utils/peg/pegparser.dart - sdk - Git at Google

 // Copyright (c) 2011, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 library PegParser;

 /*
  * The following functions are combinators for building Rules.
  *
  * A rule is one of the following
  * - A String which matches the string literally.
  * - A Symbol which matches the symbol's definition.
  * - A list of rules with an optional reducing function, which matches a sequence.
  * - The result of calling one of the combinators.
  *
  * Some rules are 'value-generating' rules, they return an 'abstract syntax
  * tree' with the match.  If a rule is not value-generating [:null:] is the
  * value.
  *
  * A Symbol is always a value-generating rule. If the value is not required, use
  * [:SKIP(aSymbol):] in place of [:aSymbol:].
  *
  * A String is not a value-generating rule but can be converted into one by
  * using [:TEXT('string'):] in place of [:'string':].
  *
  * A list or sequence is value-generating depending on the subrules.  The
  * sequence is value-generating if any of the subrules are value-generating or
  * if there is a reducing function.  If no reducing function is given, the value
  * returned depends on the number of value-generating subrules.  If there is
  * only one value generating subrule, that provideds the value for the sequence.
  * If there are more, then the value is a list of the values of the
  * value-generating subrules.
  */

 /**
  * Matches one character by a predicate on the character code.
  * If [spec] is an int, that character is matched.
  * If [spec] is a function it is used
  *
  * Example [: CHARCODE((code) => 48 <= code && code <= 57) :] recognizes an
  * ASCII digit.
  *
  * CHARCODE does not generate a value.
  */
 _Rule CHARCODE(spec, [name]) {
   if (spec is int)
     return new _CharCodeRule((code) => code == spec, name);
   else
     return new _CharCodeRule(spec, name);
 }

 /**
  * Matches one of the [characters].
  *
  * CHAR does not generate a value.
  */
 _Rule CHAR([characters]) {
   if (characters == null) return const _AnyCharRule();
   if (characters is int) return CHARCODE(characters);

   // Find the range of character codes and construct an array of flags for codes
   // within the range.
   List<int> codes = characters.codeUnits.toList();
   codes.sort((a, b) => a < b ? -1 : a > b ? 1 : 0);
   int lo = codes[0];
   int hi = codes[codes.length - 1];
   if (lo == hi) return CHARCODE(lo);
   int len = hi - lo + 1;
   var flags = new List<bool>(len);
   for (int i = 0; i < len; ++i) flags[i] = false;
   for (int code in codes) flags[code - lo] = true;

   return CHARCODE((code) => code >= lo && code <= hi && flags[code - lo]);
 }

 /**
  * Matches the end of the input.
  *
  * END does not generate a value.
  */
 _Rule get END => new _EndOfInputRule();

 /**
  * Throws an exception.
  */
 _Rule ERROR(String message) => new _ErrorRule(message);

 /**
  * Matches [rule] but does not consume the input.  Useful for matching a right
  * context.
  *
  * AT does not generate a value.
  */
 _Rule AT(rule) => new _ContextRule(_compile(rule));

 /**
  * Matches when [rule] does not match.  No input is consumed.
  *
  * NOT does not generate a value.
  */
 _Rule NOT(rule) => new _NegativeContextRule(_compile(rule));

 /**
  * Matches [rule] but generates no value even if [rule] generates a value.
  *
  * SKIP never generates a value.
  */
 _Rule SKIP(rule) => new _SkipRule(_compile(rule));

 /**
  * Matches [rule] in a lexical context where whitespace is not automatically
  * skipped.  Useful for matching what would normally be considered to be tokens.
  * [name] is a user-friendly description of what is being matched and is used in
  * error messages.
  *
  * LEX(rule)
  * LEX(name, rule)
  *
  * LEX does not generate a value.  If a value is required, wrap LEX with TEXT.
  */
 _Rule LEX(arg1, [arg2]) {
   if (arg2 == null)
     return new _LexicalRule(arg1 is String ? arg1 : null, _compile(arg1));
   else
     return new _LexicalRule(arg1, _compile(arg2));
 }

 /**
  * Matches [rule] and generates a value from the matched text. If the [rule]
  * matches, then TEXT(rule) matches and has a value derived from the string
  * fragment that was matched.  The default derived value is the string fragment.
  *
  * TEXT always generates a value.
  */
 _Rule TEXT(rule, [extractor]) => new _TextValueRule(
     _compile(rule),
     extractor == null
         ? (string, start, end) => string.substring(start, end)
         : extractor);

 /**
  * Matches an optional rule.
  *
  * MAYBE is a value generating matcher.
  *
  * If [rule] is value generating then the value is the value generated by [rule]
  * if it matches, and [:null:] if it does not.
  *
  * If [rule] is not value generating then the value is [:true:] if [rule]
  * matches and [:false:] if it does not.
  */
 _Rule MAYBE(rule) => new _OptionalRule(_compile(rule));

 /**
  * MANY(rule) matches [rule] [min] or more times.
  * [min] must be 0 or 1.
  * If [separator] is provided it is used to match a separator between matches of
  * [rule].
  *
  * MANY is a value generating matcher.  The value is a list of the matches of
  * [rule].  The list may be empty if [:min == 0:].
  */
 _Rule MANY(rule, {separator: null, int min: 1}) {
   assert(0 <= min && min <= 1);
   return new _RepeatRule(_compile(rule), _compileOptional(separator), min);
 }

 /**
  * Matches [rule] zero or more times.  Shorthand for [:MANY(rule, min:0):]
  * TODO: retire min: parameter?
  *
  * MANY0 is a value generating matcher.
  */
 _Rule MANY0(rule, [separator = null]) {
   return new _RepeatRule(_compile(rule), _compileOptional(separator), 0);
 }

