import os
import shutil
import subprocess
import pytest
from binascii import unhexlify
try:
import unittest2 as unittest
except ImportError:
import unittest
from .curves import (
NIST192p,
NIST224p,
NIST256p,
NIST384p,
NIST521p,
BRAINPOOLP160r1,
)
from .curves import curves
from .ecdh import (
ECDH,
InvalidCurveError,
InvalidSharedSecretError,
NoKeyError,
NoCurveError,
)
from .keys import SigningKey, VerifyingKey
from .ellipticcurve import CurveEdTw
@pytest.mark.parametrize(
"vcurve",
curves,
ids=[curve.name for curve in curves],
)
def test_ecdh_each(vcurve):
if isinstance(vcurve.curve, CurveEdTw):
pytest.skip("ECDH is not supported for Edwards curves")
ecdh1 = ECDH(curve=vcurve)
ecdh2 = ECDH(curve=vcurve)
ecdh2.generate_private_key()
ecdh1.load_received_public_key(ecdh2.get_public_key())
ecdh2.load_received_public_key(ecdh1.generate_private_key())
secret1 = ecdh1.generate_sharedsecret_bytes()
secret2 = ecdh2.generate_sharedsecret_bytes()
assert secret1 == secret2
def test_ecdh_both_keys_present():
key1 = SigningKey.generate(BRAINPOOLP160r1)
key2 = SigningKey.generate(BRAINPOOLP160r1)
ecdh1 = ECDH(BRAINPOOLP160r1, key1, key2.verifying_key)
ecdh2 = ECDH(private_key=key2, public_key=key1.verifying_key)
secret1 = ecdh1.generate_sharedsecret_bytes()
secret2 = ecdh2.generate_sharedsecret_bytes()
assert secret1 == secret2
def test_ecdh_no_public_key():
ecdh1 = ECDH(curve=NIST192p)
with pytest.raises(NoKeyError):
ecdh1.generate_sharedsecret_bytes()
ecdh1.generate_private_key()
with pytest.raises(NoKeyError):
ecdh1.generate_sharedsecret_bytes()
class TestECDH(unittest.TestCase):
def test_load_key_from_wrong_curve(self):
ecdh1 = ECDH()
ecdh1.set_curve(NIST192p)
key1 = SigningKey.generate(BRAINPOOLP160r1)
with self.assertRaises(InvalidCurveError) as e:
ecdh1.load_private_key(key1)
self.assertIn("Curve mismatch", str(e.exception))
def test_generate_without_curve(self):
ecdh1 = ECDH()
with self.assertRaises(NoCurveError) as e:
ecdh1.generate_private_key()
self.assertIn("Curve must be set", str(e.exception))
def test_load_bytes_without_curve_set(self):
ecdh1 = ECDH()
with self.assertRaises(NoCurveError) as e:
ecdh1.load_private_key_bytes(b"\x01" * 32)
self.assertIn("Curve must be set", str(e.exception))
def test_set_curve_from_received_public_key(self):
ecdh1 = ECDH()
key1 = SigningKey.generate(BRAINPOOLP160r1)
ecdh1.load_received_public_key(key1.verifying_key)
self.assertEqual(ecdh1.curve, BRAINPOOLP160r1)
def test_ecdh_wrong_public_key_curve():
ecdh1 = ECDH(curve=NIST192p)
ecdh1.generate_private_key()
ecdh2 = ECDH(curve=NIST256p)
ecdh2.generate_private_key()
with pytest.raises(InvalidCurveError):
ecdh1.load_received_public_key(ecdh2.get_public_key())
with pytest.raises(InvalidCurveError):
ecdh2.load_received_public_key(ecdh1.get_public_key())
ecdh1.public_key = ecdh2.get_public_key()
ecdh2.public_key = ecdh1.get_public_key()
with pytest.raises(InvalidCurveError):
ecdh1.generate_sharedsecret_bytes()
with pytest.raises(InvalidCurveError):
ecdh2.generate_sharedsecret_bytes()
def test_ecdh_invalid_shared_secret_curve():
ecdh1 = ECDH(curve=NIST256p)
ecdh1.generate_private_key()
ecdh1.load_received_public_key(
SigningKey.generate(NIST256p).get_verifying_key()
)
ecdh1.private_key.privkey.secret_multiplier = ecdh1.private_key.curve.order
with pytest.raises(InvalidSharedSecretError):
ecdh1.generate_sharedsecret_bytes()
