from test.test_support import verbose, run_unittest, import_module from test.test_support import precisionbigmemtest, _2G import re from re import Scanner import sys import string import traceback from weakref import proxy # Misc tests from Tim Peters' re.doc # WARNING: Don't change details in these tests if you don't know # what you're doing. Some of these tests were carefully modeled to # cover most of the code. import unittest class ReTests(unittest.TestCase): def test_weakref(self): s = 'QabbbcR' x = re.compile('ab+c') y = proxy(x) self.assertEqual(x.findall('QabbbcR'), y.findall('QabbbcR')) def test_search_star_plus(self): self.assertEqual(re.search('x*', 'axx').span(0), (0, 0)) self.assertEqual(re.search('x*', 'axx').span(), (0, 0)) self.assertEqual(re.search('x+', 'axx').span(0), (1, 3)) self.assertEqual(re.search('x+', 'axx').span(), (1, 3)) self.assertEqual(re.search('x', 'aaa'), None) self.assertEqual(re.match('a*', 'xxx').span(0), (0, 0)) self.assertEqual(re.match('a*', 'xxx').span(), (0, 0)) self.assertEqual(re.match('x*', 'xxxa').span(0), (0, 3)) self.assertEqual(re.match('x*', 'xxxa').span(), (0, 3)) self.assertEqual(re.match('a+', 'xxx'), None) def bump_num(self, matchobj): int_value = int(matchobj.group(0)) return str(int_value + 1) def test_basic_re_sub(self): self.assertEqual(re.sub("(?i)b+", "x", "bbbb BBBB"), 'x x') self.assertEqual(re.sub(r'\d+', self.bump_num, '08.2 -2 23x99y'), '9.3 -3 24x100y') self.assertEqual(re.sub(r'\d+', self.bump_num, '08.2 -2 23x99y', 3), '9.3 -3 23x99y') self.assertEqual(re.sub('.', lambda m: r"\n", 'x'), '\\n') self.assertEqual(re.sub('.', r"\n", 'x'), '\n') s = r"\1\1" self.assertEqual(re.sub('(.)', s, 'x'), 'xx') self.assertEqual(re.sub('(.)', re.escape(s), 'x'), s) self.assertEqual(re.sub('(.)', lambda m: s, 'x'), s) self.assertEqual(re.sub('(?Px)', '\g\g', 'xx'), 'xxxx') self.assertEqual(re.sub('(?Px)', '\g\g<1>', 'xx'), 'xxxx') self.assertEqual(re.sub('(?Px)', '\g\g', 'xx'), 'xxxx') self.assertEqual(re.sub('(?Px)', '\g<1>\g<1>', 'xx'), 'xxxx') self.assertEqual(re.sub('a',r'\t\n\v\r\f\a\b\B\Z\a\A\w\W\s\S\d\D','a'), '\t\n\v\r\f\a\b\\B\\Z\a\\A\\w\\W\\s\\S\\d\\D') self.assertEqual(re.sub('a', '\t\n\v\r\f\a', 'a'), '\t\n\v\r\f\a') self.assertEqual(re.sub('a', '\t\n\v\r\f\a', 'a'), (chr(9)+chr(10)+chr(11)+chr(13)+chr(12)+chr(7))) self.assertEqual(re.sub('^\s*', 'X', 'test'), 'Xtest') def test_bug_449964(self): # fails for group followed by other escape self.assertEqual(re.sub(r'(?Px)', '\g<1>\g<1>\\b', 'xx'), 'xx\bxx\b') def test_bug_449000(self): # Test for sub() on escaped characters self.assertEqual(re.sub(r'\r\n', r'\n', 'abc\r\ndef\r\n'), 'abc\ndef\n') self.assertEqual(re.sub('\r\n', r'\n', 'abc\r\ndef\r\n'), 'abc\ndef\n') self.assertEqual(re.sub(r'\r\n', '\n', 'abc\r\ndef\r\n'), 'abc\ndef\n') self.assertEqual(re.sub('\r\n', '\n', 'abc\r\ndef\r\n'), 'abc\ndef\n') def test_bug_1140(self): # re.sub(x, y, u'') should return u'', not '', and # re.sub(x, y, '') should return '', not u''. # Also: # re.sub(x, y, unicode(x)) should return unicode(y), and # re.sub(x, y, str(x)) should return # str(y) if isinstance(y, str) else unicode(y). for x in 'x', u'x': for y in 'y', u'y': z = re.sub(x, y, u'') self.assertEqual(z, u'') self.assertEqual(type(z), unicode) # z = re.sub(x, y, '') self.assertEqual(z, '') self.assertEqual(type(z), str) # z = re.sub(x, y, unicode(x)) self.assertEqual(z, y) self.assertEqual(type(z), unicode) # z = re.sub(x, y, str(x)) self.assertEqual(z, y) self.assertEqual(type(z), type(y)) def test_bug_1661(self): # Verify that flags do not get silently ignored with compiled patterns pattern = re.compile('.') self.assertRaises(ValueError, re.match, pattern, 'A', re.I) self.assertRaises(ValueError, re.search, pattern, 'A', re.I) self.assertRaises(ValueError, re.findall, pattern, 'A', re.I) self.assertRaises(ValueError, re.compile, pattern, re.I) def test_bug_3629(self): # A regex that triggered a bug in the sre-code validator re.compile("(?P)(?