 /**
  * Matches [rules] in order until one succeeds.
  *
  * OR is value-generating.
  */
 _Rule OR(
         [a,
         b,
         c,
         d,
         e,
         f,
         g,
         h,
         i,
         j,
         k,
         l,
         m,
         n,
         o,
         p,
         q,
         r,
         s,
         t,
         u,
         v,
         w,
         x,
         y,
         z]) =>
     _compileMultiRule(
         (a is List && b == null) // Backward compat. OR([a, b]) => OR(a, b).
             ? a
             : _unspread(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s,
                 t, u, v, w, x, y, z),
         false,
         (compiledRules, valueCount, reducer) => new _ChoiceRule(compiledRules));

 _Rule SEQ(
         [a,
         b,
         c,
         d,
         e,
         f,
         g,
         h,
         i,
         j,
         k,
         l,
         m,
         n,
         o,
         p,
         q,
         r,
         s,
         t,
         u,
         v,
         w,
         x,
         y,
         z]) =>
     _compile(_unspread(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s,
         t, u, v, w, x, y, z));

 /**
  * Matches [rule]
  */
 _Rule MEMO(rule) => new _MemoRule(_compile(rule));

 _Rule TAG(tag, rule) => _compile([
       rule,
       (ast) => [tag, ast]
     ]);

 class ParseError implements Exception {
   const ParseError(String this._message);
   String toString() => _message;
   final String _message;
 }

 /**
  * A grammar is a collection of symbols and rules that may be used to parse an
  * input.
  */
 class Grammar {
   Map<String, Symbol> _symbols;

   /** This rule may be set by the user to define whitespace. */
   _Rule _whitespace;

   _Rule get whitespace => _whitespace;
   void set whitespace(rule) {
     _whitespace = _compile(rule);
   }

   Grammar() {
     _symbols = new Map<String, Symbol>();
     whitespace = CHAR(' \t\r\n');
   }

   /**
    * operator [] is used to find or create symbols. Symbols may appear in rules
    * to define recursive rules.
    */
   Symbol operator [](String name) {
     if (_symbols.containsKey(name)) return _symbols[name];
     Symbol s = new Symbol(name, this);
     _symbols[name] = s;
     return s;
   }

   /**
    * Parses the input string and returns the parsed AST, or throws an exception
    * if the input can't be parsed.
    */
   parse(root, String text) {
     for (var symbol in _symbols.values)
       if (symbol._rule == null) print('${symbol.name} is undefined');

     var state = new _ParserState(text, whitespace: whitespace);
     var match = _compile(root).match(state, 0);
     if (match == null) return diagnose(state);
     var pos = match[0];
     pos = _skip_whitespace(state, pos);
     if (pos == state._end) return match[1];
     // TODO: Make this complain about expecting end of file.
     return diagnose(state);
   }

   diagnose(state) {
     var message = 'unexpected error';
     if (!state.max_rule.isEmpty) {
       var s = new Set();
       for (var rule in state.max_rule) s.add(rule.description());
       var tokens = new List<String>.from(s);
       tokens.sort((a, b) => a.startsWith("'") == b.startsWith("'")
           ? a.compareTo(b)
           : a.startsWith("'") ? 1 : -1);
       var expected = tokens.join(' or ');
       var found = state.max_pos == state._end
           ? 'end of file'
           : "'${state._text[state.max_pos]}'";
       message = 'Expected $expected but found $found';
     }
     int start = state.max_pos;
     int end = start;
     while (start >= 1 && state._text[start - 1] != '\n') --start;
     while (end < state._text.length && state._text[end] != '\n') ++end;
     var line = state._text.substring(start, end);
     var indicator = '';
     for (var i = 0; i < line.length && start + i < state.max_pos; i++)
       indicator = ' $indicator';
     indicator = '$indicator^';
     // TODO: Convert to an exception.
     print(message);
     print(line);
     print(indicator);
     return null;
   }
 }

 class Symbol {
   final String name;
   final Grammar grammar;
   _Rule _rule;

   Symbol(this.name, this.grammar);

   void set def(rule) {
     assert(_rule == null); // Assign once.
     _rule = _compile(rule);
   }

   toString() => _rule == null ? '<$name>' : '<$name = $_rule>';
 }

 class _ParserState {
   _ParserState(this._text, {_Rule whitespace}) {
     _end = this._text.length;
     whitespaceRule = whitespace;
     max_rule = [];
   }

   String _text;
   int _end;

   //
   bool inWhitespaceMode = false;
   _Rule whitespaceRule = null;

   // Used for constructing an error message.
   int inhibitExpectedTrackingDepth = 0;
   int max_pos = 0;
   var max_rule;
 }

 /**
  * An interface tag for rules. If this tag is on a rule, then the description()
  * of the rule is something sensible to put in a message.
  */
 abstract class _Expectable {
   String description();
 }

 class _Rule {
   const _Rule();
   // Returns null for a match failure or [pos, ast] for success.
   match(_ParserState state, int pos) {
     if (!state.inWhitespaceMode) {
       pos = _skip_whitespace(state, pos);
     }
     return matchAfterWS(state, pos);
   }

   // Faster entry point for matching a sub-rule that is matched to the start
   // position of the super-rule.  Whitespace has already been skipped so no need
   // to try to skip it again.
   matchAfterWS(_ParserState state, int pos) {
     if (state.inhibitExpectedTrackingDepth == 0) {
       // Track position for possible error messaging
       if (pos > state.max_pos) {
         // Store position and the rule.
         state.max_pos = pos;
         if (this is _Expectable) {
           state.max_rule = [this];
         } else {
           state.max_rule = [];
         }
       } else if (pos == state.max_pos) {
         if (this is _Expectable) {
           state.max_rule.add(this);
         }
       }
     }
     // Delegate the matching logic to the specialized function.
     return _match(state, pos);
   }

   // Overridden in subclasses to match the rule.
   _match(_ParserState state, int pos) => null;

