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# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
# implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from __future__ import absolute_import, division, print_function
import binascii
import itertools
import os
import pytest
from cryptography.exceptions import (
AlreadyFinalized, AlreadyUpdated, InvalidSignature, InvalidTag,
NotYetFinalized
)
from cryptography.hazmat.primitives import hashes, hmac
from cryptography.hazmat.primitives.asymmetric import rsa
from cryptography.hazmat.primitives.ciphers import Cipher
from cryptography.hazmat.primitives.kdf.hkdf import HKDF
from cryptography.hazmat.primitives.kdf.pbkdf2 import PBKDF2HMAC
from ...utils import load_vectors_from_file
def _load_all_params(path, file_names, param_loader):
all_params = []
for file_name in file_names:
all_params.extend(
load_vectors_from_file(os.path.join(path, file_name), param_loader)
)
return all_params
def generate_encrypt_test(param_loader, path, file_names, cipher_factory,
mode_factory):
all_params = _load_all_params(path, file_names, param_loader)
@pytest.mark.parametrize("params", all_params)
def test_encryption(self, backend, params):
encrypt_test(backend, cipher_factory, mode_factory, params)
return test_encryption
def encrypt_test(backend, cipher_factory, mode_factory, params):
plaintext = params["plaintext"]
ciphertext = params["ciphertext"]
cipher = Cipher(
cipher_factory(**params),
mode_factory(**params),
backend=backend
)
encryptor = cipher.encryptor()
actual_ciphertext = encryptor.update(binascii.unhexlify(plaintext))
actual_ciphertext += encryptor.finalize()
assert actual_ciphertext == binascii.unhexlify(ciphertext)
decryptor = cipher.decryptor()
actual_plaintext = decryptor.update(binascii.unhexlify(ciphertext))
actual_plaintext += decryptor.finalize()
assert actual_plaintext == binascii.unhexlify(plaintext)
def generate_aead_test(param_loader, path, file_names, cipher_factory,
mode_factory):
all_params = _load_all_params(path, file_names, param_loader)
@pytest.mark.parametrize("params", all_params)
def test_aead(self, backend, params):
aead_test(backend, cipher_factory, mode_factory, params)
return test_aead
def aead_test(backend, cipher_factory, mode_factory, params):
if params.get("pt") is not None:
plaintext = params["pt"]
ciphertext = params["ct"]
aad = params["aad"]
if params.get("fail") is True:
cipher = Cipher(
cipher_factory(binascii.unhexlify(params["key"])),
mode_factory(binascii.unhexlify(params["iv"]),
binascii.unhexlify(params["tag"])),
backend
)
decryptor = cipher.decryptor()
decryptor.authenticate_additional_data(binascii.unhexlify(aad))
actual_plaintext = decryptor.update(binascii.unhexlify(ciphertext))
with pytest.raises(InvalidTag):
decryptor.finalize()
else:
cipher = Cipher(
cipher_factory(binascii.unhexlify(params["key"])),
mode_factory(binascii.unhexlify(params["iv"]), None),
backend
)
encryptor = cipher.encryptor()
encryptor.authenticate_additional_data(binascii.unhexlify(aad))
actual_ciphertext = encryptor.update(binascii.unhexlify(plaintext))
actual_ciphertext += encryptor.finalize()
tag_len = len(params["tag"])
assert binascii.hexlify(encryptor.tag)[:tag_len] == params["tag"]
cipher = Cipher(
cipher_factory(binascii.unhexlify(params["key"])),
mode_factory(binascii.unhexlify(params["iv"]),
binascii.unhexlify(params["tag"])),
backend
)
decryptor = cipher.decryptor()
decryptor.authenticate_additional_data(binascii.unhexlify(aad))
actual_plaintext = decryptor.update(binascii.unhexlify(ciphertext))
actual_plaintext += decryptor.finalize()
assert actual_plaintext == binascii.unhexlify(plaintext)