# https://github.com/scogliani/ecc-test-vectors/blob/master/ecdh_kat/secp192r1.txt
# https://github.com/scogliani/ecc-test-vectors/blob/master/ecdh_kat/secp256r1.txt
# https://github.com/coruus/nist-testvectors/blob/master/csrc.nist.gov/groups/STM/cavp/documents/components/ecccdhtestvectors/KAS_ECC_CDH_PrimitiveTest.txt
@pytest.mark.parametrize(
"curve,privatekey,pubkey,secret",
[
pytest.param(
NIST192p,
"f17d3fea367b74d340851ca4270dcb24c271f445bed9d527",
"42ea6dd9969dd2a61fea1aac7f8e98edcc896c6e55857cc0"
"dfbe5d7c61fac88b11811bde328e8a0d12bf01a9d204b523",
"803d8ab2e5b6e6fca715737c3a82f7ce3c783124f6d51cd0",
id="NIST192p-1",
),
pytest.param(
NIST192p,
"56e853349d96fe4c442448dacb7cf92bb7a95dcf574a9bd5",
"deb5712fa027ac8d2f22c455ccb73a91e17b6512b5e030e7"
"7e2690a02cc9b28708431a29fb54b87b1f0c14e011ac2125",
"c208847568b98835d7312cef1f97f7aa298283152313c29d",
id="NIST192p-2",
),
pytest.param(
NIST192p,
"c6ef61fe12e80bf56f2d3f7d0bb757394519906d55500949",
"4edaa8efc5a0f40f843663ec5815e7762dddc008e663c20f"
"0a9f8dc67a3e60ef6d64b522185d03df1fc0adfd42478279",
"87229107047a3b611920d6e3b2c0c89bea4f49412260b8dd",
id="NIST192p-3",
),
pytest.param(
NIST192p,
"e6747b9c23ba7044f38ff7e62c35e4038920f5a0163d3cda",
"8887c276edeed3e9e866b46d58d895c73fbd80b63e382e88"
"04c5097ba6645e16206cfb70f7052655947dd44a17f1f9d5",
"eec0bed8fc55e1feddc82158fd6dc0d48a4d796aaf47d46c",
id="NIST192p-4",
),
pytest.param(
NIST192p,
"beabedd0154a1afcfc85d52181c10f5eb47adc51f655047d",
"0d045f30254adc1fcefa8a5b1f31bf4e739dd327cd18d594"
"542c314e41427c08278a08ce8d7305f3b5b849c72d8aff73",
"716e743b1b37a2cd8479f0a3d5a74c10ba2599be18d7e2f4",
id="NIST192p-5",
),
pytest.param(
NIST192p,
"cf70354226667321d6e2baf40999e2fd74c7a0f793fa8699",
"fb35ca20d2e96665c51b98e8f6eb3d79113508d8bccd4516"
"368eec0d5bfb847721df6aaff0e5d48c444f74bf9cd8a5a7",
"f67053b934459985a315cb017bf0302891798d45d0e19508",
id="NIST192p-6",
),
pytest.param(
NIST224p,
"8346a60fc6f293ca5a0d2af68ba71d1dd389e5e40837942df3e43cbd",
"af33cd0629bc7e996320a3f40368f74de8704fa37b8fab69abaae280"
"882092ccbba7930f419a8a4f9bb16978bbc3838729992559a6f2e2d7",
"7d96f9a3bd3c05cf5cc37feb8b9d5209d5c2597464dec3e9983743e8",
id="NIST224p",
),
pytest.param(
NIST256p,
"7d7dc5f71eb29ddaf80d6214632eeae03d9058af1fb6d22ed80badb62bc1a534",
"700c48f77f56584c5cc632ca65640db91b6bacce3a4df6b42ce7cc838833d287"
"db71e509e3fd9b060ddb20ba5c51dcc5948d46fbf640dfe0441782cab85fa4ac",
"46fc62106420ff012e54a434fbdd2d25ccc5852060561e68040dd7778997bd7b",
id="NIST256p-1",
),
pytest.param(
NIST256p,
"38f65d6dce47676044d58ce5139582d568f64bb16098d179dbab07741dd5caf5",
"809f04289c64348c01515eb03d5ce7ac1a8cb9498f5caa50197e58d43a86a7ae"
"b29d84e811197f25eba8f5194092cb6ff440e26d4421011372461f579271cda3",
"057d636096cb80b67a8c038c890e887d1adfa4195e9b3ce241c8a778c59cda67",
id="NIST256p-2",
),
pytest.param(
NIST256p,
"1accfaf1b97712b85a6f54b148985a1bdc4c9bec0bd258cad4b3d603f49f32c8",
"a2339c12d4a03c33546de533268b4ad667debf458b464d77443636440ee7fec3"
"ef48a3ab26e20220bcda2c1851076839dae88eae962869a497bf73cb66faf536",
"2d457b78b4614132477618a5b077965ec90730a8c81a1c75d6d4ec68005d67ec",
id="NIST256p-3",
),
pytest.param(
NIST256p,
"207c43a79bfee03db6f4b944f53d2fb76cc49ef1c9c4d34d51b6c65c4db6932d",
"df3989b9fa55495719b3cf46dccd28b5153f7808191dd518eff0c3cff2b705ed"
"422294ff46003429d739a33206c8752552c8ba54a270defc06e221e0feaf6ac4",
"96441259534b80f6aee3d287a6bb17b5094dd4277d9e294f8fe73e48bf2a0024",
id="NIST256p-4",
