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# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
from __future__ import absolute_import, division, print_function
import binascii
import collections
import json
import math
import os
import re
from contextlib import contextmanager
import pytest
import six
from cryptography.exceptions import UnsupportedAlgorithm
import cryptography_vectors
HashVector = collections.namedtuple("HashVector", ["message", "digest"])
KeyedHashVector = collections.namedtuple(
"KeyedHashVector", ["message", "digest", "key"]
)
def check_backend_support(backend, item):
for mark in item.node.iter_markers("supported"):
if not mark.kwargs["only_if"](backend):
pytest.skip("{0} ({1})".format(
mark.kwargs["skip_message"], backend
))
@contextmanager
def raises_unsupported_algorithm(reason):
with pytest.raises(UnsupportedAlgorithm) as exc_info:
yield exc_info
assert exc_info.value._reason is reason
def load_vectors_from_file(filename, loader, mode="r"):
with cryptography_vectors.open_vector_file(filename, mode) as vector_file:
return loader(vector_file)
def load_nist_vectors(vector_data):
test_data = None
data = []
for line in vector_data:
line = line.strip()
# Blank lines, comments, and section headers are ignored
if not line or line.startswith("#") or (line.startswith("[") and
line.endswith("]")):
continue
if line.strip() == "FAIL":
test_data["fail"] = True
continue
# Build our data using a simple Key = Value format
name, value = [c.strip() for c in line.split("=")]
# Some tests (PBKDF2) contain \0, which should be interpreted as a
# null character rather than literal.
value = value.replace("\\0", "\0")
# COUNT is a special token that indicates a new block of data
if name.upper() == "COUNT":
test_data = {}
data.append(test_data)
continue
# For all other tokens we simply want the name, value stored in
# the dictionary
else:
test_data[name.lower()] = value.encode("ascii")
return data
def load_cryptrec_vectors(vector_data):
cryptrec_list = []
for line in vector_data:
line = line.strip()
# Blank lines and comments are ignored
if not line or line.startswith("#"):
continue
if line.startswith("K"):
key = line.split(" : ")[1].replace(" ", "").encode("ascii")
elif line.startswith("P"):
pt = line.split(" : ")[1].replace(" ", "").encode("ascii")
elif line.startswith("C"):
ct = line.split(" : ")[1].replace(" ", "").encode("ascii")
# after a C is found the K+P+C tuple is complete
# there are many P+C pairs for each K
cryptrec_list.append({
"key": key,
"plaintext": pt,
"ciphertext": ct
})
else:
raise ValueError("Invalid line in file '{}'".format(line))
return cryptrec_list
def load_hash_vectors(vector_data):
vectors = []
key = None
msg = None
md = None
for line in vector_data:
line = line.strip()
if not line or line.startswith("#") or line.startswith("["):
continue
if line.startswith("Len"):
length = int(line.split(" = ")[1])
elif line.startswith("Key"):
# HMAC vectors contain a key attribute. Hash vectors do not.
key = line.split(" = ")[1].encode("ascii")
elif line.startswith("Msg"):
# In the NIST vectors they have chosen to represent an empty
# string as hex 00, which is of course not actually an empty
# string. So we parse the provided length and catch this edge case.
msg = line.split(" = ")[1].encode("ascii") if length > 0 else b""
elif line.startswith("MD"):
md = line.split(" = ")[1]
# after MD is found the Msg+MD (+ potential key) tuple is complete
if key is not None:
vectors.append(KeyedHashVector(msg, md, key))
key = None
msg = None
md = None
else:
vectors.append(HashVector(msg, md))
msg = None
md = None
else:
raise ValueError("Unknown line in hash vector")
return vectors
def load_pkcs1_vectors(vector_data):
"""
Loads data out of RSA PKCS #1 vector files.
