utils/tests/peg/peg_test.dart - sdk.git - 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 peg_tests;

 import 'dart:core' hide Symbol;
 import '../../peg/pegparser.dart';

 testParens() {
   Grammar g = new Grammar();
   Symbol a = g['A'];

   a.def = ['(', MANY(a, min: 0), ')', (a) => a];

   check(g, a, "", null);
   check(g, a, "()", '[]');
   check(g, a, "(()())", '[[],[]]');
   check(g, a, "(()((()))())", '[[],[[[]]],[]]');
 }

 testBlockComment() {
   // Block comment in whitespace.

   Grammar g = new Grammar();
   Symbol blockComment = g['blockComment'];

   blockComment.def = [
     '/*',
     MANY(
         OR([
           blockComment,
           [NOT('*/'), CHAR()],
           [END, ERROR('EOF in block comment')]
         ]),
         min: 0),
     '*/'
   ];
   print(blockComment);

   var a = MANY(TEXT('x'));

   g.whitespace = OR([g.whitespace, blockComment]);

   check(g, a, "x /**/ x", '[x,x]');
   check(g, a, "x /*/**/*/ x", '[x,x]');
   check(g, a, "x /*/***/ x", 'EOF in block comment');
   check(g, a, "x /*/*/x**/**/ x", '[x,x]');

   check(
       g,
       a,
       r"""
 /* Comment */
 /* Following comment with /* nested comment*/ */
 x
 /* x in comment */
 x /* outside comment */
 """,
       '[x,x]');
 }

 testTEXT() {
   Grammar g = new Grammar();

   // TEXT grabs the parsed text,
   check(g, TEXT(LEX(MANY(OR(['1', 'a'])))), '  1a1  ', '1a1');

   // Without the lexical context, TEXT will grab intervening whitespace.
   check(g, TEXT(MANY(OR(['1', 'a']))), '  1a1  ', '1a1');
   check(g, TEXT(MANY(OR(['1', 'a']))), '  1  a 1  ', '1  a 1');

   // Custom processing of the TEXT substring.
   var binaryNumber = TEXT(LEX(MANY(OR(['0', '1']))), (str, start, end) {
     var r = 0;
     var zero = '0'.codeUnitAt(0);
     for (int i = start; i < end; i++) r = r * 2 + (str.codeUnitAt(i) - zero);
     return r;
   });

   check(g, binaryNumber, ' 10101 ', 21);
   check(g, binaryNumber, '1010111', 87);
   check(g, binaryNumber, '1010 111', null);
 }

 testOR() {
   // OR matches the first match.
   Grammar g = new Grammar();
   check(
       g,
       OR([
         ['a', NOT(END), () => 1],
         ['a', () => 2],
         ['a', () => 3]
       ]),
       'a',
       2);
 }

 testCODE() {
   Grammar g = new Grammar();
   var a = TEXT(LEX('thing', MANY(CHAR('bcd'))));

   check(g, a, 'bbb', 'bbb');
   check(g, a, 'ccc', 'ccc');
   check(g, a, 'ddd', 'ddd');
   check(g, a, 'bad', null); // a is outside range.
   check(g, a, 'bed', null); // e is outside range.
 }

 testC() {
   // Curried tree builders.
   binary(operation) => (second) => (first) => [operation, first, second];
   unary(operation) => () => (first) => [operation, first];
   reform(a, fns) {
     var r = a;
     for (var fn in fns) r = fn(r);
     return r;
   }

   Grammar g = new Grammar();

   Symbol expression = g['expression'];
   Symbol postfix_e = g['postfix_e'];
   Symbol unary_e = g['unary_e'];
   Symbol cast_e = g['cast_e'];
   Symbol mult_e = g['mult_e'];
   Symbol add_e = g['add_e'];
   Symbol shift_e = g['shift_e'];
   Symbol relational_e = g['relational_e'];
   Symbol equality_e = g['equality_e'];
   Symbol cond_e = g['cond_e'];
   Symbol assignment_e = g['assignment_e'];

   // Lexical elements.
   var idStartChar =
       CHAR(r"ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz");
   var idNextChar =
       CHAR(r"ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789$_");

   var id = TEXT(LEX('identifier', [idStartChar, MANY(idNextChar, min: 0)]));

   var lit = TEXT(LEX('literal', MANY(CHAR('0123456789'))));

   var type_name = id;