def generate_stream_encryption_test(param_loader, path, file_names,
cipher_factory):
all_params = _load_all_params(path, file_names, param_loader)
@pytest.mark.parametrize("params", all_params)
def test_stream_encryption(self, backend, params):
stream_encryption_test(backend, cipher_factory, params)
return test_stream_encryption
def stream_encryption_test(backend, cipher_factory, params):
plaintext = params["plaintext"]
ciphertext = params["ciphertext"]
offset = params["offset"]
cipher = Cipher(cipher_factory(**params), None, backend=backend)
encryptor = cipher.encryptor()
# throw away offset bytes
encryptor.update(b"\x00" * int(offset))
actual_ciphertext = encryptor.update(binascii.unhexlify(plaintext))
actual_ciphertext += encryptor.finalize()
assert actual_ciphertext == binascii.unhexlify(ciphertext)
decryptor = cipher.decryptor()
decryptor.update(b"\x00" * int(offset))
actual_plaintext = decryptor.update(binascii.unhexlify(ciphertext))
actual_plaintext += decryptor.finalize()
assert actual_plaintext == binascii.unhexlify(plaintext)
def generate_hash_test(param_loader, path, file_names, hash_cls):
all_params = _load_all_params(path, file_names, param_loader)
@pytest.mark.parametrize("params", all_params)
def test_hash(self, backend, params):
hash_test(backend, hash_cls, params)
return test_hash
def hash_test(backend, algorithm, params):
msg, md = params
m = hashes.Hash(algorithm, backend=backend)
m.update(binascii.unhexlify(msg))
expected_md = md.replace(" ", "").lower().encode("ascii")
assert m.finalize() == binascii.unhexlify(expected_md)
def generate_base_hash_test(algorithm, digest_size, block_size):
def test_base_hash(self, backend):
base_hash_test(backend, algorithm, digest_size, block_size)
return test_base_hash
def base_hash_test(backend, algorithm, digest_size, block_size):
m = hashes.Hash(algorithm, backend=backend)
assert m.algorithm.digest_size == digest_size
assert m.algorithm.block_size == block_size
m_copy = m.copy()
assert m != m_copy
assert m._ctx != m_copy._ctx
m.update(b"abc")
copy = m.copy()
copy.update(b"123")
m.update(b"123")
assert copy.finalize() == m.finalize()
def generate_long_string_hash_test(hash_factory, md):
def test_long_string_hash(self, backend):
long_string_hash_test(backend, hash_factory, md)
return test_long_string_hash
def long_string_hash_test(backend, algorithm, md):
m = hashes.Hash(algorithm, backend=backend)
m.update(b"a" * 1000000)
assert m.finalize() == binascii.unhexlify(md.lower().encode("ascii"))
def generate_base_hmac_test(hash_cls):
def test_base_hmac(self, backend):
base_hmac_test(backend, hash_cls)
return test_base_hmac
def base_hmac_test(backend, algorithm):
key = b"ab"
h = hmac.HMAC(binascii.unhexlify(key), algorithm, backend=backend)
h_copy = h.copy()
assert h != h_copy
assert h._ctx != h_copy._ctx
def generate_hmac_test(param_loader, path, file_names, algorithm):
all_params = _load_all_params(path, file_names, param_loader)
@pytest.mark.parametrize("params", all_params)
def test_hmac(self, backend, params):
hmac_test(backend, algorithm, params)
return test_hmac
def hmac_test(backend, algorithm, params):
msg, md, key = params
h = hmac.HMAC(binascii.unhexlify(key), algorithm, backend=backend)
h.update(binascii.unhexlify(msg))
assert h.finalize() == binascii.unhexlify(md.encode("ascii"))
def generate_pbkdf2_test(param_loader, path, file_names, algorithm):
all_params = _load_all_params(path, file_names, param_loader)
@pytest.mark.parametrize("params", all_params)
def test_pbkdf2(self, backend, params):
pbkdf2_test(backend, algorithm, params)
return test_pbkdf2
def pbkdf2_test(backend, algorithm, params):
