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# -*- coding: utf-8 -*- # # SelfTest/Protocol/test_KDF.py: Self-test for key derivation functions # # =================================================================== # The contents of this file are dedicated to the public domain. To # the extent that dedication to the public domain is not available, # everyone is granted a worldwide, perpetual, royalty-free, # non-exclusive license to exercise all rights associated with the # contents of this file for any purpose whatsoever. # No rights are reserved. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, # EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF # MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND # NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS # BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN # ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN # CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE # SOFTWARE. # =================================================================== import re import unittest from binascii import unhexlify from Crypto.Util.py3compat import b, bchr from Crypto.SelfTest.st_common import list_test_cases from Crypto.SelfTest.loader import load_test_vectors, load_test_vectors_wycheproof from Crypto.Hash import SHA1, HMAC, SHA256, MD5, SHA224, SHA384, SHA512 from Crypto.Cipher import AES, DES3 from Crypto.Protocol.KDF import (PBKDF1, PBKDF2, _S2V, HKDF, scrypt, bcrypt, bcrypt_check, SP800_108_Counter) from Crypto.Protocol.KDF import _bcrypt_decode def t2b(t): if t is None: return None t2 = t.replace(" ", "").replace("\n", "") return unhexlify(b(t2)) class TestVector(object): pass class PBKDF1_Tests(unittest.TestCase): # List of tuples with test data. # Each tuple is made up by: # Item #0: a pass phrase # Item #1: salt (8 bytes encoded in hex) # Item #2: output key length # Item #3: iterations to use # Item #4: expected result (encoded in hex) _testData = ( # From http://www.di-mgt.com.au/cryptoKDFs.html#examplespbkdf ("password", "78578E5A5D63CB06", 16, 1000, "DC19847E05C64D2FAF10EBFB4A3D2A20"), ) def test1(self): v = self._testData[0] res = PBKDF1(v[0], t2b(v[1]), v[2], v[3], SHA1) self.assertEqual(res, t2b(v[4])) class PBKDF2_Tests(unittest.TestCase): # List of tuples with test data. # Each tuple is made up by: # Item #0: a pass phrase # Item #1: salt (encoded in hex) # Item #2: output key length # Item #3: iterations to use # Item #4: hash module # Item #5: expected result (encoded in hex) _testData = ( # From http://www.di-mgt.com.au/cryptoKDFs.html#examplespbkdf ("password","78578E5A5D63CB06",24,2048, SHA1, "BFDE6BE94DF7E11DD409BCE20A0255EC327CB936FFE93643"), # From RFC 6050 ("password","73616c74", 20, 1, SHA1, "0c60c80f961f0e71f3a9b524af6012062fe037a6"), ("password","73616c74", 20, 2, SHA1, "ea6c014dc72d6f8ccd1ed92ace1d41f0d8de8957"), ("password","73616c74", 20, 4096, SHA1, "4b007901b765489abead49d926f721d065a429c1"), ("passwordPASSWORDpassword","73616c7453414c5473616c7453414c5473616c7453414c5473616c7453414c5473616c74", 25, 4096, SHA1, "3d2eec4fe41c849b80c8d83662c0e44a8b291a964cf2f07038"), ( 'pass\x00word',"7361006c74",16,4096, SHA1, "56fa6aa75548099dcc37d7f03425e0c3"), # From draft-josefsson-scrypt-kdf-01, Chapter 10 ( 'passwd', '73616c74', 64, 1, SHA256, "55ac046e56e3089fec1691c22544b605f94185216dde0465e68b9d57c20dacbc49ca9cccf179b645991664b39d77ef317c71b845b1e30bd509112041d3a19783"), ( 'Password', '4e61436c', 64, 