   // Does the rule generate a value (AST) with the match?
   bool get generatesValue => false;

   get defaultValue => null;
 }

 int _skip_whitespace(state, pos) {
   // Returns the next non-whitespace position.
   // This is done by matching the optional whitespaceRule with the current text.
   if (state.whitespaceRule == null) return pos;
   state.inWhitespaceMode = true;
   state.inhibitExpectedTrackingDepth++;
   while (true) {
     var match = state.whitespaceRule.match(state, pos);
     if (match == null) break;
     pos = match[0];
   }
   state.inWhitespaceMode = false;
   state.inhibitExpectedTrackingDepth--;
   return pos;
 }

 _Rule _compileOptional(rule) {
   return rule == null ? null : _compile(rule);
 }

 _Rule _compile(rule) {
   if (rule is _Rule) return rule;
   if (rule is String) return new _StringRule(rule);
   if (rule is Symbol) return new _SymbolRule(rule);
   if (rule is RegExp) return new _RegExpRule(rule);
   if (rule is List) {
     return _compileMultiRule(
         rule,
         true,
         (compiledRules, valueCount, reducer) =>
             new _SequenceRule(compiledRules, valueCount, reducer));
   }
   throw new Exception('Cannot compile rule: $rule');
 }

 class _EndOfInputRule extends _Rule {
   _match(_ParserState state, int pos) {
     if (pos == state._end) return [pos, null];
     return null;
   }

   toString() => 'END';
 }

 class _ErrorRule extends _Rule {
   String message;
   _ErrorRule(String this.message);
   _match(_ParserState state, int pos) {
     throw new ParseError(message);
   }

   toString() => 'ERROR($message)';
 }

 class _CharCodeRule extends _Rule {
   Function _predicate;
   var _name;
   _CharCodeRule(this._predicate, this._name);
   _match(_ParserState state, int pos) {
     if (pos == state._end) return null;
     int code = state._text.codeUnitAt(pos);
     if (_predicate(code)) return [pos + 1, null];
     return null;
   }

   toString() => _name == null ? 'CHARCODE($_predicate)' : 'CHARCODE($_name)';
 }

 class _AnyCharRule extends _Rule {
   const _AnyCharRule();
   _match(_ParserState state, int pos) {
     if (pos == state._end) return null;
     return [pos + 1, null];
   }

   toString() => 'CHAR()';
 }

 class _SymbolRule extends _Rule {
   final Symbol _symbol;
   _SymbolRule(Symbol this._symbol);
   _match(_ParserState state, int pos) {
     if (_symbol._rule == null)
       throw new Exception("Symbol '${_symbol.name}' is undefined");
     return _symbol._rule.match(state, pos);
   }

   bool get generatesValue => true;

   toString() => '<${_symbol.name}>';
 }

 class _SkipRule extends _Rule {
   // A rule that has no value.
   _Rule _rule;
   _SkipRule(_Rule this._rule);
   _match(_ParserState state, int pos) {
     var match = _rule.matchAfterWS(state, pos);
     if (match == null) return null;
     return [match[0], null];
   }

   toString() => 'TOKEN($_rule)';
 }

 class _StringRule extends _Rule implements _Expectable {
   final String _string;
   int _len;
   _StringRule(this._string) {
     _len = _string.length;
   }

   _match(_ParserState state, int pos) {
     if (pos + _len > state._end) return null;
     for (int i = 0; i < _len; i++) {
       if (state._text.codeUnitAt(pos + i) != _string.codeUnitAt(i)) return null;
     }
     return [pos + _len, null];
   }

   //get defaultValue => _string;

   toString() => '"$_string"';

   description() => "'$_string'";
 }

 class _RegExpRule extends _Rule {
   RegExp _re;
   _RegExpRule(this._re) {
     // There is no convenient way to match an anchored substring.
     throw new Exception('RegExp matching not supported');
   }

   toString() => '"$_re"';
 }

 class _LexicalRule extends _Rule implements _Expectable {
   final String _name;
   final _Rule _rule;

   _LexicalRule(String this._name, _Rule this._rule);

   _match(_ParserState state, int pos) {
     state.inWhitespaceMode = true;
     state.inhibitExpectedTrackingDepth++;
     var match = _rule.matchAfterWS(state, pos);
     state.inhibitExpectedTrackingDepth--;
     state.inWhitespaceMode = false;
     return match;
   }

   toString() => _name;

   description() => _name == null ? '?' : _name;
 }

 class _TextValueRule extends _Rule {
   final _Rule _rule;
   final _extract; // Function

   _TextValueRule(_Rule this._rule, Function this._extract);

   _match(_ParserState state, int pos) {
     var match = _rule.matchAfterWS(state, pos);
     if (match == null) {
       return null;
     }
     var endPos = match[0];
     return [endPos, _extract(state._text, pos, endPos)];
   }

   bool get generatesValue => true;

   toString() => 'TEXT($_rule)';
 }

 _Rule _compileMultiRule(
     List rules, bool allowReducer, finish(compiledRules, valueCount, reducer)) {
   int valueCount = 0;
   List compiledRules = new List<_Rule>();
   Function reducer;
   for (var rule in rules) {
     if (reducer != null)
       throw new Exception('Reducer must be last in sequence: $rule');
     if (rule is Function) {
       if (allowReducer)
         reducer = rule;
       else
         throw new Exception('Bad rule: "$rule"');
     } else {
       _Rule compiledRule = _compile(rule);
       if (compiledRule.generatesValue) ++valueCount;
       compiledRules.add(compiledRule);
     }
   }
   return finish(compiledRules, valueCount, reducer);
 }

 String _formatMultiRule(String functor, List rules) {
   var sb = new StringBuffer(functor);
   sb.write('(');
   var separator = '';
   for (var rule in rules) {
     sb.write(separator);
     sb.write(rule);
     separator = ',';
   }
   sb.write(')');
   return sb.toString();
 }

 class _SequenceRule extends _Rule {
   // This rule matches the component rules in order.
   final List<_Rule> _rules;
   final int _generatingSubRules;
   final Function _reducer;
   bool _generatesValue;
   _SequenceRule(List<_Rule> this._rules, int this._generatingSubRules,
       Function this._reducer) {
     _generatesValue = _generatingSubRules > 0 || _reducer != null;
   }

