# =================================================================== # # Copyright (c) 2014, Legrandin # All rights reserved. # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions # are met: # # 1. Redistributions of source code must retain the above copyright # notice, this list of conditions and the following disclaimer. # 2. Redistributions in binary form must reproduce the above copyright # notice, this list of conditions and the following disclaimer in # the documentation and/or other materials provided with the # distribution. # # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS # "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT # LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS # FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE # COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, # INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, # BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; # LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER # CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT # LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN # ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE # POSSIBILITY OF SUCH DAMAGE. # =================================================================== import re import unittest from binascii import unhexlify, hexlify from Crypto.Util.py3compat import tobytes from Crypto.Util.strxor import strxor_c from Crypto.Util._file_system import pycryptodome_filename from Crypto.SelfTest.st_common import list_test_cases from Crypto.Hash import BLAKE2b, BLAKE2s class Blake2Test(unittest.TestCase): def test_new_positive(self): h = self.BLAKE2.new(digest_bits=self.max_bits) for new_func in self.BLAKE2.new, h.new: for dbits in range(8, self.max_bits + 1, 8): hobj = new_func(digest_bits=dbits) self.assertEqual(hobj.digest_size, dbits // 8) for dbytes in range(1, self.max_bytes + 1): hobj = new_func(digest_bytes=dbytes) self.assertEqual(hobj.digest_size, dbytes) digest1 = new_func(data=b"\x90", digest_bytes=self.max_bytes).digest() digest2 = new_func(digest_bytes=self.max_bytes).update(b"\x90").digest() self.assertEqual(digest1, digest2) new_func(data=b"A", key=b"5", digest_bytes=self.max_bytes) hobj = h.new() self.assertEqual(hobj.digest_size, self.max_bytes) def test_new_negative(self): h = self.BLAKE2.new(digest_bits=self.max_bits) for new_func in self.BLAKE2.new, h.new: self.assertRaises(TypeError, new_func, digest_bytes=self.max_bytes, digest_bits=self.max_bits) self.assertRaises(ValueError, new_func, digest_bytes=0) self.assertRaises(ValueError, new_func, digest_bytes=self.max_bytes + 1) self.assertRaises(ValueError, new_func, digest_bits=7) self.assertRaises(ValueError, new_func, digest_bits=15) self.assertRaises(ValueError, new_func, digest_bits=self.max_bits + 1) self.assertRaises(TypeError, new_func, digest_bytes=self.max_bytes, key=u"string") self.assertRaises(TypeError, new_func, digest_bytes=self.max_bytes, data=u"string") def test_default_digest_size(self): digest = self.BLAKE2.new(data=b'abc').digest() self.assertEquals(len(digest), self.max_bytes) def test_update(self): pieces = [b"\x0A" * 200, b"\x14" * 300] h = self.BLAKE2.new(digest_bytes=self.max_bytes) h.update(pieces[0]).update(pieces[1]) digest = h.digest() h = self.BLAKE2.new(digest_bytes=self.max_bytes) h.update(pieces[0] + pieces[1]) self.assertEqual(h.digest(), digest) def test_update_negative(self): h = self.BLAKE2.new(digest_bytes=self.max_bytes) self.assertRaises(TypeError, h.update, u"string") def test_digest(self): h = self.BLAKE2.new(digest_bytes=self.max_bytes) digest = h.digest() # hexdigest does not change the state self.assertEqual(h.digest(), digest) # digest returns a byte string self.failUnless(isinstance(digest, type(b"digest"))) def test_update_after_digest(self): msg=b"rrrrttt" # Normally, update() cannot