"""
private_key_vector = None
public_key_vector = None
attr = None
key = None
example_vector = None
examples = []
vectors = []
for line in vector_data:
if (
line.startswith("# PSS Example") or
line.startswith("# OAEP Example") or
line.startswith("# PKCS#1 v1.5")
):
if example_vector:
for key, value in six.iteritems(example_vector):
hex_str = "".join(value).replace(" ", "").encode("ascii")
example_vector[key] = hex_str
examples.append(example_vector)
attr = None
example_vector = collections.defaultdict(list)
if line.startswith("# Message"):
attr = "message"
continue
elif line.startswith("# Salt"):
attr = "salt"
continue
elif line.startswith("# Seed"):
attr = "seed"
continue
elif line.startswith("# Signature"):
attr = "signature"
continue
elif line.startswith("# Encryption"):
attr = "encryption"
continue
elif (
example_vector and
line.startswith("# =============================================")
):
for key, value in six.iteritems(example_vector):
hex_str = "".join(value).replace(" ", "").encode("ascii")
example_vector[key] = hex_str
examples.append(example_vector)
example_vector = None
attr = None
elif example_vector and line.startswith("#"):
continue
else:
if attr is not None and example_vector is not None:
example_vector[attr].append(line.strip())
continue
if (
line.startswith("# Example") or
line.startswith("# =============================================")
):
if key:
assert private_key_vector
assert public_key_vector
for key, value in six.iteritems(public_key_vector):
hex_str = "".join(value).replace(" ", "")
public_key_vector[key] = int(hex_str, 16)
for key, value in six.iteritems(private_key_vector):
hex_str = "".join(value).replace(" ", "")
private_key_vector[key] = int(hex_str, 16)
private_key_vector["examples"] = examples
examples = []
assert (
private_key_vector['public_exponent'] ==
public_key_vector['public_exponent']
)
assert (
private_key_vector['modulus'] ==
public_key_vector['modulus']
)
vectors.append(
(private_key_vector, public_key_vector)
)
public_key_vector = collections.defaultdict(list)
private_key_vector = collections.defaultdict(list)
key = None
attr = None
if private_key_vector is None or public_key_vector is None:
# Random garbage to defeat CPython's peephole optimizer so that
# coverage records correctly: https://bugs.python.org/issue2506
1 + 1
continue
if line.startswith("# Private key"):
key = private_key_vector
elif line.startswith("# Public key"):
key = public_key_vector
elif line.startswith("# Modulus:"):
attr = "modulus"
elif line.startswith("# Public exponent:"):
attr = "public_exponent"
elif line.startswith("# Exponent:"):
if key is public_key_vector:
attr = "public_exponent"
else:
assert key is private_key_vector
attr = "private_exponent"
elif line.startswith("# Prime 1:"):
attr = "p"
elif line.startswith("# Prime 2:"):
attr = "q"
elif line.startswith("# Prime exponent 1:"):
attr = "dmp1"
elif line.startswith("# Prime exponent 2:"):
attr = "dmq1"
elif line.startswith("# Coefficient:"):
attr = "iqmp"
elif line.startswith("#"):
attr = None
else:
if key is not None and attr is not None:
key[attr].append(line.strip())
return vectors
def load_rsa_nist_vectors(vector_data):
test_data = None
p = None
salt_length = None
data = []
for line in vector_data:
line = line.strip()
# Blank lines and section headers are ignored
if not line or line.startswith("["):
continue
if line.startswith("# Salt len:"):
salt_length = int(line.split(":")[1].strip())
continue
elif line.startswith("#"):
continue
# Build our data using a simple Key = Value format
name, value = [c.strip() for c in line.split("=")]
if name == "n":
n = int(value, 16)
elif name == "e" and p is None:
e = int(value, 16)
elif name == "p":
p = int(value, 16)
elif name == "q":
q = int(value, 16)
elif name == "SHAAlg":
if p is None:
test_data = {
"modulus": n,
"public_exponent": e,
"salt_length": salt_length,
"algorithm": value,
"fail": False
}
else:
test_data = {
"modulus": n,
"p": p,
"q": q,
"algorithm": value
}
if salt_length is not None:
test_data["salt_length"] = salt_length
data.append(test_data)
elif name == "e" and p is not None:
test_data["public_exponent"] = int(value, 16)
elif name == "d":
test_data["private_exponent"] = int(value, 16)
elif name == "Result":
test_data["fail"] = value.startswith("F")
# For all other tokens we simply want the name, value stored in
# the dictionary
else:
test_data[name.lower()] = value.encode("ascii")
return data
def load_fips_dsa_key_pair_vectors(vector_data):
"""
Loads data out of the FIPS DSA KeyPair vector files.