   _match(state, pos) {
     var sequence = [];
     for (var rule in _rules) {
       var match = rule.match(state, pos);
       if (match == null) return null;
       if (rule.generatesValue) {
         var ast = match[1];
         sequence.add(ast);
       }
       pos = match[0];
     }
     if (_reducer == null) {
       if (_generatingSubRules == 0) return [pos, null];
       if (_generatingSubRules == 1) return [pos, sequence[0]];
       return [pos, sequence];
     } else {
       return [pos, _apply(_reducer, sequence)];
     }
   }

   bool get generatesValue => _generatesValue;

   toString() => _formatMultiRule('SEQ', _rules);
 }

 class _ChoiceRule extends _Rule {
   // This rule matches the first component rule that matches.
   List<_Rule> _rules;
   _ChoiceRule(List<_Rule> this._rules);

   _match(state, pos) {
     for (var rule in _rules) {
       var match = rule.match(state, pos);
       if (match != null) {
         /*
         if (!rule.generatesValue) {
           var value = rule.defaultValue;
           if (value != null)
             return [match[0], value];
         }
         */
         return match;
       }
     }
     return null;
   }

   bool get generatesValue => true;

   toString() => _formatMultiRule('OR', _rules);
 }

 class _OptionalRule extends _Rule {
   _Rule _rule;
   _OptionalRule(_Rule this._rule);
   _match(_ParserState state, int pos) {
     var match = _rule.match(state, pos);
     if (_rule.generatesValue) return match == null ? [pos, null] : match;
     return match == null ? [pos, false] : [match[0], true];
   }

   bool get generatesValue => true;

   toString() => 'MAYBE($_rule)';
 }

 class _ContextRule extends _Rule {
   _Rule _rule;
   _ContextRule(_Rule this._rule);
   _match(_ParserState state, int pos) {
     // TODO: protect error state.
     var match = _rule._match(state, pos);
     if (match == null) return null;
     return [pos, null];
   }

   toString() => 'AT($_rule)';
 }

 class _NegativeContextRule extends _Rule {
   _Rule _rule;
   _NegativeContextRule(_Rule this._rule);
   _match(_ParserState state, int pos) {
     // TODO: protect error state.
     var match = _rule._match(state, pos);
     if (match == null) return [pos, null];
     return null;
   }

   toString() => 'NOT($_rule)';
 }

 class _RepeatRule extends _Rule {
   // Matches zero, one or more items.
   _Rule _rule;
   _Rule _separator;
   int _min;

   _RepeatRule(this._rule, this._separator, this._min);

   _match(state, pos) {
     // First match.
     var match = _rule.match(state, pos);
     if (match == null) if (_min == 0)
       return [pos, []];
     else
       return null;
     pos = match[0];
     var result = [match[1]];

     // Subsequent matches:
     while (true) {
       var newPos = pos;
       if (_separator != null) {
         match = _separator.match(state, pos);
         if (match == null) return [pos, result];
         newPos = match[0];
       }
       match = _rule.match(state, newPos);
       if (match == null) return [pos, result];
       pos = match[0];
       result.add(match[1]);
     }
   }

   bool get generatesValue => true;

   toString() =>
       'MANY(min:$_min, $_rule${_separator==null?'':", sep: $_separator"})';
 }

 class _MemoRule extends _Rule {
   final _Rule _rule;

   var parseInstance;

   // A map from position to result.  Can this be replaced with something
   // smaller?
   // TODO: figure out how to discard the map and parseInstance after parsing.
   Map<int, Object> map;

   _MemoRule(this._rule);

   _match(state, pos) {
     // See if we are still parsing the same input.  Relies on the fact that the
     // input is a string and strings are immutable.
     if (!identical(parseInstance, state._text)) {
       map = new Map<int, Object>();
       parseInstance = state._text;
     }
     // TODO: does this have to check or preserve parse state (like
     // inWhitespaceMode, error position info etc?)
     // Stored result can be null (memoized failure).
     if (map.containsKey(pos)) {
       return map[pos];
     }
     var match = _rule.match(state, pos);
     map[pos] = match;
     return match;
   }

   bool get generatesValue => _rule.generatesValue;

   toString() => 'MEMO($_rule)';
 }

 _apply(fn, List args) {
   switch (args.length) {
     case 0:
       return fn();
     case 1:
       return fn(args[0]);
     case 2:
       return fn(args[0], args[1]);
     case 3:
       return fn(args[0], args[1], args[2]);
     case 4:
       return fn(args[0], args[1], args[2], args[3]);
     case 5:
       return fn(args[0], args[1], args[2], args[3], args[4]);
     case 6:
       return fn(args[0], args[1], args[2], args[3], args[4], args[5]);
     case 7:
       return fn(args[0], args[1], args[2], args[3], args[4], args[5], args[6]);
     case 8:
       return fn(args[0], args[1], args[2], args[3], args[4], args[5], args[6],
           args[7]);
     case 9:
       return fn(args[0], args[1], args[2], args[3], args[4], args[5], args[6],
           args[7], args[8]);
     case 10:
       return fn(args[0], args[1], args[2], args[3], args[4], args[5], args[6],
           args[7], args[8], args[9]);

     default:
       throw new Exception('Too many arguments in _apply: $args');
   }
 }

 List _unspread(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v,
     w, x, y, z) {
   List list = new List();
   add(element) {
     if (element != null) list.add(element);
   }

   add(a);
   add(b);
   add(c);
   add(d);
   add(e);
   add(f);
   add(g);
   add(h);
   add(i);
   add(j);
   add(k);
   add(l);
   add(m);
   add(n);
   add(o);
   add(p);
   add(q);
   add(r);
   add(s);
   add(t);
   add(u);
   add(v);
   add(w);
   add(x);
   add(y);
   add(z);
   return list;
 }
	// Copyright (c) 2011, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	library PegParser;