80000, SHA256, "4ddcd8f60b98be21830cee5ef22701f9641a4418d04c0414aeff08876b34ab56a1d425a1225833549adb841b51c9b3176a272bdebba1d078478f62b397f33c8d"), ) def test1(self): # Test only for HMAC-SHA1 as PRF def prf_SHA1(p,s): return HMAC.new(p,s,SHA1).digest() def prf_SHA256(p,s): return HMAC.new(p,s,SHA256).digest() for i in range(len(self._testData)): v = self._testData[i] password = v[0] salt = t2b(v[1]) out_len = v[2] iters = v[3] hash_mod = v[4] expected = t2b(v[5]) if hash_mod is SHA1: res = PBKDF2(password, salt, out_len, iters) self.assertEqual(res, expected) res = PBKDF2(password, salt, out_len, iters, prf_SHA1) self.assertEqual(res, expected) else: res = PBKDF2(password, salt, out_len, iters, prf_SHA256) self.assertEqual(res, expected) def test2(self): # Verify that prf and hmac_hash_module are mutual exclusive def prf_SHA1(p,s): return HMAC.new(p,s,SHA1).digest() self.assertRaises(ValueError, PBKDF2, b("xxx"), b("yyy"), 16, 100, prf=prf_SHA1, hmac_hash_module=SHA1) def test3(self): # Verify that hmac_hash_module works like prf password = b("xxx") salt = b("yyy") for hashmod in (MD5, SHA1, SHA224, SHA256, SHA384, SHA512): pr1 = PBKDF2(password, salt, 16, 100, prf=lambda p, s: HMAC.new(p,s,hashmod).digest()) pr2 = PBKDF2(password, salt, 16, 100, hmac_hash_module=hashmod) self.assertEqual(pr1, pr2) def test4(self): # Verify that PBKDF2 can take bytes or strings as password or salt k1 = PBKDF2("xxx", b("yyy"), 16, 10) k2 = PBKDF2(b("xxx"), b("yyy"), 16, 10) self.assertEqual(k1, k2) k1 = PBKDF2(b("xxx"), "yyy", 16, 10) k2 = PBKDF2(b("xxx"), b("yyy"), 16, 10) self.assertEqual(k1, k2) class S2V_Tests(unittest.TestCase): # Sequence of test vectors. # Each test vector is made up by: # Item #0: a tuple of strings # Item #1: an AES key # Item #2: the result # Item #3: the cipher module S2V is based on # Everything is hex encoded _testData = [ # RFC5297, A.1 ( ( '101112131415161718191a1b1c1d1e1f2021222324252627', '112233445566778899aabbccddee' ), 'fffefdfcfbfaf9f8f7f6f5f4f3f2f1f0', '85632d07c6e8f37f950acd320a2ecc93', AES ), # RFC5297, A.2 ( ( '00112233445566778899aabbccddeeffdeaddadadeaddadaffeeddcc'+ 'bbaa99887766554433221100', '102030405060708090a0', '09f911029d74e35bd84156c5635688c0', '7468697320697320736f6d6520706c61'+ '696e7465787420746f20656e63727970'+ '74207573696e67205349562d414553'), '7f7e7d7c7b7a79787776757473727170', '7bdb6e3b432667eb06f4d14bff2fbd0f', AES ), ] def test1(self): """Verify correctness of test vector""" for tv in self._testData: s2v = _S2V.new(t2b(tv[1]), tv[3]) for s in tv[0]: s2v.update(t2b(s)) result = s2v.derive() self.assertEqual(result, t2b(tv[2])) def test2(self): """Verify that no more than 127(AES) and 63(TDES) components are accepted.""" key = bchr(0) * 8 + bchr(255) * 8 for module in (AES, DES3): s2v = _S2V.new(key, module) max_comps = module.block_size*8-1 for i in range(max_comps): s2v.update(b("XX")) self.assertRaises(TypeError, s2v.update, b("YY")) class HKDF_Tests(unittest.TestCase): # Test vectors from RFC5869, Appendix A # Each tuple is made up by: # Item #0: hash module # Item #1: secret # Item #2: salt # Item #3: context # Item #4: expected result _test_vector = ( ( SHA256, "0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b", "000102030405060708090a0b0c", "f0f1f2f3f4f5f6f7f8f9", 