"""
vectors = []
for line in vector_data:
line = line.strip()
if not line or line.startswith("#") or line.startswith("[mod"):
continue
if line.startswith("P"):
vectors.append({'p': int(line.split("=")[1], 16)})
elif line.startswith("Q"):
vectors[-1]['q'] = int(line.split("=")[1], 16)
elif line.startswith("G"):
vectors[-1]['g'] = int(line.split("=")[1], 16)
elif line.startswith("X") and 'x' not in vectors[-1]:
vectors[-1]['x'] = int(line.split("=")[1], 16)
elif line.startswith("X") and 'x' in vectors[-1]:
vectors.append({'p': vectors[-1]['p'],
'q': vectors[-1]['q'],
'g': vectors[-1]['g'],
'x': int(line.split("=")[1], 16)
})
elif line.startswith("Y"):
vectors[-1]['y'] = int(line.split("=")[1], 16)
return vectors
def load_fips_dsa_sig_vectors(vector_data):
"""
Loads data out of the FIPS DSA SigVer vector files.
"""
vectors = []
sha_regex = re.compile(
r"\[mod = L=...., N=..., SHA-(?P<sha>1|224|256|384|512)\]"
)
for line in vector_data:
line = line.strip()
if not line or line.startswith("#"):
continue
sha_match = sha_regex.match(line)
if sha_match:
digest_algorithm = "SHA-{0}".format(sha_match.group("sha"))
if line.startswith("[mod"):
continue
name, value = [c.strip() for c in line.split("=")]
if name == "P":
vectors.append({'p': int(value, 16),
'digest_algorithm': digest_algorithm})
elif name == "Q":
vectors[-1]['q'] = int(value, 16)
elif name == "G":
vectors[-1]['g'] = int(value, 16)
elif name == "Msg" and 'msg' not in vectors[-1]:
hexmsg = value.strip().encode("ascii")
vectors[-1]['msg'] = binascii.unhexlify(hexmsg)
elif name == "Msg" and 'msg' in vectors[-1]:
hexmsg = value.strip().encode("ascii")
vectors.append({'p': vectors[-1]['p'],
'q': vectors[-1]['q'],
'g': vectors[-1]['g'],
'digest_algorithm':
vectors[-1]['digest_algorithm'],
'msg': binascii.unhexlify(hexmsg)})
elif name == "X":
vectors[-1]['x'] = int(value, 16)
elif name == "Y":
vectors[-1]['y'] = int(value, 16)
elif name == "R":
vectors[-1]['r'] = int(value, 16)
elif name == "S":
vectors[-1]['s'] = int(value, 16)
elif name == "Result":
vectors[-1]['result'] = value.split("(")[0].strip()
return vectors
# http://tools.ietf.org/html/rfc4492#appendix-A
_ECDSA_CURVE_NAMES = {
"P-192": "secp192r1",
"P-224": "secp224r1",
"P-256": "secp256r1",
"P-384": "secp384r1",
"P-521": "secp521r1",
"K-163": "sect163k1",
"K-233": "sect233k1",
"K-256": "secp256k1",
"K-283": "sect283k1",
"K-409": "sect409k1",
"K-571": "sect571k1",
"B-163": "sect163r2",
"B-233": "sect233r1",
"B-283": "sect283r1",
"B-409": "sect409r1",
"B-571": "sect571r1",
}
def load_fips_ecdsa_key_pair_vectors(vector_data):
"""
Loads data out of the FIPS ECDSA KeyPair vector files.