(quote))") def test_sub_template_numeric_escape(self): # bug 776311 and friends self.assertEqual(re.sub('x', r'\0', 'x'), '\0') self.assertEqual(re.sub('x', r'\000', 'x'), '\000') self.assertEqual(re.sub('x', r'\001', 'x'), '\001') self.assertEqual(re.sub('x', r'\008', 'x'), '\0' + '8') self.assertEqual(re.sub('x', r'\009', 'x'), '\0' + '9') self.assertEqual(re.sub('x', r'\111', 'x'), '\111') self.assertEqual(re.sub('x', r'\117', 'x'), '\117') self.assertEqual(re.sub('x', r'\1111', 'x'), '\1111') self.assertEqual(re.sub('x', r'\1111', 'x'), '\111' + '1') self.assertEqual(re.sub('x', r'\00', 'x'), '\x00') self.assertEqual(re.sub('x', r'\07', 'x'), '\x07') self.assertEqual(re.sub('x', r'\08', 'x'), '\0' + '8') self.assertEqual(re.sub('x', r'\09', 'x'), '\0' + '9') self.assertEqual(re.sub('x', r'\0a', 'x'), '\0' + 'a') self.assertEqual(re.sub('x', r'\400', 'x'), '\0') self.assertEqual(re.sub('x', r'\777', 'x'), '\377') self.assertRaises(re.error, re.sub, 'x', r'\1', 'x') self.assertRaises(re.error, re.sub, 'x', r'\8', 'x') self.assertRaises(re.error, re.sub, 'x', r'\9', 'x') self.assertRaises(re.error, re.sub, 'x', r'\11', 'x') self.assertRaises(re.error, re.sub, 'x', r'\18', 'x') self.assertRaises(re.error, re.sub, 'x', r'\1a', 'x') self.assertRaises(re.error, re.sub, 'x', r'\90', 'x') self.assertRaises(re.error, re.sub, 'x', r'\99', 'x') self.assertRaises(re.error, re.sub, 'x', r'\118', 'x') # r'\11' + '8' self.assertRaises(re.error, re.sub, 'x', r'\11a', 'x') self.assertRaises(re.error, re.sub, 'x', r'\181', 'x') # r'\18' + '1' self.assertRaises(re.error, re.sub, 'x', r'\800', 'x') # r'\80' + '0' # in python2.3 (etc), these loop endlessly in sre_parser.py self.assertEqual(re.sub('(((((((((((x)))))))))))', r'\11', 'x'), 'x') self.assertEqual(re.sub('((((((((((y))))))))))(.)', r'\118', 'xyz'), 'xz8') self.assertEqual(re.sub('((((((((((y))))))))))(.)', r'\11a', 'xyz'), 'xza') def test_qualified_re_sub(self): self.assertEqual(re.sub('a', 'b', 'aaaaa'), 'bbbbb') self.assertEqual(re.sub('a', 'b', 'aaaaa', 1), 'baaaa') def test_bug_114660(self): self.assertEqual(re.sub(r'(\S)\s+(\S)', r'\1 \2', 'hello there'), 'hello there') def test_bug_462270(self): # Test for empty sub() behaviour, see SF bug #462270 self.assertEqual(re.sub('x*', '-', 'abxd'), '-a-b-d-') self.assertEqual(re.sub('x+', '-', 'abxd'), 'ab-d') def test_symbolic_groups(self): re.compile('(?Px)(?P=a)(?(a)y)') re.compile('(?Px)(?P=a1)(?(a1)y)') self.assertRaises(re.error, re.compile, '(?P)(?P)') self.assertRaises(re.error, re.compile, '(?Px)') self.assertRaises(re.error, re.compile, '(?P=)') self.assertRaises(re.error, re.compile, '(?P=1)') self.assertRaises(re.error, re.compile, '(?P=a)') self.assertRaises(re.error, re.compile, '(?P=a1)') self.assertRaises(re.error, re.compile, '(?P=a.)') self.assertRaises(re.error, re.compile, '(?P<)') self.assertRaises(re.error, re.compile, '(?P<>)') self.assertRaises(re.error, re.compile, '(?P<1>)') self.assertRaises(re.error, re.compile, '(?P)') self.assertRaises(re.error, re.compile, '(?())') self.assertRaises(re.error, re.compile, '(?(a))') self.assertRaises(re.error, re.compile, '(?(1a))') self.assertRaises(re.error, re.compile, '(?(a.))') def test_symbolic_refs(self): self.assertRaises(re.error, re.sub, '(?Px)', '\gx)', '\g<', 'xx') self.assertRaises(re.error, re.sub, '(?Px)', '\g', 'xx') self.assertRaises(re.error, re.sub, '(?Px)', '\g', 'xx') self.assertRaises(re.error, re.sub, '(?Px)', '\g<>', 'xx') self.assertRaises(re.error, re.sub, '(?Px)', '\g<1a1>', 'xx') self.assertRaises(IndexError, re.sub, '(?Px)', '\g', 'xx') self.assertRaises(re.error, re.sub, '(?Px)|(?Py)', '\g', 'xx') self.assertRaises(re.error, re.sub, '(?Px)|(?Py)', '\\2', 'xx') self.assertRaises(re.error, re.sub, '(?Px)', '\g<-1>', 'xx') def test_re_subn(self): self.assertEqual(re.subn("(?i)b+", "x", "bbbb BBBB"), ('x x', 2)) self.assertEqual(re.subn("b+", "x", "bbbb BBBB"), ('x BBBB', 1)) self.assertEqual(re.subn("b+", "x", "xyz"), ('xyz', 0)) self.assertEqual(re.subn("b*", "x", "xyz"), ('xxxyxzx', 4)) self.assertEqual(re.subn("b*", "x", "xyz", 2), ('xxxyz', 2)) def test_re_split(self): self.assertEqual(re.split(":", ":a:b::c"), ['', 'a', 'b', '', 'c']) self.assertEqual(re.split(":*", ":a:b::c"), ['', 'a', 'b', 'c']) self.assertEqual(re.split("(:*)", ":a:b::c"), ['', ':', 'a', ':', 'b', '::', 'c']) self.assertEqual(re.split("(?::*)", ":a:b::c"), ['', 'a', 'b', 'c']) self.assertEqual(re.split("(:)*", ":a:b::c"), ['', ':', 'a', ':', 'b', ':', 'c']) self.assertEqual(re.split("([b:]+)", ":a:b::c"), ['', ':', 'a', ':b::', 'c']) self.assertEqual(re.split("(b)|(:+)", ":a:b::c"), ['', None, ':', 'a', None, ':', '', 'b', None, '', None, '::', 'c']) self.assertEqual(re.split("(?:b)|(?::+)", ":a:b::c"), ['', 'a', '', '', 'c']) def test_qualified_re_split(self): self.assertEqual(re.split(":", ":a:b::c", 2), ['', 'a', 'b::c']) self.assertEqual(re.split(':', 'a:b:c:d', 2), ['a', 'b', 'c:d']) self.assertEqual(re.split("(:)", ":a:b::c", 2), ['', ':', 'a', ':', 'b::c']) self.assertEqual(re.split("(:*)", ":a:b::c", 2), ['', ':', 'a', ':', 'b::c']) def test_re_findall(self): self.assertEqual(re.findall(":+", "abc"), []) self.assertEqual(re.findall(":+", "a:b::c:::d"), [":", "::", ":::"]) self.assertEqual(re.findall("(:+)", "a:b::c:::d"), [":", "::", ":::"]) self.assertEqual(re.findall("(:)(:*)", "a:b::c:::d"), [(":", ""), (":", ":"), (":", "::")]) def test_bug_117612(self): self.assertEqual(re.findall(r"(a|(b))", "aba"), [("a", ""),("b", "b"),("a", "")]) def test_re_match(self): self.assertEqual(re.match('a', 'a').groups(), ()) self.assertEqual(re.match('(a)', 'a').groups(), ('a',)) self.assertEqual(re.match(r'(a)', 'a').group(0), 'a') self.assertEqual(re.match(r'(a)', 'a').group(1), 'a') self.assertEqual(re.match(r'(a)', 'a').group(1, 1), ('a', 'a')) pat = re.compile('((a)|(b))(c)?') self.assertEqual(pat.match('a').groups(), ('a', 'a', None, None)) self.assertEqual(pat.match('b').groups(), ('b', None, 'b', None)) self.assertEqual(pat.match('ac').groups(), ('a', 'a', None, 'c')) self.assertEqual(pat.match('bc').groups(), ('b', None, 'b', 'c')) self.assertEqual(pat.match('bc').groups(""), ('b', "", 'b', 'c')) # A single group m = re.match('(a)', 'a') self.assertEqual(m.group(0), 'a') self.assertEqual(m.group(0), 'a') self.assertEqual(m.group(1), 'a') self.assertEqual(m.group(1, 1), ('a', 'a')) pat = re.compile('(?:(?Pa)|(?Pb))(?Pc)?') self.assertEqual(pat.match('a').group(1, 2, 3), ('a', None, None)) self.assertEqual(pat.match('b').group('a1', 'b2', 'c3'), (None, 'b', None)) self.assertEqual(pat.match('ac').group(1, 'b2', 3), ('a', None, 'c')) def test_re_groupref_exists(self): self.assertEqual(re.match('^(\()?([^()]+)(?(1)\))$', '(a)').groups(), ('(', 'a')) self.assertEqual(re.match('^(\()?([^()]+)(?(1)\))$', 'a').groups(), (None, 'a')) self.assertEqual(re.match('^(\()?([^()]+)(?(1)\))$', 'a)'), None) self.assertEqual(re.match('^(\()?([^()]+)(?(1)\))$', '(a'), None) self.assertEqual(re.match('^(?:(a)|c)((?(1)b|d))$', 'ab').groups(), ('a', 'b')) self.assertEqual(re.match('^(?:(a)|c)((?(1)b|d))$', 'cd').groups(), (None, 'd')) self.assertEqual(re.match('^(?:(a)|c)((?(1)|d))$', 'cd').groups(), (None, 'd')) self.assertEqual(re.match('^(?:(a)|c)((?(1)|d))$', 'a').groups(), ('a', '')) # Tests for bug #1177831: exercise groups other than the first group p = re.compile('(?Pa)(?Pb)?((?(g2)c|d))') self.assertEqual(p.match('abc').groups(), ('a', 'b', 'c')) self.assertEqual(p.match('ad').groups(), ('a', None, 'd')) self.assertEqual(p.match('abd'), None) self.assertEqual(p.match('ac'), None) def test_re_groupref(self): self.assertEqual(re.match(r'^(\|)?([^()]+)\1$', '|a|').groups(), ('|', 'a')) self.assertEqual(re.match(r'^(\|)?([^()]+)\1?$', 'a').groups(), (None, 'a')) self.assertEqual(re.match(r'^(\|)?([^()]+)\1$', 'a|'), None) self.assertEqual(re.match(r'^(\|)?([^()]+)\1$', '|a'), None) self.assertEqual(re.match(r'^(?:(a)|c)(\1)$', 'aa').groups(), ('a', 'a')) self.assertEqual(re.match(r'^(?:(a)|c)(\1)?$', 'c').groups(), (None, None)) def test_groupdict(self): self.assertEqual(re.match('(?Pfirst) (?Psecond)', 'first second').groupdict(), {'first':'first', 'second':'second'}) def test_expand(self): self.assertEqual(re.match("(?Pfirst) (?Psecond)", "first second") .expand(r"\2 \1 \g \g"), "second first second first") def test_repeat_minmax(self): self.assertEqual(re.match("^(\w){1}$", "abc"), None) self.assertEqual(re.match("^(\w){1}?$", "abc"), None) self.assertEqual(re.match("^(\w){1,2}$", "abc"), None) self.assertEqual(re.match("^(\w){1,2}?$", "abc"), None) self.assertEqual(re.match("^(\w){3}$", "abc").group(1), "c") self.assertEqual(re.match("^(\w){1,3}$", "abc").group(1), "c") self.assertEqual(re.match("^(\w){1,4}$", "abc").group(1), "c") self.assertEqual(re.match("^(\w){3,4}?$", "abc").group(1), "c") self.assertEqual(re.match("^(\w){3}?$", "abc").group(1), "c") self.assertEqual(re.match("^(\w){1,3}?$", "abc").group(1), "c") self.assertEqual(re.match("^(\w){1,4}?$", "abc").group(1), "c") self.assertEqual(re.match("^(\w){3,4}?