	/*
	* The following functions are combinators for building Rules.
	*
	* A rule is one of the following
	* - A String which matches the string literally.
	* - A Symbol which matches the symbol's definition.
	* - A list of rules with an optional reducing function, which matches a sequence.
	* - The result of calling one of the combinators.
	*
	* Some rules are 'value-generating' rules, they return an 'abstract syntax
	* tree' with the match. If a rule is not value-generating [:null:] is the
	* value.
	*
	* A Symbol is always a value-generating rule. If the value is not required, use
	* [:SKIP(aSymbol):] in place of [:aSymbol:].
	*
	* A String is not a value-generating rule but can be converted into one by
	* using [:TEXT('string'):] in place of [:'string':].
	*
	* A list or sequence is value-generating depending on the subrules. The
	* sequence is value-generating if any of the subrules are value-generating or
	* if there is a reducing function. If no reducing function is given, the value
	* returned depends on the number of value-generating subrules. If there is
	* only one value generating subrule, that provideds the value for the sequence.
	* If there are more, then the value is a list of the values of the
	* value-generating subrules.
	*/

	/**
	* Matches one character by a predicate on the character code.
	* If [spec] is an int, that character is matched.
	* If [spec] is a function it is used
	*
	* Example [: CHARCODE((code) => 48 <= code && code <= 57) :] recognizes an
	* ASCII digit.
	*
	* CHARCODE does not generate a value.
	*/
	_Rule CHARCODE(spec, [name]) {
	if (spec is int)
	return new _CharCodeRule((code) => code == spec, name);
	else
	return new _CharCodeRule(spec, name);
	}

	/**
	* Matches one of the [characters].
	*
	* CHAR does not generate a value.
	*/
	_Rule CHAR([characters]) {
	if (characters == null) return const _AnyCharRule();
	if (characters is int) return CHARCODE(characters);

	// Find the range of character codes and construct an array of flags for codes
	// within the range.
	List<int> codes = characters.codeUnits.toList();
	codes.sort((a, b) => a < b ? -1 : a > b ? 1 : 0);
	int lo = codes[0];
	int hi = codes[codes.length - 1];
	if (lo == hi) return CHARCODE(lo);
	int len = hi - lo + 1;
	var flags = new List<bool>(len);
	for (int i = 0; i < len; ++i) flags[i] = false;
	for (int code in codes) flags[code - lo] = true;

	return CHARCODE((code) => code >= lo && code <= hi && flags[code - lo]);
	}

	/**
	* Matches the end of the input.
	*
	* END does not generate a value.
	*/
	_Rule get END => new _EndOfInputRule();

	/**
	* Throws an exception.
	*/
	_Rule ERROR(String message) => new _ErrorRule(message);

	/**
	* Matches [rule] but does not consume the input. Useful for matching a right
	* context.
	*
	* AT does not generate a value.
	*/
	_Rule AT(rule) => new _ContextRule(_compile(rule));

	/**
	* Matches when [rule] does not match. No input is consumed.
	*
	* NOT does not generate a value.
	*/
	_Rule NOT(rule) => new _NegativeContextRule(_compile(rule));

	/**
	* Matches [rule] but generates no value even if [rule] generates a value.
	*
	* SKIP never generates a value.
	*/
	_Rule SKIP(rule) => new _SkipRule(_compile(rule));

	/**
	* Matches [rule] in a lexical context where whitespace is not automatically
	* skipped. Useful for matching what would normally be considered to be tokens.
	* [name] is a user-friendly description of what is being matched and is used in
	* error messages.
	*
	* LEX(rule)
	* LEX(name, rule)
	*
	* LEX does not generate a value. If a value is required, wrap LEX with TEXT.
	*/
	_Rule LEX(arg1, [arg2]) {
	if (arg2 == null)
	return new _LexicalRule(arg1 is String ? arg1 : null, _compile(arg1));
	else
	return new _LexicalRule(arg1, _compile(arg2));
	}

	/**
	* Matches [rule] and generates a value from the matched text. If the [rule]
	* matches, then TEXT(rule) matches and has a value derived from the string
	* fragment that was matched. The default derived value is the string fragment.
	*
	* TEXT always generates a value.
	*/
	_Rule TEXT(rule, [extractor]) => new _TextValueRule(
	_compile(rule),
	extractor == null
	? (string, start, end) => string.substring(start, end)
	: extractor);

	/**
	* Matches an optional rule.
	*
	* MAYBE is a value generating matcher.
	*
	* If [rule] is value generating then the value is the value generated by [rule]
	* if it matches, and [:null:] if it does not.
	*
	* If [rule] is not value generating then the value is [:true:] if [rule]
	* matches and [:false:] if it does not.
	*/
	_Rule MAYBE(rule) => new _OptionalRule(_compile(rule));

	/**
	* MANY(rule) matches [rule] [min] or more times.
	* [min] must be 0 or 1.
	* If [separator] is provided it is used to match a separator between matches of
	* [rule].
	*
	* MANY is a value generating matcher. The value is a list of the matches of
	* [rule]. The list may be empty if [:min == 0:].
	*/
	_Rule MANY(rule, {separator: null, int min: 1}) {
	assert(0 <= min && min <= 1);
	return new _RepeatRule(_compile(rule), _compileOptional(separator), min);
	}

	/**
	* Matches [rule] zero or more times. Shorthand for [:MANY(rule, min:0):]
	* TODO: retire min: parameter?
	*
	* MANY0 is a value generating matcher.
	*/
	_Rule MANY0(rule, [separator = null]) {
	return new _RepeatRule(_compile(rule), _compileOptional(separator), 0);
	}

