// Copyright 2012-2014 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. //! This is an Earley-like parser, without support for in-grammar nonterminals, //! only by calling out to the main rust parser for named nonterminals (which it //! commits to fully when it hits one in a grammar). This means that there are no //! completer or predictor rules, and therefore no need to store one column per //! token: instead, there's a set of current Earley items and a set of next //! ones. Instead of NTs, we have a special case for Kleene star. The big-O, in //! pathological cases, is worse than traditional Earley parsing, but it's an //! easier fit for Macro-by-Example-style rules, and I think the overhead is //! lower. (In order to prevent the pathological case, we'd need to lazily //! construct the resulting `NamedMatch`es at the very end. It'd be a pain, //! and require more memory to keep around old items, but it would also save //! overhead) //! //! Quick intro to how the parser works: //! //! A 'position' is a dot in the middle of a matcher, usually represented as a //! dot. For example `· a $( a )* a b` is a position, as is `a $( · a )* a b`. //! //! The parser walks through the input a character at a time, maintaining a list //! of items consistent with the current position in the input string: `cur_eis`. //! //! As it processes them, it fills up `eof_eis` with items that would be valid if //! the macro invocation is now over, `bb_eis` with items that are waiting on //! a Rust nonterminal like `$e:expr`, and `next_eis` with items that are waiting //! on a particular token. Most of the logic concerns moving the · through the //! repetitions indicated by Kleene stars. It only advances or calls out to the //! real Rust parser when no `cur_eis` items remain //! //! Example: Start parsing `a a a a b` against [· a $( a )* a b]. //! //! Remaining input: `a a a a b` //! next_eis: [· a $( a )* a b] //! //! - - - Advance over an `a`. - - - //! //! Remaining input: `a a a b` //! cur: [a · $( a )* a b] //! Descend/Skip (first item). //! next: [a $( · a )* a b] [a $( a )* · a b]. //! //! - - - Advance over an `a`. - - - //! //! Remaining input: `a a b` //! cur: [a $( a · )* a b] next: [a $( a )* a · b] //! Finish/Repeat (first item) //! next: [a $( a )* · a b] [a $( · a )* a b] [a $( a )* a · b] //! //! - - - Advance over an `a`. - - - (this looks exactly like the last step) //! //! Remaining input: `a b` //! cur: [a $( a · )* a b] next: [a $( a )* a · b] //! Finish/Repeat (first item) //! next: [a $( a )* · a b] [a $( · a )* a b] [a $( a )* a · b] //! //! - - - Advance over an `a`. - - - (this looks exactly like the last step) //! //! Remaining input: `b` //! cur: [a $( a · )* a b] next: [a $( a )* a · b] //! Finish/Repeat (first item) //! next: [a $( a )* · a b] [a $( · a )* a b] //! //! - - - Advance over a `b`. - - - //! //! Remaining input: `` //! eof: [a $( a )* a b ·] pub use self::NamedMatch::*; pub use self::ParseResult::*; use self::TokenTreeOrTokenTreeVec::*; use ast; use ast::{TokenTree, Name, Ident}; use codemap::{BytePos, mk_sp, Span, Spanned}; use codemap; use errors::FatalError; use parse::lexer::*; //resolve bug? use parse::ParseSess; use parse::parser::{PathStyle, Parser}; use parse::token::{DocComment, MatchNt, SubstNt}; use parse::token::{Token, Nonterminal}; use parse::token; use print::pprust; use ptr::P; use std::mem; use std::rc::Rc; use std::collections::HashMap; use std::collections::hash_map::Entry::{Vacant, Occupied}; // To avoid costly uniqueness checks, we require that `MatchSeq` always has // a nonempty body. #[derive(Clone)] enum TokenTreeOrTokenTreeVec { Tt(ast::TokenTree), TtSeq(Rc>), } impl