import os from cryptography import x509 from cryptography.hazmat.backends import default_backend from cryptography.hazmat.primitives import hashes, hmac from cryptography.hazmat.primitives.asymmetric import dh, padding from cryptography.hazmat.primitives.serialization import load_pem_private_key from cryptography.hazmat.primitives.ciphers import ( Cipher, algorithms, modes, ) from ipaddress import IPv4Address from scapy.layers.ipsec import ESP from scapy.layers.inet import IP, UDP, Ether from scapy.packet import raw, Raw from scapy.utils import long_converter from framework import VppTestCase, VppTestRunner from vpp_ikev2 import Profile, IDType, AuthMethod from vpp_papi import VppEnum KEY_PAD = b"Key Pad for IKEv2" SALT_SIZE = 4 GCM_ICV_SIZE = 16 GCM_IV_SIZE = 8 # defined in rfc3526 # tuple structure is (p, g, key_len) DH = { '2048MODPgr': (long_converter(""" FFFFFFFF FFFFFFFF C90FDAA2 2168C234 C4C6628B 80DC1CD1 29024E08 8A67CC74 020BBEA6 3B139B22 514A0879 8E3404DD EF9519B3 CD3A431B 302B0A6D F25F1437 4FE1356D 6D51C245 E485B576 625E7EC6 F44C42E9 A637ED6B 0BFF5CB6 F406B7ED EE386BFB 5A899FA5 AE9F2411 7C4B1FE6 49286651 ECE45B3D C2007CB8 A163BF05 98DA4836 1C55D39A 69163FA8 FD24CF5F 83655D23 DCA3AD96 1C62F356 208552BB 9ED52907 7096966D 670C354E 4ABC9804 F1746C08 CA18217C 32905E46 2E36CE3B E39E772C 180E8603 9B2783A2 EC07A28F B5C55DF0 6F4C52C9 DE2BCBF6 95581718 3995497C EA956AE5 15D22618 98FA0510 15728E5A 8AACAA68 FFFFFFFF FFFFFFFF"""), 2, 256), '3072MODPgr': (long_converter(""" FFFFFFFF FFFFFFFF C90FDAA2 2168C234 C4C6628B 80DC1CD1 29024E08 8A67CC74 020BBEA6 3B139B22 514A0879 8E3404DD EF9519B3 CD3A431B 302B0A6D F25F1437 4FE1356D 6D51C245 E485B576 625E7EC6 F44C42E9 A637ED6B 0BFF5CB6 F406B7ED EE386BFB 5A899FA5 AE9F2411 7C4B1FE6 49286651 ECE45B3D C2007CB8 A163BF05 98DA4836 1C55D39A 69163FA8 FD24CF5F 83655D23 DCA3AD96 1C62F356 208552BB 9ED52907 7096966D 670C354E 4ABC9804 F1746C08 CA18217C 32905E46 2E36CE3B E39E772C 180E8603 9B2783A2 EC07A28F B5C55DF0 6F4C52C9 DE2BCBF6 95581718 3995497C EA956AE5 15D22618 98FA0510 15728E5A 8AAAC42D AD33170D 04507A33 A85521AB DF1CBA64 ECFB8504 58DBEF0A 8AEA7157 5D060C7D B3970F85 A6E1E4C7 ABF5AE8C DB0933D7 1E8C94E0 4A25619D CEE3D226 1AD2EE6B F12FFA06 D98A0864 D8760273 3EC86A64 521F2B18 177B200C BBE11757 7A615D6C 770988C0 BAD946E2 08E24FA0 74E5AB31 43DB5BFC E0FD108E 4B82D120 A93AD2CA FFFFFFFF FFFFFFFF"""), 2, 384) } class CryptoAlgo(object): def __init__(self, name, cipher, mode): self.name = name self.cipher = cipher self.mode = mode if self.cipher is not None: self.bs = self.cipher.block_size // 8 if self.name == 'AES-GCM-16ICV': self.iv_len = GCM_IV_SIZE else: self.iv_len = self.bs def encrypt(self, data, key, aad=None): iv = os.urandom(self.iv_len) if aad is None: encryptor = Cipher(self.cipher(key), self.mode(iv), default_backend()).encryptor() return iv + encryptor.update(data) + encryptor.finalize() else: salt = key[-SALT_SIZE:] nonce = salt + iv encryptor = Cipher(self.cipher(key[:-SALT_SIZE]), self.mode(nonce), default_backend()).encryptor() encryptor.authenticate_additional_data(aad) data = encryptor.update(data) + encryptor.finalize() data += encryptor.tag[:GCM_ICV_SIZE] return iv + data def decrypt(self, data, key, aad=None, icv=None): if aad is None: iv = data[:self.iv_len] ct = data[self.iv_len:] decryptor = Cipher(algorithms.AES(key), self.mode(iv), default_backend()).decryptor() return decryptor.update(ct) + decryptor.finalize() else: salt = key[-SALT_SIZE:] nonce = salt + data[:GCM_IV_SIZE] ct = data[GCM_IV_SIZE:] key = key[:-SALT_SIZE] decryptor = Cipher(algorithms.AES(key), self.mode(nonce, icv, len(icv)), default_backend()).decryptor() decryptor.authenticate_additional_data(aad) pt = decryptor.update(ct) + decryptor.finalize() pad_len = pt[-1] + 1 return pt[:-pad_len] def pad(self, data): pad_len = (len(data) // self.bs + 1) * self.bs - len(data) data = data + b'\x00' * (pad_len - 1) return data + bytes([pad_len]) class AuthAlgo(object): def __init__(self, name, mac, mod, key_len, trunc_len=None): self.name = name self.mac = mac self.mod = mod self.key_len = key_len self.trunc_len = trunc_len or key_len CRYPTO_ALGOS = { 'NULL': CryptoAlgo('NULL', cipher=None, mode=None), 