42, "3cb25f25faacd57a90434f64d0362f2a" + "2d2d0a90cf1a5a4c5db02d56ecc4c5bf" + "34007208d5b887185865" ), ( SHA256, "000102030405060708090a0b0c0d0e0f" + "101112131415161718191a1b1c1d1e1f" + "202122232425262728292a2b2c2d2e2f" + "303132333435363738393a3b3c3d3e3f" + "404142434445464748494a4b4c4d4e4f", "606162636465666768696a6b6c6d6e6f" + "707172737475767778797a7b7c7d7e7f" + "808182838485868788898a8b8c8d8e8f" + "909192939495969798999a9b9c9d9e9f" + "a0a1a2a3a4a5a6a7a8a9aaabacadaeaf", "b0b1b2b3b4b5b6b7b8b9babbbcbdbebf" + "c0c1c2c3c4c5c6c7c8c9cacbcccdcecf" + "d0d1d2d3d4d5d6d7d8d9dadbdcdddedf" + "e0e1e2e3e4e5e6e7e8e9eaebecedeeef" + "f0f1f2f3f4f5f6f7f8f9fafbfcfdfeff", 82, "b11e398dc80327a1c8e7f78c596a4934" + "4f012eda2d4efad8a050cc4c19afa97c" + "59045a99cac7827271cb41c65e590e09" + "da3275600c2f09b8367793a9aca3db71" + "cc30c58179ec3e87c14c01d5c1f3434f" + "1d87" ), ( SHA256, "0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b", None, None, 42, "8da4e775a563c18f715f802a063c5a31" + "b8a11f5c5ee1879ec3454e5f3c738d2d" + "9d201395faa4b61a96c8" ), ( SHA1, "0b0b0b0b0b0b0b0b0b0b0b", "000102030405060708090a0b0c", "f0f1f2f3f4f5f6f7f8f9", 42, "085a01ea1b10f36933068b56efa5ad81" + "a4f14b822f5b091568a9cdd4f155fda2" + "c22e422478d305f3f896" ), ( SHA1, "000102030405060708090a0b0c0d0e0f" + "101112131415161718191a1b1c1d1e1f" + "202122232425262728292a2b2c2d2e2f" + "303132333435363738393a3b3c3d3e3f" + "404142434445464748494a4b4c4d4e4f", "606162636465666768696a6b6c6d6e6f" + "707172737475767778797a7b7c7d7e7f" + "808182838485868788898a8b8c8d8e8f" + "909192939495969798999a9b9c9d9e9f" + "a0a1a2a3a4a5a6a7a8a9aaabacadaeaf", "b0b1b2b3b4b5b6b7b8b9babbbcbdbebf" + "c0c1c2c3c4c5c6c7c8c9cacbcccdcecf" + "d0d1d2d3d4d5d6d7d8d9dadbdcdddedf" + "e0e1e2e3e4e5e6e7e8e9eaebecedeeef" + "f0f1f2f3f4f5f6f7f8f9fafbfcfdfeff", 82, "0bd770a74d1160f7c9f12cd5912a06eb" + "ff6adcae899d92191fe4305673ba2ffe" + "8fa3f1a4e5ad79f3f334b3b202b2173c" + "486ea37ce3d397ed034c7f9dfeb15c5e" + "927336d0441f4c4300e2cff0d0900b52" + "d3b4" ), ( SHA1, "0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b0b", "", "", 42, "0ac1af7002b3d761d1e55298da9d0506" + "b9ae52057220a306e07b6b87e8df21d0" + "ea00033de03984d34918" ), ( SHA1, "0c0c0c0c0c0c0c0c0c0c0c0c0c0c0c0c0c0c0c0c0c0c", None, "", 42, "2c91117204d745f3500d636a62f64f0a" + "b3bae548aa53d423b0d1f27ebba6f5e5" + "673a081d70cce7acfc48" ) ) def test1(self): for tv in self._test_vector: secret, salt, info, exp = [ t2b(tv[x]) for x in (1,2,3,5) ] key_len, hashmod = [ tv[x] for x in (4,0) ] output = HKDF(secret, key_len, salt, hashmod, 1, info) self.assertEqual(output, exp) def test2(self): ref = HKDF(b("XXXXXX"), 12, b("YYYY"), SHA1) # Same output, but this time split over 2 keys key1, key2 = HKDF(b("XXXXXX"), 6, b("YYYY"), SHA1, 2) self.assertEqual((ref[:6], ref[6:]), (key1, key2)) # Same output, but this time split over 3 keys key1, key2, key3 = HKDF(b("XXXXXX"), 4, b("YYYY"), SHA1, 3) self.assertEqual((ref[:4], ref[4:8], ref[8:]), (key1, key2, key3)) class scrypt_Tests(unittest.TestCase): # Test vectors taken from # https://tools.ietf.org/html/rfc7914 # - password # - salt # - N # - r # - p data = ( ( "", "", 16, # 2K 1, 1, """ 77 d6 57 62 38 65 7b 20 3b 19 ca 42 c1 8a 04 97 f1 6b 48 44 e3 07 4a e8 df df fa 3f ed e2 14 42 fc d0 06 9d ed 09 48 f8 32 6a 75 3a 0f c8 1f 17 e8 d3 e0 fb 2e 0d 36 28 cf 35 e2 0c 38 d1 89 06 """ ), ( "password", "NaCl", 1024, # 1M 8, 16, """ fd ba be 1c 9d 34 72 00 78 56 e7 19 0d 01 e9 fe 7c 6a d7 cb c8 23 78 30 e7 73 76 63 4b 37 31 62 2e af 30 d9 2e 22 a3 88 6f f1 09 27 9d 98 30 da c7 27 af b9 4a 83 ee 6d 83 60 cb df a2 cc 06 40 """ ), ( "pleaseletmein", "SodiumChloride", 16384, # 16M 8, 1, """ 70 23 bd cb 3a fd 73 48 46 1c 06 cd 81 fd 38 eb fd a8 fb ba 90 4f 8e 3e a9 b5 43 f6 54 5d a1 f2 d5 43 29 55 61 3f 0f cf 62 d4 97 05 24 2a 9a f9 e6 1e 85 dc 0d 65 1e 40 df