TokenTreeOrTokenTreeVec { fn len(&self) -> usize { match *self { TtSeq(ref v) => v.len(), Tt(ref tt) => tt.len(), } } fn get_tt(&self, index: usize) -> TokenTree { match *self { TtSeq(ref v) => v[index].clone(), Tt(ref tt) => tt.get_tt(index), } } } /// an unzipping of `TokenTree`s #[derive(Clone)] struct MatcherTtFrame { elts: TokenTreeOrTokenTreeVec, idx: usize, } #[derive(Clone)] pub struct MatcherPos { stack: Vec, top_elts: TokenTreeOrTokenTreeVec, sep: Option, idx: usize, up: Option>, matches: Vec>>, match_lo: usize, match_cur: usize, match_hi: usize, sp_lo: BytePos, } pub fn count_names(ms: &[TokenTree]) -> usize { ms.iter().fold(0, |count, elt| { count + match *elt { TokenTree::Sequence(_, ref seq) => { seq.num_captures } TokenTree::Delimited(_, ref delim) => { count_names(&delim.tts) } TokenTree::Token(_, MatchNt(..)) => { 1 } TokenTree::Token(_, _) => 0, } }) } pub fn initial_matcher_pos(ms: Rc>, sep: Option, lo: BytePos) -> Box { let match_idx_hi = count_names(&ms[..]); let matches: Vec<_> = (0..match_idx_hi).map(|_| Vec::new()).collect(); Box::new(MatcherPos { stack: vec![], top_elts: TtSeq(ms), sep: sep, idx: 0, up: None, matches: matches, match_lo: 0, match_cur: 0, match_hi: match_idx_hi, sp_lo: lo }) } /// NamedMatch is a pattern-match result for a single token::MATCH_NONTERMINAL: /// so it is associated with a single ident in a parse, and all /// `MatchedNonterminal`s in the NamedMatch have the same nonterminal type /// (expr, item, etc). Each leaf in a single NamedMatch corresponds to a /// single token::MATCH_NONTERMINAL in the TokenTree that produced it. /// /// The in-memory structure of a particular NamedMatch represents the match /// that occurred when a particular subset of a matcher was applied to a /// particular token tree. /// /// The width of each MatchedSeq in the NamedMatch, and the identity of the /// `MatchedNonterminal`s, will depend on the token tree it was applied to: /// each MatchedSeq corresponds to a single TTSeq in the originating /// token tree. The depth of the NamedMatch structure will therefore depend /// only on the nesting depth of `ast::TTSeq`s in the originating /// token tree it was derived from. pub enum NamedMatch { MatchedSeq(Vec>, codemap::Span), MatchedNonterminal(Nonterminal) } pub fn nameize(p_s: &ParseSess, ms: &[TokenTree], res: &[Rc]) -> ParseResult>> { fn n_rec(p_s: &ParseSess, m: &TokenTree, res: &[Rc], ret_val: &mut HashMap>, idx: &mut usize) -> Result<(), (codemap::Span, String)> { match *m { TokenTree::Sequence(_, ref seq) => { for next_m in &seq.tts { n_rec(p_s, next_m, res, ret_val, idx)? } } TokenTree::Delimited(_, ref delim) => { for next_m in &delim.tts { n_rec(p_s, next_m, res, ret_val, idx)?; } } TokenTree::Token(sp, MatchNt(bind_name, _)) => { match ret_val.entry(bind_name.name) { Vacant(spot) => { spot.insert(res[*idx].clone()); *idx += 1; } Occupied(..) => { return Err((sp, format!("duplicated bind name: {}", bind_name))) } } } TokenTree::Token(sp, SubstNt(..)) => { return Err((sp, "missing fragment specifier".to_string())) } TokenTree::Token(_, _) => (), } Ok(()) } let mut ret_val = HashMap::new(); let mut idx = 0; for m in ms { match n_rec(p_s, m, res, &mut ret_val, &mut idx) { Ok(_) => {}, Err((sp, msg)) => return Error(sp, msg), } } Success(ret_val) } pub enum ParseResult { Success(T), /// Arm failed to match Failure(codemap::Span, String), /// Fatal error (malformed macro?). Abort compilation. Error(codemap::Span, String) } pub type NamedParseResult = ParseResult>>; pub type PositionalParseResult = ParseResult>>; /// Perform a token equality check, ignoring syntax context (that is, an /// unhygienic comparison) pub fn token_name_eq(t1 : &Token, t2 : &Token) -> bool { match (t1,t2) { (&token::Ident(id1),&token::Ident(id2)) | (&token::Lifetime(id1),&token::Lifetime(id2)) => id1.name == id2.name, _ => *t1 == *t2 } } pub fn parse(sess: &ParseSess, cfg: ast::CrateConfig, mut rdr: TtReader, ms: &[TokenTree]) -> NamedParseResult { let mut cur_eis = Vec::new(); cur_eis.push(initial_matcher_pos(Rc::new(ms.iter() .cloned() .collect()), None, rdr.peek().sp.lo)); loop { let mut bb_eis = Vec::new(); // black-box parsed by parser.rs let mut next_eis = Vec::new(); // or proceed normally let mut eof_eis = Vec::new(); let TokenAndSpan { tok, sp } = rdr.peek(); /* we append new items to this while we go */ loop { let mut ei = match cur_eis.pop() { None => break, /* for each Earley Item */ Some(ei) => ei, }; // When unzipped trees end, remove them while ei.idx >= ei.top_elts.len() { match ei.stack.pop() { Some(MatcherTtFrame { elts, idx }) => { ei.top_elts = elts; ei.idx = idx + 1; } None => break } } let idx = ei.idx; let len = ei.top_elts.len(); /* at end of sequence */ if idx >= len { // can't move out of `match`es, so: if ei.up.is_some() { // hack: a matcher sequence is repeating iff it has a // parent (the top level is just a container) // disregard separator, try to go up // (remove this condition to make trailing seps ok) if idx == len { // pop from the matcher position let mut new_pos = ei.up.clone().unwrap(); // update matches (the MBE "parse tree") by appending // each tree as a subtree. // I bet this is a perf problem: we're preemptively // doing a lot of array work that will get thrown away // most of the time. // Only touch the binders we have actually bound for idx in ei.match_lo..ei.match_hi { let sub = (ei.matches[idx]).clone(); (&mut new_pos.matches[idx]) .push(Rc::new(MatchedSeq(sub, mk_sp(ei.sp_lo, sp.hi)))); } new_pos.match_cur = ei.match_hi; new_pos.idx += 1; cur_eis.push(new_pos); } // can we go around again? // the *_t vars are workarounds for the lack of unary move match ei.sep { Some(ref t) if idx == len => { // we need a separator // i'm conflicted about whether this should be hygienic.... // though in this case, if the separators are never legal // idents, it shouldn't matter. if token_name_eq(&tok, t) { //pass the separator let mut ei_t = ei.clone(); // ei_t.match_cur = ei_t.match_lo; ei_t.idx += 1; next_eis.push(ei_t); } } _ => { // we don't need a separator let mut ei_t = ei; ei_t.match_cur = ei_t.match_lo; ei_t.idx = 0; cur_eis.push(ei_t); } } } else { eof_eis.push(ei); } } else { match ei.top_elts.get_tt(idx) { /* need to descend into sequence */ TokenTree::Sequence(sp, seq) => { if seq.op == ast::KleeneOp::ZeroOrMore { let mut new_ei = ei.clone(); new_ei.match_cur += seq.num_captures; new_ei.idx += 1; //we specifically matched zero repeats. for idx in ei.match_cur..ei.match_cur + seq.num_captures { (&mut new_ei.matches[idx]).push(Rc::new(MatchedSeq(vec![], sp))); } cur_eis.push(new_ei); } let matches: Vec<_> = (0..ei.matches.len()) .map(|_| Vec::new()).collect(); let ei_t = ei; cur_eis.push(Box::new(MatcherPos { stack: vec![], sep: seq.separator.clone(), idx: 0, matches: matches, match_lo: ei_t.match_cur, match_cur: ei_t.match_cur, match_hi: ei_t.match_cur + seq.num_captures, up: Some(ei_t), sp_lo: sp.lo, top_elts: Tt(TokenTree::Sequence(sp, seq)), })); } TokenTree::Token(_, MatchNt(..)) => { // Built-in nonterminals never start with these tokens, // so we can eliminate them from consideration. match tok { token::CloseDelim(_) => {}, _ => bb_eis.push(ei), } } TokenTree::Token(sp, SubstNt(..)) => { return Error(sp, "missing fragment specifier".to_string()) } seq @ TokenTree::Delimited(..) | seq @ TokenTree::Token(_, DocComment(..)) => { let