# =================================================================== # # Copyright (c) 2015, 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 json import unittest from binascii import unhexlify from Cryptodome.SelfTest.st_common import list_test_cases from Cryptodome.SelfTest.loader import load_test_vectors_wycheproof from Cryptodome.Util.py3compat import tobytes, bchr from Cryptodome.Cipher import AES from Cryptodome.Hash import SHAKE128 from Cryptodome.Util.strxor import strxor def get_tag_random(tag, length): return SHAKE128.new(data=tobytes(tag)).read(length) class SivTests(unittest.TestCase): key_256 = get_tag_random("key_256", 32) key_384 = get_tag_random("key_384", 48) key_512 = get_tag_random("key_512", 64) nonce_96 = get_tag_random("nonce_128", 12) data = get_tag_random("data", 128) def test_loopback_128(self): for key in self.key_256, self.key_384, self.key_512: cipher = AES.new(key, AES.MODE_SIV, nonce=self.nonce_96) pt = get_tag_random("plaintext", 16 * 100) ct, mac = cipher.encrypt_and_digest(pt) cipher = AES.new(key, AES.MODE_SIV, nonce=self.nonce_96) pt2 = cipher.decrypt_and_verify(ct, mac) self.assertEqual(pt, pt2) def test_nonce(self): # Deterministic encryption AES.new(self.key_256, AES.MODE_SIV) cipher = AES.new(self.key_256, AES.MODE_SIV, self.nonce_96) ct1, tag1 = cipher.encrypt_and_digest(self.data) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) ct2, tag2 = cipher.encrypt_and_digest(self.data) self.assertEqual(ct1 + tag1, ct2 + tag2) def test_nonce_must_be_bytes(self): self.assertRaises(TypeError, AES.new, self.key_256, AES.MODE_SIV, nonce=u'test12345678') def test_nonce_length(self): # nonce can be of any length (but not empty) self.assertRaises(ValueError, AES.new, self.key_256, AES.MODE_SIV, nonce=b"") for x in range(1, 128): cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=bchr(1) * x) cipher.encrypt_and_digest(b'\x01') def test_block_size_128(self): cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertEqual(cipher.block_size, AES.block_size) def test_nonce_attribute(self): cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertEqual(cipher.nonce, self.nonce_96) # By default, no nonce is randomly generated self.assertFalse(hasattr(AES.new(self.key_256, AES.MODE_SIV), "nonce")) def test_unknown_parameters(self): self.assertRaises(TypeError, AES.new, self.key_256, AES.MODE_SIV, self.nonce_96, 7) self.assertRaises(TypeError, AES.new, self.key_256, AES.MODE_SIV, nonce=self.nonce_96, unknown=7) # But some are only known by the base cipher # (e.g. use_aesni consumed by the AES module) AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96, use_aesni=False) def test_encrypt_excludes_decrypt(self): cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.encrypt_and_digest(self.data) self.assertRaises(TypeError, cipher.decrypt, self.data) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.encrypt_and_digest(self.data) self.assertRaises(TypeError, cipher.decrypt_and_verify, self.data, self.data) def test_data_must_be_bytes(self): cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertRaises(TypeError, cipher.encrypt, u'test1234567890-*') cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertRaises(TypeError, cipher.decrypt_and_verify, u'test1234567890-*', b"xxxx") def test_mac_len(self): cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) _, mac = cipher.encrypt_and_digest(self.data) self.assertEqual(len(mac), 16) def test_invalid_mac(self): from Cryptodome.Util.strxor import strxor_c cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) ct, mac = cipher.encrypt_and_digest(self.data) invalid_mac = strxor_c(mac, 0x01) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertRaises(ValueError, cipher.decrypt_and_verify, ct, invalid_mac) def test_hex_mac(self): cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) mac_hex = cipher.hexdigest() self.assertEqual(cipher.digest(), unhexlify(mac_hex)) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.hexverify(mac_hex) def test_bytearray(self): # Encrypt key = bytearray(self.key_256) nonce = bytearray(self.nonce_96) data = bytearray(self.data) header = bytearray(self.data) cipher1 = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher1.update(self.data) ct, tag = cipher1.encrypt_and_digest(self.data) cipher2 = AES.new(key, AES.MODE_SIV, nonce=nonce) key[:3] = b'\xFF\xFF\xFF' nonce[:3] = b'\xFF\xFF\xFF' cipher2.update(header) header[:3] = b'\xFF\xFF\xFF' ct_test, tag_test = cipher2.encrypt_and_digest(data) self.assertEqual(ct, ct_test) self.assertEqual(tag, tag_test) self.assertEqual(cipher1.nonce, cipher2.nonce) # Decrypt key = bytearray(self.key_256) nonce = bytearray(self.nonce_96) header = bytearray(self.data) ct_ba = bytearray(ct) tag_ba = bytearray(tag) cipher3 = AES.new(key, AES.MODE_SIV, nonce=nonce) key[:3] = b'\xFF\xFF\xFF' nonce[:3] = b'\xFF\xFF\xFF' cipher3.update(header) header[:3] = b'\xFF\xFF\xFF' pt_test = cipher3.decrypt_and_verify(ct_ba, tag_ba) self.assertEqual(self.data, pt_test) def test_memoryview(self): # Encrypt key = memoryview(bytearray(self.key_256)) nonce = memoryview(bytearray(self.nonce_96)) data = memoryview(bytearray(self.data)) header = memoryview(bytearray(self.data)) cipher1 = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher1.update(self.data) ct, tag = cipher1.encrypt_and_digest(self.data) cipher2 = AES.new(key, AES.MODE_SIV, nonce=nonce) key[:3] = b'\xFF\xFF\xFF' nonce[:3] = b'\xFF\xFF\xFF' cipher2.update(header) header[:3] = b'\xFF\xFF\xFF' ct_test, tag_test= cipher2.encrypt_and_digest(data) self.assertEqual(ct, ct_test) self.assertEqual(tag, tag_test) self.assertEqual(cipher1.nonce, cipher2.nonce) # Decrypt key = memoryview(bytearray(self.key_256)) nonce = memoryview(bytearray(self.nonce_96)) header = memoryview(bytearray(self.data)) ct_ba = memoryview(bytearray(ct)) tag_ba = memoryview(bytearray(tag)) cipher3 = AES.new(key, AES.MODE_SIV, nonce=nonce) key[:3] = b'\xFF\xFF\xFF' nonce[:3] = b'\xFF\xFF\xFF' cipher3.update(header) header[:3] = b'\xFF\xFF\xFF' pt_test = cipher3.decrypt_and_verify(ct_ba, tag_ba) self.assertEqual(self.data, pt_test) def test_output_param(self): pt = b'5' * 128 cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) ct, tag = cipher.encrypt_and_digest(pt) output = bytearray(128) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) res, tag_out = cipher.encrypt_and_digest(pt, output=output) self.assertEqual(ct, output) self.assertEqual(res, None) self.assertEqual(tag, tag_out) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) res = cipher.decrypt_and_verify(ct, tag, output=output) self.assertEqual(pt, output) self.assertEqual(res, None) def test_output_param_memoryview(self): pt = b'5' * 128 cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) ct, tag = cipher.encrypt_and_digest(pt) output = memoryview(bytearray(128)) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.encrypt_and_digest(pt, output=output) self.assertEqual(ct, output) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.decrypt_and_verify(ct, tag, output=output) self.assertEqual(pt, output) def test_output_param_neg(self): LEN_PT = 128 pt = b'5' * LEN_PT cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) ct, tag = cipher.encrypt_and_digest(pt) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertRaises(TypeError, cipher.encrypt_and_digest, pt, output=b'0' * LEN_PT) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertRaises(TypeError, cipher.decrypt_and_verify, ct, tag, output=b'0' * LEN_PT) shorter_output = bytearray(LEN_PT - 1) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertRaises(ValueError, cipher.encrypt_and_digest, pt, output=shorter_output) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertRaises(ValueError, cipher.decrypt_and_verify, ct, tag, output=shorter_output) class SivFSMTests(unittest.TestCase): key_256 = get_tag_random("key_256", 32) nonce_96 = get_tag_random("nonce_96", 12) data = get_tag_random("data", 128) def test_invalid_init_encrypt(self): # Path INIT->ENCRYPT fails cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertRaises(TypeError, cipher.encrypt, b"xxx") def test_invalid_init_decrypt(self): # Path INIT->DECRYPT fails cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) self.assertRaises(TypeError, cipher.decrypt, b"xxx") def test_valid_init_update_digest_verify(self): # No plaintext, fixed authenticated data # Verify path INIT->UPDATE->DIGEST cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.update(self.data) mac = cipher.digest() # Verify path INIT->UPDATE->VERIFY cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.update(self.data) cipher.verify(mac) def test_valid_init_digest(self): # Verify path INIT->DIGEST cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.digest() def test_valid_init_verify(self): # Verify path INIT->VERIFY cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) mac = cipher.digest() cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.verify(mac) def test_valid_multiple_digest_or_verify(self): # Multiple calls to digest cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.update(self.data) first_mac = cipher.digest() for x in range(4): self.assertEqual(first_mac, cipher.digest()) # Multiple calls to verify cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.update(self.data) for x in range(5): cipher.verify(first_mac) def test_valid_encrypt_and_digest_decrypt_and_verify(self): # encrypt_and_digest cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.update(self.data) ct, mac = cipher.encrypt_and_digest(self.data) # decrypt_and_verify cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.update(self.data) pt = cipher.decrypt_and_verify(ct, mac) self.assertEqual(self.data, pt) def test_invalid_multiple_encrypt_and_digest(self): cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) ct, tag = cipher.encrypt_and_digest(self.data) self.assertRaises(TypeError, cipher.encrypt_and_digest, b'') def test_invalid_multiple_decrypt_and_verify(self): cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) ct, tag = cipher.encrypt_and_digest(self.data) cipher = AES.new(self.key_256, AES.MODE_SIV, nonce=self.nonce_96) cipher.decrypt_and_verify(ct, tag) self.assertRaises(TypeError, cipher.decrypt_and_verify, ct, tag) def transform(tv): new_tv = [[unhexlify(x) for x in tv[0].split("-")]] new_tv += [ unhexlify(x) for x in tv[1:5]] if tv[5]: nonce = unhexlify(tv[5]) else: nonce = None new_tv += [ nonce ] return new_tv class TestVectors(unittest.TestCase): """Class exercising the SIV test vectors found in RFC5297""" # This is a list of tuples with 5 items: # # 1. Header + '|' + plaintext # 2. Header + '|' + ciphertext + '|' + MAC # 3. AES-128 key # 4. Description # 5. Dictionary of parameters to be passed to AES.new(). # It