def decode_jwt(token):
"""
Validate and decode the web token from the Amazon Cognito.
Stores the public key needed to decrypt the token.
Returns
"""
url="https://cognito-idp.{}.amazonaws.com/{}/.well-known/jwks.json".format(AWS_REGION,USER_POOL_ID)
try:
r = requests.get(url)
logger.debug(r.status_code)
key_set = load_jwks(r.text)
except:
logger.debug(traceback.format_exc())
return False
try:
token_dict = jws.verify_compact(token, keys=key_set)
logger.info(token_dict)
if token_dict['exp'] < time.time():
logger.debug("Token Expired")
return False
if token_dict['email_verified']:
return {"user_id":token_dict['sub'],
"user_email":token_dict['email']}
else:
logger.debug("E-mail not verfied.")
return False
except:
logger.debug(traceback.format_exc())
return False
def gen_sym_key(ekid, new_kid=None, iv=None, k=None):
out = {'kid': ekid, 'cty': 'b5+jwk+json'}
if new_kid != None:
kid = new_kid
else:
kid = gen_uuid()
if k != None:
new_key = k
else:
new_key = get_random_bytes(32)
key_dat = {
'alg': 'A256GCM',
'ext': True,
'key_ops': ['decrypt', 'encrypt'],
'kty': 'oct',
'kid': kid
}
key_dat['k'] = optestlib.opb64e(new_key)
key_dat_str = json.dumps(key_dat)
optestlib.p_str("New symmetric key", json.dumps(key_dat, indent=4))
sym_keys[kid] = new_key
if ekid == 'mp':
# sym_keys['mk'] = new_key
optestlib.p_debug('\n*** Encrypting sym key with AES kid %s' % ekid)
iv, ct = optestlib.enc_aes_gcm(key_dat_str, sym_keys[ekid], iv=iv)
optestlib.p_data('IV', iv, dump=False)
optestlib.p_data('KEY', sym_keys[ekid], dump=False)
optestlib.p_data('Ciphertext', ct, dump=False)
out['iv'] = optestlib.opb64e(iv)
out['data'] = optestlib.opb64e(ct)
out['enc'] = 'A256GCM'
else: # only the primary sym_key is itself AES encrypted, rest by RSA
optestlib.p_debug('\n*** Encrypting sym key with RSA kid %s\n' % ekid)
jwkj = '{"keys": [%s]}' % json.dumps(pub_keys[ekid])
jwk = load_jwks(jwkj)[0]
optestlib.p_str('Public key e:', jwk.e)
optestlib.p_str('Public key n:', jwk.n)
RSA_Key = RSA.construct((jwk.n, jwk.e))
C = PKCS1_OAEP.new(RSA_Key)
ct = C.encrypt(key_dat_str)
out['enc'] = 'RSA-OAEP'
out['data'] = optestlib.opb64e(ct)
optestlib.p_debug('')
optestlib.p_data('RSA-OAEP ciphertext', ct, dump=False)
return kid, out
def store_key(self, access_token, tir):
"""
Store key that was returned in response from token introspection
:param access_token: The token that was introspected
:param tir: TokenIntrospectionResponse instance
"""
key = load_jwks(json.dumps({'keys': [json.loads(tir['key'])]}))
self.token2key[access_token] = key
def store_key(self, access_token, tir):
"""
Store key that was returned in response from token introspection
:param access_token: The token that was introspected
:param tir: TokenIntrospectionResponse instance
"""
key = load_jwks(json.dumps({'keys': [json.loads(tir['key'])]}))
self.token2key[access_token] = key
def test_load_jwk():
_ckey = x509_rsa_loads(open(CERT).read())
jwk = dump_jwks([{"key": _ckey}])
wk = load_jwks(jwk)
print wk
assert len(wk) == 1
key = wk[0]
assert key.kty == "RSA"
assert isinstance(key.key, M2Crypto.RSA.RSA)
def test_load_jwk():
_ckey = pem_cert2rsa(CERT)
jwk = dump_jwks([{"key": _ckey}])
wk = load_jwks(jwk)
print wk
assert len(wk) == 1
key = wk[0]
assert key.kty == "RSA"
assert isinstance(key.key, _RSAobj)
def test_load_jwk():
_ckey = pem_cert2rsa(CERT)
jwk = dump_jwks([{"key": _ckey}])
wk = load_jwks(jwk)
print wk
assert len(wk) == 1
key = wk[0]
assert key.kty == "RSA"
assert isinstance(key.key, _RSAobj)
def _decode_token(self, token):
"""
Checks for a valid signarute and decodes JWT signed LTI message
This also touches the public keyset method.