   // Expression grammar.
   var primary_e = OR([
     id,
     lit,
     ['(', expression, ')', (e) => e]
   ]);

   var postfixes = OR([
     ['(', MANY(assignment_e, separator: ',', min: 0), ')', binary('apply')],
     ['++', unary('postinc')],
     ['--', unary('postdec')],
     ['.', id, binary('field')],
     ['->', id, binary('ptr')],
   ]);

   postfix_e.def = [primary_e, MANY(postfixes, min: 0), reform];

   var unary_op = OR([
     ['&', () => 'address'],
     ['*', () => 'indir'],
     ['!', () => 'not'],
     ['~', () => 'not'],
     ['-', () => 'negate'],
     ['+', () => 'uplus'],
   ]);
   var sizeof = LEX('sizeof', ['sizeof', NOT(idNextChar)]);

   Symbol unary_e_plain = g['unary_e_plain'];
   unary_e_plain.def = OR([
     [
       '++', unary_e, (e) => ['preinc', e] //
     ],
     [
       '--', unary_e, (e) => ['predec', e] //
     ],
     [
       unary_op, cast_e, (o, e) => [o, e] //
     ],
     [
       sizeof, unary_e, (e) => ['sizeof-expr', e] //
     ],
     [
       sizeof, '(', type_name, ')', (t) => ['sizeof-type', t] //
     ],
     postfix_e
   ]);

   unary_e.def = MEMO(unary_e_plain);
   //unary_e.def = unary_e_plain;

   cast_e.def = OR([
     [
       '(', type_name, ')', cast_e, (t, e) => ['cast', t, e] //
     ],
     unary_e,
   ]);

   var mult_ops = OR([
     ['*', cast_e, binary('mult')],
     ['/', cast_e, binary('div')],
     ['%', cast_e, binary('rem')],
   ]);
   mult_e.def = [cast_e, MANY(mult_ops, min: 0), reform];

   var add_ops = OR([
     ['+', mult_e, binary('add')],
     ['-', mult_e, binary('sub')],
   ]);
   add_e.def = [mult_e, MANY(add_ops, min: 0), reform];

   var shift_ops = OR([
     ['>>', add_e, binary('shl')],
     ['<<', add_e, binary('shr')],
   ]);
   shift_e.def = [add_e, MANY(shift_ops, min: 0), reform];

   var relational_ops = OR([
     ['<=', shift_e, binary('le')],
     ['>=', shift_e, binary('ge')],
     ['<', shift_e, binary('lt')],
     ['>', shift_e, binary('gt')],
   ]);
   relational_e.def = [shift_e, MANY(relational_ops, min: 0), reform];

   var equality_ops = OR([
     ['==', shift_e, binary('eq')],
     ['!=', shift_e, binary('ne')],
   ]);
   equality_e.def = [relational_e, MANY(equality_ops, min: 0), reform];

   var bit_and_op = LEX('&', ['&', NOT('&')]); // Don't see '&&' and '&', '&'
   var bit_or_op = LEX('|', ['|', NOT('|')]);

   var and_e = [
     equality_e,
     MANY([bit_and_op, equality_e, binary('bitand')], min: 0),
     reform
   ];
   var xor_e = [
     and_e,
     MANY(['^', and_e, binary('bitxor')], min: 0),
     reform
   ];
   var or_e = [
     xor_e,
     MANY([bit_or_op, xor_e, binary('bitor')], min: 0),
     reform
   ];

   var log_and_e = [
     or_e,
     MANY(['&&', or_e, binary('and')], min: 0),
     reform
   ];

   var log_or_e = [
     log_and_e,
     MANY(['||', log_and_e, binary('or')], min: 0),
     reform
   ];

   //cond_e.def = OR([ [log_or_e, '?', expression, ':', cond_e,
   //                   (p,a,b) => ['cond', p, a, b]],
   //                  log_or_e]);
   // Alternate version avoids reparsing log_or_e.
   cond_e.def = [
     log_or_e,
     MAYBE(['?', expression, ':', cond_e]),
     (p, r) => r == null || r == false ? p : ['cond', p, r[0], r[1]]
   ];

   var assign_op = OR([
     ['*=', () => 'mulassign'],
     ['=', () => 'assign']
   ]);