must include the nonce. # # A "Header" is a dash ('-') separated sequece of components. # test_vectors_hex = [ ( '101112131415161718191a1b1c1d1e1f2021222324252627', '112233445566778899aabbccddee', '40c02b9690c4dc04daef7f6afe5c', '85632d07c6e8f37f950acd320a2ecc93', 'fffefdfcfbfaf9f8f7f6f5f4f3f2f1f0f0f1f2f3f4f5f6f7f8f9fafbfcfdfeff', None ), ( '00112233445566778899aabbccddeeffdeaddadadeaddadaffeeddccbbaa9988' + '7766554433221100-102030405060708090a0', '7468697320697320736f6d6520706c61696e7465787420746f20656e63727970' + '74207573696e67205349562d414553', 'cb900f2fddbe404326601965c889bf17dba77ceb094fa663b7a3f748ba8af829' + 'ea64ad544a272e9c485b62a3fd5c0d', '7bdb6e3b432667eb06f4d14bff2fbd0f', '7f7e7d7c7b7a79787776757473727170404142434445464748494a4b4c4d4e4f', '09f911029d74e35bd84156c5635688c0' ), ] test_vectors = [ transform(tv) for tv in test_vectors_hex ] def runTest(self): for assoc_data, pt, ct, mac, key, nonce in self.test_vectors: # Encrypt cipher = AES.new(key, AES.MODE_SIV, nonce=nonce) for x in assoc_data: cipher.update(x) ct2, mac2 = cipher.encrypt_and_digest(pt) self.assertEqual(ct, ct2) self.assertEqual(mac, mac2) # Decrypt cipher = AES.new(key, AES.MODE_SIV, nonce=nonce) for x in assoc_data: cipher.update(x) pt2 = cipher.decrypt_and_verify(ct, mac) self.assertEqual(pt, pt2) class TestVectorsWycheproof(unittest.TestCase): def __init__(self): unittest.TestCase.__init__(self) self._id = "None" def setUp(self): self.tv = load_test_vectors_wycheproof(("Cipher", "wycheproof"), "aes_siv_cmac_test.json", "Wycheproof AES SIV") def shortDescription(self): return self._id def test_encrypt(self, tv): self._id = "Wycheproof Encrypt AES-SIV Test #" + str(tv.id) cipher = AES.new(tv.key, AES.MODE_SIV) cipher.update(tv.aad) ct, tag = cipher.encrypt_and_digest(tv.msg) if tv.valid: self.assertEqual(tag + ct, tv.ct) def test_decrypt(self, tv): self._id = "Wycheproof Decrypt AES_SIV Test #" + str(tv.id) cipher = AES.new(tv.key, AES.MODE_SIV) cipher.update(tv.aad) try: pt = cipher.decrypt_and_verify(tv.ct[16:], tv.ct[:16]) except ValueError: assert not tv.valid else: assert tv.valid self.assertEqual(pt, tv.msg) def runTest(self): for tv in self.tv: self.test_encrypt(tv) self.test_decrypt(tv) class TestVectorsWycheproof2(unittest.TestCase): def __init__(self): unittest.TestCase.__init__(self) self._id = "None" def setUp(self): self.tv = load_test_vectors_wycheproof(("Cipher", "wycheproof"), "aead_aes_siv_cmac_test.json", "Wycheproof AEAD SIV") def shortDescription(self): return self._id def test_encrypt(self, tv): self._id = "Wycheproof Encrypt AEAD-AES-SIV Test #" + str(tv.id) cipher = AES.new(tv.key, AES.MODE_SIV, nonce=tv.iv) cipher.update(tv.aad) ct, tag = cipher.encrypt_and_digest(tv.msg) if tv.valid: self.assertEqual(ct, tv.ct) self.assertEqual(tag, tv.tag) def test_decrypt(self, tv): self._id = "Wycheproof Decrypt AEAD-AES-SIV Test #" + str(tv.id) cipher = AES.new(tv.key, AES.MODE_SIV, nonce=tv.iv) cipher.update(tv.aad) try: pt = cipher.decrypt_and_verify(tv.ct, tv.tag) except ValueError: assert not tv.valid else: assert tv.valid self.assertEqual(pt, tv.msg) def runTest(self): for tv in self.tv: self.test_encrypt(tv) self.test_decrypt(tv) def get_tests(config={}): wycheproof_warnings = config.get('wycheproof_warnings') tests = [] tests += list_test_cases(SivTests) tests += list_test_cases(SivFSMTests) tests += [ TestVectors() ] tests += [ TestVectorsWycheproof() ] tests += [ TestVectorsWycheproof2() ] return tests if __name__ == '__main__': suite = lambda: unittest.TestSuite(get_tests()) unittest.main(defaultTest='suite')