Mercurial > lcfOS
view test/testpyy.py @ 389:2ec730e45ea1
Added check for recursive struct
author | Windel Bouwman |
---|---|
date | Fri, 16 May 2014 12:29:31 +0200 |
parents | 4d204f6f7d4e |
children | fb3c1f029b30 |
line wrap: on
line source
import unittest from pyyacc import Grammar, Item, ParserGenerationException, ParserException from pyyacc import EPS, EOF, calculate_first_sets from ppci import Token class genTokens: def __init__(self, lst): def tokGen(): for t in lst: yield Token(t, t) while True: yield Token(EOF, EOF) self.tokens = tokGen() self.token = self.tokens.__next__() def next_token(self): t = self.token if t.typ != EOF: self.token = self.tokens.__next__() return t class testLR(unittest.TestCase): """ Test basic LR(1) parser generator constructs """ def testSimpleGrammar(self): # 1. define a simple grammar: g = Grammar(['identifier', '(', ')', '+', '*']) g.add_production('input', ['expression']) g.add_production('expression', ['term']) g.add_production('expression', ['expression', '+', 'term']) g.add_production('term', ['factor']) g.add_production('term', ['term', '*', 'factor']) g.add_production('factor', ['(', 'expression', ')']) g.add_production('factor', ['identifier']) g.start_symbol = 'input' # 2. define input: tokens = genTokens(['identifier', '+', 'identifier', '+', 'identifier']) # 3. build parser: p = g.generate_parser() # 4. feed input: p.parse(tokens) def testReduceReduceConflict(self): """ Check if a reduce-reduce conflict is detected """ # Define a grammar with an obvious reduce-reduce conflict: g = Grammar(['id']) g.add_production('goal', ['a']) g.add_production('a', ['b']) g.add_production('a', ['c']) g.add_production('b', ['id']) g.add_production('c', ['id']) g.start_symbol = 'goal' with self.assertRaises(ParserGenerationException): p = g.generate_parser() def testShiftReduceConflict(self): """ Must be handled automatically by doing shift """ g = Grammar([EOF, 'if', 'then', 'else', 'ass']) # Ambiguous grammar: g.add_production('if_stmt', ['if', 'then', 'stmt']) g.add_production('if_stmt', ['if', 'then', 'stmt', 'else', 'stmt']) g.add_production('stmt', ['if_stmt']) g.add_production('stmt', ['ass']) g.start_symbol = 'stmt' p = g.generate_parser() # Ambiguous program: tokens = genTokens(['if', 'then','if', 'then', 'ass', 'else', 'ass']) p.parse(tokens) def testUndefinedTerminal(self): """ Test correct behavior when a terminal is undefined """ g = Grammar(['b']) g.add_production('goal', ['a']) g.add_production('a', ['b']) g.add_production('a', ['c']) g.start_symbol = 'goal' with self.assertRaises(ParserGenerationException): g.generate_parser() def testRedefineTerminal(self): """ Test correct behavior when a terminal is redefined """ g = Grammar([EOF, 'b', 'c']) g.add_production('goal', ['a']) with self.assertRaises(ParserGenerationException): g.add_production('b', ['c']) # Not allowed g.add_production('a', ['c']) g.start_symbol = 'goal' g.generate_parser() def testEmpty(self): """ Test empty token stream """ g = Grammar([',']) g.add_production('input', [',']) g.start_symbol = 'input' p = g.generate_parser() tokens = genTokens([]) with self.assertRaises(ParserException): p.parse(tokens) def testEps(self): """ Test epsilon terminal """ g = Grammar(['a', 'b']) g.add_production('input', ['optional_a', 'b']) g.add_production('optional_a', ['a']) g.add_production('optional_a', []) g.start_symbol = 'input' p = g.generate_parser() tokens = genTokens(['b']) p.parse(tokens) def testEps2(self): g = Grammar(['id', ':']) g.add_production('input', ['opt_lab', 'ins', 'op1']) g.add_production('input', ['ins', 'op1']) g.add_production('opt_lab', ['id', ':']) g.add_production('ins', ['id']) g.add_production('op1', ['id']) g.start_symbol = 'input' p = g.generate_parser() tokens = genTokens(['id', ':', 'id', 'id']) # i.e. "lab_0: inc rax" p.parse(tokens) tokens = genTokens(['id', 'id']) # i.e. "inc rax" p.parse(tokens) def testEpsSequence(self): """ Test epsilon terminal for use in sequences """ g = Grammar(['a']) g.add_production('aas', []) g.add_production('aas', ['aas', 'a']) g.start_symbol = 'aas' p = g.generate_parser() tokens = genTokens(['a', 'a', 'a']) p.parse(tokens) tokens = genTokens([]) p.parse(tokens) def test_cb(self): """ Test callback of one rule and order or parameters """ self.cb_called = False def cb(a, c, b): self.cb_called = True self.assertEqual(a.val, 'a') self.assertEqual(b.val, 'b') self.assertEqual(c.val, 'c') g = Grammar(['a', 'b', 'c']) g.add_production('goal', ['a', 'c', 'b'], cb) g.start_symbol = 'goal' p = g.generate_parser() tokens = genTokens(['a', 'c', 'b']) p.parse(tokens) self.assertTrue(self.cb_called) class testExpressionGrammar(unittest.TestCase): def setUp(self): g = Grammar(['EOF', 'identifier', '(', ')', '+', '*', 'num']) g.add_production('input', ['expression']) g.add_production('expression', ['term']) g.add_production('expression', ['expression', '+', 'term']) g.add_production('term', ['factor']) g.add_production('term', ['term', '*', 'factor']) g.add_production('factor', ['(', 'expression', ')']) g.add_production('factor', ['identifier']) g.add_production('factor', ['num']) g.start_symbol = 'input' self.g = g def testFirstSimpleGrammar(self): # 1. define a simple grammar: first = calculate_first_sets(self.g) self.assertEqual(first['input'], {'identifier', '(', 'num'}) self.assertEqual(first['term'], {'identifier', '(', 'num'}) def testCanonical(self): s0 = self.g.initialItemSet() s, gt = self.g.genCanonicalSet(s0) # Must result in 12 sets: self.assertEqual(len(s), 24) class testParserGenerator(unittest.TestCase): """ Tests several parts of the parser generator """ def setUp(self): g = Grammar(['(', ')']) g.add_production('goal', ['list']) g.add_production('list', ['list', 'pair']) g.add_production('list', ['pair']) g.add_production('pair', ['(', 'pair', ')']) g.add_production('pair', ['(', ')']) g.start_symbol = 'goal' self.g = g def testFirstSet(self): for a in ['(', ')', EOF, 'EPS']: self.assertEqual(self.g.first[a], {a}) for nt in ['list', 'pair', 'goal']: self.assertEqual(self.g.first[nt], {'('}) def testInitItemSet(self): p0, p1, p2, p3, p4 = self.g.productions s0 = self.g.initialItemSet() self.assertEqual(len(s0), 9) # 9 with the goal rule included! self.assertIn(Item(p0, 0, EOF), s0) self.assertIn(Item(p1, 0, EOF), s0) self.assertIn(Item(p1, 0, '('), s0) self.assertIn(Item(p2, 0, EOF), s0) self.assertIn(Item(p2, 0, '('), s0) self.assertIn(Item(p3, 0, EOF), s0) self.assertIn(Item(p3, 0, '('), s0) self.assertIn(Item(p4, 0, EOF), s0) self.assertIn(Item(p4, 0, '('), s0) def testCanonical(self): s0 = self.g.initialItemSet() s, gt = self.g.genCanonicalSet(s0) # Must result in 12 sets: self.assertEqual(len(s), 12) def testClosure(self): p0, p1, p2, p3, p4 = self.g.productions s0 = set() s0.add(Item(p0, 0, EOF)) self.assertEqual(len(s0), 1) # 1 rule self.assertIn(Item(p0, 0, EOF), s0) # Invoke closure on set: s0 = self.g.closure(s0) self.assertIn(Item(p0, 0, EOF), s0) self.assertIn(Item(p1, 0, EOF), s0) self.assertIn(Item(p1, 0, '('), s0) self.assertIn(Item(p2, 0, EOF), s0) self.assertIn(Item(p2, 0, '('), s0) self.assertIn(Item(p3, 0, EOF), s0) self.assertIn(Item(p3, 0, '('), s0) self.assertIn(Item(p4, 0, EOF), s0) self.assertIn(Item(p4, 0, '('), s0) def testParser(self): tokens = ['(', '(', ')', ')', '(', ')'] # 3. build parser: p = self.g.generate_parser() self.assertEqual(len(p.goto_table), 5) self.assertEqual(len(p.action_table), 19) # 4. feed input: p.parse(genTokens(tokens)) if __name__ == '__main__': unittest.main()