"""
public_keyset = self.key_handler.get_public_jwk()
key_set = load_jwks(json.dumps(public_keyset))
return JWS().verify_compact(token, keys=key_set)
def _decode_token(self, token):
"""
Checks for a valid signarute and decodes JWT signed LTI message
This also tests the public keyset function.
"""
public_keyset = self.lti_consumer.get_public_keyset()
key_set = load_jwks(json.dumps(public_keyset))
return JWS().verify_compact(token, keys=key_set)
def test_loads_0():
keys = load_jwks(json.dumps(JWK))
assert len(keys) == 1
key = keys[0]
assert key.kid == "abc"
assert key.kty == "RSA"
_ckey = pem_cert2rsa(CERT)
print key
assert key.n == _ckey.n
assert key.e == _ckey.e
def test_loads_0():
keys = load_jwks(json.dumps(JWK))
assert len(keys) == 1
key = keys[0]
assert key.kid == "abc"
assert key.kty == "RSA"
_ckey = x509_rsa_loads(open(CERT).read())
print key
_n = long_to_mpi(base64_to_long(str(key.n)))
assert _n == _ckey.n
_e = long_to_mpi(base64_to_long(str(key.e)))
assert _e == _ckey.e
def test_loads_0():
keys = load_jwks(json.dumps(JWK))
assert len(keys) == 1
key = keys[0]
assert key.kid == "abc"
assert key.kty == "RSA"
_ckey = pem_cert2rsa(CERT)
print key
_n = base64_to_long(str(key.n))
assert _n == _ckey.n
_e = base64_to_long(str(key.e))
assert _e == _ckey.e
def test_loads_1():
jwk = {
"keys": [
{
'kty': 'RSA',
'use': 'foo',
'e': 'AQAB',
"n": 'wf-wiusGhA-gleZYQAOPQlNUIucPiqXdPVyieDqQbXXOPBe3nuggtVzeq7pVFH1dZz4dY2Q2LA5DaegvP8kRvoSB_87ds3dy3Rfym_GUSc5B0l1TgEobcyaep8jguRoHto6GWHfCfKqoUYZq4N8vh4LLMQwLR6zi6Jtu82nB5k8',
'kid': "1"
}, {
'kty': 'RSA',
'use': 'bar',
'e': 'AQAB',
"n": 'wf-wiusGhA-gleZYQAOPQlNUIucPiqXdPVyieDqQbXXOPBe3nuggtVzeq7pVFH1dZz4dY2Q2LA5DaegvP8kRvoSB_87ds3dy3Rfym_GUSc5B0l1TgEobcyaep8jguRoHto6GWHfCfKqoUYZq4N8vh4LLMQwLR6zi6Jtu82nB5k8',
'kid': "2"
}
]
}
keys = load_jwks(json.dumps(jwk))
print keys
assert len(keys) == 2
kids = [k.kid for k in keys]
assert _eq(kids, ["1", "2"])
def test_loads_1():
JWK = {
"keys": [
{
'kty': 'RSA',
'use': 'foo',
'e': 'AQAB',
"n": 'wf-wiusGhA-gleZYQAOPQlNUIucPiqXdPVyieDqQbXXOPBe3nuggtVzeq7pVFH1dZz4dY2Q2LA5DaegvP8kRvoSB_87ds3dy3Rfym_GUSc5B0l1TgEobcyaep8jguRoHto6GWHfCfKqoUYZq4N8vh4LLMQwLR6zi6Jtu82nB5k8',
'kid': "1"
}, {
'kty': 'RSA',
'use': 'bar',
'e': 'AQAB',
"n": 'wf-wiusGhA-gleZYQAOPQlNUIucPiqXdPVyieDqQbXXOPBe3nuggtVzeq7pVFH1dZz4dY2Q2LA5DaegvP8kRvoSB_87ds3dy3Rfym_GUSc5B0l1TgEobcyaep8jguRoHto6GWHfCfKqoUYZq4N8vh4LLMQwLR6zi6Jtu82nB5k8',
'kid': "2"
}
]
}
keys = load_jwks(json.dumps(JWK))
print keys
assert len(keys) == 2
kids = [k.kid for k in keys]
assert _eq(kids, ["1", "2"])
dest="jwk_url",
help="URL pointing to a file containing a JWK")
parser.add_argument('-r',
dest="rsa_file",
help="A file containing a RSA key")
parser.add_argument("-i", dest="int", help="Integrity method")
parser.add_argument("-f", dest="file", help="File with the message")
parser.add_argument("message", nargs="?", help="The message to encrypt")
args = parser.parse_args()
keys = {}
if args.jwk_url:
keys = assign(load_jwks_from_url(lrequest, args.jwk_url))
elif args.jwk_file:
keys = load_jwks(open(args.jwk_file).read())
elif args.x509_url:
keys = load_x509_cert(lrequest, args.x509_url)
elif args.x509_file:
keys = [import_rsa_key_from_file(args.x509_file)]
elif args.rsa_file:
key = rsa_load(args.rsa_file)
rsa_key = RSAKey(key=key)
rsa_key.serialize()
keys = [rsa_key]
else:
print("Needs encryption key")
exit()
if args.file:
msg = open(args.file).read()
def test_load_jwks():
keysl = load_jwks(json.dumps(JWKS))
