source_file` without source: {}", source_file.name)); }); let (token_trees, unmatched_braces) = lexer::parse_token_trees(sess, src.as_str(), source_file.start_pos, override_span); match token_trees { Ok(stream) => Ok((stream, unmatched_braces)), Err(err) => { let mut buffer = Vec::with_capacity(1); err.buffer(&mut buffer); // Not using `emit_unclosed_delims` to use `db.buffer` for unmatched in unmatched_braces { if let Some(err) = make_unclosed_delims_error(unmatched, &sess) { err.buffer(&mut buffer); } } Err(buffer) } } } /// Given a stream and the `ParseSess`, produces a parser. pub fn stream_to_parser<'a>( sess: &'a ParseSess, stream: TokenStream, subparser_name: Option<&'static str>, ) -> Parser<'a> { Parser::new(sess, stream, false, subparser_name) } /// Runs the given subparser `f` on the tokens of the given `attr`'s item. pub fn parse_in<'a, T>( sess: &'a ParseSess, tts: TokenStream, name: &'static str, mut f: impl FnMut(&mut Parser<'a>) -> PResult<'a, T>, ) -> PResult<'a, T> { let mut parser = Parser::new(sess, tts, false, Some(name)); let result = f(&mut parser)?; if parser.token != token::Eof { parser.unexpected()?; } Ok(result) } // NOTE(Centril): The following probably shouldn't be here but it acknowledges the // fact that architecturally, we are using parsing (read on below to understand why). pub fn nt_to_tokenstream(nt: &Nonterminal, sess: &ParseSess, span: Span) -> TokenStream { // A `Nonterminal` is often a parsed AST item. At this point we now // need to convert the parsed AST to an actual token stream, e.g. // un-parse it basically. // // Unfortunately there's not really a great way to do that in a // guaranteed lossless fashion right now. The fallback here is to just // stringify the AST node and reparse it, but this loses all span // information. // // As a result, some AST nodes are annotated with the token stream they // came from. Here we attempt to extract these lossless token streams // before we fall back to the stringification. let tokens = match *nt { Nonterminal::NtItem(ref item) => { prepend_attrs(sess, &item.attrs, item.tokens.as_ref(), span) } Nonterminal::NtBlock(ref block) => block.tokens.clone(), Nonterminal::NtPat(ref pat) => pat.tokens.clone(), Nonterminal::NtTy(ref ty) => ty.tokens.clone(), Nonterminal::NtIdent(ident, is_raw) => { Some(tokenstream::TokenTree::token(token::Ident(ident.name, is_raw), ident.span).into()) } Nonterminal::NtLifetime(ident) => { Some(tokenstream::TokenTree::token(token::Lifetime(ident.name), ident.span).into()) } Nonterminal::NtTT(ref tt) => Some(tt.clone().into()), Nonterminal::NtExpr(ref expr) | Nonterminal::NtLiteral(ref expr) => { if expr.tokens.is_none() { debug!("missing tokens for expr {:?}", expr); } prepend_attrs(sess, &expr.attrs, expr.tokens.as_ref(), span) } _ => None, }; // FIXME(#43081): Avoid this pretty-print + reparse hack let source = pprust::nonterminal_to_string(nt); let filename = FileName::macro_expansion_source_code(&source); let tokens_for_real = parse_stream_from_source_str(filename, source, sess, Some(span)); // During early phases of the compiler the AST could get modified // directly (e.g., attributes added or removed) and the internal cache // of tokens my not be invalidated or updated. Consequently if the // "lossless" token stream disagrees with our actual stringification // (which has historically been much more battle-tested) then we go // with the lossy stream anyway (losing span information). // // Note that the comparison isn't `==` here to avoid comparing spans, // but it *also* is a "probable" equality which is a pretty weird // definition. We mostly want to catch actual changes to the AST // like a `#[cfg]` being processed or some weird `macro_rules!` // expansion. // // What we *don't* want to catch is the fact that a user-defined // literal like `0xf` is stringified as `15`, causing the cached token // stream to not be literal `==` token-wise (ignoring spans) to the // token stream we got from stringification. // // Instead the "probably equal" check here is "does each token // recursively have the same discriminant?" We basically don't look at // the token values here and assume that such fine grained token stream // modifications, including adding/removing typically non-semantic // tokens such as extra braces and commas, don't happen. if let Some(tokens) = tokens { if tokenstream_probably_equal_for_proc_macro(&tokens, &tokens_for_real, sess) { return tokens; } info!( "cached tokens found, but they're not \"probably equal\", \ going with stringified version" ); info!