cf 01 7b 45 57 58 87 """ ), ( "pleaseletmein", "SodiumChloride", 1048576, # 1G 8, 1, """ 21 01 cb 9b 6a 51 1a ae ad db be 09 cf 70 f8 81 ec 56 8d 57 4a 2f fd 4d ab e5 ee 98 20 ad aa 47 8e 56 fd 8f 4b a5 d0 9f fa 1c 6d 92 7c 40 f4 c3 37 30 40 49 e8 a9 52 fb cb f4 5c 6f a7 7a 41 a4 """ ), ) def setUp(self): new_test_vectors = [] for tv in self.data: new_tv = TestVector() new_tv.P = b(tv[0]) new_tv.S = b(tv[1]) new_tv.N = tv[2] new_tv.r = tv[3] new_tv.p = tv[4] new_tv.output = t2b(tv[5]) new_tv.dkLen = len(new_tv.output) new_test_vectors.append(new_tv) self.data = new_test_vectors def test2(self): for tv in self.data: try: output = scrypt(tv.P, tv.S, tv.dkLen, tv.N, tv.r, tv.p) except ValueError as e: if " 2 " in str(e) and tv.N >= 1048576: import warnings warnings.warn("Not enough memory to unit test scrypt() with N=1048576", RuntimeWarning) continue else: raise e self.assertEqual(output, tv.output) def test3(self): ref = scrypt(b("password"), b("salt"), 12, 16, 1, 1) # Same output, but this time split over 2 keys key1, key2 = scrypt(b("password"), b("salt"), 6, 16, 1, 1, 2) self.assertEqual((ref[:6], ref[6:]), (key1, key2)) # Same output, but this time split over 3 keys key1, key2, key3 = scrypt(b("password"), b("salt"), 4, 16, 1, 1, 3) self.assertEqual((ref[:4], ref[4:8], ref[8:]), (key1, key2, key3)) class bcrypt_Tests(unittest.TestCase): def test_negative_cases(self): self.assertRaises(ValueError, bcrypt, b"1" * 73, 10) self.assertRaises(ValueError, bcrypt, b"1" * 10, 3) self.assertRaises(ValueError, bcrypt, b"1" * 10, 32) self.assertRaises(ValueError, bcrypt, b"1" * 10, 4, salt=b"") self.assertRaises(ValueError, bcrypt, b"1" * 10, 4, salt=b"1") self.assertRaises(ValueError, bcrypt, b"1" * 10, 4, salt=b"1" * 17) self.assertRaises(ValueError, bcrypt, b"1\x00" * 10, 4) def test_bytearray_mismatch(self): ref = bcrypt("pwd", 4) bcrypt_check("pwd", ref) bref = bytearray(ref) bcrypt_check("pwd", bref) wrong = ref[:-1] + bchr(bref[-1] ^ 0x01) self.assertRaises(ValueError, bcrypt_check, "pwd", wrong) wrong = b"x" + ref[1:] self.assertRaises(ValueError, bcrypt_check, "pwd", wrong) # https://github.com/patrickfav/bcrypt/wiki/Published-Test-Vectors def test_empty_password(self): # password, cost, salt, bcrypt hash tvs = [ (b"", 4, b"zVHmKQtGGQob.b/Nc7l9NO", b"$2a$04$zVHmKQtGGQob.b/Nc7l9NO8UlrYcW05FiuCj/SxsFO/ZtiN9.mNzy"), (b"", 5, b"zVHmKQtGGQob.b/Nc7l9NO", b"$2a$05$zVHmKQtGGQob.b/Nc7l9NOWES.1hkVBgy5IWImh9DOjKNU8atY4Iy"), (b"", 6, b"zVHmKQtGGQob.b/Nc7l9NO", b"$2a$06$zVHmKQtGGQob.b/Nc7l9NOjOl7l4oz3WSh5fJ6414Uw8IXRAUoiaO"), (b"", 7, b"zVHmKQtGGQob.b/Nc7l9NO", b"$2a$07$zVHmKQtGGQob.b/Nc7l9NOBsj1dQpBA1HYNGpIETIByoNX9jc.hOi"), (b"", 8, b"zVHmKQtGGQob.b/Nc7l9NO", b"$2a$08$zVHmKQtGGQob.b/Nc7l9NOiLTUh/9MDpX86/DLyEzyiFjqjBFePgO"), ] for (idx, (password, cost, salt64, result)) in enumerate(tvs): x = bcrypt(password, cost, salt=_bcrypt_decode(salt64)) self.assertEqual(x, result) bcrypt_check(password, result) def test_random_password_and_salt_short_pw(self): # password, cost, salt, bcrypt hash tvs = [ (b"<.S.2K(Zq'", 4, b"VYAclAMpaXY/oqAo9yUpku", b"$2a$04$VYAclAMpaXY/oqAo9yUpkuWmoYywaPzyhu56HxXpVltnBIfmO9tgu"), (b"5.rApO%5jA", 5, b"kVNDrnYKvbNr5AIcxNzeIu", b"$2a$05$kVNDrnYKvbNr5AIcxNzeIuRcyIF5cZk6UrwHGxENbxP5dVv.WQM/G"), (b"oW++kSrQW^", 6, b"QLKkRMH9Am6irtPeSKN5sO", b"$2a$06$QLKkRMH9Am6irtPeSKN5sObJGr3j47cO6Pdf5JZ0AsJXuze0IbsNm"), (b"ggJ\\KbTnDG", 7, b"4H896R09bzjhapgCPS/LYu", b"$2a$07$4H896R09bzjhapgCPS/LYuMzAQluVgR5iu/ALF8L8Aln6lzzYXwbq"), (b"49b0:;VkH/", 