"""
vectors = []
key_data = None
for line in vector_data:
line = line.strip()
if not line or line.startswith("#"):
continue
if line[1:-1] in _ECDSA_CURVE_NAMES:
curve_name = _ECDSA_CURVE_NAMES[line[1:-1]]
elif line.startswith("d = "):
if key_data is not None:
vectors.append(key_data)
key_data = {
"curve": curve_name,
"d": int(line.split("=")[1], 16)
}
elif key_data is not None:
if line.startswith("Qx = "):
key_data["x"] = int(line.split("=")[1], 16)
elif line.startswith("Qy = "):
key_data["y"] = int(line.split("=")[1], 16)
assert key_data is not None
vectors.append(key_data)
return vectors
def load_fips_ecdsa_signing_vectors(vector_data):
"""
Loads data out of the FIPS ECDSA SigGen vector files.
"""
vectors = []
curve_rx = re.compile(
r"\[(?P<curve>[PKB]-[0-9]{3}),SHA-(?P<sha>1|224|256|384|512)\]"
)
data = None
for line in vector_data:
line = line.strip()
curve_match = curve_rx.match(line)
if curve_match:
curve_name = _ECDSA_CURVE_NAMES[curve_match.group("curve")]
digest_name = "SHA-{0}".format(curve_match.group("sha"))
elif line.startswith("Msg = "):
if data is not None:
vectors.append(data)
hexmsg = line.split("=")[1].strip().encode("ascii")
data = {
"curve": curve_name,
"digest_algorithm": digest_name,
"message": binascii.unhexlify(hexmsg)
}
elif data is not None:
if line.startswith("Qx = "):
data["x"] = int(line.split("=")[1], 16)
elif line.startswith("Qy = "):
data["y"] = int(line.split("=")[1], 16)
elif line.startswith("R = "):
data["r"] = int(line.split("=")[1], 16)
elif line.startswith("S = "):
data["s"] = int(line.split("=")[1], 16)
elif line.startswith("d = "):
data["d"] = int(line.split("=")[1], 16)
elif line.startswith("Result = "):
data["fail"] = line.split("=")[1].strip()[0] == "F"
assert data is not None
vectors.append(data)
return vectors
def load_kasvs_dh_vectors(vector_data):
"""
Loads data out of the KASVS key exchange vector data
"""
result_rx = re.compile(r"([FP]) \(([0-9]+) -")
vectors = []
data = {
"fail_z": False,
"fail_agree": False
}
for line in vector_data:
line = line.strip()
if not line or line.startswith("#"):
continue
if line.startswith("P = "):
data["p"] = int(line.split("=")[1], 16)
elif line.startswith("Q = "):
data["q"] = int(line.split("=")[1], 16)
elif line.startswith("G = "):
data["g"] = int(line.split("=")[1], 16)
elif line.startswith("Z = "):
z_hex = line.split("=")[1].strip().encode("ascii")
data["z"] = binascii.unhexlify(z_hex)
elif line.startswith("XstatCAVS = "):
data["x1"] = int(line.split("=")[1], 16)
elif line.startswith("YstatCAVS = "):
data["y1"] = int(line.split("=")[1], 16)
elif line.startswith("XstatIUT = "):
data["x2"] = int(line.split("=")[1], 16)
elif line.startswith("YstatIUT = "):
data["y2"] = int(line.split("=")[1], 16)
elif line.startswith("Result = "):
result_str = line.split("=")[1].strip()
match = result_rx.match(result_str)
if match.group(1) == "F":
if int(match.group(2)) in (5, 10):
data["fail_z"] = True
else:
data["fail_agree"] = True
vectors.append(data)
data = {
"p": data["p"],
"q": data["q"],
"g": data["g"],
"fail_z": False,
"fail_agree": False
}
return vectors
def load_kasvs_ecdh_vectors(vector_data):
"""
Loads data out of the KASVS key exchange vector data
"""
curve_name_map = {
"P-192": "secp192r1",
"P-224": "secp224r1",
"P-256": "secp256r1",
"P-384": "secp384r1",
"P-521": "secp521r1",
}
result_rx = re.compile(r"([FP]) \(([0-9]+) -")
tags = []
sets = {}
vectors = []
# find info in header
for line in vector_data:
line = line.strip()
if line.startswith("#"):
parm = line.split("Parameter set(s) supported:")
if len(parm) == 2:
names = parm[1].strip().split()
for n in names:
tags.append("[%s]" % n)
break
# Sets Metadata
tag = None
curve = None
for line in vector_data:
line = line.strip()
if not line or line.startswith("#"):
continue
if line in tags:
tag = line
curve = None
elif line.startswith("[Curve selected:"):
curve = curve_name_map[line.split(':')[1].strip()[:-1]]
if tag is not None and curve is not None:
sets[tag.strip("[]")] = curve
tag = None
if len(tags) == len(sets):
break
# Data
data = {
"CAVS": {},
"IUT": {},
}
tag = None
for line in vector_data:
line = line.strip()
if not line or line.startswith("#"):
continue
if line.startswith("["):
tag = line.split()[0][1:]
elif line.startswith("COUNT = "):
data["COUNT"] = int(line.split("=")[1])
elif line.startswith("dsCAVS = "):
data["CAVS"]["d"] = int(line.split("=")[1], 16)
elif line.startswith("QsCAVSx = "):
data["CAVS"]["x"] = int(line.split("=")[1], 16)
elif line.startswith("QsCAVSy = "):
data["CAVS"]["y"] = int(line.split("=")[1], 16)
elif line.startswith("dsIUT = "):
data["IUT"]["d"] = int(line.split("=")[1], 16)
elif line.startswith("QsIUTx = "):
data["IUT"]["x"] = int(line.split("=")[1], 16)
elif line.startswith("QsIUTy = "):
data["IUT"]["y"] = int(line.split("=")[1], 16)
elif line.startswith("OI = "):
data["OI"] = int(line.split("=")[1], 16)
elif line.startswith("Z = "):
data["Z"] = int(line.split("=")[1], 16)
elif line.startswith("DKM = "):
data["DKM"] = int(line.split("=")[1], 16)
elif line.startswith("Result = "):
result_str = line.split("=")[1].strip()
match = result_rx.match(result_str)
if match.group(1) == "F":
data["fail"] = True
else:
data["fail"] = False
data["errno"] = int(match.group(2))
data["curve"] = sets[tag]
vectors.append(data)
data = {
"CAVS": {},
"IUT": {},
}
return vectors
def load_x963_vectors(vector_data):
"""
Loads data out of the X9.63 vector data
"""
vectors = []
# Sets Metadata
hashname = None
vector = {}
for line in vector_data:
line = line.strip()
if line.startswith("[SHA"):
hashname = line[1:-1]
shared_secret_len = 0
shared_info_len = 0
key_data_len = 0
elif line.startswith("[shared secret length"):
shared_secret_len = int(line[1:-1].split("=")[1].strip())
elif line.startswith("[SharedInfo length"):
shared_info_len = int(line[1:-1].split("=")[1].strip())
elif line.startswith("[key data length"):
key_data_len = int(line[1:-1].split("=")[1].strip())
elif line.startswith("COUNT"):
count = int(line.split("=")[1].strip())
vector["hash"] = hashname
vector["count"] = count
vector["shared_secret_length"] = shared_secret_len
vector["sharedinfo_length"] = shared_info_len
vector["key_data_length"] = key_data_len
elif line.startswith("Z"):
vector["Z"] = line.split("=")[1].strip()
assert math.ceil(shared_secret_len / 8) * 2 == len(vector["Z"])
elif line.startswith("SharedInfo"):
if shared_info_len != 0:
vector["sharedinfo"] = line.split("=")[1].strip()
silen = len(vector["sharedinfo"])
assert math.ceil(shared_info_len / 8) * 2 == silen
elif line.startswith("key_data"):
vector["key_data"] = line.split("=")[1].strip()
assert math.ceil(key_data_len / 8) * 2 == len(vector["key_data"])
vectors.append(vector)
vector = {}
return vectors
def load_nist_kbkdf_vectors(vector_data):
"""
Load NIST SP 800-108 KDF Vectors
"""
vectors = []
test_data = None
tag = {}
for line in vector_data:
line = line.strip()
if not line or line.startswith("#"):
continue
if line.startswith("[") and line.endswith("]"):
tag_data = line[1:-1]
name, value = [c.strip() for c in tag_data.split("=")]
if value.endswith('_BITS'):
value = int(value.split('_')[0])
tag.update({name.lower(): value})
continue
tag.update({name.lower(): value.lower()})
elif line.startswith("COUNT="):
test_data = dict()
test_data.update(tag)
vectors.append(test_data)
elif line.startswith("L"):
name, value = [c.strip() for c in line.split("=")]
test_data[name.lower()] = int(value)
else:
name, value = [c.strip() for c in line.split("=")]
test_data[name.lower()] = value.encode("ascii")
return vectors
def load_ed25519_vectors(vector_data):
data = []
for line in vector_data:
secret_key, public_key, message, signature, _ = line.split(':')
# In the vectors the first element is secret key + public key
secret_key = secret_key[0:64]
# In the vectors the signature section is signature + message
signature = signature[0:128]
data.append({
"secret_key": secret_key,
"public_key": public_key,
"message": message,
"signature": signature
})
return data
def load_nist_ccm_vectors(vector_data):
test_data = None
section_data = None
global_data = {}
new_section = False
data = []
for line in vector_data:
line = line.strip()
# Blank lines and comments should be ignored
if not line or line.startswith("#"):
continue
# Some of the CCM vectors have global values for this. They are always
# at the top before the first section header (see: VADT, VNT, VPT)
if line.startswith(("Alen", "Plen", "Nlen", "Tlen")):
name, value = [c.strip() for c in line.split("=")]
global_data[name.lower()] = int(value)
continue
# section headers contain length data we might care about
if line.startswith("["):
new_section = True
section_data = {}
section = line[1:-1]
items = [c.strip() for c in section.split(",")]
for item in items:
name, value = [c.strip() for c in item.split("=")]
section_data[name.lower()] = int(value)
continue
name, value = [c.strip() for c in line.split("=")]
if name.lower() in ("key", "nonce") and new_section:
section_data[name.lower()] = value.encode("ascii")
continue
new_section = False
# Payload is sometimes special because these vectors are absurd. Each
# example may or may not have a payload. If it does not then the
# previous example's payload should be used. We accomplish this by
# writing it into the section_data. Because we update each example
# with the section data it will be overwritten if a new payload value
# is present. NIST should be ashamed of their vector creation.
if name.lower() == "payload":
section_data[name.lower()] = value.encode("ascii")
# Result is a special token telling us if the test should pass/fail.
# This is only present in the DVPT CCM tests
if name.lower() == "result":
if value.lower() == "pass":
test_data["fail"] = False
else:
test_data["fail"] = True
continue
# COUNT is a special token that indicates a new block of data
if name.lower() == "count":
test_data = {}
test_data.update(global_data)
test_data.update(section_data)
data.append(test_data)
continue
# For all other tokens we simply want the name, value stored in
# the dictionary
else:
test_data[name.lower()] = value.encode("ascii")
return data
class WycheproofTest(object):
def __init__(self, testgroup, testcase):
self.testgroup = testgroup
self.testcase = testcase
def __repr__(self):
return "<WycheproofTest({!r}, {!r}, tcId={})>".format(
self.testgroup, self.testcase, self.testcase["tcId"],
)
@property
def valid(self):
return self.testcase["result"] == "valid"
@property
def acceptable(self):
return self.testcase["result"] == "acceptable"
@property
def invalid(self):
return self.testcase["result"] == "invalid"
def has_flag(self, flag):
return flag in self.testcase["flags"]
def skip_if_wycheproof_none(wycheproof):
# This is factored into its own function so we can easily test both
# branches
if wycheproof is None:
pytest.skip("--wycheproof-root not provided")
def load_wycheproof_tests(wycheproof, test_file):
path = os.path.join(wycheproof, "testvectors", test_file)
with open(path) as f:
data = json.load(f)
for group in data["testGroups"]:
cases = group.pop("tests")
for c in cases:
yield WycheproofTest(group, c)
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