	/**
	* Matches [rules] in order until one succeeds.
	*
	* OR is value-generating.
	*/
	_Rule OR(
	[a,
	b,
	c,
	d,
	e,
	f,
	g,
	h,
	i,
	j,
	k,
	l,
	m,
	n,
	o,
	p,
	q,
	r,
	s,
	t,
	u,
	v,
	w,
	x,
	y,
	z]) =>
	_compileMultiRule(
	(a is List && b == null) // Backward compat. OR([a, b]) => OR(a, b).
	? a
	: _unspread(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s,
	t, u, v, w, x, y, z),
	false,
	(compiledRules, valueCount, reducer) => new _ChoiceRule(compiledRules));

	_Rule SEQ(
	[a,
	b,
	c,
	d,
	e,
	f,
	g,
	h,
	i,
	j,
	k,
	l,
	m,
	n,
	o,
	p,
	q,
	r,
	s,
	t,
	u,
	v,
	w,
	x,
	y,
	z]) =>
	_compile(_unspread(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s,
	t, u, v, w, x, y, z));

	/**
	* Matches [rule]
	*/
	_Rule MEMO(rule) => new _MemoRule(_compile(rule));

	_Rule TAG(tag, rule) => _compile([
	rule,
	(ast) => [tag, ast]
	]);

	class ParseError implements Exception {
	const ParseError(String this._message);
	String toString() => _message;
	final String _message;
	}

	/**
	* A grammar is a collection of symbols and rules that may be used to parse an
	* input.
	*/
	class Grammar {
	Map<String, Symbol> _symbols;

	/** This rule may be set by the user to define whitespace. */
	_Rule _whitespace;

	_Rule get whitespace => _whitespace;
	void set whitespace(rule) {
	_whitespace = _compile(rule);
	}

	Grammar() {
	_symbols = new Map<String, Symbol>();
	whitespace = CHAR(' \t\r\n');
	}

	/**
	* operator [] is used to find or create symbols. Symbols may appear in rules
	* to define recursive rules.
	*/
	Symbol operator [](String name) {
	if (_symbols.containsKey(name)) return _symbols[name];
	Symbol s = new Symbol(name, this);
	_symbols[name] = s;
	return s;
	}

	/**
	* Parses the input string and returns the parsed AST, or throws an exception
	* if the input can't be parsed.
	*/
	parse(root, String text) {
	for (var symbol in _symbols.values)
	if (symbol._rule == null) print('${symbol.name} is undefined');

	var state = new _ParserState(text, whitespace: whitespace);
	var match = _compile(root).match(state, 0);
	if (match == null) return diagnose(state);
	var pos = match[0];
	pos = _skip_whitespace(state, pos);
	if (pos == state._end) return match[1];
	// TODO: Make this complain about expecting end of file.
	return diagnose(state);
	}

	diagnose(state) {
	var message = 'unexpected error';
	if (!state.max_rule.isEmpty) {
	var s = new Set();
	for (var rule in state.max_rule) s.add(rule.description());
	var tokens = new List<String>.from(s);
	tokens.sort((a, b) => a.startsWith("'") == b.startsWith("'")
	? a.compareTo(b)
	: a.startsWith("'") ? 1 : -1);
	var expected = tokens.join(' or ');
	var found = state.max_pos == state._end
	? 'end of file'
	: "'${state._text[state.max_pos]}'";
	message = 'Expected $expected but found $found';
	}
	int start = state.max_pos;
	int end = start;
	while (start >= 1 && state._text[start - 1] != '\n') --start;
	while (end < state._text.length && state._text[end] != '\n') ++end;
	var line = state._text.substring(start, end);
	var indicator = '';
	for (var i = 0; i < line.length && start + i < state.max_pos; i++)
	indicator = ' $indicator';
	indicator = '$indicator^';
	// TODO: Convert to an exception.
	print(message);
	print(line);
	print(indicator);
	return null;
	}
	}

	class Symbol {
	final String name;
	final Grammar grammar;
	_Rule _rule;

	Symbol(this.name, this.grammar);

	void set def(rule) {
	assert(_rule == null); // Assign once.
	_rule = _compile(rule);
	}

	toString() => _rule == null ? '<$name>' : '<$name = $_rule>';
	}

	class _ParserState {
	_ParserState(this._text, {_Rule whitespace}) {
	_end = this._text.length;
	whitespaceRule = whitespace;
	max_rule = [];
	}

	String _text;
	int _end;

	//
	bool inWhitespaceMode = false;
	_Rule whitespaceRule = null;

	// Used for constructing an error message.
	int inhibitExpectedTrackingDepth = 0;
	int max_pos = 0;
	var max_rule;
	}

	/**
	* An interface tag for rules. If this tag is on a rule, then the description()
	* of the rule is something sensible to put in a message.
	*/
	abstract class _Expectable {
	String description();
	}

	class _Rule {
	const _Rule();
	// Returns null for a match failure or [pos, ast] for success.
	match(_ParserState state, int pos) {
	if (!state.inWhitespaceMode) {
	pos = _skip_whitespace(state, pos);
	}
	return matchAfterWS(state, pos);
	}

	// Faster entry point for matching a sub-rule that is matched to the start
	// position of the super-rule. Whitespace has already been skipped so no need
	// to try to skip it again.
	matchAfterWS(_ParserState state, int pos) {
	if (state.inhibitExpectedTrackingDepth == 0) {
	// Track position for possible error messaging
	if (pos > state.max_pos) {
	// Store position and the rule.
	state.max_pos = pos;
	if (this is _Expectable) {
	state.max_rule = [this];
	} else {
	state.max_rule = [];
	}
	} else if (pos == state.max_pos) {
	if (this is _Expectable) {
	state.max_rule.add(this);
	}
	}
	}
	// Delegate the matching logic to the specialized function.
	return _match(state, pos);
	}

	// Overridden in subclasses to match the rule.
	_match(_ParserState state, int pos) => null;