be done after digest() h = self.BLAKE2.new(digest_bits=256, data=msg[:4]) dig1 = h.digest() self.assertRaises(TypeError, h.update, msg[4:]) dig2 = self.BLAKE2.new(digest_bits=256, data=msg).digest() # With the proper flag, it is allowed h = self.BLAKE2.new(digest_bits=256, data=msg[:4], update_after_digest=True) self.assertEquals(h.digest(), dig1) # ... and the subsequent digest applies to the entire message # up to that point h.update(msg[4:]) self.assertEquals(h.digest(), dig2) def test_hex_digest(self): mac = self.BLAKE2.new(digest_bits=self.max_bits) digest = mac.digest() hexdigest = mac.hexdigest() # hexdigest is equivalent to digest self.assertEqual(hexlify(digest), tobytes(hexdigest)) # hexdigest does not change the state self.assertEqual(mac.hexdigest(), hexdigest) # hexdigest returns a string self.failUnless(isinstance(hexdigest, type("digest"))) def test_verify(self): h = self.BLAKE2.new(digest_bytes=self.max_bytes, key=b"4") mac = h.digest() h.verify(mac) wrong_mac = strxor_c(mac, 255) self.assertRaises(ValueError, h.verify, wrong_mac) def test_hexverify(self): h = self.BLAKE2.new(digest_bytes=self.max_bytes, key=b"4") mac = h.hexdigest() h.hexverify(mac) self.assertRaises(ValueError, h.hexverify, "4556") def test_oid(self): prefix = "1.3.6.1.4.1.1722.12.2." + self.oid_variant + "." for digest_bits in self.digest_bits_oid: h = self.BLAKE2.new(digest_bits=digest_bits) self.assertEqual(h.oid, prefix + str(digest_bits // 8)) h = self.BLAKE2.new(digest_bits=digest_bits, key=b"secret") self.assertRaises(AttributeError, lambda: h.oid) for digest_bits in (8, self.max_bits): if digest_bits in self.digest_bits_oid: continue self.assertRaises(AttributeError, lambda: h.oid) def test_bytearray(self): key = b'0' * 16 data = b"\x00\x01\x02" # Data and key can be a bytearray (during initialization) key_ba = bytearray(key) data_ba = bytearray(data) h1 = self.BLAKE2.new(data=data, key=key) h2 = self.BLAKE2.new(data=data_ba, key=key_ba) key_ba[:1] = b'\xFF' data_ba[:1] = b'\xFF' self.assertEqual(h1.digest(), h2.digest()) # Data can be a bytearray (during operation) data_ba = bytearray(data) h1 = self.BLAKE2.new() h2 = self.BLAKE2.new() h1.update(data) h2.update(data_ba) data_ba[:1] = b'\xFF' self.assertEqual(h1.digest(), h2.digest()) def test_memoryview(self): key = b'0' * 16 data = b"\x00\x01\x02" def get_mv_ro(data): return memoryview(data) def get_mv_rw(data): return memoryview(bytearray(data)) for get_mv in (get_mv_ro, get_mv_rw): # Data and key can be a memoryview (during initialization) key_mv = get_mv(key) data_mv = get_mv(data) h1 = self.BLAKE2.new(data=data, key=key) h2 = self.BLAKE2.new(data=data_mv, key=key_mv) if not data_mv.readonly: data_mv[:1] = b'\xFF' key_mv[:1] = b'\xFF' self.assertEqual(h1.digest(), h2.digest()) # Data can be a memoryview (during operation) data_mv = get_mv(data) h1 = self.BLAKE2.new() h2 = self.BLAKE2.new() h1.update(data) h2.update(data_mv) if not data_mv.readonly: data_mv[:1] = b'\xFF' self.assertEqual(h1.digest(), h2.digest()) import sys if sys.version[:3] == "2.6": del test_memoryview class Blake2bTest(Blake2Test): #: Module BLAKE2 = BLAKE2b #: Max output size (in bits) max_bits = 512 #: Max output size (in bytes) max_bytes = 64 #: Bit size of the digests for which an ASN OID exists digest_bits_oid = (160, 256, 384, 512) # http://tools.ietf.org/html/draft-saarinen-blake2-02 oid_variant = "1" class Blake2sTest(Blake2Test): #: Module BLAKE2 = BLAKE2s #: Max output size (in bits) max_bits = 256 #: Max output size (in bytes) max_bytes = 32 #: Bit size of the digests for which an ASN OID exists digest_bits_oid = (128, 160, 224, 256) # http://tools.ietf.org/html/draft-saarinen-blake2-02 oid_variant = "2" class Blake2OfficialTestVector(unittest.TestCase): def setUp(self): test_vector_file = pycryptodome_filename( ("Crypto", "SelfTest", "Hash", "test_vectors", self.name), self.name.lower() + "-test.txt") expected = "in" self.test_vectors = [] with open(test_vector_file, "rt") as test_vector_fd: for line_number, line in enumerate(test_vector_fd): if line.strip() == "" or line.startswith("#"): continue res = re.match("%s:\t([0-9A-Fa-f]*)" % expected, line) if not res: raise ValueError("Incorrect test vector format (line %d)" % line_number) if res.group(1): bin_value = unhexlify(tobytes(res.group(1))) else: bin_value = b"" if expected == "in": input_data = bin_value expected = "key" elif expected == "key": key = bin_value expected = "hash" else: result = bin_value expected = "in" self.test_vectors.append((input_data, key, result)) def runTest(self): for (input_data, key, result) in self.test_vectors: mac = self.BLAKE2.new(key=key, digest_bytes=self.max_bytes) mac.update(input_data) self.assertEqual(mac.digest(), result) class Blake2bOfficialTestVector(Blake2OfficialTestVector): #: Module BLAKE2 = BLAKE2b #: Hash name name = "BLAKE2b" #: Max digest size max_bytes = 64 class Blake2sOfficialTestVector(Blake2OfficialTestVector): #: Module BLAKE2 = BLAKE2s #: Hash name name = "BLAKE2s" #: Max digest size max_bytes = 32 class Blake2TestVector1(unittest.TestCase): def setUp(self): test_vector_file = pycryptodome_filename( ("Crypto", "SelfTest", "Hash", "test_vectors", self.name), "tv1.txt") self.test_vectors = [] with open(test_vector_file, "rt") as test_vector_fd: for line_number, line in enumerate(test_vector_fd): if line.strip() == "" or line.startswith("#"): continue res = re.match("digest: ([0-9A-Fa-f]*)", line) if not res: raise ValueError("Incorrect test vector format (line %d)" % line_number) self.test_vectors.append(unhexlify(tobytes(res.group(1)))) def runTest(self): for tv in self.test_vectors: digest_bytes = len(tv) next_data = b"" for _ in range(100): h = self.BLAKE2.new(digest_bytes=digest_bytes) h.update(next_data) next_data = h.digest() + next_data self.assertEqual(h.digest(), tv) class Blake2bTestVector1(Blake2TestVector1): #: Module BLAKE2 = BLAKE2b #: Hash name name = "BLAKE2b" class Blake2sTestVector1(Blake2TestVector1): #: Module BLAKE2 = BLAKE2s #: Hash name name = "BLAKE2s" class Blake2TestVector2(unittest.TestCase): def setUp(self): test_vector_file = pycryptodome_filename( ("Crypto", "SelfTest", "Hash", "test_vectors", self.name), "tv2.txt") self.test_vectors = [] with open(test_vector_file, "rt") as test_vector_fd: for line_number, line in enumerate(test_vector_fd): if line.strip() == "" or line.startswith("#"): continue res = re.match(r"digest\(([0-9]+)\): ([0-9A-Fa-f]*)", line) if not res: raise ValueError("Incorrect test vector format (line %d)" % line_number) key_size = int(res.group(1)) result = unhexlify(tobytes(res.group(2))) self.test_vectors.append((key_size, result)) def runTest(self): for key_size, result in self.test_vectors: next_data = b"" for _ in range(100): h = self.BLAKE2.new(digest_bytes=self.max_bytes, key=b"A" * key_size) h.update(next_data) next_data = h.digest() + next_data self.assertEqual(h.digest(), result) class Blake2bTestVector2(Blake2TestVector1): #: Module BLAKE2 = BLAKE2b #: Hash name name = "BLAKE2b" #: Max digest size in bytes max_bytes = 64 class Blake2sTestVector2(Blake2TestVector1): #: Module BLAKE2 = BLAKE2s #: Hash name name = "BLAKE2s" #: Max digest size in bytes max_bytes = 32 def get_tests(config={}): tests = [] tests += list_test_cases(Blake2bTest) tests.append(Blake2bOfficialTestVector()) tests.append(Blake2bTestVector1()) tests.append(Blake2bTestVector2()) tests += list_test_cases(Blake2sTest) tests.append(Blake2sOfficialTestVector()) tests.append(Blake2sTestVector1()) tests.append(Blake2sTestVector2()) return tests if __name__ == '__main__': import unittest suite = lambda: unittest.TestSuite(get_tests()) unittest.main(defaultTest='suite')