# Password and salt can contain \0, which should be loaded as a null char.
# The NIST loader loads them as literal strings so we replace with the
# proper value.
kdf = PBKDF2HMAC(
algorithm,
int(params["length"]),
params["salt"],
int(params["iterations"]),
backend
)
derived_key = kdf.derive(params["password"])
assert binascii.hexlify(derived_key) == params["derived_key"]
def generate_aead_exception_test(cipher_factory, mode_factory):
def test_aead_exception(self, backend):
aead_exception_test(backend, cipher_factory, mode_factory)
return test_aead_exception
def aead_exception_test(backend, cipher_factory, mode_factory):
cipher = Cipher(
cipher_factory(binascii.unhexlify(b"0" * 32)),
mode_factory(binascii.unhexlify(b"0" * 24)),
backend
)
encryptor = cipher.encryptor()
encryptor.update(b"a" * 16)
with pytest.raises(NotYetFinalized):
encryptor.tag
with pytest.raises(AlreadyUpdated):
encryptor.authenticate_additional_data(b"b" * 16)
encryptor.finalize()
with pytest.raises(AlreadyFinalized):
encryptor.authenticate_additional_data(b"b" * 16)
with pytest.raises(AlreadyFinalized):
encryptor.update(b"b" * 16)
with pytest.raises(AlreadyFinalized):
encryptor.finalize()
cipher = Cipher(
cipher_factory(binascii.unhexlify(b"0" * 32)),
mode_factory(binascii.unhexlify(b"0" * 24), b"0" * 16),
backend
)
decryptor = cipher.decryptor()
decryptor.update(b"a" * 16)
with pytest.raises(AttributeError):
decryptor.tag
def generate_aead_tag_exception_test(cipher_factory, mode_factory):
def test_aead_tag_exception(self, backend):
aead_tag_exception_test(backend, cipher_factory, mode_factory)
return test_aead_tag_exception
def aead_tag_exception_test(backend, cipher_factory, mode_factory):
cipher = Cipher(
cipher_factory(binascii.unhexlify(b"0" * 32)),
mode_factory(binascii.unhexlify(b"0" * 24)),
backend
)
with pytest.raises(ValueError):
cipher.decryptor()
with pytest.raises(ValueError):
mode_factory(binascii.unhexlify(b"0" * 24), b"000")
cipher = Cipher(
cipher_factory(binascii.unhexlify(b"0" * 32)),
mode_factory(binascii.unhexlify(b"0" * 24), b"0" * 16),
backend
)
with pytest.raises(ValueError):
cipher.encryptor()
def hkdf_derive_test(backend, algorithm, params):
hkdf = HKDF(
algorithm,
int(params["l"]),
salt=binascii.unhexlify(params["salt"]) or None,
info=binascii.unhexlify(params["info"]) or None,
backend=backend
)
okm = hkdf.derive(binascii.unhexlify(params["ikm"]))
assert okm == binascii.unhexlify(params["okm"])
def hkdf_extract_test(backend, algorithm, params):
hkdf = HKDF(
algorithm,
int(params["l"]),
salt=binascii.unhexlify(params["salt"]) or None,
info=binascii.unhexlify(params["info"]) or None,
backend=backend
)
prk = hkdf._extract(binascii.unhexlify(params["ikm"]))
assert prk == binascii.unhexlify(params["prk"])
def hkdf_expand_test(backend, algorithm, params):
hkdf = HKDF(
algorithm,
int(params["l"]),
salt=binascii.unhexlify(params["salt"]) or None,
info=binascii.unhexlify(params["info"]) or None,
backend=backend
)
okm = hkdf._expand(binascii.unhexlify(params["prk"]))
assert okm == binascii.unhexlify(params["okm"])
def generate_hkdf_test(param_loader, path, file_names, algorithm):
all_params = _load_all_params(path, file_names, param_loader)
all_tests = [hkdf_extract_test, hkdf_expand_test, hkdf_derive_test]
@pytest.mark.parametrize(
("params", "hkdf_test"),
itertools.product(all_params, all_tests)
)
def test_hkdf(self, backend, params, hkdf_test):
hkdf_test(backend, algorithm, params)
return test_hkdf
def generate_rsa_verification_test(param_loader, path, file_names, hash_alg,
pad_factory):
all_params = _load_all_params(path, file_names, param_loader)
all_params = [i for i in all_params
if i["algorithm"] == hash_alg.name.upper()]
@pytest.mark.parametrize("params", all_params)
def test_rsa_verification(self, backend, params):
rsa_verification_test(backend, params, hash_alg, pad_factory)
return test_rsa_verification
def rsa_verification_test(backend, params, hash_alg, pad_factory):
public_key = rsa.RSAPublicKey(
public_exponent=params["public_exponent"],
modulus=params["modulus"]
)
pad = pad_factory(params, hash_alg)
verifier = public_key.verifier(
binascii.unhexlify(params["s"]),
pad,
hash_alg,
backend
)
verifier.update(binascii.unhexlify(params["msg"]))
if params["fail"]:
with pytest.raises(InvalidSignature):
verifier.verify()
else:
verifier.verify()
def _check_rsa_private_key(skey):
assert skey
assert skey.modulus
assert skey.public_exponent
assert skey.private_exponent
assert skey.p * skey.q == skey.modulus
assert skey.key_size
assert skey.dmp1 == rsa.rsa_crt_dmp1(skey.d, skey.p)
assert skey.dmq1 == rsa.rsa_crt_dmq1(skey.d, skey.q)
assert skey.iqmp == rsa.rsa_crt_iqmp(skey.p, skey.q)
pkey = skey.public_key()
assert pkey
assert skey.modulus == pkey.modulus
assert skey.public_exponent == pkey.public_exponent
assert skey.key_size == pkey.key_size
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