	// Does the rule generate a value (AST) with the match?
	bool get generatesValue => false;

	get defaultValue => null;
	}

	int _skip_whitespace(state, pos) {
	// Returns the next non-whitespace position.
	// This is done by matching the optional whitespaceRule with the current text.
	if (state.whitespaceRule == null) return pos;
	state.inWhitespaceMode = true;
	state.inhibitExpectedTrackingDepth++;
	while (true) {
	var match = state.whitespaceRule.match(state, pos);
	if (match == null) break;
	pos = match[0];
	}
	state.inWhitespaceMode = false;
	state.inhibitExpectedTrackingDepth--;
	return pos;
	}

	_Rule _compileOptional(rule) {
	return rule == null ? null : _compile(rule);
	}

	_Rule _compile(rule) {
	if (rule is _Rule) return rule;
	if (rule is String) return new _StringRule(rule);
	if (rule is Symbol) return new _SymbolRule(rule);
	if (rule is RegExp) return new _RegExpRule(rule);
	if (rule is List) {
	return _compileMultiRule(
	rule,
	true,
	(compiledRules, valueCount, reducer) =>
	new _SequenceRule(compiledRules, valueCount, reducer));
	}
	throw new Exception('Cannot compile rule: $rule');
	}

	class _EndOfInputRule extends _Rule {
	_match(_ParserState state, int pos) {
	if (pos == state._end) return [pos, null];
	return null;
	}

	toString() => 'END';
	}

	class _ErrorRule extends _Rule {
	String message;
	_ErrorRule(String this.message);
	_match(_ParserState state, int pos) {
	throw new ParseError(message);
	}

	toString() => 'ERROR($message)';
	}

	class _CharCodeRule extends _Rule {
	Function _predicate;
	var _name;
	_CharCodeRule(this._predicate, this._name);
	_match(_ParserState state, int pos) {
	if (pos == state._end) return null;
	int code = state._text.codeUnitAt(pos);
	if (_predicate(code)) return [pos + 1, null];
	return null;
	}

	toString() => _name == null ? 'CHARCODE($_predicate)' : 'CHARCODE($_name)';
	}

	class _AnyCharRule extends _Rule {
	const _AnyCharRule();
	_match(_ParserState state, int pos) {
	if (pos == state._end) return null;
	return [pos + 1, null];
	}

	toString() => 'CHAR()';
	}

	class _SymbolRule extends _Rule {
	final Symbol _symbol;
	_SymbolRule(Symbol this._symbol);
	_match(_ParserState state, int pos) {
	if (_symbol._rule == null)
	throw new Exception("Symbol '${_symbol.name}' is undefined");
	return _symbol._rule.match(state, pos);
	}

	bool get generatesValue => true;

	toString() => '<${_symbol.name}>';
	}

	class _SkipRule extends _Rule {
	// A rule that has no value.
	_Rule _rule;
	_SkipRule(_Rule this._rule);
	_match(_ParserState state, int pos) {
	var match = _rule.matchAfterWS(state, pos);
	if (match == null) return null;
	return [match[0], null];
	}

	toString() => 'TOKEN($_rule)';
	}

	class _StringRule extends _Rule implements _Expectable {
	final String _string;
	int _len;
	_StringRule(this._string) {
	_len = _string.length;
	}

	_match(_ParserState state, int pos) {
	if (pos + _len > state._end) return null;
	for (int i = 0; i < _len; i++) {
	if (state._text.codeUnitAt(pos + i) != _string.codeUnitAt(i)) return null;
	}
	return [pos + _len, null];
	}

	//get defaultValue => _string;

	toString() => '"$_string"';

	description() => "'$_string'";
	}

	class _RegExpRule extends _Rule {
	RegExp _re;
	_RegExpRule(this._re) {
	// There is no convenient way to match an anchored substring.
	throw new Exception('RegExp matching not supported');
	}

	toString() => '"$_re"';
	}

	class _LexicalRule extends _Rule implements _Expectable {
	final String _name;
	final _Rule _rule;

	_LexicalRule(String this._name, _Rule this._rule);

	_match(_ParserState state, int pos) {
	state.inWhitespaceMode = true;
	state.inhibitExpectedTrackingDepth++;
	var match = _rule.matchAfterWS(state, pos);
	state.inhibitExpectedTrackingDepth--;
	state.inWhitespaceMode = false;
	return match;
	}

	toString() => _name;

	description() => _name == null ? '?' : _name;
	}

	class _TextValueRule extends _Rule {
	final _Rule _rule;
	final _extract; // Function

	_TextValueRule(_Rule this._rule, Function this._extract);

	_match(_ParserState state, int pos) {
	var match = _rule.matchAfterWS(state, pos);
	if (match == null) {
	return null;
	}
	var endPos = match[0];
	return [endPos, _extract(state._text, pos, endPos)];
	}

	bool get generatesValue => true;

	toString() => 'TEXT($_rule)';
	}

	_Rule _compileMultiRule(
	List rules, bool allowReducer, finish(compiledRules, valueCount, reducer)) {
	int valueCount = 0;
	List compiledRules = new List<_Rule>();
	Function reducer;
	for (var rule in rules) {
	if (reducer != null)
	throw new Exception('Reducer must be last in sequence: $rule');
	if (rule is Function) {
	if (allowReducer)
	reducer = rule;
	else
	throw new Exception('Bad rule: "$rule"');
	} else {
	_Rule compiledRule = _compile(rule);
	if (compiledRule.generatesValue) ++valueCount;
	compiledRules.add(compiledRule);
	}
	}
	return finish(compiledRules, valueCount, reducer);
	}

	String _formatMultiRule(String functor, List rules) {
	var sb = new StringBuffer(functor);
	sb.write('(');
	var separator = '';
	for (var rule in rules) {
	sb.write(separator);
	sb.write(rule);
	separator = ',';
	}
	sb.write(')');
	return sb.toString();
	}

	class _SequenceRule extends _Rule {
	// This rule matches the component rules in order.
	final List<_Rule> _rules;
	final int _generatingSubRules;
	final Function _reducer;
	bool _generatesValue;
	_SequenceRule(List<_Rule> this._rules, int this._generatingSubRules,
	Function this._reducer) {
	_generatesValue = _generatingSubRules > 0 \|\| _reducer != null;
	}