),
pytest.param(
NIST256p,
"59137e38152350b195c9718d39673d519838055ad908dd4757152fd8255c09bf",
"41192d2813e79561e6a1d6f53c8bc1a433a199c835e141b05a74a97b0faeb922"
"1af98cc45e98a7e041b01cf35f462b7562281351c8ebf3ffa02e33a0722a1328",
"19d44c8d63e8e8dd12c22a87b8cd4ece27acdde04dbf47f7f27537a6999a8e62",
id="NIST256p-5",
),
pytest.param(
NIST256p,
"f5f8e0174610a661277979b58ce5c90fee6c9b3bb346a90a7196255e40b132ef",
"33e82092a0f1fb38f5649d5867fba28b503172b7035574bf8e5b7100a3052792"
"f2cf6b601e0a05945e335550bf648d782f46186c772c0f20d3cd0d6b8ca14b2f",
"664e45d5bba4ac931cd65d52017e4be9b19a515f669bea4703542a2c525cd3d3",
id="NIST256p-6",
),
pytest.param(
NIST384p,
"3cc3122a68f0d95027ad38c067916ba0eb8c38894d22e1b1"
"5618b6818a661774ad463b205da88cf699ab4d43c9cf98a1",
"a7c76b970c3b5fe8b05d2838ae04ab47697b9eaf52e76459"
"2efda27fe7513272734466b400091adbf2d68c58e0c50066"
"ac68f19f2e1cb879aed43a9969b91a0839c4c38a49749b66"
"1efedf243451915ed0905a32b060992b468c64766fc8437a",
"5f9d29dc5e31a163060356213669c8ce132e22f57c9a04f4"
"0ba7fcead493b457e5621e766c40a2e3d4d6a04b25e533f1",
id="NIST384p",
),
pytest.param(
NIST521p,
"017eecc07ab4b329068fba65e56a1f8890aa935e57134ae0ffcce802735151f4ea"
"c6564f6ee9974c5e6887a1fefee5743ae2241bfeb95d5ce31ddcb6f9edb4d6fc47",
"00685a48e86c79f0f0875f7bc18d25eb5fc8c0b07e5da4f4370f3a949034085433"
"4b1e1b87fa395464c60626124a4e70d0f785601d37c09870ebf176666877a2046d"
"01ba52c56fc8776d9e8f5db4f0cc27636d0b741bbe05400697942e80b739884a83"
"bde99e0f6716939e632bc8986fa18dccd443a348b6c3e522497955a4f3c302f676",
"005fc70477c3e63bc3954bd0df3ea0d1f41ee21746ed95fc5e1fdf90930d5e1366"
"72d72cc770742d1711c3c3a4c334a0ad9759436a4d3c5bf6e74b9578fac148c831",
id="NIST521p",
),
],
)
def test_ecdh_NIST(curve, privatekey, pubkey, secret):
ecdh = ECDH(curve=curve)
ecdh.load_private_key_bytes(unhexlify(privatekey))
ecdh.load_received_public_key_bytes(unhexlify(pubkey))
sharedsecret = ecdh.generate_sharedsecret_bytes()
assert sharedsecret == unhexlify(secret)
pem_local_private_key = (
"-----BEGIN EC PRIVATE KEY-----\n"
"MF8CAQEEGF7IQgvW75JSqULpiQQ8op9WH6Uldw6xxaAKBggqhkjOPQMBAaE0AzIA\n"
"BLiBd9CE7xf15FY5QIAoNg+fWbSk1yZOYtoGUdzkejWkxbRc9RWTQjqLVXucIJnz\n"
"bA==\n"
"-----END EC PRIVATE KEY-----\n"
)
der_local_private_key = (
"305f02010104185ec8420bd6ef9252a942e989043ca29f561fa525770eb1c5a00a06082a864"
"8ce3d030101a13403320004b88177d084ef17f5e45639408028360f9f59b4a4d7264e62da06"
"51dce47a35a4c5b45cf51593423a8b557b9c2099f36c"
)
pem_remote_public_key = (
"-----BEGIN PUBLIC KEY-----\n"
"MEkwEwYHKoZIzj0CAQYIKoZIzj0DAQEDMgAEuIF30ITvF/XkVjlAgCg2D59ZtKTX\n"
"Jk5i2gZR3OR6NaTFtFz1FZNCOotVe5wgmfNs\n"
"-----END PUBLIC KEY-----\n"
)
der_remote_public_key = (
"3049301306072a8648ce3d020106082a8648ce3d03010103320004b88177d084ef17f5e4563"
"9408028360f9f59b4a4d7264e62da0651dce47a35a4c5b45cf51593423a8b557b9c2099f36c"
)
gshared_secret = "8f457e34982478d1c34b9cd2d0c15911b72dd60d869e2cea"
def test_ecdh_pem():
ecdh = ECDH()
ecdh.load_private_key_pem(pem_local_private_key)
ecdh.load_received_public_key_pem(pem_remote_public_key)
sharedsecret = ecdh.generate_sharedsecret_bytes()
assert sharedsecret == unhexlify(gshared_secret)
def test_ecdh_der():
ecdh = ECDH()
ecdh.load_private_key_der(unhexlify(der_local_private_key))
ecdh.load_received_public_key_der(unhexlify(der_remote_public_key))
sharedsecret = ecdh.generate_sharedsecret_bytes()
assert sharedsecret == unhexlify(gshared_secret)
