// Copyright 2017 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. use {ast, attr}; use ext::tt::macro_parser; use feature_gate::{self, emit_feature_err, Features, GateIssue}; use parse::{token, ParseSess}; use print::pprust; use symbol::keywords; use syntax_pos::{BytePos, Span, DUMMY_SP}; use tokenstream; use std::iter::Peekable; use rustc_data_structures::sync::Lrc; /// Contains the sub-token-trees of a "delimited" token tree, such as the contents of `(`. Note /// that the delimiter itself might be `NoDelim`. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct Delimited { pub delim: token::DelimToken, pub tts: Vec, } impl Delimited { /// Return the opening delimiter (possibly `NoDelim`). pub fn open_token(&self) -> token::Token { token::OpenDelim(self.delim) } /// Return the closing delimiter (possibly `NoDelim`). pub fn close_token(&self) -> token::Token { token::CloseDelim(self.delim) } /// Return a `self::TokenTree` with a `Span` corresponding to the opening delimiter. pub fn open_tt(&self, span: Span) -> TokenTree { let open_span = if span == DUMMY_SP { DUMMY_SP } else { span.with_lo(span.lo() + BytePos(self.delim.len() as u32)) }; TokenTree::Token(open_span, self.open_token()) } /// Return a `self::TokenTree` with a `Span` corresponding to the closing delimiter. pub fn close_tt(&self, span: Span) -> TokenTree { let close_span = if span == DUMMY_SP { DUMMY_SP } else { span.with_lo(span.hi() - BytePos(self.delim.len() as u32)) }; TokenTree::Token(close_span, self.close_token()) } } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug)] pub struct SequenceRepetition { /// The sequence of token trees pub tts: Vec, /// The optional separator pub separator: Option, /// Whether the sequence can be repeated zero (*), or one or more times (+) pub op: KleeneOp, /// The number of `Match`s that appear in the sequence (and subsequences) pub num_captures: usize, } /// A Kleene-style [repetition operator](http://en.wikipedia.org/wiki/Kleene_star) /// for token sequences. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash, Debug, Copy)] pub enum KleeneOp { /// Kleene star (`*`) for zero or more repetitions ZeroOrMore, /// Kleene plus (`+`) for one or more repetitions OneOrMore, ZeroOrOne, } /// Similar to `tokenstream::TokenTree`, except that `$i`, `$i:ident`, and `$(...)` /// are "first-class" token trees. Useful for parsing macros. #[derive(Debug, Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, Hash)] pub enum TokenTree { Token(Span, token::Token), Delimited(Span, Lrc), /// A kleene-style repetition sequence Sequence(Span, Lrc), /// E.g. `$var` MetaVar(Span, ast::Ident), /// E.g. `$var:expr`. This is only used in the left hand side of MBE macros. MetaVarDecl( Span, ast::Ident, /* name to bind */ ast::Ident, /* kind of nonterminal */ ), } impl TokenTree { /// Return the number of tokens in the tree. pub fn len(&self) -> usize { match *self { TokenTree::Delimited(_, ref delimed) => match delimed.delim { token::NoDelim => delimed.tts.len(), _ => delimed.tts.len() + 2, }, TokenTree::Sequence(_, ref seq) => seq.tts.len(), _ => 0, } } /// Returns true if the given token tree contains no other tokens. This is vacuously true for /// single tokens or metavar/decls, but may be false for delimited trees or sequences. pub fn is_empty(&self) -> bool { match *self { TokenTree::Delimited(_, ref delimed) => match delimed.delim { token::NoDelim => delimed.tts.is_empty(), _ => false, }, TokenTree::Sequence(_, ref seq) => seq.tts.is_empty(), _ => true, } } /// Get the `index`-th sub-token-tree. This only makes sense for delimited trees and sequences. pub fn get_tt(&self, index: usize) -> TokenTree { match (self, index) { (&TokenTree::Delimited(_, ref delimed), _) if delimed.delim == token::NoDelim => { delimed.tts[index].clone() } (&TokenTree::Delimited(span, ref delimed), _) => { if index == 0 { return delimed.open_tt(span); } if index == delimed.tts.len() + 1 { return delimed.close_tt(span); } delimed.tts[index - 1].clone() } (&TokenTree::Sequence(_, ref seq), _) => seq.tts[index].clone(), _ => panic!