   // TODO: Figure out how not to re-parse a unary_e.
   // Order matters - cond_e can't go first since cond_e will succeed on, e.g. 'a'.
   assignment_e.def = OR([
     [
       unary_e,
       assign_op,
       assignment_e,
       (u, op, a) => [op, u, a]
     ],
     cond_e
   ]);

   expression.def = [
     assignment_e,
     MANY([',', assignment_e, binary('comma')], min: 0),
     reform
   ];

   show(g, expression, 'a');
   check(g, expression, 'a', 'a');
   check(g, expression, '(a)', 'a');
   check(g, expression, '  (  ( a ) ) ', 'a');

   check(g, expression, 'a(~1,2)', '[apply,a,[[not,1],2]]');
   check(g, expression, 'a(1)(x,2)', '[apply,[apply,a,[1]],[x,2]]');
   check(g, expression, 'a(1,2())', '[apply,a,[1,[apply,2,[]]]]');

   check(g, expression, '++a++', '[preinc,[postinc,a]]');
   check(g, expression, 'a++++b', null);
   check(g, expression, 'a++ ++b', null);
   check(g, expression, 'a+ +++b', '[add,a,[preinc,[uplus,b]]]');
   check(g, expression, 'a+ + ++b', '[add,a,[uplus,[preinc,b]]]');
   check(g, expression, 'a+ + + +b', '[add,a,[uplus,[uplus,[uplus,b]]]]');
   check(g, expression, 'a+ ++ +b', '[add,a,[preinc,[uplus,b]]]');
   check(g, expression, 'a++ + +b', '[add,[postinc,a],[uplus,b]]');
   check(g, expression, 'a+++ +b', '[add,[postinc,a],[uplus,b]]');

   check(g, expression, '((T)f)(x)', '[apply,[cast,T,f],[x]]');
   check(g, expression, '(T)f(x)', '[cast,T,[apply,f,[x]]]');

   check(g, expression, 'a++*++b', '[mult,[postinc,a],[preinc,b]]');

   check(g, expression, 'a<<1>>++b', '[shl,[shr,a,1],[preinc,b]]');

   check(g, expression, 'a<1&&b', '[and,[lt,a,1],b]');

   check(g, expression, 'a<1 & &b', '[bitand,[lt,a,1],[address,b]]');
   check(g, expression, 'a ? b ? c : d : e ? f : g',
       '[cond,a,[cond,b,c,d],[cond,e,f,g]]');

   check(g, expression, 'a,b,c', '[comma,[comma,a,b],c]');
   check(g, expression, 'a=1,b,c', '[comma,[comma,[assign,a,1],b],c]');

   check(g, expression, '((((((((((((a))))))))))))=1,b,c',
       '[comma,[comma,[assign,a,1],b],c]');

   check(g, expression, 'sizeof a', '[sizeof-expr,a]');
   check(g, expression, 'sizeofa', 'sizeofa');
   check(g, expression, 'sizeof (a)', '[sizeof-expr,a]');
 }

 show(grammar, rule, input) {
   print('show: "$input"');
   var ast;
   try {
     ast = grammar.parse(rule, input);
   } catch (exception) {
     if (exception is ParseError)
       ast = exception;
     else
       rethrow;
   }
   print('${printList(ast)}');
 }

 void check(grammar, rule, input, expected) {
   // If [expected] is String then the result is coerced to string.
   // If [expected] is !String, the result is compared directly.
   print('check: "$input"');
   var ast;
   try {
     ast = grammar.parse(rule, input);
   } catch (exception) {
     ast = exception;
   }

   var formatted = ast;
   if (expected is String) formatted = printList(ast);

   //Expect.equals(expected, formatted, "parse: $input");
   if (expected != formatted) {
     throw new ArgumentError("parse: $input"
         "\n  expected: $expected"
         "\n     found: $formatted");
   }
 }

 // Prints the list in [1,2,3] notation, including nested lists.
 printList(item) {
   if (item is List) {
     StringBuffer sb = new StringBuffer();
     sb.write('[');
     var sep = '';
     for (var x in item) {
       sb.write(sep);
       sb.write(printList(x));
       sep = ',';
     }
     sb.write(']');
     return sb.toString();
   }
   if (item == null) return 'null';
   return item.toString();
 }

 main() {
   testCODE();
   testParens();
   testOR();
   testTEXT();
   testBlockComment();
   testC();
 }
	// 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 peg_tests;

	import 'dart:core' hide Symbol;
	import '../../peg/pegparser.dart';

	testParens() {
	Grammar g = new Grammar();
	Symbol a = g['A'];

	a.def = ['(', MANY(a, min: 0), ')', (a) => a];

	check(g, a, "", null);
	check(g, a, "()", '[]');
	check(g, a, "(()())", '[[],[]]');
	check(g, a, "(()((()))())", '[[],[[[]]],[]]');
	}

	testBlockComment() {
	// Block comment in whitespace.

	Grammar g = new Grammar();
	Symbol blockComment = g['blockComment'];

	blockComment.def = [
	'/*',
	MANY(
	OR([
	blockComment,
	[NOT('*/'), CHAR()],
	[END, ERROR('EOF in block comment')]
	]),
	min: 0),
	'*/'
	];
	print(blockComment);

	var a = MANY(TEXT('x'));

	g.whitespace = OR([g.whitespace, blockComment]);

	check(g, a, "x /**/ x", '[x,x]');
	check(g, a, "x //// x", '[x,x]');
	check(g, a, "x //**/ x", 'EOF in block comment');
	check(g, a, "x ///x// x", '[x,x]');

	check(
	g,
	a,
	r"""
	/* Comment */
	/* Following comment with /* nested comment/ /
	x
	/* x in comment */
	x /* outside comment */
	""",
	'[x,x]');
	}

	testTEXT() {
	Grammar g = new Grammar();

	// TEXT grabs the parsed text,
	check(g, TEXT(LEX(MANY(OR(['1', 'a'])))), ' 1a1 ', '1a1');

	// Without the lexical context, TEXT will grab intervening whitespace.
	check(g, TEXT(MANY(OR(['1', 'a']))), ' 1a1 ', '1a1');
	check(g, TEXT(MANY(OR(['1', 'a']))), ' 1 a 1 ', '1 a 1');

	// Custom processing of the TEXT substring.
	var binaryNumber = TEXT(LEX(MANY(OR(['0', '1']))), (str, start, end) {
	var r = 0;
	var zero = '0'.codeUnitAt(0);
	for (int i = start; i < end; i++) r = r * 2 + (str.codeUnitAt(i) - zero);
	return r;
	});

	check(g, binaryNumber, ' 10101 ', 21);
	check(g, binaryNumber, '1010111', 87);
	check(g, binaryNumber, '1010 111', null);
	}

	testOR() {
	// OR matches the first match.
	Grammar g = new Grammar();
	check(
	g,
	OR([
	['a', NOT(END), () => 1],
	['a', () => 2],
	['a', () => 3]
	]),
	'a',
	2);
	}

	testCODE() {
	Grammar g = new Grammar();
	var a = TEXT(LEX('thing', MANY(CHAR('bcd'))));

	check(g, a, 'bbb', 'bbb');
	check(g, a, 'ccc', 'ccc');
	check(g, a, 'ddd', 'ddd');
	check(g, a, 'bad', null); // a is outside range.
	check(g, a, 'bed', null); // e is outside range.
	}

	testC() {
	// Curried tree builders.
	binary(operation) => (second) => (first) => [operation, first, second];
	unary(operation) => () => (first) => [operation, first];
	reform(a, fns) {
	var r = a;
	for (var fn in fns) r = fn(r);
	return r;
	}

	Grammar g = new Grammar();

	Symbol expression = g['expression'];
	Symbol postfix_e = g['postfix_e'];
	Symbol unary_e = g['unary_e'];
	Symbol cast_e = g['cast_e'];
	Symbol mult_e = g['mult_e'];
	Symbol add_e = g['add_e'];
	Symbol shift_e = g['shift_e'];
	Symbol relational_e = g['relational_e'];
	Symbol equality_e = g['equality_e'];
	Symbol cond_e = g['cond_e'];
	Symbol assignment_e = g['assignment_e'];

	// Lexical elements.
	var idStartChar =
	CHAR(r"ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz");
	var idNextChar =
	CHAR(r"ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789$_");

	var id = TEXT(LEX('identifier', [idStartChar, MANY(idNextChar, min: 0)]));

	var lit = TEXT(LEX('literal', MANY(CHAR('0123456789'))));

	var type_name = id;

