// Copyright 2012 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. // Earley-like parser for macros. use ast::{matcher, match_tok, match_seq, match_nonterminal, ident}; use codemap::{BytePos, mk_sp}; use codemap; use parse::common::*; //resolve bug? use parse::lexer::*; //resolve bug? use parse::ParseSess; use parse::parser::Parser; use parse::token::{Token, EOF, to_str, nonterminal}; use parse::token; use core::dvec::DVec; use core::dvec; use core::io; use core::option; use core::str; use core::uint; use core::vec; use std::oldmap::HashMap; /* 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 `named_match`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 the 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 ·] */ /* to avoid costly uniqueness checks, we require that `match_seq` always has a nonempty body. */ pub enum matcher_pos_up { /* to break a circularity */ matcher_pos_up(Option<~MatcherPos>) } pub fn is_some(&&mpu: matcher_pos_up) -> bool { match &mpu { &matcher_pos_up(None) => false, _ => true } } pub struct MatcherPos { elts: ~[ast::matcher], // maybe should be /&? Need to understand regions. sep: Option, idx: uint, up: matcher_pos_up, // mutable for swapping only matches: ~[DVec<@named_match>], match_lo: uint, match_hi: uint, sp_lo: BytePos, } pub fn copy_up(&& mpu: matcher_pos_up) -> ~MatcherPos { match &mpu { &matcher_pos_up(Some(ref mp)) => copy (*mp), _ => fail!() } } pub fn count_names(ms: &[matcher]) -> uint { vec::foldl(0u, ms, |ct, m| { ct + match m.node { match_tok(_) => 0u, match_seq(ref more_ms, _, _, _, _) => count_names((*more_ms)), match_nonterminal(_,_,_) => 1u }}) } #[allow(non_implicitly_copyable_typarams)] pub fn initial_matcher_pos(ms: ~[matcher], sep: Option, lo: BytePos) -> ~MatcherPos { let mut match_idx_hi = 0u; for ms.each() |elt| { match elt.node { match_tok(_) => (), match_seq(_,_,_,_,hi) => { match_idx_hi = hi; // it is monotonic... } match_nonterminal(_,_,pos) => { match_idx_hi = pos+1u; // ...so latest is highest } } } ~MatcherPos { elts: ms, sep: sep, idx: 0u, up: matcher_pos_up(None), matches: copy vec::from_fn(count_names(ms), |_i| dvec::DVec()), match_lo: 0u, match_hi: match_idx_hi, sp_lo: lo } } // named_match is a pattern-match result for a single ast::match_nonterminal: // so it is associated with a single ident in a parse, and all // matched_nonterminals in the named_match have the same nonterminal type // (expr, item, etc). All the leaves in a single named_match correspond to a // single matcher_nonterminal in the ast::matcher that produced it. // // It should probably be renamed, it has more or less exact correspondence to // ast::match nodes, and the in-memory structure of a particular named_match // represents the match that occurred when a particular subset of an // ast::match -- those ast::matcher nodes leading to a single // match_nonterminal -- was applied to a particular token tree. // // The width of each matched_seq in the named_match, and the identity of the // matched_nonterminals, will depend on the token tree it was applied to: each // matched_seq corresponds to a single match_seq in the originating // ast::matcher. The depth of the named_match structure will therefore depend // only on the nesting depth of ast::match_seqs in the originating // ast::matcher it was derived from. pub enum named_match { matched_seq(~[@named_match], codemap::span), matched_nonterminal(nonterminal) } pub type earley_item = ~MatcherPos; pub fn nameize(p_s: @mut ParseSess, ms: ~[matcher], res: ~[@named_match]) -> HashMap { fn n_rec(p_s: @mut ParseSess, m: matcher, res: ~[@named_match], ret_val: HashMap) { match m { codemap::spanned {node: match_tok(_), _} => (), codemap::spanned {node: match_seq(ref more_ms, _, _, _, _), _} => { for (*more_ms).each() |next_m| { n_rec(p_s, *next_m, res, ret_val) }; } codemap::spanned { node: match_nonterminal(bind_name, _, idx), span: sp } => { if ret_val.contains_key(&bind_name) { p_s.span_diagnostic.span_fatal(sp, ~"Duplicated bind name: "+ *p_s.interner.get(bind_name)) } ret_val.insert(bind_name, res[idx]); } } } let ret_val = HashMap(); for ms.each() |m| { n_rec(p_s, *m, res, ret_val) } return ret_val; } pub enum parse_result { success(HashMap), failure(codemap::span, ~str), error(codemap::span, ~str) } pub fn parse_or_else(sess: @mut ParseSess, cfg: ast::crate_cfg, rdr: reader, ms: ~[matcher]) -> HashMap { match parse(sess, cfg, rdr, ms) { success(m) => m, failure(sp, ref str) => sess.span_diagnostic.span_fatal(sp, (*str)), error(sp, ref str) => sess.span_diagnostic.span_fatal(sp, (*str)) } } pub fn parse(sess: @mut ParseSess, cfg: ast::crate_cfg, rdr: reader, ms: ~[matcher]) -> parse_result { let mut cur_eis = ~[]; cur_eis.push(initial_matcher_pos(ms, None, rdr.peek().sp.lo)); loop { let mut bb_eis = ~[]; // black-box parsed by parser.rs let mut next_eis = ~[]; // or proceed normally let mut eof_eis = ~[]; let TokenAndSpan {tok: tok, sp: sp} = rdr.peek(); /* we append new items to this while we go */ while cur_eis.len() > 0u { /* for each Earley Item */ let mut ei = cur_eis.pop(); let idx = ei.idx; let len = ei.elts.len(); /* at end of sequence */ if idx >= len { // can't move out of `match`es, so: if is_some(ei.up) { // 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 = copy_up(ei.up); // 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 uint::range(ei.match_lo, ei.match_hi) |idx| { let sub = ei.matches[idx].get(); new_pos.matches[idx] .push(@matched_seq(sub, mk_sp(ei.sp_lo, sp.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 copy ei.sep { Some(ref t) if idx == len => { // we need a separator if tok == (*t) { //pass the separator let mut ei_t = ei; ei_t.idx += 1; next_eis.push(ei_t); } } _ => { // we don't need a separator let mut ei_t = ei; ei_t.idx = 0; cur_eis.push(ei_t); } } } else { eof_eis.push(ei); } } else { match copy ei.elts[idx].node { /* need to descend into sequence */ match_seq(ref matchers, ref sep, zero_ok, match_idx_lo, match_idx_hi) => { if zero_ok { let mut new_ei = copy ei; new_ei.idx += 1u; //we specifically matched zero repeats. for uint::range(match_idx_lo, match_idx_hi) |idx| { new_ei.matches[idx].push(@matched_seq(~[], sp)); } cur_eis.push(new_ei); } let matches = vec::map(ei.matches, // fresh, same size: |_m| DVec::<@named_match>()); let ei_t = ei; cur_eis.push(~MatcherPos { elts: (*matchers), sep: (*sep), idx: 0u, up: matcher_pos_up(Some(ei_t)), matches: matches, match_lo: match_idx_lo, match_hi: match_idx_hi, sp_lo: sp.lo }); } match_nonterminal(_,_,_) => { bb_eis.push(ei) } match_tok(ref t) => { let mut ei_t = ei; if (*t) == tok { ei_t.idx += 1; next_eis.push(ei_t); } } } } } /* error messages here could be improved with links to orig. rules */ if tok == EOF { if eof_eis.len() == 1u { return success( nameize(sess, ms, eof_eis[0u].matches.map(|dv| dv.pop()))); } else if eof_eis.len() > 1u { return error(sp, ~"Ambiguity: multiple successful parses"); } else { return failure(sp, ~"Unexpected end of macro invocation"); } } else { if (bb_eis.len() > 0u && next_eis.len() > 0u) || bb_eis.len() > 1u { let nts = str::connect(vec::map(bb_eis, |ei| { match ei.elts[ei.idx].node { match_nonterminal(bind,name,_) => { fmt!("%s ('%s')", *sess.interner.get(name), *sess.interner.get(bind)) } _ => fail!() } }), ~" or "); return error(sp, fmt!( "Local ambiguity: multiple parsing options: \ built-in NTs %s or %u other options.", nts, next_eis.len())); } else if (bb_eis.len() == 0u && next_eis.len() == 0u) { return failure(sp, ~"No rules expected the token: " + to_str(rdr.interner(), &tok)); } else if (next_eis.len() > 0u) { /* Now process the next token */ while(next_eis.len() > 0u) { cur_eis.push(next_eis.pop()); } rdr.next_token(); } else /* bb_eis.len() == 1 */ { let rust_parser = Parser(sess, cfg, rdr.dup()); let mut ei = bb_eis.pop(); match ei.elts[ei.idx].node { match_nonterminal(_, name, idx) => { ei.matches[idx].push(@matched_nonterminal( parse_nt(rust_parser, *sess.interner.get(name)))); ei.idx += 1u; } _ => fail!() } cur_eis.push(ei); for rust_parser.tokens_consumed.times() || { rdr.next_token(); } } } assert cur_eis.len() > 0u; } } pub fn parse_nt(p: Parser, name: ~str) -> nonterminal { match name { ~"item" => match p.parse_item(~[]) { Some(i) => token::nt_item(i), None => p.fatal(~"expected an item keyword") }, ~"block" => token::nt_block(p.parse_block()), ~"stmt" => token::nt_stmt(p.parse_stmt(~[])), ~"pat" => token::nt_pat(p.parse_pat(true)), ~"expr" => token::nt_expr(p.parse_expr()), ~"ty" => token::nt_ty(p.parse_ty(false /* no need to disambiguate*/)), // this could be handled like a token, since it is one ~"ident" => match *p.token { token::IDENT(sn,b) => { p.bump(); token::nt_ident(sn,b) } _ => p.fatal(~"expected ident, found " + token::to_str(p.reader.interner(), © *p.token)) }, ~"path" => token::nt_path(p.parse_path_with_tps(false)), ~"tt" => { *p.quote_depth += 1u; //but in theory, non-quoted tts might be useful let res = token::nt_tt(@p.parse_token_tree()); *p.quote_depth -= 1u; res } ~"matchers" => token::nt_matchers(p.parse_matchers()), _ => p.fatal(~"Unsupported builtin nonterminal parser: " + name) } } // Local Variables: // mode: rust; // fill-column: 78; // indent-tabs-mode: nil // c-basic-offset: 4 // buffer-file-coding-system: utf-8-unix // End: