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"""tests for passlib.util""" #============================================================================= # imports #============================================================================= from __future__ import with_statement # core from functools import partial import warnings # site # pkg # module from passlib.utils import is_ascii_safe, to_bytes from passlib.utils.compat import irange, PY2, PY3, u, unicode, join_bytes, PYPY from passlib.tests.utils import TestCase, hb, run_with_fixed_seeds #============================================================================= # byte funcs #============================================================================= class MiscTest(TestCase): """tests various parts of utils module""" # NOTE: could test xor_bytes(), but it's exercised well enough by pbkdf2 test def test_compat(self): """test compat's lazymodule""" from passlib.utils import compat # "<module 'passlib.utils.compat' from 'passlib/utils/compat.pyc'>" self.assertRegex(repr(compat), r"^<module 'passlib.utils.compat' from '.*?'>$") # test synthentic dir() dir(compat) self.assertTrue('UnicodeIO' in dir(compat)) self.assertTrue('irange' in dir(compat)) def test_classproperty(self): from passlib.utils.decor import classproperty class test(object): xvar = 1 @classproperty def xprop(cls): return cls.xvar self.assertEqual(test.xprop, 1) prop = test.__dict__['xprop'] self.assertIs(prop.im_func, prop.__func__) def test_deprecated_function(self): from passlib.utils.decor import deprecated_function # NOTE: not comprehensive, just tests the basic behavior @deprecated_function(deprecated="1.6", removed="1.8") def test_func(*args): """test docstring""" return args self.assertTrue(".. deprecated::" in test_func.__doc__) with self.assertWarningList(dict(category=DeprecationWarning, message="the function passlib.tests.test_utils.test_func() " "is deprecated as of Passlib 1.6, and will be " "removed in Passlib 1.8." )): self.assertEqual(test_func(1,2), (1,2)) def test_memoized_property(self): from passlib.utils.decor import memoized_property class dummy(object): counter = 0 @memoized_property def value(self): value = self.counter self.counter = value+1 return value d = dummy() self.assertEqual(d.value, 0) self.assertEqual(d.value, 0) self.assertEqual(d.counter, 1) prop = dummy.value if not PY3: self.assertIs(prop.im_func, prop.__func__) def test_getrandbytes(self): """getrandbytes()""" from passlib.utils import getrandbytes wrapper = partial(getrandbytes, self.getRandom()) self.assertEqual(len(wrapper(0)), 0) a = wrapper(10) b = wrapper(10) self.assertIsInstance(a, bytes) self.assertEqual(len(a), 10) self.assertEqual(len(b), 10) self.assertNotEqual(a, b) @run_with_fixed_seeds(count=1024) def test_getrandstr(self, seed): """getrandstr()""" from passlib.utils import getrandstr wrapper = partial(getrandstr, self.getRandom(seed=seed)) # count 0 self.assertEqual(wrapper('abc',0), '') # count <0 self.assertRaises(ValueError, wrapper, 'abc', -1) # letters 0 self.assertRaises(ValueError, wrapper, '', 0) # letters 1 self.assertEqual(wrapper('a', 5), 'aaaaa') # NOTE: the following parts are non-deterministic, # with a small chance of failure (outside chance it may pick # a string w/o one char, even more remote chance of picking # same string). to combat this, we run it against multiple # fixed seeds (using run_with_fixed_seeds decorator), # and hope that they're sufficient to test the range of behavior. # letters x = wrapper(u('abc'), 32) y = wrapper(u('abc'), 32) self.assertIsInstance(x, unicode) self.assertNotEqual(x,y) self.assertEqual(sorted(set(x)), [u('a'),u('b'),u('c')]) # bytes x = wrapper(b'abc', 32) y = wrapper(b'abc', 32) self.assertIsInstance(x, bytes) self.assertNotEqual(x,y) # NOTE: decoding this due to py3 bytes self.assertEqual(sorted(set(x.decode("ascii"))), [u('a'),u('b'),u('c')]) def test_generate_password(self): """generate_password()""" from passlib.utils import generate_password warnings.filterwarnings("ignore", "The function.*generate_password\(\) is deprecated") self.assertEqual(len(generate_password(15)), 15) def test_is_crypt_context(self): """test is_crypt_context()""" from passlib.utils import is_crypt_context from passlib.context import CryptContext cc = CryptContext(["des_crypt"]) self.assertTrue(is_crypt_context(cc)) self.assertFalse(not is_crypt_context(cc)) def test_genseed(self): """test genseed()""" import random from passlib.utils import genseed rng = random.Random(genseed()) a = rng.randint(0, 10**10) rng = random.Random(genseed()) b = rng.randint(0, 10**10) self.assertNotEqual(a,b) rng.seed(genseed(rng)) def test_crypt(self): """test crypt.crypt() wrappers""" from passlib.utils import has_crypt, safe_crypt, test_crypt from passlib.registry import get_supported_os_crypt_schemes, get_crypt_handler # test everything is disabled supported = get_supported_os_crypt_schemes() if not has_crypt: self.assertEqual(supported, ()) self.assertEqual(safe_crypt("test", "aa"), None) self.assertFalse(test_crypt("test", "aaqPiZY5xR5l.")) # des_crypt() hash of "test" raise self.skipTest("crypt.crypt() not available") # expect there to be something supported, if crypt() is present if not supported: # NOTE: failures here should be investigated. usually means one of: # 1) at least one of passlib's os_crypt detection routines is giving false negative # 2) crypt() ONLY supports some hash alg which passlib doesn't know about # 3) crypt() is present but completely disabled (never encountered this yet) raise self.fail("crypt() present, but no supported schemes found!") # pick cheap alg if possible, with minimum rounds, to speed up this test. # NOTE: trusting hasher class works properly (should have been verified using it's own UTs) for scheme in ("md5_crypt", "sha256_crypt"): if scheme in supported: break else: scheme = supported[-1] hasher = get_crypt_handler(scheme) if getattr(hasher, "min_rounds", None): hasher = hasher.using(rounds=hasher.min_rounds) # helpers to generate hashes & config strings to work with def get_hash(secret): assert isinstance(secret, unicode) hash = hasher.hash(secret) if isinstance(hash, bytes): # py2 hash = hash.decode("utf-8") assert isinstance(hash, unicode) return hash # test ascii password & return type s1 = u("test") h1 = get_hash(s1) result = safe_crypt(s1, h1) self.assertIsInstance(result, unicode) self.assertEqual(result, h1) self.assertEqual(safe_crypt(to_bytes(s1), to_bytes(h1)), h1) # make sure crypt doesn't just blindly return h1 for whatever we pass in h1x = h1[:-2] + 'xx' self.assertEqual(safe_crypt(s1, h1x), h1) # test utf-8 / unicode password s2 = u('test\u1234') h2 = get_hash(s2) self.assertEqual(safe_crypt(s2, h2), h2) self.assertEqual(safe_crypt(to_bytes(s2), to_bytes(h2)), h2) # test rejects null chars in password self.assertRaises(ValueError, safe_crypt, '\x00', h1) # check test_crypt() self.assertTrue(test_crypt("test", h1)) self.assertFalse(test_crypt("test", h1x)) # check crypt returning variant error indicators # some platforms return None on errors, others empty string, # The BSDs in some cases return ":" import passlib.utils as mod orig = mod._crypt try: retval = None mod._crypt = lambda secret, hash: retval for retval in [None, "", ":", ":0", "*0"]: self.assertEqual(safe_crypt("test", h1), None) self.assertFalse(test_crypt("test", h1)) retval = 'xxx' self.assertEqual(safe_crypt("test", h1), "xxx") self.assertFalse(test_crypt("test", h1)) finally: mod._crypt = orig def test_consteq(self): """test consteq()""" # NOTE: this test is kind of over the top, but that's only because # this is used for the critical task of comparing hashes for equality. from passlib.utils import consteq, str_consteq # ensure error raises for wrong types self.assertRaises(TypeError, consteq, u(''), b'') self.assertRaises(TypeError, consteq, u(''), 1) self.assertRaises(TypeError, consteq, u(''), None) self.assertRaises(TypeError, consteq, b'', u('')) self.assertRaises(TypeError, consteq, b'', 1) self.assertRaises(TypeError, consteq, b'', None) self.assertRaises(TypeError, consteq, None, u('')) self.assertRaises(TypeError, consteq, None, b'') self.assertRaises(TypeError, consteq, 1, u('')) self.assertRaises(TypeError, consteq, 1, b'') def consteq_supports_string(value): # under PY2, it supports all unicode strings (when present at all), # under PY3, compare_digest() only supports ascii unicode strings. # confirmed for: cpython 2.7.9, cpython 3.4, pypy, pypy3, pyston return (consteq is str_consteq or PY2 or is_ascii_safe(value)) # check equal inputs compare correctly for value in [ u("a"), u("abc"), u("\xff\xa2\x12\x00")*10, ]: if consteq_supports_string(value): self.assertTrue(consteq(value, value), "value %r:" % (value,)) else: self.assertRaises(TypeError, consteq, value, value) self.assertTrue(str_consteq(value, value), "value %r:" % (value,)) value = value.encode("latin-1") self.assertTrue(consteq(value, value), "value %r:" % (value,)) # check non-equal inputs compare correctly for l,r in [ # check same-size comparisons with differing contents fail. (u("a"), u("c")), (u("abcabc"), u("zbaabc")), (u("abcabc"), u("abzabc")), (u("abcabc"), u("abcabz")), ((u("\xff\xa2\x12\x00")*10)[:-1] + u("\x01"), u("\xff\xa2\x12\x00")*10), # check different-size comparisons fail. (u(""), u("a")), (u("abc"), u("abcdef")), (u("abc"), u("defabc")), (u("qwertyuiopasdfghjklzxcvbnm"), u("abc")), ]: if consteq_supports_string(l) and consteq_supports_string(r): self.assertFalse(consteq(l, r), "values %r %r:" % (l,r)) self.assertFalse(consteq(r, l), "values %r %r:" % (r,l)) else: self.assertRaises(TypeError, consteq, l, r) self.assertRaises(TypeError, consteq, r, l) self.assertFalse(str_consteq(l, r), "values %r %r:" % (l,r)) self.assertFalse(str_consteq(r, l), "values %r %r:" % (r,l)) l = l.encode("latin-1") r = r.encode("latin-1") self.assertFalse(consteq(l, r), "values %r %r:" % (l,r)) self.assertFalse(consteq(r, l), "values %r %r:" % (r,l)) # TODO: add some tests to ensure we take THETA(strlen) time. # this might be hard to do reproducably. # NOTE: below code was used to generate stats for analysis ##from math import log as logb ##import timeit ##multipliers = [ 1<<s for s in irange(9)] ##correct = u"abcdefgh"*(1<<4) ##incorrect = u"abcdxfgh" ##print ##first = True ##for run in irange(1): ## times = [] ## chars = [] ## for m in multipliers: ## supplied = incorrect * m ## def test(): ## self.assertFalse(consteq(supplied,correct)) ## ##self.assertFalse(supplied == correct) ## times.append(timeit.timeit(test, number=100000)) ## chars.append(len(supplied)) ## # output for wolfram alpha ## print ", ".join("{%r, %r}" % (c,round(t,4)) for c,t in zip(chars,times)) ## def scale(c): ## return logb(c,2) ## print ", ".join("{%r, %r}" % (scale(c),round(t,4)) for c,t in zip(chars,times)) ## # output for spreadsheet ## ##if first: ## ## print "na, " + ", ".join(str(c) for c in chars) ## ## first = False ## ##print ", ".join(str(c) for c in [run] + times) def test_saslprep(self): """test saslprep() unicode normalizer""" self.require_stringprep() from passlib.utils import saslprep as sp # invalid types self.assertRaises(TypeError, sp, None) self.assertRaises(TypeError, sp, 1) self.assertRaises(TypeError, sp, b'') # empty strings self.assertEqual(sp(u('')), u('')) self.assertEqual(sp(u('\u00AD')), u('')) # verify B.1 chars are stripped, self.assertEqual(sp(u("$\u00AD$\u200D$")), u("$$$")) # verify C.1.2 chars are replaced with space self.assertEqual(sp(u("$ $\u00A0$\u3000$")), u("$ $ $ $")) # verify normalization to KC self.assertEqual(sp(u("a\u0300")), u("\u00E0")) self.assertEqual(sp(u("\u00E0")), u("\u00E0")) # verify various forbidden characters # control chars self.assertRaises(ValueError, sp, u("\u0000")) self.assertRaises(ValueError, sp, u("\u007F")) self.assertRaises(ValueError, sp, u("\u180E")) self.assertRaises(ValueError, sp, u("\uFFF9")) # private use self.assertRaises(ValueError, sp, u("\uE000")) # non-characters self.assertRaises(ValueError, sp, u("\uFDD0")) # surrogates self.assertRaises(ValueError, sp, u("\uD800")) # non-plaintext chars self.assertRaises(ValueError, sp, u("\uFFFD")) # non-canon self.assertRaises(ValueError, sp, u("\u2FF0")) # change display properties self.assertRaises(ValueError, sp, u("\u200E")) self.assertRaises(ValueError, sp, u("\u206F")) # unassigned code points (as of unicode 3.2) self.assertRaises(ValueError, sp, u("\u0900")) self.assertRaises(ValueError, sp, u("\uFFF8")) # tagging characters self.assertRaises(ValueError, sp, u("\U000e0001")) # verify bidi behavior # if starts with R/AL -- must end with R/AL self.assertRaises(ValueError, sp, u("\u0627\u0031")) self.assertEqual(sp(u("\u0627")), u("\u0627")) self.assertEqual(sp(u("\u0627\u0628")), u("\u0627\u0628")) self.assertEqual(sp(u("\u0627\u0031\u0628")), u("\u0627\u0031\u0628")) # if starts with R/AL -- cannot contain L self.assertRaises(ValueError, sp, u("\u0627\u0041\u0628")) # if doesn't start with R/AL -- can contain R/AL, but L & EN allowed self.assertRaises(ValueError, sp, u("x\u0627z")) self.assertEqual(sp(u("x\u0041z")), u("x\u0041z")) #------------------------------------------------------ # examples pulled from external sources, to be thorough #------------------------------------------------------ # rfc 4031 section 3 examples self.assertEqual(sp(u("I\u00ADX")), u("IX")) # strip SHY self.assertEqual(sp(u("user")), u("user")) # unchanged self.assertEqual(sp(u("USER")), u("USER")) # case preserved self.assertEqual(sp(u("\u00AA")), u("a")) # normalize to KC form self.assertEqual(sp(u("\u2168")), u("IX")) # normalize to KC form self.assertRaises(ValueError, sp, u("\u0007")) # forbid control chars self.assertRaises(ValueError, sp, u("\u0627\u0031")) # invalid bidi # rfc 3454 section 6 examples # starts with RAL char, must end with RAL char self.assertRaises(ValueError, sp, u("\u0627\u0031")) self.assertEqual(sp(u("\u0627\u0031\u0628")), u("\u0627\u0031\u0628")) def test_splitcomma(self): from passlib.utils import splitcomma self.assertEqual(splitcomma(""), []) self.assertEqual(splitcomma(","), []) self.assertEqual(splitcomma("a"), ['a']) self.assertEqual(splitcomma(" a , "), ['a']) self.assertEqual(splitcomma(" a , b"), ['a', 'b']) self.assertEqual(splitcomma(" a, b, "), ['a', 'b']) def test_utf8_truncate(self): """ utf8_truncate() """ from passlib.utils import utf8_truncate # # run through a bunch of reference strings, # and make sure they truncate properly across all possible indexes # for source in [ # empty string b"", # strings w/ only single-byte chars b"1", b"123", b'\x1a', b'\x1a' * 10, b'\x7f', b'\x7f' * 10, # strings w/ properly formed UTF8 continuation sequences b'a\xc2\xa0\xc3\xbe\xc3\xbe', b'abcdefghjusdfaoiu\xc2\xa0\xc3\xbe\xc3\xbedsfioauweoiruer', ]: source.decode("utf-8") # sanity check - should always be valid UTF8 end = len(source) for idx in range(end + 16): prefix = "source=%r index=%r: " % (source, idx) result = utf8_truncate(source, idx) # result should always be valid utf-8 result.decode("utf-8") # result should never be larger than source self.assertLessEqual(len(result), end, msg=prefix) # result should always be in range(idx, idx+4) self.assertGreaterEqual(len(result), min(idx, end), msg=prefix) self.assertLess(len(result), min(idx + 4, end + 1), msg=prefix) # should be strict prefix of source self.assertEqual(result, source[:len(result)], msg=prefix) # # malformed utf8 -- # strings w/ only initial chars (should cut just like single-byte chars) # for source in [ b'\xca', b'\xca' * 10, # also test null bytes (not valid utf8, but this func should treat them like ascii) b'\x00', b'\x00' * 10, ]: end = len(source) for idx in range(end + 16): prefix = "source=%r index=%r: " % (source, idx) result = utf8_truncate(source, idx) self.assertEqual(result, source[:idx], msg=prefix) # # malformed utf8 -- # strings w/ only continuation chars (should cut at index+3) # for source in [ b'\xaa', b'\xaa' * 10, ]: end = len(source) for idx in range(end + 16): prefix = "source=%r index=%r: " % (source, idx) result = utf8_truncate(source, idx) self.assertEqual(result, source[:idx+3], msg=prefix) # # string w/ some invalid utf8 -- # * \xaa byte is too many continuation byte after \xff start byte # * \xab byte doesn't have preceding start byte # XXX: could also test continuation bytes w/o start byte, WITHIN the string. # but think this covers edges well enough... # source = b'MN\xff\xa0\xa1\xa2\xaaOP\xab' self.assertEqual(utf8_truncate(source, 0), b'') # index="M", stops there self.assertEqual(utf8_truncate(source, 1), b'M') # index="N", stops there self.assertEqual(utf8_truncate(source, 2), b'MN') # index="\xff", stops there self.assertEqual(utf8_truncate(source, 3), b'MN\xff\xa0\xa1\xa2') # index="\xa0", runs out after index+3="\xa2" self.assertEqual(utf8_truncate(source, 4), b'MN\xff\xa0\xa1\xa2\xaa') # index="\xa1", runs out after index+3="\xaa" self.assertEqual(utf8_truncate(source, 5), b'MN\xff\xa0\xa1\xa2\xaa') # index="\xa2", stops before "O" self.assertEqual(utf8_truncate(source, 6), b'MN\xff\xa0\xa1\xa2\xaa') # index="\xaa", stops before "O" self.assertEqual(utf8_truncate(source, 7), b'MN\xff\xa0\xa1\xa2\xaa') # index="O", stops there self.assertEqual(utf8_truncate(source, 8), b'MN\xff\xa0\xa1\xa2\xaaO') # index="P", stops there self.assertEqual(utf8_truncate(source, 9), b'MN\xff\xa0\xa1\xa2\xaaOP\xab') # index="\xab", runs out at end self.assertEqual(utf8_truncate(source, 10), b'MN\xff\xa0\xa1\xa2\xaaOP\xab') # index=end self.assertEqual(utf8_truncate(source, 11), b'MN\xff\xa0\xa1\xa2\xaaOP\xab') # index=end+1 #============================================================================= # byte/unicode helpers #============================================================================= class CodecTest(TestCase): """tests bytes/unicode helpers in passlib.utils""" def test_bytes(self): """test b() helper, bytes and native str type""" if PY3: import builtins self.assertIs(bytes, builtins.bytes) else: import __builtin__ as builtins self.assertIs(bytes, builtins.str) self.assertIsInstance(b'', bytes) self.assertIsInstance(b'\x00\xff', bytes) if PY3: self.assertEqual(b'\x00\xff'.decode("latin-1"), "\x00\xff") else: self.assertEqual(b'\x00\xff', "\x00\xff") def test_to_bytes(self): """test to_bytes()""" from passlib.utils import to_bytes # check unicode inputs self.assertEqual(to_bytes(u('abc')), b'abc') self.assertEqual(to_bytes(u('\x00\xff')), b'\x00\xc3\xbf') # check unicode w/ encodings self.assertEqual(to_bytes(u('\x00\xff'), 'latin-1'), b'\x00\xff') self.assertRaises(ValueError, to_bytes, u('\x00\xff'), 'ascii') # check bytes inputs self.assertEqual(to_bytes(b'abc'), b'abc') self.assertEqual(to_bytes(b'\x00\xff'), b'\x00\xff') self.assertEqual(to_bytes(b'\x00\xc3\xbf'), b'\x00\xc3\xbf') # check byte inputs ignores enocding self.assertEqual(to_bytes(b'\x00\xc3\xbf', "latin-1"), b'\x00\xc3\xbf') # check bytes transcoding self.assertEqual(to_bytes(b'\x00\xc3\xbf', "latin-1", "", "utf-8"), b'\x00\xff') # check other self.assertRaises(AssertionError, to_bytes, 'abc', None) self.assertRaises(TypeError, to_bytes, None) def test_to_unicode(self): """test to_unicode()""" from passlib.utils import to_unicode # check unicode inputs self.assertEqual(to_unicode(u('abc')), u('abc')) self.assertEqual(to_unicode(u('\x00\xff')), u('\x00\xff')) # check unicode input ignores encoding self.assertEqual(to_unicode(u('\x00\xff'), "ascii"), u('\x00\xff')) # check bytes input self.assertEqual(to_unicode(b'abc'), u('abc')) self.assertEqual(to_unicode(b'\x00\xc3\xbf'), u('\x00\xff')) self.assertEqual(to_unicode(b'\x00\xff', 'latin-1'), u('\x00\xff')) self.assertRaises(ValueError, to_unicode, b'\x00\xff') # check other self.assertRaises(AssertionError, to_unicode, 'abc', None) self.assertRaises(TypeError, to_unicode, None) def test_to_native_str(self): """test to_native_str()""" from passlib.utils import to_native_str # test plain ascii self.assertEqual(to_native_str(u('abc'), 'ascii'), 'abc') self.assertEqual(to_native_str(b'abc', 'ascii'), 'abc') # test invalid ascii if PY3: self.assertEqual(to_native_str(u('\xE0'), 'ascii'), '\xE0') self.assertRaises(UnicodeDecodeError, to_native_str, b'\xC3\xA0', 'ascii') else: self.assertRaises(UnicodeEncodeError, to_native_str, u('\xE0'), 'ascii') self.assertEqual(to_native_str(b'\xC3\xA0', 'ascii'), '\xC3\xA0') # test latin-1 self.assertEqual(to_native_str(u('\xE0'), 'latin-1'), '\xE0') self.assertEqual(to_native_str(b'\xE0', 'latin-1'), '\xE0') # test utf-8 self.assertEqual(to_native_str(u('\xE0'), 'utf-8'), '\xE0' if PY3 else '\xC3\xA0') self.assertEqual(to_native_str(b'\xC3\xA0', 'utf-8'), '\xE0' if PY3 else '\xC3\xA0') # other types rejected self.assertRaises(TypeError, to_native_str, None, 'ascii') def test_is_ascii_safe(self): """test is_ascii_safe()""" from passlib.utils import is_ascii_safe self.assertTrue(is_ascii_safe(b"\x00abc\x7f")) self.assertTrue(is_ascii_safe(u("\x00abc\x7f"))) self.assertFalse(is_ascii_safe(b"\x00abc\x80")) self.assertFalse(is_ascii_safe(u("\x00abc\x80"))) def test_is_same_codec(self): """test is_same_codec()""" from passlib.utils import is_same_codec self.assertTrue(is_same_codec(None, None)) self.assertFalse(is_same_codec(None, 'ascii')) self.assertTrue(is_same_codec("ascii", "ascii")) self.assertTrue(is_same_codec("ascii", "ASCII")) self.assertTrue(is_same_codec("utf-8", "utf-8")) self.assertTrue(is_same_codec("utf-8", "utf8")) self.assertTrue(is_same_codec("utf-8", "UTF_8")) self.assertFalse(is_same_codec("ascii", "utf-8")) #============================================================================= # base64engine #============================================================================= class Base64EngineTest(TestCase): """test standalone parts of Base64Engine""" # NOTE: most Base64Engine testing done via _Base64Test subclasses below. def test_constructor(self): from passlib.utils.binary import Base64Engine, AB64_CHARS # bad charmap type self.assertRaises(TypeError, Base64Engine, 1) # bad charmap size self.assertRaises(ValueError, Base64Engine, AB64_CHARS[:-1]) # dup charmap letter self.assertRaises(ValueError, Base64Engine, AB64_CHARS[:-1] + "A") def test_ab64_decode(self): """ab64_decode()""" from passlib.utils.binary import ab64_decode # accept bytes or unicode self.assertEqual(ab64_decode(b"abc"), hb("69b7")) self.assertEqual(ab64_decode(u("abc")), hb("69b7")) # reject non-ascii unicode self.assertRaises(ValueError, ab64_decode, u("ab\xff")) # underlying a2b_ascii treats non-base64 chars as "Incorrect padding" self.assertRaises(TypeError, ab64_decode, b"ab\xff") self.assertRaises(TypeError, ab64_decode, b"ab!") self.assertRaises(TypeError, ab64_decode, u("ab!")) # insert correct padding, handle dirty padding bits self.assertEqual(ab64_decode(b"abcd"), hb("69b71d")) # 0 mod 4 self.assertRaises(ValueError, ab64_decode, b"abcde") # 1 mod 4 self.assertEqual(ab64_decode(b"abcdef"), hb("69b71d79")) # 2 mod 4, dirty padding bits self.assertEqual(ab64_decode(b"abcdeQ"), hb("69b71d79")) # 2 mod 4, clean padding bits self.assertEqual(ab64_decode(b"abcdefg"), hb("69b71d79f8")) # 3 mod 4, clean padding bits # support "./" or "+/" altchars # (lets us transition to "+/" representation, merge w/ b64s_decode) self.assertEqual(ab64_decode(b"ab+/"), hb("69bfbf")) self.assertEqual(ab64_decode(b"ab./"), hb("69bfbf")) def test_ab64_encode(self): """ab64_encode()""" from passlib.utils.binary import ab64_encode # accept bytes self.assertEqual(ab64_encode(hb("69b7")), b"abc") # reject unicode self.assertRaises(TypeError if PY3 else UnicodeEncodeError, ab64_encode, hb("69b7").decode("latin-1")) # insert correct padding before decoding self.assertEqual(ab64_encode(hb("69b71d")), b"abcd") # 0 mod 4 self.assertEqual(ab64_encode(hb("69b71d79")), b"abcdeQ") # 2 mod 4 self.assertEqual(ab64_encode(hb("69b71d79f8")), b"abcdefg") # 3 mod 4 # output "./" altchars self.assertEqual(ab64_encode(hb("69bfbf")), b"ab./") def test_b64s_decode(self): """b64s_decode()""" from passlib.utils.binary import b64s_decode # accept bytes or unicode self.assertEqual(b64s_decode(b"abc"), hb("69b7")) self.assertEqual(b64s_decode(u("abc")), hb("69b7")) # reject non-ascii unicode self.assertRaises(ValueError, b64s_decode, u("ab\xff")) # underlying a2b_ascii treats non-base64 chars as "Incorrect padding" self.assertRaises(TypeError, b64s_decode, b"ab\xff") self.assertRaises(TypeError, b64s_decode, b"ab!") self.assertRaises(TypeError, b64s_decode, u("ab!")) # insert correct padding, handle dirty padding bits self.assertEqual(b64s_decode(b"abcd"), hb("69b71d")) # 0 mod 4 self.assertRaises(ValueError, b64s_decode, b"abcde") # 1 mod 4 self.assertEqual(b64s_decode(b"abcdef"), hb("69b71d79")) # 2 mod 4, dirty padding bits self.assertEqual(b64s_decode(b"abcdeQ"), hb("69b71d79")) # 2 mod 4, clean padding bits self.assertEqual(b64s_decode(b"abcdefg"), hb("69b71d79f8")) # 3 mod 4, clean padding bits def test_b64s_encode(self): """b64s_encode()""" from passlib.utils.binary import b64s_encode # accept bytes self.assertEqual(b64s_encode(hb("69b7")), b"abc") # reject unicode self.assertRaises(TypeError if PY3 else UnicodeEncodeError, b64s_encode, hb("69b7").decode("latin-1")) # insert correct padding before decoding self.assertEqual(b64s_encode(hb("69b71d")), b"abcd") # 0 mod 4 self.assertEqual(b64s_encode(hb("69b71d79")), b"abcdeQ") # 2 mod 4 self.assertEqual(b64s_encode(hb("69b71d79f8")), b"abcdefg") # 3 mod 4 # output "+/" altchars self.assertEqual(b64s_encode(hb("69bfbf")), b"ab+/") class _Base64Test(TestCase): """common tests for all Base64Engine instances""" #=================================================================== # class attrs #=================================================================== # Base64Engine instance to test engine = None # pairs of (raw, encoded) bytes to test - should encode/decode correctly encoded_data = None # tuples of (encoded, value, bits) for known integer encodings encoded_ints = None # invalid encoded byte bad_byte = b"?" # helper to generate bytemap-specific strings def m(self, *offsets): """generate byte string from offsets""" return join_bytes(self.engine.bytemap[o:o+1] for o in offsets) #=================================================================== # test encode_bytes #=================================================================== def test_encode_bytes(self): """test encode_bytes() against reference inputs""" engine = self.engine encode = engine.encode_bytes for raw, encoded in self.encoded_data: result = encode(raw) self.assertEqual(result, encoded, "encode %r:" % (raw,)) def test_encode_bytes_bad(self): """test encode_bytes() with bad input""" engine = self.engine encode = engine.encode_bytes self.assertRaises(TypeError, encode, u('\x00')) self.assertRaises(TypeError, encode, None) #=================================================================== # test decode_bytes #=================================================================== def test_decode_bytes(self): """test decode_bytes() against reference inputs""" engine = self.engine decode = engine.decode_bytes for raw, encoded in self.encoded_data: result = decode(encoded) self.assertEqual(result, raw, "decode %r:" % (encoded,)) def test_decode_bytes_padding(self): """test decode_bytes() ignores padding bits""" bchr = (lambda v: bytes([v])) if PY3 else chr engine = self.engine m = self.m decode = engine.decode_bytes BNULL = b"\x00" # length == 2 mod 4: 4 bits of padding self.assertEqual(decode(m(0,0)), BNULL) for i in range(0,6): if engine.big: # 4 lsb padding correct = BNULL if i < 4 else bchr(1<<(i-4)) else: # 4 msb padding correct = bchr(1<<(i+6)) if i < 2 else BNULL self.assertEqual(decode(m(0,1<<i)), correct, "%d/4 bits:" % i) # length == 3 mod 4: 2 bits of padding self.assertEqual(decode(m(0,0,0)), BNULL*2) for i in range(0,6): if engine.big: # 2 lsb are padding correct = BNULL if i < 2 else bchr(1<<(i-2)) else: # 2 msg are padding correct = bchr(1<<(i+4)) if i < 4 else BNULL self.assertEqual(decode(m(0,0,1<<i)), BNULL + correct, "%d/2 bits:" % i) def test_decode_bytes_bad(self): """test decode_bytes() with bad input""" engine = self.engine decode = engine.decode_bytes # wrong size (1 % 4) self.assertRaises(ValueError, decode, engine.bytemap[:5]) # wrong char self.assertTrue(self.bad_byte not in engine.bytemap) self.assertRaises(ValueError, decode, self.bad_byte*4) # wrong type self.assertRaises(TypeError, decode, engine.charmap[:4]) self.assertRaises(TypeError, decode, None) #=================================================================== # encode_bytes+decode_bytes #=================================================================== def test_codec(self): """test encode_bytes/decode_bytes against random data""" engine = self.engine from passlib.utils import getrandbytes, getrandstr rng = self.getRandom() saw_zero = False for i in irange(500): # # test raw -> encode() -> decode() -> raw # # generate some random bytes size = rng.randint(1 if saw_zero else 0, 12) if not size: saw_zero = True enc_size = (4*size+2)//3 raw = getrandbytes(rng, size) # encode them, check invariants encoded = engine.encode_bytes(raw) self.assertEqual(len(encoded), enc_size) # make sure decode returns original result = engine.decode_bytes(encoded) self.assertEqual(result, raw) # # test encoded -> decode() -> encode() -> encoded # # generate some random encoded data if size % 4 == 1: size += rng.choice([-1,1,2]) raw_size = 3*size//4 encoded = getrandstr(rng, engine.bytemap, size) # decode them, check invariants raw = engine.decode_bytes(encoded) self.assertEqual(len(raw), raw_size, "encoded %d:" % size) # make sure encode returns original (barring padding bits) result = engine.encode_bytes(raw) if size % 4: self.assertEqual(result[:-1], encoded[:-1]) else: self.assertEqual(result, encoded) def test_repair_unused(self): """test repair_unused()""" # NOTE: this test relies on encode_bytes() always returning clear # padding bits - which should be ensured by test vectors. from passlib.utils import getrandstr rng = self.getRandom() engine = self.engine check_repair_unused = self.engine.check_repair_unused i = 0 while i < 300: size = rng.randint(0,23) cdata = getrandstr(rng, engine.charmap, size).encode("ascii") if size & 3 == 1: # should throw error self.assertRaises(ValueError, check_repair_unused, cdata) continue rdata = engine.encode_bytes(engine.decode_bytes(cdata)) if rng.random() < .5: cdata = cdata.decode("ascii") rdata = rdata.decode("ascii") if cdata == rdata: # should leave unchanged ok, result = check_repair_unused(cdata) self.assertFalse(ok) self.assertEqual(result, rdata) else: # should repair bits self.assertNotEqual(size % 4, 0) ok, result = check_repair_unused(cdata) self.assertTrue(ok) self.assertEqual(result, rdata) i += 1 #=================================================================== # test transposed encode/decode - encoding independant #=================================================================== # NOTE: these tests assume normal encode/decode has been tested elsewhere. transposed = [ # orig, result, transpose map (b"\x33\x22\x11", b"\x11\x22\x33",[2,1,0]), (b"\x22\x33\x11", b"\x11\x22\x33",[1,2,0]), ] transposed_dups = [ # orig, result, transpose projection (b"\x11\x11\x22", b"\x11\x22\x33",[0,0,1]), ] def test_encode_transposed_bytes(self): """test encode_transposed_bytes()""" engine = self.engine for result, input, offsets in self.transposed + self.transposed_dups: tmp = engine.encode_transposed_bytes(input, offsets) out = engine.decode_bytes(tmp) self.assertEqual(out, result) self.assertRaises(TypeError, engine.encode_transposed_bytes, u("a"), []) def test_decode_transposed_bytes(self): """test decode_transposed_bytes()""" engine = self.engine for input, result, offsets in self.transposed: tmp = engine.encode_bytes(input) out = engine.decode_transposed_bytes(tmp, offsets) self.assertEqual(out, result) def test_decode_transposed_bytes_bad(self): """test decode_transposed_bytes() fails if map is a one-way""" engine = self.engine for input, _, offsets in self.transposed_dups: tmp = engine.encode_bytes(input) self.assertRaises(TypeError, engine.decode_transposed_bytes, tmp, offsets) #=================================================================== # test 6bit handling #=================================================================== def check_int_pair(self, bits, encoded_pairs): """helper to check encode_intXX & decode_intXX functions""" rng = self.getRandom() engine = self.engine encode = getattr(engine, "encode_int%s" % bits) decode = getattr(engine, "decode_int%s" % bits) pad = -bits % 6 chars = (bits+pad)//6 upper = 1<<bits # test encode func for value, encoded in encoded_pairs: result = encode(value) self.assertIsInstance(result, bytes) self.assertEqual(result, encoded) self.assertRaises(ValueError, encode, -1) self.assertRaises(ValueError, encode, upper) # test decode func for value, encoded in encoded_pairs: self.assertEqual(decode(encoded), value, "encoded %r:" % (encoded,)) m = self.m self.assertRaises(ValueError, decode, m(0)*(chars+1)) self.assertRaises(ValueError, decode, m(0)*(chars-1)) self.assertRaises(ValueError, decode, self.bad_byte*chars) self.assertRaises(TypeError, decode, engine.charmap[0]) self.assertRaises(TypeError, decode, None) # do random testing. from passlib.utils import getrandstr for i in irange(100): # generate random value, encode, and then decode value = rng.randint(0, upper-1) encoded = encode(value) self.assertEqual(len(encoded), chars) self.assertEqual(decode(encoded), value) # generate some random encoded data, decode, then encode. encoded = getrandstr(rng, engine.bytemap, chars) value = decode(encoded) self.assertGreaterEqual(value, 0, "decode %r out of bounds:" % encoded) self.assertLess(value, upper, "decode %r out of bounds:" % encoded) result = encode(value) if pad: self.assertEqual(result[:-2], encoded[:-2]) else: self.assertEqual(result, encoded) def test_int6(self): engine = self.engine m = self.m self.check_int_pair(6, [(0, m(0)), (63, m(63))]) def test_int12(self): engine = self.engine m = self.m self.check_int_pair(12,[(0, m(0,0)), (63, m(0,63) if engine.big else m(63,0)), (0xFFF, m(63,63))]) def test_int24(self): engine = self.engine m = self.m self.check_int_pair(24,[(0, m(0,0,0,0)), (63, m(0,0,0,63) if engine.big else m(63,0,0,0)), (0xFFFFFF, m(63,63,63,63))]) def test_int64(self): # NOTE: this isn't multiple of 6, it has 2 padding bits appended # before encoding. engine = self.engine m = self.m self.check_int_pair(64, [(0, m(0,0,0,0, 0,0,0,0, 0,0,0)), (63, m(0,0,0,0, 0,0,0,0, 0,3,60) if engine.big else m(63,0,0,0, 0,0,0,0, 0,0,0)), ((1<<64)-1, m(63,63,63,63, 63,63,63,63, 63,63,60) if engine.big else m(63,63,63,63, 63,63,63,63, 63,63,15))]) def test_encoded_ints(self): """test against reference integer encodings""" if not self.encoded_ints: raise self.skipTests("none defined for class") engine = self.engine for data, value, bits in self.encoded_ints: encode = getattr(engine, "encode_int%d" % bits) decode = getattr(engine, "decode_int%d" % bits) self.assertEqual(encode(value), data) self.assertEqual(decode(data), value) #=================================================================== # eoc #=================================================================== # NOTE: testing H64 & H64Big should be sufficient to verify # that Base64Engine() works in general. from passlib.utils.binary import h64, h64big class H64_Test(_Base64Test): """test H64 codec functions""" engine = h64 descriptionPrefix = "h64 codec" encoded_data = [ # test lengths 0..6 to ensure tail is encoded properly (b"",b""), (b"\x55",b"J/"), (b"\x55\xaa",b"Jd8"), (b"\x55\xaa\x55",b"JdOJ"), (b"\x55\xaa\x55\xaa",b"JdOJe0"), (b"\x55\xaa\x55\xaa\x55",b"JdOJeK3"), (b"\x55\xaa\x55\xaa\x55\xaa",b"JdOJeKZe"), # test padding bits are null (b"\x55\xaa\x55\xaf",b"JdOJj0"), # len = 1 mod 3 (b"\x55\xaa\x55\xaa\x5f",b"JdOJey3"), # len = 2 mod 3 ] encoded_ints = [ (b"z.", 63, 12), (b".z", 4032, 12), ] class H64Big_Test(_Base64Test): """test H64Big codec functions""" engine = h64big descriptionPrefix = "h64big codec" encoded_data = [ # test lengths 0..6 to ensure tail is encoded properly (b"",b""), (b"\x55",b"JE"), (b"\x55\xaa",b"JOc"), (b"\x55\xaa\x55",b"JOdJ"), (b"\x55\xaa\x55\xaa",b"JOdJeU"), (b"\x55\xaa\x55\xaa\x55",b"JOdJeZI"), (b"\x55\xaa\x55\xaa\x55\xaa",b"JOdJeZKe"), # test padding bits are null (b"\x55\xaa\x55\xaf",b"JOdJfk"), # len = 1 mod 3 (b"\x55\xaa\x55\xaa\x5f",b"JOdJeZw"), # len = 2 mod 3 ] encoded_ints = [ (b".z", 63, 12), (b"z.", 4032, 12), ] #============================================================================= # eof #=============================================================================