	// Expression grammar.
	var primary_e = OR([
	id,
	lit,
	['(', expression, ')', (e) => e]
	]);

	var postfixes = OR([
	['(', MANY(assignment_e, separator: ',', min: 0), ')', binary('apply')],
	['++', unary('postinc')],
	['--', unary('postdec')],
	['.', id, binary('field')],
	['->', id, binary('ptr')],
	]);

	postfix_e.def = [primary_e, MANY(postfixes, min: 0), reform];

	var unary_op = OR([
	['&', () => 'address'],
	['*', () => 'indir'],
	['!', () => 'not'],
	['~', () => 'not'],
	['-', () => 'negate'],
	['+', () => 'uplus'],
	]);
	var sizeof = LEX('sizeof', ['sizeof', NOT(idNextChar)]);

	Symbol unary_e_plain = g['unary_e_plain'];
	unary_e_plain.def = OR([
	[
	'++', unary_e, (e) => ['preinc', e] //
	],
	[
	'--', unary_e, (e) => ['predec', e] //
	],
	[
	unary_op, cast_e, (o, e) => [o, e] //
	],
	[
	sizeof, unary_e, (e) => ['sizeof-expr', e] //
	],
	[
	sizeof, '(', type_name, ')', (t) => ['sizeof-type', t] //
	],
	postfix_e
	]);

	unary_e.def = MEMO(unary_e_plain);
	//unary_e.def = unary_e_plain;

	cast_e.def = OR([
	[
	'(', type_name, ')', cast_e, (t, e) => ['cast', t, e] //
	],
	unary_e,
	]);

	var mult_ops = OR([
	['*', cast_e, binary('mult')],
	['/', cast_e, binary('div')],
	['%', cast_e, binary('rem')],
	]);
	mult_e.def = [cast_e, MANY(mult_ops, min: 0), reform];

	var add_ops = OR([
	['+', mult_e, binary('add')],
	['-', mult_e, binary('sub')],
	]);
	add_e.def = [mult_e, MANY(add_ops, min: 0), reform];

	var shift_ops = OR([
	['>>', add_e, binary('shl')],
	['<<', add_e, binary('shr')],
	]);
	shift_e.def = [add_e, MANY(shift_ops, min: 0), reform];

	var relational_ops = OR([
	['<=', shift_e, binary('le')],
	['>=', shift_e, binary('ge')],
	['<', shift_e, binary('lt')],
	['>', shift_e, binary('gt')],
	]);
	relational_e.def = [shift_e, MANY(relational_ops, min: 0), reform];

	var equality_ops = OR([
	['==', shift_e, binary('eq')],
	['!=', shift_e, binary('ne')],
	]);
	equality_e.def = [relational_e, MANY(equality_ops, min: 0), reform];

	var bit_and_op = LEX('&', ['&', NOT('&')]); // Don't see '&&' and '&', '&'
	var bit_or_op = LEX('\|', ['\|', NOT('\|')]);

	var and_e = [
	equality_e,
	MANY([bit_and_op, equality_e, binary('bitand')], min: 0),
	reform
	];
	var xor_e = [
	and_e,
	MANY(['^', and_e, binary('bitxor')], min: 0),
	reform
	];
	var or_e = [
	xor_e,
	MANY([bit_or_op, xor_e, binary('bitor')], min: 0),
	reform
	];

	var log_and_e = [
	or_e,
	MANY(['&&', or_e, binary('and')], min: 0),
	reform
	];

	var log_or_e = [
	log_and_e,
	MANY(['\|\|', log_and_e, binary('or')], min: 0),
	reform
	];

	//cond_e.def = OR([ [log_or_e, '?', expression, ':', cond_e,
	// (p,a,b) => ['cond', p, a, b]],
	// log_or_e]);
	// Alternate version avoids reparsing log_or_e.
	cond_e.def = [
	log_or_e,
	MAYBE(['?', expression, ':', cond_e]),
	(p, r) => r == null \|\| r == false ? p : ['cond', p, r[0], r[1]]
	];

	var assign_op = OR([
	['*=', () => 'mulassign'],
	['=', () => 'assign']
	]);