# Exception classes used by run_openssl.
class RunOpenSslError(Exception):
pass
def run_openssl(cmd):
OPENSSL = "openssl"
p = subprocess.Popen(
[OPENSSL] + cmd.split(),
stdout=subprocess.PIPE,
stderr=subprocess.STDOUT,
)
stdout, ignored = p.communicate()
if p.returncode != 0:
raise RunOpenSslError(
"cmd '%s %s' failed: rc=%s, stdout/err was %s"
% (OPENSSL, cmd, p.returncode, stdout)
)
return stdout.decode()
OPENSSL_SUPPORTED_CURVES = set(
c.split(":")[0].strip()
for c in run_openssl("ecparam -list_curves").split("\n")
)
@pytest.mark.parametrize(
"vcurve",
curves,
ids=[curve.name for curve in curves],
)
def test_ecdh_with_openssl(vcurve):
if isinstance(vcurve.curve, CurveEdTw):
pytest.skip("Edwards curves are not supported for ECDH")
assert vcurve.openssl_name
if vcurve.openssl_name not in OPENSSL_SUPPORTED_CURVES:
pytest.skip("system openssl does not support " + vcurve.openssl_name)
try:
hlp = run_openssl("pkeyutl -help")
if hlp.find("-derive") == 0: # pragma: no cover
pytest.skip("system openssl does not support `pkeyutl -derive`")
except RunOpenSslError: # pragma: no cover
pytest.skip("system openssl could not be executed")
if os.path.isdir("t"): # pragma: no branch
shutil.rmtree("t")
os.mkdir("t")
run_openssl(
"ecparam -name %s -genkey -out t/privkey1.pem" % vcurve.openssl_name
)
run_openssl(
"ecparam -name %s -genkey -out t/privkey2.pem" % vcurve.openssl_name
)
run_openssl("ec -in t/privkey1.pem -pubout -out t/pubkey1.pem")
ecdh1 = ECDH(curve=vcurve)
ecdh2 = ECDH(curve=vcurve)
with open("t/privkey1.pem") as e:
key = e.read()
ecdh1.load_private_key_pem(key)
with open("t/privkey2.pem") as e:
key = e.read()
ecdh2.load_private_key_pem(key)
with open("t/pubkey1.pem") as e:
key = e.read()
vk1 = VerifyingKey.from_pem(key)
assert vk1.to_string() == ecdh1.get_public_key().to_string()
vk2 = ecdh2.get_public_key()
with open("t/pubkey2.pem", "wb") as e:
e.write(vk2.to_pem())
ecdh1.load_received_public_key(vk2)
ecdh2.load_received_public_key(vk1)
secret1 = ecdh1.generate_sharedsecret_bytes()
secret2 = ecdh2.generate_sharedsecret_bytes()
assert secret1 == secret2
run_openssl(
"pkeyutl -derive -inkey t/privkey1.pem -peerkey t/pubkey2.pem -out t/secret1"
)
run_openssl(
"pkeyutl -derive -inkey t/privkey2.pem -peerkey t/pubkey1.pem -out t/secret2"
)
with open("t/secret1", "rb") as e:
ssl_secret1 = e.read()
with open("t/secret1", "rb") as e:
ssl_secret2 = e.read()
assert len(ssl_secret1) == vk1.curve.verifying_key_length // 2
assert len(secret1) == vk1.curve.verifying_key_length // 2
assert ssl_secret1 == ssl_secret2
assert secret1 == ssl_secret1