$", "abc").group(1), "c") self.assertEqual(re.match("^x{1}$", "xxx"), None) self.assertEqual(re.match("^x{1}?$", "xxx"), None) self.assertEqual(re.match("^x{1,2}$", "xxx"), None) self.assertEqual(re.match("^x{1,2}?$", "xxx"), None) self.assertNotEqual(re.match("^x{3}$", "xxx"), None) self.assertNotEqual(re.match("^x{1,3}$", "xxx"), None) self.assertNotEqual(re.match("^x{1,4}$", "xxx"), None) self.assertNotEqual(re.match("^x{3,4}?$", "xxx"), None) self.assertNotEqual(re.match("^x{3}?$", "xxx"), None) self.assertNotEqual(re.match("^x{1,3}?$", "xxx"), None) self.assertNotEqual(re.match("^x{1,4}?$", "xxx"), None) self.assertNotEqual(re.match("^x{3,4}?$", "xxx"), None) self.assertEqual(re.match("^x{}$", "xxx"), None) self.assertNotEqual(re.match("^x{}$", "x{}"), None) def test_getattr(self): self.assertEqual(re.match("(a)", "a").pos, 0) self.assertEqual(re.match("(a)", "a").endpos, 1) self.assertEqual(re.match("(a)", "a").string, "a") self.assertEqual(re.match("(a)", "a").regs, ((0, 1), (0, 1))) self.assertNotEqual(re.match("(a)", "a").re, None) def test_special_escapes(self): self.assertEqual(re.search(r"\b(b.)\b", "abcd abc bcd bx").group(1), "bx") self.assertEqual(re.search(r"\B(b.)\B", "abc bcd bc abxd").group(1), "bx") self.assertEqual(re.search(r"\b(b.)\b", "abcd abc bcd bx", re.LOCALE).group(1), "bx") self.assertEqual(re.search(r"\B(b.)\B", "abc bcd bc abxd", re.LOCALE).group(1), "bx") self.assertEqual(re.search(r"\b(b.)\b", "abcd abc bcd bx", re.UNICODE).group(1), "bx") self.assertEqual(re.search(r"\B(b.)\B", "abc bcd bc abxd", re.UNICODE).group(1), "bx") self.assertEqual(re.search(r"^abc$", "\nabc\n", re.M).group(0), "abc") self.assertEqual(re.search(r"^\Aabc\Z$", "abc", re.M).group(0), "abc") self.assertEqual(re.search(r"^\Aabc\Z$", "\nabc\n", re.M), None) self.assertEqual(re.search(r"\b(b.)\b", u"abcd abc bcd bx").group(1), "bx") self.assertEqual(re.search(r"\B(b.)\B", u"abc bcd bc abxd").group(1), "bx") self.assertEqual(re.search(r"^abc$", u"\nabc\n", re.M).group(0), "abc") self.assertEqual(re.search(r"^\Aabc\Z$", u"abc", re.M).group(0), "abc") self.assertEqual(re.search(r"^\Aabc\Z$", u"\nabc\n", re.M), None) self.assertEqual(re.search(r"\d\D\w\W\s\S", "1aa! a").group(0), "1aa! a") self.assertEqual(re.search(r"\d\D\w\W\s\S", "1aa! a", re.LOCALE).group(0), "1aa! a") self.assertEqual(re.search(r"\d\D\w\W\s\S", "1aa! a", re.UNICODE).group(0), "1aa! a") def test_string_boundaries(self): # See http://bugs.python.org/issue10713 self.assertEqual(re.search(r"\b(abc)\b", "abc").group(1), "abc") # There's a word boundary at the start of a string. self.assertTrue(re.match(r"\b", "abc")) # A non-empty string includes a non-boundary zero-length match. self.assertTrue(re.search(r"\B", "abc")) # There is no non-boundary match at the start of a string. self.assertFalse(re.match(r"\B", "abc")) # However, an empty string contains no word boundaries, and also no # non-boundaries. self.assertEqual(re.search(r"\B", ""), None) # This one is questionable and different from the perlre behaviour, # but describes current behavior. self.assertEqual(re.search(r"\b", ""), None) # A single word-character string has two boundaries, but no # non-boundary gaps. self.assertEqual(len(re.findall(r"\b", "a")), 2) self.assertEqual(len(re.findall(r"\B", "a")), 0) # If there are no words, there are no boundaries self.assertEqual(len(re.findall(r"\b", " ")), 0) self.assertEqual(len(re.findall(r"\b", " ")), 0) # Can match around the whitespace. self.assertEqual(len(re.findall(r"\B", " ")), 2) def test_bigcharset(self): self.assertEqual(re.match(u"([\u2222\u2223])", u"\u2222").group(1), u"\u2222") self.assertEqual(re.match(u"([\u2222\u2223])", u"\u2222", re.UNICODE).group(1), u"\u2222") def test_big_codesize(self): # Issue #1160 r = re.compile('|'.join(('%d'%x for x in range(10000)))) self.assertIsNotNone(r.match('1000')) self.assertIsNotNone(r.match('9999')) def test_anyall(self): self.assertEqual(re.match("a.b", "a\nb", re.DOTALL).group(0), "a\nb") self.assertEqual(re.match("a.*b", "a\n\nb", re.DOTALL).group(0), "a\n\nb") def test_non_consuming(self): self.assertEqual(re.match("(a(?=\s[^a]))", "a b").group(1), "a") self.assertEqual(re.match("(a(?=\s[^a]*))", "a b").group(1), "a") self.assertEqual(re.match("(a(?=\s[abc]))", "a b").group(1), "a") self.assertEqual(re.match("(a(?