assert len(keysl) == 3
parser.add_argument('-a', dest="alg",
help="The encryption algorithm")
parser.add_argument("-e", dest="enc", help="The encryption method")
parser.add_argument("-m", dest="mode", default="public",
help="Whether a public or private key should be used")
parser.add_argument("-f", dest="file",
help="File to be encrypted")
parser.add_argument("message", nargs="?", help="The message to encrypt")
args = parser.parse_args()
keys = {}
if args.jwk_url:
keys = load_jwks_from_url(args.jwk_url, {})
elif args.jwk_file:
keys = load_jwks(open(args.jwk_file).read())
elif args.x509_url:
# load_x509_cert returns list of 2-tuples
keys = [RSAKey(key=x) for x, y in load_x509_cert(lrequest,
args.x509_url)]
for key in keys:
key.serialize()
elif args.x509_file:
# import_rsa_key_from_file returns RSA key instance
_key = RSAKey(key=import_rsa_key_from_file(args.x509_file))
_key.serialize()
keys = [_key]
elif args.rsa_file:
_key = RSAKey(key=rsa_load(args.rsa_file))
_key.serialize()
keys = [_key]
import optestlib
#
# this ugly stuff is here because on some platforms (macOS), raw_input hangs
# after like 1024 bytes.
#
import termios, tty
old_tty_attr = termios.tcgetattr(sys.stdin)
new_tty_attr = old_tty_attr[:]
new_tty_attr[3] = new_tty_attr[3] & ~(tty.ICANON)
termios.tcsetattr(sys.stdin, tty.TCSANOW, new_tty_attr)
key_raw = raw_input("Enter RSA private key (as json, decrypted from keyset): ")
termios.tcsetattr(sys.stdin, tty.TCSANOW, old_tty_attr)
jwkj = '{"keys": [%s]}' % key_raw
jwk = json.loads(jwkj)
jwk = load_jwks(jwkj)[0]
RSA_Key = RSA.construct((jwk.n, jwk.e, jwk.d))
ct = optestlib.get_binary("\nEnter ciphertext (base-64 or hex): ")
cipher = PKCS1_OAEP.new(RSA_Key)
message = cipher.decrypt(ct)
print "\nDecrypted data:\n"
print message
def test_load_jwks():
keysl = load_jwks(json.dumps(JWKS))
assert len(keysl) == 3
args = parser.parse_args()
keys = []
if args.rsa_file:
keys = [RSAKey(key=import_rsa_key_from_file(args.rsa_file))]
elif args.hmac_key:
keys = [SYMKey(key=args.hmac_key)]
if args.jwk:
kspec = json.loads(open(args.jwk).read())
keys.append(keyrep(kspec))
if args.jwks:
keys.extend(load_jwks(open(args.jwk).read()))
if not keys:
exit(-1)
if args.msg_file:
if args.msg_file == "A.2.1":
message = open("A.2.1").read().replace("\n","\r\n")
else:
message = open(args.msg_file).read().strip("\n")
elif args.message == "-":
message = sys.stdin.read()
else:
message = args.message
if args.sign:
parser.add_argument("-m", dest="mode", default="private",
help="Whether a public or private key should be used")
parser.add_argument("-f", dest="file", help="File with the message")
parser.add_argument("message", nargs="?", help="The message to encrypt")
args = parser.parse_args()
keys = {}
if args.jwk_url:
keys = assign(load_jwks_from_url(lrequest, args.jwk_url))
if args.mode == "private":
print >> sys.stderr, "Missing private key to decrypt with"
exit()
elif args.jwk_file:
keys = assign(load_jwks(open(args.jwk_file).read()))
if args.mode == "private":
print >> sys.stderr, "Missing private key to decrypt with"
exit()
elif args.x509_url:
keys = assign(load_x509_cert(lrequest, args.x509_url))
if args.mode == "private":
print >> sys.stderr, "Missing private key to decrypt with"
exit()
elif args.x509_file:
keys = {"rsa": [x509_rsa_loads(open(args.x509_file).read())]}
if args.mode == "private":
print >> sys.stderr, "Missing private key to decrypt with"
exit()
elif args.rsa_file:
keys = {"rsa": [rsa_load(args.rsa_file)]}