8, b"hfvO2retKrSrx5f2RXikWe", b"$2a$08$hfvO2retKrSrx5f2RXikWeFWdtSesPlbj08t/uXxCeZoHRWDz/xFe"), (b">9N^5jc##'", 9, b"XZLvl7rMB3EvM0c1.JHivu", b"$2a$09$XZLvl7rMB3EvM0c1.JHivuIDPJWeNJPTVrpjZIEVRYYB/mF6cYgJK"), (b"\\$ch)s4WXp", 10, b"aIjpMOLK5qiS9zjhcHR5TO", b"$2a$10$aIjpMOLK5qiS9zjhcHR5TOU7v2NFDmcsBmSFDt5EHOgp/jeTF3O/q"), (b"RYoj\\_>2P7", 12, b"esIAHiQAJNNBrsr5V13l7.", b"$2a$12$esIAHiQAJNNBrsr5V13l7.RFWWJI2BZFtQlkFyiWXjou05GyuREZa"), ] for (idx, (password, cost, salt64, result)) in enumerate(tvs): x = bcrypt(password, cost, salt=_bcrypt_decode(salt64)) self.assertEqual(x, result) bcrypt_check(password, result) def test_random_password_and_salt_long_pw(self): # password, cost, salt, bcrypt hash tvs = [ (b"^Q&\"]A`%/A(BVGt>QaX0M-#<Q148&f", 4, b"vrRP5vQxyD4LrqiLd/oWRO", b"$2a$04$vrRP5vQxyD4LrqiLd/oWROgrrGINsw3gb4Ga5x2sn01jNmiLVECl6"), (b"nZa!rRf\\U;OL;R?>1ghq_+\":Y0CRmY", 5, b"YuQvhokOGVnevctykUYpKu", b"$2a$05$YuQvhokOGVnevctykUYpKutZD2pWeGGYn3auyLOasguMY3/0BbIyq"), (b"F%uN/j>[GuB7-jB'_Yj!Tnb7Y!u^6)", 6, b"5L3vpQ0tG9O7k5gQ8nAHAe", b"$2a$06$5L3vpQ0tG9O7k5gQ8nAHAe9xxQiOcOLh8LGcI0PLWhIznsDt.S.C6"), (b"Z>BobP32ub\"Cfe*Q<<WUq3rc=[GJr-", 7, b"hp8IdLueqE6qFh1zYycUZ.", b"$2a$07$hp8IdLueqE6qFh1zYycUZ.twmUH8eSTPQAEpdNXKMlwms9XfKqfea"), (b"Ik&8N['7*[1aCc1lOm8\\jWeD*H$eZM", 8, b"2ANDTYCB9m7vf0Prh7rSru", b"$2a$08$2ANDTYCB9m7vf0Prh7rSrupqpO3jJOkIz2oW/QHB4lCmK7qMytGV6"), (b"O)=%3[E$*q+>-q-=tRSjOBh8\\mLNW.", 9, b"nArqOfdCsD9kIbVnAixnwe", b"$2a$09$nArqOfdCsD9kIbVnAixnwe6s8QvyPYWtQBpEXKir2OJF9/oNBsEFe"), (b"/MH51`!BP&0tj3%YCA;Xk%e3S`o\\EI", 10, b"ePiAc.s.yoBi3B6p1iQUCe", b"$2a$10$ePiAc.s.yoBi3B6p1iQUCezn3mraLwpVJ5XGelVyYFKyp5FZn/y.u"), (b"ptAP\"mcg6oH.\";c0U2_oll.OKi<!ku", 12, b"aroG/pwwPj1tU5fl9a9pkO", b"$2a$12$aroG/pwwPj1tU5fl9a9pkO4rydAmkXRj/LqfHZOSnR6LGAZ.z.jwa"), ] for (idx, (password, cost, salt64, result)) in enumerate(tvs): x = bcrypt(password, cost, salt=_bcrypt_decode(salt64)) self.assertEqual(x, result) bcrypt_check(password, result) def test_same_password_and_random_salt(self): # password, cost, salt, bcrypt hash tvs = [ (b"Q/A:k3DP;X@=<0\"hg&9c", 4, b"wbgDTvLMtyjQlNK7fjqwyO", b"$2a$04$wbgDTvLMtyjQlNK7fjqwyOakBoACQuYh11.VsKNarF4xUIOBWgD6S"), (b"Q/A:k3DP;X@=<0\"hg&9c", 5, b"zbAaOmloOhxiKItjznRqru", b"$2a$05$zbAaOmloOhxiKItjznRqrunRqHlu3MAa7pMGv26Rr3WwyfGcwoRm6"), (b"Q/A:k3DP;X@=<0\"hg&9c", 6, b"aOK0bWUvLI0qLkc3ti5jyu", b"$2a$06$aOK0bWUvLI0qLkc3ti5jyuAIQoqRzuqoK09kQqQ6Ou/YKDhW50/qa"), ] for (idx, (password, cost, salt64, result)) in enumerate(tvs): x = bcrypt(password, cost, salt=_bcrypt_decode(salt64)) self.assertEqual(x, result) bcrypt_check(password, result) def test_same_password_and_salt_increasing_cost_factor(self): # password, cost, salt, bcrypt hash tvs = [ (b"o<&+X'F4AQ8H,LU,N`&r", 4, b"BK5u.QHk1Driey7bvnFTH.", b"$2a$04$BK5u.QHk1Driey7bvnFTH.3smGwxd91PtoK2GxH5nZ7pcBsYX4lMq"), (b"o<&+X'F4AQ8H,LU,N`&r", 5, b"BK5u.QHk1Driey7bvnFTH.", b"$2a$05$BK5u.QHk1Driey7bvnFTH.t5P.jZvFBMzDB1IY4PwkkRPOyVbEtFG"), (b"o<&+X'F4AQ8H,LU,N`&r", 6, b"BK5u.QHk1Driey7bvnFTH.", b"$2a$06$BK5u.QHk1Driey7bvnFTH.6Ea1Z5db2p25CPXZbxb/3OyKQagg3pa"), (b"o<&+X'F4AQ8H,LU,N`&r", 7, b"BK5u.QHk1Driey7bvnFTH.", b"$2a$07$BK5u.QHk1Driey7bvnFTH.sruuQi8Lhv/0LWKDvNp3AGFk7ltdkm6"), (b"o<&+X'F4AQ8H,LU,N`&r", 8, b"BK5u.QHk1Driey7bvnFTH.", b"$2a$08$BK5u.QHk1Driey7bvnFTH.IE7KsaUzc4m7gzAMlyUPUeiYyACWe0q"), (b"o<&+X'F4AQ8H,LU,N`&r", 9, b"BK5u.QHk1Driey7bvnFTH.", b"$2a$09$BK5u.QHk1Driey7bvnFTH.1v4Xj1dwkp44QNg0cVAoQt4FQMMrvnS"), (b"o<&+X'F4AQ8H,LU,N`&r", 10, b"BK5u.QHk1Driey7bvnFTH.", b"$2a$10$BK5u.QHk1Driey7bvnFTH.ESINe9YntUMcVgFDfkC.Vbhc9vMhNX2"), (b"o<&+X'F4AQ8H,LU,N`&r", 12, b"BK5u.QHk1Driey7bvnFTH.", b"$2a$12$BK5u.QHk1Driey7bvnFTH.QM1/nnGe/f5cTzb6XTTi/vMzcAnycqG"), ] for (idx, (password, cost, salt64, result)) in enumerate(tvs): x = bcrypt(password, cost, salt=_bcrypt_decode(salt64)) self.assertEqual(x, result) bcrypt_check(password, result) def test_long_passwords(self): # password, cost, salt, bcrypt hash tvs = [ (b"g*3Q45=\"8NNgpT&mbMJ$Omfr.