=\s[abc]*))", "a bc").group(1), "a") self.assertEqual(re.match(r"(a)(?=\s\1)", "a a").group(1), "a") self.assertEqual(re.match(r"(a)(?=\s\1*)", "a aa").group(1), "a") self.assertEqual(re.match(r"(a)(?=\s(abc|a))", "a a").group(1), "a") self.assertEqual(re.match(r"(a(?!\s[^a]))", "a a").group(1), "a") self.assertEqual(re.match(r"(a(?!\s[abc]))", "a d").group(1), "a") self.assertEqual(re.match(r"(a)(?!\s\1)", "a b").group(1), "a") self.assertEqual(re.match(r"(a)(?!\s(abc|a))", "a b").group(1), "a") def test_ignore_case(self): self.assertEqual(re.match("abc", "ABC", re.I).group(0), "ABC") self.assertEqual(re.match("abc", u"ABC", re.I).group(0), "ABC") self.assertEqual(re.match(r"(a\s[^a])", "a b", re.I).group(1), "a b") self.assertEqual(re.match(r"(a\s[^a]*)", "a bb", re.I).group(1), "a bb") self.assertEqual(re.match(r"(a\s[abc])", "a b", re.I).group(1), "a b") self.assertEqual(re.match(r"(a\s[abc]*)", "a bb", re.I).group(1), "a bb") self.assertEqual(re.match(r"((a)\s\2)", "a a", re.I).group(1), "a a") self.assertEqual(re.match(r"((a)\s\2*)", "a aa", re.I).group(1), "a aa") self.assertEqual(re.match(r"((a)\s(abc|a))", "a a", re.I).group(1), "a a") self.assertEqual(re.match(r"((a)\s(abc|a)*)", "a aa", re.I).group(1), "a aa") def test_category(self): self.assertEqual(re.match(r"(\s)", " ").group(1), " ") def test_getlower(self): import _sre self.assertEqual(_sre.getlower(ord('A'), 0), ord('a')) self.assertEqual(_sre.getlower(ord('A'), re.LOCALE), ord('a')) self.assertEqual(_sre.getlower(ord('A'), re.UNICODE), ord('a')) self.assertEqual(re.match("abc", "ABC", re.I).group(0), "ABC") self.assertEqual(re.match("abc", u"ABC", re.I).group(0), "ABC") def test_not_literal(self): self.assertEqual(re.search("\s([^a])", " b").group(1), "b") self.assertEqual(re.search("\s([^a]*)", " bb").group(1), "bb") def test_search_coverage(self): self.assertEqual(re.search("\s(b)", " b").group(1), "b") self.assertEqual(re.search("a\s", "a ").group(0), "a ") def assertMatch(self, pattern, text, match=None, span=None, matcher=re.match): if match is None and span is None: # the pattern matches the whole text match = text span = (0, len(text)) elif match is None or span is None: raise ValueError('If match is not None, span should be specified ' '(and vice versa).') m = matcher(pattern, text) self.assertTrue(m) self.assertEqual(m.group(), match) self.assertEqual(m.span(), span) def test_re_escape(self): alnum_chars = string.ascii_letters + string.digits p = u''.join(unichr(i) for i in range(256)) for c in p: if c in alnum_chars: self.assertEqual(re.escape(c), c) elif c == u'\x00': self.assertEqual(re.escape(c), u'\\000') else: self.assertEqual(re.escape(c), u'\\' + c) self.assertMatch(re.escape(c), c) self.assertMatch(re.escape(p), p) def test_re_escape_byte(self): alnum_chars = (string.ascii_letters + string.digits).encode('ascii') p = ''.join(chr(i) for i in range(256)) for b in p: if b in alnum_chars: self.assertEqual(re.escape(b), b) elif b == b'\x00': self.assertEqual(re.escape(b), b'\\000') else: self.assertEqual(re.escape(b), b'\\' + b) self.assertMatch(re.escape(b), b) self.assertMatch(re.escape(p), p) def test_re_escape_non_ascii(self): s = u'xxx\u2620\u2620\u2620xxx' s_escaped = re.escape(s) self.assertEqual(s_escaped, u'xxx\\\u2620\\\u2620\\\u2620xxx') self.assertMatch(s_escaped, s) self.assertMatch(u'.%s+.' % re.escape(u'\u2620'), s, u'x\u2620\u2620\u2620x', (2, 7), re.search) def test_re_escape_non_ascii_bytes(self): b = u'y\u2620y\u2620y'.encode('utf-8') b_escaped = re.escape(b) self.assertEqual(b_escaped, b'y\\\xe2\\\x98\\\xa0y\\\xe2\\\x98\\\xa0y') self.assertMatch(b_escaped, b) res = re.findall(re.escape(u'\u2620'.encode('utf-8')), b) self.assertEqual(len(res), 2) def test_pickling(self): import pickle self.pickle_test(pickle) import cPickle self.pickle_test(cPickle) # old pickles expect the _compile() reconstructor in sre module import_module("sre", deprecated=True) from sre import _compile def pickle_test(self, pickle): oldpat = re.compile('a(?:b|(c|e){1,2}?|d)+?