("Cannot expand a token tree"), } } /// Retrieve the `TokenTree`'s span. pub fn span(&self) -> Span { match *self { TokenTree::Token(sp, _) | TokenTree::MetaVar(sp, _) | TokenTree::MetaVarDecl(sp, _, _) | TokenTree::Delimited(sp, _) | TokenTree::Sequence(sp, _) => sp, } } } /// Takes a `tokenstream::TokenStream` and returns a `Vec`. Specifically, this /// takes a generic `TokenStream`, such as is used in the rest of the compiler, and returns a /// collection of `TokenTree` for use in parsing a macro. /// /// # Parameters /// /// - `input`: a token stream to read from, the contents of which we are parsing. /// - `expect_matchers`: `parse` can be used to parse either the "patterns" or the "body" of a /// macro. Both take roughly the same form _except_ that in a pattern, metavars are declared with /// their "matcher" type. For example `$var:expr` or `$id:ident`. In this example, `expr` and /// `ident` are "matchers". They are not present in the body of a macro rule -- just in the /// pattern, so we pass a parameter to indicate whether to expect them or not. /// - `sess`: the parsing session. Any errors will be emitted to this session. /// - `features`, `attrs`: language feature flags and attributes so that we know whether to use /// unstable features or not. /// /// # Returns /// /// A collection of `self::TokenTree`. There may also be some errors emitted to `sess`. pub fn parse( input: tokenstream::TokenStream, expect_matchers: bool, sess: &ParseSess, features: &Features, attrs: &[ast::Attribute], ) -> Vec { // Will contain the final collection of `self::TokenTree` let mut result = Vec::new(); // For each token tree in `input`, parse the token into a `self::TokenTree`, consuming // additional trees if need be. let mut trees = input.trees().peekable(); while let Some(tree) = trees.next() { // Given the parsed tree, if there is a metavar and we are expecting matchers, actually // parse out the matcher (i.e. in `$id:ident` this would parse the `:` and `ident`). let tree = parse_tree(tree, &mut trees, expect_matchers, sess, features, attrs); match tree { TokenTree::MetaVar(start_sp, ident) if expect_matchers => { let span = match trees.next() { Some(tokenstream::TokenTree::Token(span, token::Colon)) => match trees.next() { Some(tokenstream::TokenTree::Token(end_sp, ref tok)) => match tok.ident() { Some(kind) => { let span = end_sp.with_lo(start_sp.lo()); result.push(TokenTree::MetaVarDecl(span, ident, kind)); continue; } _ => end_sp, }, tree => tree.as_ref() .map(tokenstream::TokenTree::span) .unwrap_or(span), }, tree => tree.as_ref() .map(tokenstream::TokenTree::span) .unwrap_or(start_sp), }; sess.missing_fragment_specifiers.borrow_mut().insert(span); result.push(TokenTree::MetaVarDecl( span, ident, keywords::Invalid.ident(), )); } // Not a metavar or no matchers allowed, so just return the tree _ => result.push(tree), } } result } /// Takes a `tokenstream::TokenTree` and returns a `self::TokenTree`. Specifically, this takes a /// generic `TokenTree`, such as is used in the rest of the compiler, and returns a `TokenTree` /// for use in parsing a macro. /// /// Converting the given tree may involve reading more tokens. /// /// # Parameters /// /// - `tree`: the tree we wish to convert. /// - `trees`: an iterator over trees. We may need to read more tokens from it in order to finish /// converting `tree` /// - `expect_matchers`: same as for `parse` (see above). /// - `sess`: the parsing session. Any errors will be emitted to this session. /// - `features`, `attrs`: language feature flags and attributes so that we know whether to use /// unstable features or not. fn parse_tree( tree: tokenstream::TokenTree, trees: &mut Peekable, expect_matchers: bool, sess: &ParseSess, features: &Features, attrs: &[ast::Attribute], ) -> TokenTree where I: Iterator, { // Depending on what `tree` is, we could be parsing different parts of a macro match tree { // `tree` is a `$` token. Look at the next token in `trees` tokenstream::TokenTree::Token(span, token::Dollar) => match trees.next() { // `tree` is followed by a delimited set of token trees. This indicates the beginning // of a repetition sequence in the macro (e.g. `$(pat)*`). Some(tokenstream::TokenTree::Delimited(span, delimited)) => { // Must have `(` not `{` or `[` if delimited.delim != token::Paren { let tok = pprust::token_to_string(&token::OpenDelim(delimited.delim)); let msg = format!("expected `(`, found `{}`", tok); sess.span_diagnostic.span_err(span, &msg); } // Parse the contents of the sequence itself let sequence = parse(delimited.tts.into(), expect_matchers, sess, features, attrs); // Get the Kleene operator and optional separator let (separator, op) = parse_sep_and_kleene_op(trees, span, sess, features, attrs); // Count the number of captured "names" (i.e. named metavars) let name_captures = macro_parser::count_names(&sequence); TokenTree::Sequence( span, Lrc::new(SequenceRepetition { tts: sequence, separator, op, num_captures: name_captures, }), ) } // `tree` is followed by an `ident`. This could be `$meta_var` or the `$crate` special // metavariable that names the crate of the invokation. Some(tokenstream::TokenTree::Token(ident_span, ref token)) if token.is_ident() => { let ident = token.ident().unwrap(); let span = ident_span.with_lo(span.lo()); if ident.name == keywords::Crate.name() { let ident = ast::Ident { name: keywords::DollarCrate.name(), ..ident }; TokenTree::Token(span, token::Ident(ident)) } else { TokenTree::MetaVar(span, ident) } } // `tree` is followed by a random token. This is an error. Some(tokenstream::TokenTree::Token(span, tok)) => { let msg = format!( "expected identifier, found `{}`", pprust::token_to_string(&tok) ); sess.span_diagnostic.span_err(span, &msg); TokenTree::MetaVar(span, keywords::Invalid.ident()) } // There are no more tokens. Just return the `$` we already have. None => TokenTree::Token(span, token::Dollar), }, // `tree` is an arbitrary token. Keep it. tokenstream::TokenTree::Token(span, tok) => TokenTree::Token(span, tok), // `tree` is the beginning of a delimited set of tokens (e.g. `(` or `{`). We need to // descend into the delimited set and further parse it. tokenstream::TokenTree::Delimited(span, delimited) => TokenTree::Delimited( span, Lrc::new(Delimited { delim: delimited.delim, tts: parse(delimited.tts.into(), expect_matchers, sess, features, attrs), }), ), } } /// Takes a token and returns `Some(KleeneOp)` if the token is `+` `*` or `?`. Otherwise, return /// `None`. fn kleene_op(token: &token::Token) -> Option { match *token { token::BinOp(token::Star) => Some(KleeneOp::ZeroOrMore), token::BinOp(token::Plus) => Some(KleeneOp::OneOrMore), token::Question => Some(KleeneOp::ZeroOrOne), _ => None, } } /// Parse the next token tree of the input looking for a KleeneOp. Returns /// /// - Ok(Ok(op)) if the next token tree is a KleeneOp /// - Ok(Err(tok, span)) if the next token tree is a token but not a KleeneOp /// - Err(span) if the next token tree is not a token fn parse_kleene_op( input: &mut I, span: Span, ) -> Result, Span> where I: Iterator, { match input.next() { Some(tokenstream::TokenTree::Token(span, tok)) => match kleene_op(&tok) { Some(op) => Ok(Ok(op)), None => Ok(Err((tok, span))), }, tree => Err(tree.as_ref() .map(tokenstream::TokenTree::span) .unwrap_or(span)), } } /// Attempt