#ZeW?FP=CE$#roHd?97uL0F-]`?u73c\"\\[.\"*)qU34@VG", 4, b"T2XJ5MOWvHQZRijl8LIKkO", b"$2a$04$T2XJ5MOWvHQZRijl8LIKkOQKIyX75KBfuLsuRYOJz5OjwBNF2lM8a"), (b"\\M+*8;&QE=Ll[>5?Ui\"^ai#iQH7ZFtNMfs3AROnIncE9\"BNNoEgO[[*Yk8;RQ(#S,;I+aT", 5, b"wgkOlGNXIVE2fWkT3gyRoO", b"$2a$05$wgkOlGNXIVE2fWkT3gyRoOqWi4gbi1Wv2Q2Jx3xVs3apl1w.Wtj8C"), (b"M.E1=dt<.L0Q&p;94NfGm_Oo23+Kpl@M5?WIAL.[@/:'S)W96G8N^AWb7_smmC]>7#fGoB", 6, b"W9zTCl35nEvUukhhFzkKMe", b"$2a$06$W9zTCl35nEvUukhhFzkKMekjT9/pj7M0lihRVEZrX3m8/SBNZRX7i"), ] for (idx, (password, cost, salt64, result)) in enumerate(tvs): x = bcrypt(password, cost, salt=_bcrypt_decode(salt64)) self.assertEqual(x, result) bcrypt_check(password, result) def test_increasing_password_length(self): # password, cost, salt, bcrypt hash tvs = [ (b"a", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.l4WvgHIVg17ZawDIrDM2IjlE64GDNQS"), (b"aa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.AyUxBk.ThHlsLvRTH7IqcG7yVHJ3SXq"), (b"aaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.BxOVac5xPB6XFdRc/ZrzM9FgZkqmvbW"), (b"aaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.Qbr209bpCtfl5hN7UQlG/L4xiD3AKau"), (b"aaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.oWszihPjDZI0ypReKsaDOW1jBl7oOii"), (b"aaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ./k.Xxn9YiqtV/sxh3EHbnOHd0Qsq27K"), (b"aaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.PYJqRFQbgRbIjMd5VNKmdKS4sBVOyDe"), (b"aaaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ..VMYfzaw1wP/SGxowpLeGf13fxCCt.q"), (b"aaaaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.5B0p054nO5WgAD1n04XslDY/bqY9RJi"), (b"aaaaaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.INBTgqm7sdlBJDg.J5mLMSRK25ri04y"), (b"aaaaaaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.s3y7CdFD0OR5p6rsZw/eZ.Dla40KLfm"), (b"aaaaaaaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.Jx742Djra6Q7PqJWnTAS.85c28g.Siq"), (b"aaaaaaaaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.oKMXW3EZcPHcUV0ib5vDBnh9HojXnLu"), (b"aaaaaaaaaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.w6nIjWpDPNSH5pZUvLjC1q25ONEQpeS"), (b"aaaaaaaaaaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.k1b2/r9A/hxdwKEKurg6OCn4MwMdiGq"), (b"aaaaaaaaaaaaaaaa", 4, b"5DCebwootqWMCp59ISrMJ.", b"$2a$04$5DCebwootqWMCp59ISrMJ.3prCNHVX1Ws.7Hm2bJxFUnQOX9f7DFa"), ] for (idx, (password, cost, salt64, result)) in enumerate(tvs): x = bcrypt(password, cost, salt=_bcrypt_decode(salt64)) self.assertEqual(x, result) bcrypt_check(password, result) def test_non_ascii_characters(self): # password, cost, salt, bcrypt hash tvs = [ ("àèìòùÀÈÌÒÙáéíóúýÁÉÍÓÚÝðÐ", 4, b"D3qS2aoTVyqM7z8v8crLm.", b"$2a$04$D3qS2aoTVyqM7z8v8crLm.3nKt4CzBZJbyFB.ZebmfCvRw7BGs.Xm"), ("àèìòùÀÈÌÒÙáéíóúýÁÉÍÓÚÝðÐ", 5, b"VA1FujiOCMPkUHQ8kF7IaO", b"$2a$05$VA1FujiOCMPkUHQ8kF7IaOg7NGaNvpxwWzSluQutxEVmbZItRTsAa"), ("àèìòùÀÈÌÒÙáéíóúýÁÉÍÓÚÝðÐ", 6, b"TXiaNrPeBSz5ugiQlehRt.", b"$2a$06$TXiaNrPeBSz5ugiQlehRt.gwpeDQnXWteQL4z2FulouBr6G7D9KUi"), ("âêîôûÂÊÎÔÛãñõÃÑÕäëïöüÿ", 4, b"YTn1Qlvps8e1odqMn6G5x.", b"$2a$04$YTn1Qlvps8e1odqMn6G5x.85pqKql6w773EZJAExk7/BatYAI4tyO"), ("âêîôûÂÊÎÔÛãñõÃÑÕäëïöüÿ", 