(.)') s = pickle.dumps(oldpat) newpat = pickle.loads(s) self.assertEqual(oldpat, newpat) def test_constants(self): self.assertEqual(re.I, re.IGNORECASE) self.assertEqual(re.L, re.LOCALE) self.assertEqual(re.M, re.MULTILINE) self.assertEqual(re.S, re.DOTALL) self.assertEqual(re.X, re.VERBOSE) def test_flags(self): for flag in [re.I, re.M, re.X, re.S, re.L]: self.assertNotEqual(re.compile('^pattern$', flag), None) def test_sre_character_literals(self): for i in [0, 8, 16, 32, 64, 127, 128, 255]: self.assertNotEqual(re.match(r"\%03o" % i, chr(i)), None) self.assertNotEqual(re.match(r"\%03o0" % i, chr(i)+"0"), None) self.assertNotEqual(re.match(r"\%03o8" % i, chr(i)+"8"), None) self.assertNotEqual(re.match(r"\x%02x" % i, chr(i)), None) self.assertNotEqual(re.match(r"\x%02x0" % i, chr(i)+"0"), None) self.assertNotEqual(re.match(r"\x%02xz" % i, chr(i)+"z"), None) self.assertRaises(re.error, re.match, "\911", "") def test_sre_character_class_literals(self): for i in [0, 8, 16, 32, 64, 127, 128, 255]: self.assertNotEqual(re.match(r"[\%03o]" % i, chr(i)), None) self.assertNotEqual(re.match(r"[\%03o0]" % i, chr(i)), None) self.assertNotEqual(re.match(r"[\%03o8]" % i, chr(i)), None) self.assertNotEqual(re.match(r"[\x%02x]" % i, chr(i)), None) self.assertNotEqual(re.match(r"[\x%02x0]" % i, chr(i)), None) self.assertNotEqual(re.match(r"[\x%02xz]" % i, chr(i)), None) self.assertRaises(re.error, re.match, "[\911]", "") def test_bug_113254(self): self.assertEqual(re.match(r'(a)|(b)', 'b').start(1), -1) self.assertEqual(re.match(r'(a)|(b)', 'b').end(1), -1) self.assertEqual(re.match(r'(a)|(b)', 'b').span(1), (-1, -1)) def test_bug_527371(self): # bug described in patches 527371/672491 self.assertEqual(re.match(r'(a)?a','a').lastindex, None) self.assertEqual(re.match(r'(a)(b)?b','ab').lastindex, 1) self.assertEqual(re.match(r'(?Pa)(?Pb)?b','ab').lastgroup, 'a') self.assertEqual(re.match("(?Pa(b))", "ab").lastgroup, 'a') self.assertEqual(re.match("((a))", "a").lastindex, 1) def test_bug_545855(self): # bug 545855 -- This pattern failed to cause a compile error as it # should, instead provoking a TypeError. self.assertRaises(re.error, re.compile, 'foo[a-') def test_bug_418626(self): # bugs 418626 at al. -- Testing Greg Chapman's addition of op code # SRE_OP_MIN_REPEAT_ONE for eliminating recursion on simple uses of # pattern '*?' on a long string. self.assertEqual(re.match('.*?c', 10000*'ab'+'cd').end(0), 20001) self.assertEqual(re.match('.*?cd', 5000*'ab'+'c'+5000*'ab'+'cde').end(0), 20003) self.assertEqual(re.match('.*?cd', 20000*'abc'+'de').end(0), 60001) # non-simple '*?' still used to hit the recursion limit, before the # non-recursive scheme was implemented. self.assertEqual(re.search('(a|b)*?c', 10000*'ab'+'cd').end(0), 20001) def test_bug_612074(self): pat=u"["+re.escape(u"\u2039")+u"]" self.assertEqual(re.compile(pat) and 1, 1) def test_stack_overflow(self): # nasty cases that used to overflow the straightforward recursive # implementation of repeated groups. self.assertEqual(re.match('(x)*', 50000*'x').group(1), 'x') self.assertEqual(re.match('(x)*y', 50000*'x'+'y').group(1), 'x') self.assertEqual(re.match('(x)*?y', 50000*'x'+'y').group(1), 'x') def test_scanner(self): def s_ident(scanner, token): return token def s_operator(scanner, token): return "op%s" % token def s_float(scanner, token): return float(token) def s_int(scanner, token): return int(token) scanner = Scanner([ (r"[a-zA-Z_]\w*", s_ident), (r"\d+\.\d*", s_float), (r"\d+", s_int), (r"=|\+|-|\*|/", s_operator), (r"\s+", None), ]) self.assertNotEqual(scanner.scanner.scanner("").pattern, None) self.assertEqual(scanner.scan("sum = 3*foo + 312.50 + bar"), (['sum', 'op=', 3, 'op*', 'foo', 'op+', 312.5, 'op+', 'bar'], '')) def test_bug_448951(self): # bug 448951 (similar to 429357, but with single char match) # (Also test greedy matches.) for op in '','?','*': self.assertEqual(re.match(r'((.%s):)?z'%op, 'z').groups(), (None, None)) self.assertEqual(re.match(r'((.%s):)?z'%op, 'a:z').groups(), ('a:', 'a')) def test_bug_725106(self): # capturing groups in alternatives in repeats self.assertEqual(re.match('^((a)|b)*', 'abc').groups(), ('b', 'a')) self.assertEqual(re.match('^(([ab])|c)*', 'abc').groups(), ('c', 'b')) self.assertEqual(re.match('^((d)|[ab])*', 'abc').groups(), ('b', None)) self.assertEqual(re.match('^((a)c|[ab])*', 'abc').groups(), ('b', None)) self.assertEqual(re.match('^((a)|b)*?c', 'abc').groups(), ('b', 'a')) self.assertEqual(re.match('^(([ab])|c)*?d', 'abcd').groups(), ('c', 'b')) self.assertEqual(re.match('^((d)|[ab])*?c', 'abc').groups(), ('b', None)) self.assertEqual(re.match('^((a)c|[ab])*?c', 'abc').groups(), ('b', None)) def test_bug_725149(self): # mark_stack_base restoring before restoring marks self.assertEqual(re.match('(a)(?:(?