to parse a single Kleene star, possibly with a separator. /// /// For example, in a pattern such as `$(a),*`, `a` is the pattern to be repeated, `,` is the /// separator, and `*` is the Kleene operator. This function is specifically concerned with parsing /// the last two tokens of such a pattern: namely, the optional separator and the Kleene operator /// itself. Note that here we are parsing the _macro_ itself, rather than trying to match some /// stream of tokens in an invocation of a macro. /// /// This function will take some input iterator `input` corresponding to `span` and a parsing /// session `sess`. If the next one (or possibly two) tokens in `input` correspond to a Kleene /// operator and separator, then a tuple with `(separator, KleeneOp)` is returned. Otherwise, an /// error with the appropriate span is emitted to `sess` and a dummy value is returned. fn parse_sep_and_kleene_op( input: &mut Peekable, span: Span, sess: &ParseSess, features: &Features, attrs: &[ast::Attribute], ) -> (Option, KleeneOp) where I: Iterator, { // We basically look at two token trees here, denoted as #1 and #2 below let span = match parse_kleene_op(input, span) { // #1 is a `+` or `*` KleeneOp // // `?` is ambiguous: it could be a separator or a Kleene::ZeroOrOne, so we need to look // ahead one more token to be sure. Ok(Ok(op)) if op != KleeneOp::ZeroOrOne => return (None, op), // #1 is `?` token, but it could be a Kleene::ZeroOrOne without a separator or it could // be a `?` separator followed by any Kleene operator. We need to look ahead 1 token to // find out which. Ok(Ok(op)) => { assert_eq!(op, KleeneOp::ZeroOrOne); // Lookahead at #2. If it is a KleenOp, then #1 is a separator. let is_1_sep = if let Some(&tokenstream::TokenTree::Token(_, ref tok2)) = input.peek() { kleene_op(tok2).is_some() } else { false }; if is_1_sep { // #1 is a separator and #2 should be a KleepeOp::* // (N.B. We need to advance the input iterator.) match parse_kleene_op(input, span) { // #2 is a KleeneOp (this is the only valid option) :) Ok(Ok(op)) if op == KleeneOp::ZeroOrOne => { if !features.macro_at_most_once_rep && !attr::contains_name(attrs, "allow_internal_unstable") { let explain = feature_gate::EXPLAIN_MACRO_AT_MOST_ONCE_REP; emit_feature_err( sess, "macro_at_most_once_rep", span, GateIssue::Language, explain, ); } return (Some(token::Question), op); } Ok(Ok(op)) => return (Some(token::Question), op), // #2 is a random token (this is an error) :( Ok(Err((_, span))) => span, // #2 is not even a token at all :( Err(span) => span, } } else { if !features.macro_at_most_once_rep && !attr::contains_name(attrs, "allow_internal_unstable") { let explain = feature_gate::EXPLAIN_MACRO_AT_MOST_ONCE_REP; emit_feature_err( sess, "macro_at_most_once_rep", span, GateIssue::Language, explain, ); } // #2 is a random tree and #1 is KleeneOp::ZeroOrOne return (None, op); } } // #1 is a separator followed by #2, a KleeneOp Ok(Err((tok, span))) => match parse_kleene_op(input, span) { // #2 is a KleeneOp :D Ok(Ok(op)) if op == KleeneOp::ZeroOrOne => { if !features.macro_at_most_once_rep && !attr::contains_name(attrs, "allow_internal_unstable") { let explain = feature_gate::EXPLAIN_MACRO_AT_MOST_ONCE_REP; emit_feature_err( sess, "macro_at_most_once_rep", span, GateIssue::Language, explain, ); } return (Some(tok), op); } Ok(Ok(op)) => return (Some(tok), op), // #2 is a random token :( Ok(Err((_, span))) => span, // #2 is not a token at all :( Err(span) => span, }, // #1 is not a token Err(span) => span, }; if !features.macro_at_most_once_rep && !attr::contains_name(attrs, "allow_internal_unstable") { sess.span_diagnostic .span_err(span, "expected one of: `*`, `+`, or `?`"); } else { sess.span_diagnostic.span_err(span, "expected `*` or `+`"); } (None, KleeneOp::ZeroOrMore) }