lower_elts = mem::replace(&mut ei.top_elts, Tt(seq)); let idx = ei.idx; ei.stack.push(MatcherTtFrame { elts: lower_elts, idx: idx, }); ei.idx = 0; cur_eis.push(ei); } TokenTree::Token(_, ref t) => { let mut ei_t = ei.clone(); if token_name_eq(t,&tok) { ei_t.idx += 1; next_eis.push(ei_t); } } } } } /* error messages here could be improved with links to orig. rules */ if token_name_eq(&tok, &token::Eof) { if eof_eis.len() == 1 { let mut v = Vec::new(); for dv in &mut (&mut eof_eis[0]).matches { v.push(dv.pop().unwrap()); } return nameize(sess, ms, &v[..]); } else if eof_eis.len() > 1 { return Error(sp, "ambiguity: multiple successful parses".to_string()); } else { return Failure(sp, "unexpected end of macro invocation".to_string()); } } else { if (!bb_eis.is_empty() && !next_eis.is_empty()) || bb_eis.len() > 1 { let nts = bb_eis.iter().map(|ei| match ei.top_elts.get_tt(ei.idx) { TokenTree::Token(_, MatchNt(bind, name)) => { format!("{} ('{}')", name, bind) } _ => panic!() }).collect::>().join(" or "); return Error(sp, format!( "local ambiguity: multiple parsing options: {}", match next_eis.len() { 0 => format!("built-in NTs {}.", nts), 1 => format!("built-in NTs {} or 1 other option.", nts), n => format!("built-in NTs {} or {} other options.", nts, n), } )) } else if bb_eis.is_empty() && next_eis.is_empty() { return Failure(sp, format!("no rules expected the token `{}`", pprust::token_to_string(&tok))); } else if !next_eis.is_empty() { /* Now process the next token */ while !next_eis.is_empty() { cur_eis.push(next_eis.pop().unwrap()); } rdr.next_token(); } else /* bb_eis.len() == 1 */ { let mut rust_parser = Parser::new(sess, cfg.clone(), Box::new(rdr.clone())); let mut ei = bb_eis.pop().unwrap(); match ei.top_elts.get_tt(ei.idx) { TokenTree::Token(span, MatchNt(_, ident)) => { let match_cur = ei.match_cur; (&mut ei.matches[match_cur]).push(Rc::new(MatchedNonterminal( parse_nt(&mut rust_parser, span, &ident.name.as_str())))); ei.idx += 1; ei.match_cur += 1; } _ => panic!() } cur_eis.push(ei); for _ in 0..rust_parser.tokens_consumed { let _ = rdr.next_token(); } } } assert!(!cur_eis.is_empty()); } } pub fn parse_nt<'a>(p: &mut Parser<'a>, sp: Span, name: &str) -> Nonterminal { match name { "tt" => { p.quote_depth += 1; //but in theory, non-quoted tts might be useful let res: ::parse::PResult<'a, _> = p.parse_token_tree(); let res = token::NtTT(P(panictry!(res))); p.quote_depth -= 1; return res; } _ => {} } // check at the beginning and the parser checks after each bump p.check_unknown_macro_variable(); match name { "item" => match panictry!(p.parse_item()) { Some(i) => token::NtItem(i), None => { p.fatal("expected an item keyword").emit(); panic!(FatalError); } }, "block" => token::NtBlock(panictry!(p.parse_block())), "stmt" => match panictry!(p.parse_stmt()) { Some(s) => token::NtStmt(P(s)), None => { p.fatal("expected a statement").emit(); panic!(FatalError); } }, "pat" => token::NtPat(panictry!(p.parse_pat())), "expr" => token::NtExpr(panictry!(p.parse_expr())), "ty" => token::NtTy(panictry!(p.parse_ty())), // this could be handled like a token, since it is one "ident" => match p.token { token::Ident(sn) => { p.bump(); token::NtIdent(Box::new(Spanned::{node: sn, span: p.span})) } _ => { let token_str = pprust::token_to_string(&p.token); p.fatal(&format!("expected ident, found {}", &token_str[..])).emit(); panic!(FatalError) } }, "path" => { token::NtPath(Box::new(panictry!(p.parse_path(PathStyle::Type)))) }, "meta" => token::NtMeta(panictry!(p.parse_meta_item())), // this is not supposed to happen, since it has been checked // when compiling the macro. _ => p.span_bug(sp, "invalid fragment specifier") } }