	// TODO: Figure out how not to re-parse a unary_e.
	// Order matters - cond_e can't go first since cond_e will succeed on, e.g. 'a'.
	assignment_e.def = OR([
	[
	unary_e,
	assign_op,
	assignment_e,
	(u, op, a) => [op, u, a]
	],
	cond_e
	]);

	expression.def = [
	assignment_e,
	MANY([',', assignment_e, binary('comma')], min: 0),
	reform
	];

	show(g, expression, 'a');
	check(g, expression, 'a', 'a');
	check(g, expression, '(a)', 'a');
	check(g, expression, ' ( ( a ) ) ', 'a');

	check(g, expression, 'a(~1,2)', '[apply,a,[[not,1],2]]');
	check(g, expression, 'a(1)(x,2)', '[apply,[apply,a,[1]],[x,2]]');
	check(g, expression, 'a(1,2())', '[apply,a,[1,[apply,2,[]]]]');

	check(g, expression, '++a++', '[preinc,[postinc,a]]');
	check(g, expression, 'a++++b', null);
	check(g, expression, 'a++ ++b', null);
	check(g, expression, 'a+ +++b', '[add,a,[preinc,[uplus,b]]]');
	check(g, expression, 'a+ + ++b', '[add,a,[uplus,[preinc,b]]]');
	check(g, expression, 'a+ + + +b', '[add,a,[uplus,[uplus,[uplus,b]]]]');
	check(g, expression, 'a+ ++ +b', '[add,a,[preinc,[uplus,b]]]');
	check(g, expression, 'a++ + +b', '[add,[postinc,a],[uplus,b]]');
	check(g, expression, 'a+++ +b', '[add,[postinc,a],[uplus,b]]');

	check(g, expression, '((T)f)(x)', '[apply,[cast,T,f],[x]]');
	check(g, expression, '(T)f(x)', '[cast,T,[apply,f,[x]]]');

	check(g, expression, 'a++*++b', '[mult,[postinc,a],[preinc,b]]');

	check(g, expression, 'a<<1>>++b', '[shl,[shr,a,1],[preinc,b]]');

	check(g, expression, 'a<1&&b', '[and,[lt,a,1],b]');

	check(g, expression, 'a<1 & &b', '[bitand,[lt,a,1],[address,b]]');
	check(g, expression, 'a ? b ? c : d : e ? f : g',
	'[cond,a,[cond,b,c,d],[cond,e,f,g]]');

	check(g, expression, 'a,b,c', '[comma,[comma,a,b],c]');
	check(g, expression, 'a=1,b,c', '[comma,[comma,[assign,a,1],b],c]');

	check(g, expression, '((((((((((((a))))))))))))=1,b,c',
	'[comma,[comma,[assign,a,1],b],c]');

	check(g, expression, 'sizeof a', '[sizeof-expr,a]');
	check(g, expression, 'sizeofa', 'sizeofa');
	check(g, expression, 'sizeof (a)', '[sizeof-expr,a]');
	}

	show(grammar, rule, input) {
	print('show: "$input"');
	var ast;
	try {
	ast = grammar.parse(rule, input);
	} catch (exception) {
	if (exception is ParseError)
	ast = exception;
	else
	rethrow;
	}
	print('${printList(ast)}');
	}

	void check(grammar, rule, input, expected) {
	// If [expected] is String then the result is coerced to string.
	// If [expected] is !String, the result is compared directly.
	print('check: "$input"');
	var ast;
	try {
	ast = grammar.parse(rule, input);
	} catch (exception) {
	ast = exception;
	}

	var formatted = ast;
	if (expected is String) formatted = printList(ast);

	//Expect.equals(expected, formatted, "parse: $input");
	if (expected != formatted) {
	throw new ArgumentError("parse: $input"
	"\n expected: $expected"
	"\n found: $formatted");
	}
	}

	// Prints the list in [1,2,3] notation, including nested lists.
	printList(item) {
	if (item is List) {
	StringBuffer sb = new StringBuffer();
	sb.write('[');
	var sep = '';
	for (var x in item) {
	sb.write(sep);
	sb.write(printList(x));
	sep = ',';
	}
	sb.write(']');
	return sb.toString();
	}
	if (item == null) return 'null';
	return item.toString();
	}

	main() {
	testCODE();
	testParens();
	testOR();
	testTEXT();
	testBlockComment();
	testC();
	}