5, b"C.8k5vJKD2NtfrRI9o17DO", b"$2a$05$C.8k5vJKD2NtfrRI9o17DOfIW0XnwItA529vJnh2jzYTb1QdoY0py"), ("âêîôûÂÊÎÔÛãñõÃÑÕäëïöüÿ", 6, b"xqfRPj3RYAgwurrhcA6uRO", b"$2a$06$xqfRPj3RYAgwurrhcA6uROtGlXDp/U6/gkoDYHwlubtcVcNft5.vW"), ("ÄËÏÖÜŸåÅæÆœŒßçÇøØ¢¿¡€", 4, b"y8vGgMmr9EdyxP9rmMKjH.", b"$2a$04$y8vGgMmr9EdyxP9rmMKjH.wv2y3r7yRD79gykQtmb3N3zrwjKsyay"), ("ÄËÏÖÜŸåÅæÆœŒßçÇøØ¢¿¡€", 5, b"iYH4XIKAOOm/xPQs7xKP1u", b"$2a$05$iYH4XIKAOOm/xPQs7xKP1upD0cWyMn3Jf0ZWiizXbEkVpS41K1dcO"), ("ÄËÏÖÜŸåÅæÆœŒßçÇøØ¢¿¡€", 6, b"wCOob.D0VV8twafNDB2ape", b"$2a$06$wCOob.D0VV8twafNDB2apegiGD5nqF6Y1e6K95q6Y.R8C4QGd265q"), ("ΔημοσιεύθηκεστηνΕφημερίδατης", 4, b"E5SQtS6P4568MDXW7cyUp.", b"$2a$04$E5SQtS6P4568MDXW7cyUp.18wfDisKZBxifnPZjAI1d/KTYMfHPYO"), ("АБбВвГгДдЕеЁёЖжЗзИиЙйКкЛлМмН", 4, b"03e26gQFHhQwRNf81/ww9.", b"$2a$04$03e26gQFHhQwRNf81/ww9.p1UbrNwxpzWjLuT.zpTLH4t/w5WhAhC"), ("нОоПпРрСсТтУуФфХхЦцЧчШшЩщЪъЫыЬьЭэЮю", 4, b"PHNoJwpXCfe32nUtLv2Upu", b"$2a$04$PHNoJwpXCfe32nUtLv2UpuhJXOzd4k7IdFwnEpYwfJVCZ/f/.8Pje"), ("電电電島岛島兔兔兎龜龟亀國国国區区区", 4, b"wU4/0i1TmNl2u.1jIwBX.u", b"$2a$04$wU4/0i1TmNl2u.1jIwBX.uZUaOL3Rc5ID7nlQRloQh6q5wwhV/zLW"), ("诶比伊艾弗豆贝尔维吾艾尺开艾丝维贼德", 4, b"P4kreGLhCd26d4WIy7DJXu", b"$2a$04$P4kreGLhCd26d4WIy7DJXusPkhxLvBouzV6OXkL5EB0jux0osjsry"), ] for (idx, (password, cost, salt64, result)) in enumerate(tvs): x = bcrypt(password, cost, salt=_bcrypt_decode(salt64)) self.assertEqual(x, result) bcrypt_check(password, result) def test_special_case_salt(self): # password, cost, salt, bcrypt hash tvs = [ ("-O_=*N!2JP", 4, b"......................", b"$2a$04$......................JjuKLOX9OOwo5PceZZXSkaLDvdmgb82"), ("7B[$Q<4b>U", 5, b"......................", b"$2a$05$......................DRiedDQZRL3xq5A5FL8y7/6NM8a2Y5W"), (">d5-I_8^.h", 6, b"......................", b"$2a$06$......................5Mq1Ng8jgDY.uHNU4h5p/x6BedzNH2W"), (")V`/UM/]1t", 4, b".OC/.OC/.OC/.OC/.OC/.O", b"$2a$04$.OC/.OC/.OC/.OC/.OC/.OQIvKRDAam.Hm5/IaV/.hc7P8gwwIbmi"), (":@t2.bWuH]", 5, b".OC/.OC/.OC/.OC/.OC/.O", b"$2a$05$.OC/.OC/.OC/.OC/.OC/.ONDbUvdOchUiKmQORX6BlkPofa/QxW9e"), ("b(#KljF5s\"", 6, b".OC/.OC/.OC/.OC/.OC/.O", b"$2a$06$.OC/.OC/.OC/.OC/.OC/.OHfTd9e7svOu34vi1PCvOcAEq07ST7.K"), ("@3YaJ^Xs]*", 4, b"eGA.eGA.eGA.eGA.eGA.e.", b"$2a$04$eGA.eGA.eGA.eGA.eGA.e.stcmvh.R70m.0jbfSFVxlONdj1iws0C"), ("'\"5\\!k*C(p", 5, b"eGA.eGA.eGA.eGA.eGA.e.", b"$2a$05$eGA.eGA.eGA.eGA.eGA.e.vR37mVSbfdHwu.F0sNMvgn8oruQRghy"), ("edEu7C?$'W", 6, b"eGA.eGA.eGA.eGA.eGA.e.", b"$2a$06$eGA.eGA.eGA.eGA.eGA.e.tSq0FN8MWHQXJXNFnHTPQKtA.n2a..G"), ("N7dHmg\\PI^", 4, b"999999999999999999999u", b"$2a$04$999999999999999999999uCZfA/pLrlyngNDMq89r1uUk.bQ9icOu"), ("\"eJuHh!)7*", 5, b"999999999999999999999u", b"$2a$05$999999999999999999999uj8Pfx.ufrJFAoWFLjapYBS5vVEQQ/hK"), ("ZeDRJ:_tu:", 6, b"999999999999999999999u", b"$2a$06$999999999999999999999u6RB0P9UmbdbQgjoQFEJsrvrKe.BoU6q"), ] for (idx, (password, cost, salt64, result)) in enumerate(tvs): x = bcrypt(password, cost, salt=_bcrypt_decode(salt64)) self.assertEqual(x, result) bcrypt_check(password, result) class TestVectorsHKDFWycheproof(unittest.TestCase): def __init__(self, wycheproof_warnings): unittest.TestCase.