	_match(state, pos) {
	var sequence = [];
	for (var rule in _rules) {
	var match = rule.match(state, pos);
	if (match == null) return null;
	if (rule.generatesValue) {
	var ast = match[1];
	sequence.add(ast);
	}
	pos = match[0];
	}
	if (_reducer == null) {
	if (_generatingSubRules == 0) return [pos, null];
	if (_generatingSubRules == 1) return [pos, sequence[0]];
	return [pos, sequence];
	} else {
	return [pos, _apply(_reducer, sequence)];
	}
	}

	bool get generatesValue => _generatesValue;

	toString() => _formatMultiRule('SEQ', _rules);
	}

	class _ChoiceRule extends _Rule {
	// This rule matches the first component rule that matches.
	List<_Rule> _rules;
	_ChoiceRule(List<_Rule> this._rules);

	_match(state, pos) {
	for (var rule in _rules) {
	var match = rule.match(state, pos);
	if (match != null) {
	/*
	if (!rule.generatesValue) {
	var value = rule.defaultValue;
	if (value != null)
	return [match[0], value];
	}
	*/
	return match;
	}
	}
	return null;
	}

	bool get generatesValue => true;

	toString() => _formatMultiRule('OR', _rules);
	}

	class _OptionalRule extends _Rule {
	_Rule _rule;
	_OptionalRule(_Rule this._rule);
	_match(_ParserState state, int pos) {
	var match = _rule.match(state, pos);
	if (_rule.generatesValue) return match == null ? [pos, null] : match;
	return match == null ? [pos, false] : [match[0], true];
	}

	bool get generatesValue => true;

	toString() => 'MAYBE($_rule)';
	}

	class _ContextRule extends _Rule {
	_Rule _rule;
	_ContextRule(_Rule this._rule);
	_match(_ParserState state, int pos) {
	// TODO: protect error state.
	var match = _rule._match(state, pos);
	if (match == null) return null;
	return [pos, null];
	}

	toString() => 'AT($_rule)';
	}

	class _NegativeContextRule extends _Rule {
	_Rule _rule;
	_NegativeContextRule(_Rule this._rule);
	_match(_ParserState state, int pos) {
	// TODO: protect error state.
	var match = _rule._match(state, pos);
	if (match == null) return [pos, null];
	return null;
	}

	toString() => 'NOT($_rule)';
	}

	class _RepeatRule extends _Rule {
	// Matches zero, one or more items.
	_Rule _rule;
	_Rule _separator;
	int _min;

	_RepeatRule(this._rule, this._separator, this._min);

	_match(state, pos) {
	// First match.
	var match = _rule.match(state, pos);
	if (match == null) if (_min == 0)
	return [pos, []];
	else
	return null;
	pos = match[0];
	var result = [match[1]];

	// Subsequent matches:
	while (true) {
	var newPos = pos;
	if (_separator != null) {
	match = _separator.match(state, pos);
	if (match == null) return [pos, result];
	newPos = match[0];
	}
	match = _rule.match(state, newPos);
	if (match == null) return [pos, result];
	pos = match[0];
	result.add(match[1]);
	}
	}

	bool get generatesValue => true;

	toString() =>
	'MANY(min:$_min, $_rule${_separator==null?'':", sep: $_separator"})';
	}

	class _MemoRule extends _Rule {
	final _Rule _rule;

	var parseInstance;

	// A map from position to result. Can this be replaced with something
	// smaller?
	// TODO: figure out how to discard the map and parseInstance after parsing.
	Map<int, Object> map;

	_MemoRule(this._rule);

	_match(state, pos) {
	// See if we are still parsing the same input. Relies on the fact that the
	// input is a string and strings are immutable.
	if (!identical(parseInstance, state._text)) {
	map = new Map<int, Object>();
	parseInstance = state._text;
	}
	// TODO: does this have to check or preserve parse state (like
	// inWhitespaceMode, error position info etc?)
	// Stored result can be null (memoized failure).
	if (map.containsKey(pos)) {
	return map[pos];
	}
	var match = _rule.match(state, pos);
	map[pos] = match;
	return match;
	}

	bool get generatesValue => _rule.generatesValue;

	toString() => 'MEMO($_rule)';
	}

	_apply(fn, List args) {
	switch (args.length) {
	case 0:
	return fn();
	case 1:
	return fn(args[0]);
	case 2:
	return fn(args[0], args[1]);
	case 3:
	return fn(args[0], args[1], args[2]);
	case 4:
	return fn(args[0], args[1], args[2], args[3]);
	case 5:
	return fn(args[0], args[1], args[2], args[3], args[4]);
	case 6:
	return fn(args[0], args[1], args[2], args[3], args[4], args[5]);
	case 7:
	return fn(args[0], args[1], args[2], args[3], args[4], args[5], args[6]);
	case 8:
	return fn(args[0], args[1], args[2], args[3], args[4], args[5], args[6],
	args[7]);
	case 9:
	return fn(args[0], args[1], args[2], args[3], args[4], args[5], args[6],
	args[7], args[8]);
	case 10:
	return fn(args[0], args[1], args[2], args[3], args[4], args[5], args[6],
	args[7], args[8], args[9]);

	default:
	throw new Exception('Too many arguments in _apply: $args');
	}
	}

	List _unspread(a, b, c, d, e, f, g, h, i, j, k, l, m, n, o, p, q, r, s, t, u, v,
	w, x, y, z) {
	List list = new List();
	add(element) {
	if (element != null) list.add(element);
	}

	add(a);
	add(b);
	add(c);
	add(d);
	add(e);
	add(f);
	add(g);
	add(h);
	add(i);
	add(j);
	add(k);
	add(l);
	add(m);
	add(n);
	add(o);
	add(p);
	add(q);
	add(r);
	add(s);
	add(t);
	add(u);
	add(v);
	add(w);
	add(x);
	add(y);
	add(z);
	return list;
	}