=(b)*)c)*', 'abb').groups(), ('a', None)) self.assertEqual(re.match('(a)((?!(b)*))*', 'abb').groups(), ('a', None, None)) def test_bug_764548(self): # bug 764548, re.compile() barfs on str/unicode subclasses try: unicode except NameError: return # no problem if we have no unicode class my_unicode(unicode): pass pat = re.compile(my_unicode("abc")) self.assertEqual(pat.match("xyz"), None) def test_finditer(self): iter = re.finditer(r":+", "a:b::c:::d") self.assertEqual([item.group(0) for item in iter], [":", "::", ":::"]) def test_bug_926075(self): try: unicode except NameError: return # no problem if we have no unicode self.assertTrue(re.compile('bug_926075') is not re.compile(eval("u'bug_926075'"))) def test_bug_931848(self): try: unicode except NameError: pass pattern = eval('u"[\u002E\u3002\uFF0E\uFF61]"') self.assertEqual(re.compile(pattern).split("a.b.c"), ['a','b','c']) def test_bug_581080(self): iter = re.finditer(r"\s", "a b") self.assertEqual(iter.next().span(), (1,2)) self.assertRaises(StopIteration, iter.next) scanner = re.compile(r"\s").scanner("a b") self.assertEqual(scanner.search().span(), (1, 2)) self.assertEqual(scanner.search(), None) def test_bug_817234(self): iter = re.finditer(r".*", "asdf") self.assertEqual(iter.next().span(), (0, 4)) self.assertEqual(iter.next().span(), (4, 4)) self.assertRaises(StopIteration, iter.next) def test_bug_6561(self): # '\d' should match characters in Unicode category 'Nd' # (Number, Decimal Digit), but not those in 'Nl' (Number, # Letter) or 'No' (Number, Other). decimal_digits = [ u'\u0037', # '\N{DIGIT SEVEN}', category 'Nd' u'\u0e58', # '\N{THAI DIGIT SIX}', category 'Nd' u'\uff10', # '\N{FULLWIDTH DIGIT ZERO}', category 'Nd' ] for x in decimal_digits: self.assertEqual(re.match('^\d$', x, re.UNICODE).group(0), x) not_decimal_digits = [ u'\u2165', # '\N{ROMAN NUMERAL SIX}', category 'Nl' u'\u3039', # '\N{HANGZHOU NUMERAL TWENTY}', category 'Nl' u'\u2082', # '\N{SUBSCRIPT TWO}', category 'No' u'\u32b4', # '\N{CIRCLED NUMBER THIRTY NINE}', category 'No' ] for x in not_decimal_digits: self.assertIsNone(re.match('^\d$', x, re.UNICODE)) def test_empty_array(self): # SF buf 1647541 import array for typecode in 'cbBuhHiIlLfd': a = array.array(typecode) self.assertEqual(re.compile("bla").match(a), None) self.assertEqual(re.compile("").match(a).groups(), ()) def test_inline_flags(self): # Bug #1700 upper_char = unichr(0x1ea0) # Latin Capital Letter A with Dot Bellow lower_char = unichr(0x1ea1) # Latin Small Letter A with Dot Bellow p = re.compile(upper_char, re.I | re.U) q = p.match(lower_char) self.assertNotEqual(q, None) p = re.compile(lower_char, re.I | re.U) q = p.match(upper_char) self.assertNotEqual(q, None) p = re.compile('(?i)' + upper_char, re.U) q = p.match(lower_char) self.assertNotEqual(q, None) p = re.compile('(?i)' + lower_char, re.U) q = p.match(upper_char) self.assertNotEqual(q, None) p = re.compile('(?iu)' + upper_char) q = p.match(lower_char) self.assertNotEqual(q, None) p = re.compile('(?iu)' + lower_char) q = p.match(upper_char) self.assertNotEqual(q, None) def test_dollar_matches_twice(self): "$ matches the end of string, and just before the terminating \n" pattern = re.compile('$') self.assertEqual(pattern.sub('#', 'a\nb\n'), 'a\nb#\n#') self.assertEqual(pattern.sub('#', 'a\nb\nc'), 'a\nb\nc#') self.assertEqual(pattern.sub('#', '\n'), '#\n#') pattern = re.compile('$', re.MULTILINE) self.assertEqual(pattern.sub('#', 'a\nb\n' ), 'a#\nb#\n#' ) self.assertEqual(pattern.sub('#', 'a\nb\nc'), 'a#\nb#\nc#') self.assertEqual(pattern.sub('#', '\n'), '#\n#') def test_dealloc(self): # issue 3299: check for segfault in debug build import _sre # the overflow limit is different on wide and narrow builds and it # depends on the definition of SRE_CODE (see sre.h). # 2**128 should be big enough to overflow on both. For smaller values # a RuntimeError is raised instead of OverflowError. long_overflow = 2**128 self.assertRaises(TypeError, re.finditer, "a", {}) self.assertRaises(OverflowError, _sre.compile, "abc", 0, [long_overflow]) def test_compile(self): # Test return value when given string and pattern as parameter pattern = re.compile('random pattern') self.assertIsInstance(pattern, re._pattern_type) same_pattern = re.compile(pattern) self.assertIsInstance(same_pattern, re._pattern_type) self.assertIs(same_pattern, pattern) # Test behaviour when not given a string or pattern as parameter self.assertRaises(TypeError, re.compile, 0) @precisionbigmemtest(size=_2G, memuse=1) def test_large_search(self, size): # Issue #10182: indices were 32-bit-truncated. s = 'a' * size m = re.search('$', s) self.assertIsNotNone(m) self.assertEqual(m.start(), size) self.assertEqual(m.end(), size) # The huge memuse is because of re.sub() using a list and a join() # to create the replacement result. @precisionbigmemtest(size=_2G, memuse=16 + 2) def test_large_subn(self, size): # Issue #10182: indices were 32-bit-truncated. s = 'a' * size r, n = re.subn('', '', s) self.assertEqual(r, s) self.assertEqual(n, size + 1) def run_re_tests(): from test.re_tests import tests, SUCCEED, FAIL, SYNTAX_ERROR if verbose: print 'Running re_tests test suite' else: # To save time, only run the first and last 10 tests #tests = tests[:10] + tests[-10:] pass for t in tests: sys.stdout.flush() pattern = s = outcome = repl = expected = None if len(t) == 5: pattern, s, outcome, repl, expected = t elif len(t) == 3: pattern, s, outcome = t else: raise ValueError, ('Test tuples should have 3 or 5 fields', t) try: obj = re.compile(pattern) except re.error: if outcome == SYNTAX_ERROR: pass # Expected a syntax error else: print '=== Syntax error:', t except KeyboardInterrupt: raise KeyboardInterrupt except: print '*** Unexpected error ***', t if verbose: traceback.print_exc(file=sys.stdout) else: try: result = obj.search(s) except re.error, msg: print '=== Unexpected exception', t, repr(msg) if outcome == SYNTAX_ERROR: # This should have been a syntax error; forget it. pass elif outcome == FAIL: if result is None: pass # No match, as expected else: print '=== Succeeded incorrectly', t elif outcome == SUCCEED: if result is not None: # Matched, as expected, so now we compute the # result string and compare it to our expected result. start, end = result.span(0) vardict={'found': result.group(0), 'groups': result.group(), 'flags': result.re.flags} for i in range(1, 100): try: gi = result.group(i) # Special hack because else the string concat fails: if gi is None: gi = "None" except IndexError: gi = "Error" vardict['g%d' % i] = gi for i in result.re.groupindex.keys(): try: gi = result.group(i) if gi is None: gi = "None" except IndexError: gi = "Error" vardict[i] = gi repl = eval(repl, vardict) if repl != expected: print '=== grouping error', t, print repr(repl) + ' should be ' + repr(expected) else: print '=== Failed incorrectly', t # Try the match on a unicode string, and check that it # still succeeds. try: result = obj.search(unicode(s, "latin-1")) if result is None: print '=== Fails on unicode match', t except NameError: continue # 1.5.2 except TypeError: continue # unicode test case # Try the match on a unicode pattern, and check that it # still succeeds. obj=re.compile(unicode(pattern, "latin-1")) result = obj.search(s) if result is None: print '=== Fails on unicode pattern match', t # Try the match with the search area limited to the extent # of the match and see if it still succeeds. \B will # break (because it won't match at the end or start of a # string), so we'll ignore patterns that feature it. if pattern[:2] != '\\B' and pattern[-2:] != '\\B' \ and result is not None: obj = re.compile(pattern) result = obj.search(s, result.start(0), result.end(0) + 1) if result is None: print '=== Failed on range-limited match', t # Try the match with IGNORECASE enabled, and check that it # still succeeds. obj = re.compile(pattern, re.IGNORECASE) result = obj.search(s) if result is None: print '=== Fails on case-insensitive match', t # Try the match with LOCALE enabled, and check that it # still succeeds. obj = re.compile(pattern, re.LOCALE) result = obj.search(s) if result is None: print '=== Fails on locale-sensitive match', t # Try the match with UNICODE locale enabled, and check # that it still succeeds. obj = re.compile(pattern, re.UNICODE) result = obj.search(s) if result is None: print '=== Fails on unicode-sensitive match', t def test_main(): run_unittest(ReTests) run_re_tests() if __name__ == "__main__": test_main()