("cached tokens: {:?}", tokens); info!("reparsed tokens: {:?}", tokens_for_real); } tokens_for_real } // See comments in `Nonterminal::to_tokenstream` for why we care about // *probably* equal here rather than actual equality // // This is otherwise the same as `eq_unspanned`, only recursing with a // different method. pub fn tokenstream_probably_equal_for_proc_macro( first: &TokenStream, other: &TokenStream, sess: &ParseSess, ) -> bool { // When checking for `probably_eq`, we ignore certain tokens that aren't // preserved in the AST. Because they are not preserved, the pretty // printer arbitrarily adds or removes them when printing as token // streams, making a comparison between a token stream generated from an // AST and a token stream which was parsed into an AST more reliable. fn semantic_tree(tree: &TokenTree) -> bool { if let TokenTree::Token(token) = tree { if let // The pretty printer tends to add trailing commas to // everything, and in particular, after struct fields. | token::Comma // The pretty printer emits `NoDelim` as whitespace. | token::OpenDelim(DelimToken::NoDelim) | token::CloseDelim(DelimToken::NoDelim) // The pretty printer collapses many semicolons into one. | token::Semi // The pretty printer can turn `$crate` into `::crate_name` | token::ModSep = token.kind { return false; } } true } // When comparing two `TokenStream`s, we ignore the `IsJoint` information. // // However, `rustc_parse::lexer::tokentrees::TokenStreamBuilder` will // use `Token.glue` on adjacent tokens with the proper `IsJoint`. // Since we are ignoreing `IsJoint`, a 'glued' token (e.g. `BinOp(Shr)`) // and its 'split'/'unglued' compoenents (e.g. `Gt, Gt`) are equivalent // when determining if two `TokenStream`s are 'probably equal'. // // Therefore, we use `break_two_token_op` to convert all tokens // to the 'unglued' form (if it exists). This ensures that two // `TokenStream`s which differ only in how their tokens are glued // will be considered 'probably equal', which allows us to keep spans. // // This is important when the original `TokenStream` contained // extra spaces (e.g. `f :: < Vec < _ > > ( ) ;'). These extra spaces // will be omitted when we pretty-print, which can cause the original // and reparsed `TokenStream`s to differ in the assignment of `IsJoint`, // leading to some tokens being 'glued' together in one stream but not // the other. See #68489 for more details. fn break_tokens(tree: TokenTree) -> impl Iterator { // In almost all cases, we should have either zero or one levels // of 'unglueing'. However, in some unusual cases, we may need // to iterate breaking tokens mutliple times. For example: // '[BinOpEq(Shr)] => [Gt, Ge] -> [Gt, Gt, Eq]' let mut token_trees: SmallVec<[_; 2]>; if let TokenTree::Token(token) = &tree { let mut out = SmallVec::<[_; 2]>::new(); out.push(token.clone()); // Iterate to fixpoint: // * We start off with 'out' containing our initial token, and `temp` empty // * If we are able to break any tokens in `out`, then `out` will have // at least one more element than 'temp', so we will try to break tokens // again. // * If we cannot break any tokens in 'out', we are done loop { let mut temp = SmallVec::<[_; 2]>::new(); let mut changed = false; for token in out.into_iter() { if let Some((first, second)) = token.kind.break_two_token_op() { temp.push(Token::new(first, DUMMY_SP)); temp.push(Token::new(second, DUMMY_SP)); changed = true; } else { temp.push(token); } } out = temp; if !changed { break; } } token_trees = out.into_iter().map(TokenTree::Token).collect(); } else { token_trees = SmallVec::new(); token_trees.push(tree); } token_trees.into_iter() } let expand_nt = |tree: TokenTree| { if let TokenTree::Token(Token { kind: TokenKind::Interpolated(nt), span }) = &tree { // When checking tokenstreams for 'probable equality', we are comparing // a captured (from parsing) `TokenStream` to a reparsed tokenstream. // The reparsed Tokenstream will never have `None`-delimited groups, // since they are only ever inserted as a result of macro expansion. // Therefore, inserting a `None`-delimtied group here (when we // convert a nested `Nonterminal` to a tokenstream) would cause // a mismatch with the reparsed tokenstream. // // Note that we currently do not handle the case where the // reparsed stream has a `Parenthesis`-delimited group // inserted. This will cause a spurious mismatch: // issue #75734 tracks resolving this. nt_to_tokenstream(nt, sess, *span).into_trees() } else { TokenStream::new(vec![(tree, Spacing::Alone)]).into_trees() } }; // Break tokens after we expand any nonterminals, so that we break tokens // that are produced as a result of nonterminal expansion. let mut t1 = first.trees().filter(semantic_tree).flat_map(expand_nt).flat_map(break_tokens); let mut t2 = other.trees().filter(semantic_tree).flat_map(expand_nt).flat_map(break_tokens); for (t1, t2) in t1.by_ref().zip(t2.by_ref()) { if !tokentree_probably_equal_for_proc_macro(&t1, &t2, sess) { return false; } } t1.next().is_none() && t2.next().is_none() } // See comments in `Nonterminal::to_tokenstream` for why we care about // *probably* equal here rather than actual equality // // This is otherwise the same as `eq_unspanned`, only recursing with a // different method. pub fn tokentree_probably_equal_for_proc_macro( first: &TokenTree, other: &TokenTree, sess: &ParseSess, ) -> bool { match (first, other) { (TokenTree::Token(token), TokenTree::Token(token2)) => { token_probably_equal_for_proc_macro(token, token2) } (TokenTree::Delimited(_, delim, tts), TokenTree::Delimited(_, delim2, tts2)) => { delim == delim2 && tokenstream_probably_equal_for_proc_macro(&tts, &tts2, sess) } _ => false, } } // See comments in `Nonterminal::to_tokenstream` for why we care about // *probably* equal here rather than actual equality fn token_probably_equal_for_proc_macro(first: &Token, other: &Token) -> bool { if mem::discriminant(&first.kind) != mem::discriminant(&other.kind) { return false; } use rustc_ast::token::TokenKind::*; match (&first.kind, &other.kind) { (&Eq, &Eq) | (&Lt, &Lt) | (&Le, &Le) | (&EqEq, &EqEq) | (&Ne, &Ne) | (&Ge, &Ge) | (&Gt, &Gt) | (&AndAnd, &AndAnd) | (&OrOr, &OrOr) | (&Not, &Not) | (&Tilde, &Tilde) | (&At, &At) | (&Dot, &Dot) | (&DotDot, &DotDot) | (&DotDotDot, &DotDotDot) | (&DotDotEq, &DotDotEq) | (&Comma, &Comma) | (&Semi, &Semi) | (&Colon, &Colon) | (&ModSep, &ModSep) | (&RArrow, &RArrow) | (&LArrow, &LArrow) | (&FatArrow, &FatArrow) | (&Pound, &Pound) | (&Dollar, &Dollar) | (&Question, &Question) | (&Eof, &Eof) => true, (&BinOp(a), &BinOp(b)) | (&BinOpEq(a), &BinOpEq(b)) => a == b, (&OpenDelim(a), &OpenDelim(b)) | (&CloseDelim(a), &CloseDelim(b)) => a == b, (&DocComment(a1, a2, a3), &DocComment(b1, b2, b3)) => a1 == b1 && a2 == b2 && a3 == b3, (&Literal(a), &Literal(b)) => a == b, (&Lifetime(a), &Lifetime(b)) => a == b, (&Ident(a, b), &Ident(c, d)) => { b == d && (a == c || a == kw::DollarCrate || c == kw::DollarCrate) } (&Interpolated(..), &Interpolated(..)) => panic!("Unexpanded Interpolated!"), _ => panic!("forgot to add a token?"), } } fn prepend_attrs( sess: &ParseSess, attrs: &[ast::Attribute], tokens: Option<&tokenstream::TokenStream>, span: rustc_span::Span, ) -> Option { let tokens = tokens?; if attrs.is_empty() { return Some(tokens.clone()); } let mut builder = tokenstream::TokenStreamBuilder::new(); for attr in attrs { assert_eq!( attr.style, ast::AttrStyle::Outer, "inner attributes should prevent cached tokens from existing" ); let source = pprust::attribute_to_string(attr); let macro_filename = FileName::macro_expansion_source_code(&source); let item = match attr.kind { ast::AttrKind::Normal(ref item) => item, ast::AttrKind::DocComment(..) => { let stream = parse_stream_from_source_str(macro_filename, source, sess, Some(span)); builder.push(stream); continue; } }; // synthesize # [ $path $tokens ] manually here let mut brackets = tokenstream::TokenStreamBuilder::new(); // For simple paths, push the identifier directly if item.path.segments.len() == 1 && item.path.segments[0].args.is_none() { let ident = item.path.segments[0].ident; let token = token::Ident(ident.name, ident.as_str().starts_with("r#")); brackets.push(tokenstream::TokenTree::token(token, ident.span)); // ... and for more complicated paths, fall back to a reparse hack that // should eventually be removed. } else { let stream = parse_stream_from_source_str(macro_filename, source, sess, Some(span)); brackets.push(stream); } brackets.push(item.args.outer_tokens()); // The span we list here for `#` and for `[ ... ]` are both wrong in // that it encompasses more than each token, but it hopefully is "good // enough" for now at least. builder.push(tokenstream::TokenTree::token(token::Pound, attr.span)); let delim_span = tokenstream::DelimSpan::from_single(attr.span); builder.push(tokenstream::TokenTree::Delimited( delim_span, token::DelimToken::Bracket, brackets.build(), )); } builder.push(tokens.clone()); Some(builder.build()) }