__init__(self) self._wycheproof_warnings = wycheproof_warnings self._id = "None" def add_tests(self, filename): def filter_algo(root): algo_name = root['algorithm'] if algo_name == "HKDF-SHA-1": return SHA1 elif algo_name == "HKDF-SHA-256": return SHA256 elif algo_name == "HKDF-SHA-384": return SHA384 elif algo_name == "HKDF-SHA-512": return SHA512 else: raise ValueError("Unknown algorithm " + algo_name) def filter_size(unit): return int(unit['size']) result = load_test_vectors_wycheproof(("Protocol", "wycheproof"), filename, "Wycheproof HMAC (%s)" % filename, root_tag={'hash_module': filter_algo}, unit_tag={'size': filter_size}) return result def setUp(self): self.tv = [] self.add_tests("hkdf_sha1_test.json") self.add_tests("hkdf_sha256_test.json") self.add_tests("hkdf_sha384_test.json") self.add_tests("hkdf_sha512_test.json") def shortDescription(self): return self._id def warn(self, tv): if tv.warning and self._wycheproof_warnings: import warnings warnings.warn("Wycheproof warning: %s (%s)" % (self._id, tv.comment)) def test_verify(self, tv): self._id = "Wycheproof HKDF Test #%d (%s, %s)" % (tv.id, tv.comment, tv.filename) try: key = HKDF(tv.ikm, tv.size, tv.salt, tv.hash_module, 1, tv.info) except ValueError: assert not tv.valid else: if key != tv.okm: assert not tv.valid else: assert tv.valid self.warn(tv) def runTest(self): for tv in self.tv: self.test_verify(tv) def load_hash_by_name(hash_name): return __import__("Crypto.Hash." + hash_name, globals(), locals(), ["new"]) class SP800_180_Counter_Tests(unittest.TestCase): def test_negative_zeroes(self): def prf(s, x): return HMAC.new(s, x, SHA256).digest() self.assertRaises(ValueError, SP800_108_Counter, b'0' * 16, 1, prf, label=b'A\x00B') self.assertRaises(ValueError, SP800_108_Counter, b'0' * 16, 1, prf, context=b'A\x00B') def test_multiple_keys(self): def prf(s, x): return HMAC.new(s, x, SHA256).digest() key = b'0' * 16 expected = SP800_108_Counter(key, 2*3*23, prf) for r in (1, 2, 3, 23): dks = SP800_108_Counter(key, r, prf, 138//r) self.assertEqual(len(dks), 138//r) self.assertEqual(len(dks[0]), r) self.assertEqual(b''.join(dks), expected) def add_tests_sp800_108_counter(cls): test_vectors_sp800_108_counter = load_test_vectors(("Protocol", ), "KDF_SP800_108_COUNTER.txt", "NIST SP 800 108 KDF Counter Mode", {'count': lambda x: int(x)}, ) or [] mac_type = None for idx, tv in enumerate(test_vectors_sp800_108_counter): if isinstance(tv, str): res = re.match(r"\[HMAC-(SHA-[0-9]+)\]", tv) if res: hash_name = res.group(1).replace("-", "") hash_module = load_hash_by_name(hash_name) mac_type = "hmac" continue res = re.match(r"\[CMAC-AES-128\]", tv) if res: mac_type = "cmac" continue assert res if mac_type == "hmac": def prf(s, x, hash_module=hash_module): return HMAC.new(s, x, hash_module).digest() elif mac_type == "cmac": def prf(s, x, hash_module=hash_module): return CMAC.new(s, x, AES).digest() continue def kdf_test(self, prf=prf, kin=tv.kin, label=tv.label, context=tv.context, kout=tv.kout, count=tv.count): result = SP800_108_Counter(kin, len(kout), prf, 1, label, context) assert(len(result) == len(kout)) self.assertEqual(result, kout) setattr(cls, "test_kdf_sp800_108_counter_%d" % idx, kdf_test) add_tests_sp800_108_counter(SP800_180_Counter_Tests) def get_tests(config={}): wycheproof_warnings = config.get('wycheproof_warnings') if not config.get('slow_tests'): PBKDF2_Tests._testData = PBKDF2_Tests._testData[:3] scrypt_Tests.data = scrypt_Tests.data[:3] tests = [] tests += list_test_cases(PBKDF1_Tests) tests += list_test_cases(PBKDF2_Tests) tests += list_test_cases(S2V_Tests) tests += list_test_cases(HKDF_Tests) tests += [TestVectorsHKDFWycheproof(wycheproof_warnings)] tests += list_test_cases(scrypt_Tests) tests += list_test_cases(bcrypt_Tests) tests += list_test_cases(SP800_180_Counter_Tests) return tests if __name__ == '__main__': suite = lambda: unittest.TestSuite(get_tests()) unittest.main(defaultTest='suite')