'AES-CBC': CryptoAlgo('AES-CBC', cipher=algorithms.AES, mode=modes.CBC), 'AES-GCM-16ICV': CryptoAlgo('AES-GCM-16ICV', cipher=algorithms.AES, mode=modes.GCM), } AUTH_ALGOS = { 'NULL': AuthAlgo('NULL', mac=None, mod=None, key_len=0, trunc_len=0), 'HMAC-SHA1-96': AuthAlgo('HMAC-SHA1-96', hmac.HMAC, hashes.SHA1, 20, 12), 'SHA2-256-128': AuthAlgo('SHA2-256-128', hmac.HMAC, hashes.SHA256, 32, 16), 'SHA2-384-192': AuthAlgo('SHA2-384-192', hmac.HMAC, hashes.SHA256, 48, 24), 'SHA2-512-256': AuthAlgo('SHA2-512-256', hmac.HMAC, hashes.SHA256, 64, 32), } PRF_ALGOS = { 'NULL': AuthAlgo('NULL', mac=None, mod=None, key_len=0, trunc_len=0), 'PRF_HMAC_SHA2_256': AuthAlgo('PRF_HMAC_SHA2_256', hmac.HMAC, hashes.SHA256, 32), } class IKEv2ChildSA(object): def __init__(self, local_ts, remote_ts, spi=None): self.spi = spi or os.urandom(4) self.local_ts = local_ts self.remote_ts = remote_ts class IKEv2SA(object): def __init__(self, test, is_initiator=True, spi=b'\x04' * 8, i_id=None, r_id=None, id_type='fqdn', nonce=None, auth_data=None, local_ts=None, remote_ts=None, auth_method='shared-key', priv_key=None, natt=False): self.natt = natt if natt: self.sport = 4500 self.dport = 4500 else: self.sport = 500 self.dport = 500 self.dh_params = None self.test = test self.priv_key = priv_key self.is_initiator = is_initiator nonce = nonce or os.urandom(32) self.auth_data = auth_data self.i_id = i_id self.r_id = r_id if isinstance(id_type, str): self.id_type = IDType.value(id_type) else: self.id_type = id_type self.auth_method = auth_method if self.is_initiator: self.rspi = None self.ispi = spi self.i_nonce = nonce else: self.rspi = spi self.ispi = None self.r_nonce = None self.child_sas = [IKEv2ChildSA(local_ts, remote_ts)] def dh_pub_key(self): return self.i_dh_data def compute_secret(self): priv = self.dh_private_key peer = self.r_dh_data p, g, l = self.ike_group return pow(int.from_bytes(peer, 'big'), int.from_bytes(priv, 'big'), p).to_bytes(l, 'big') def generate_dh_data(self): # generate DH keys if self.is_initiator: if self.ike_dh not in DH: raise NotImplementedError('%s not in DH group' % self.ike_dh) if self.dh_params is None: dhg = DH[self.ike_dh] pn = dh.DHParameterNumbers(dhg[0], dhg[1]) self.dh_params = pn.parameters(default_backend()) priv = self.dh_params.generate_private_key() pub = priv.public_key() x = priv.private_numbers().x self.dh_private_key = x.to_bytes(priv.key_size // 8, 'big') y = pub.public_numbers().y self.i_dh_data = y.to_bytes(pub.key_size // 8, 'big') def complete_dh_data(self): self.dh_shared_secret = self.compute_secret() def calc_child_keys(self): prf = self.ike_prf_alg.mod() s = self.i_nonce + self.r_nonce c = self.child_sas[0] encr_key_len = self.esp_crypto_key_len integ_key_len = self.esp_integ_alg.key_len salt_len = 0 if integ_key_len else 4 l = (integ_key_len * 2 + encr_key_len * 2 + salt_len * 2) keymat = self.calc_prfplus(prf, self.sk_d, s, l) pos = 0 c.sk_ei = keymat[pos:pos+encr_key_len] pos += encr_key_len if integ_key_len: c.sk_ai = keymat[pos:pos+integ_key_len] pos += integ_key_len else: c.salt_ei = keymat[pos:pos+salt_len] pos += salt_len c.sk_er = keymat[pos:pos+encr_key_len] pos += encr_key_len if integ_key_len: c.sk_ar = keymat[pos:pos+integ_key_len] pos += integ_key_len else: c.salt_er = keymat[pos:pos+salt_len] pos += salt_len def calc_prfplus(self, prf, key, seed, length): r = b'' t = None x = 1 while len(r) < length and x < 255: if t is not None: s = t else: s = b'' s = s + seed + bytes([x]) t = self.calc_prf(prf, key, s) r = r + t x = x + 1 if x == 255: return None return r def calc_prf(self, prf, key, data): h = self.ike_prf_alg.mac(key, prf, backend=default_backend()) h.update(data) return h.finalize() def calc_keys(self): prf = self.ike_prf_alg.mod() # SKEYSEED = prf(Ni | Nr, g^ir) s = self.i_nonce + self.r_nonce self.skeyseed = self.calc_prf(prf, s, self.dh_shared_secret) # calculate S = Ni | Nr | SPIi SPIr s = s + self.ispi + self.rspi prf_key_trunc = self.ike_prf_alg.trunc_len encr_key_len = self.ike_crypto_key_len tr_prf_key_len = self.ike_prf_alg.key_len integ_key_len = self.ike_integ_alg.key_len if integ_key_len == 0: salt_size = 4 else: salt_size = 0 l = (prf_key_trunc + integ_key_len * 2 + encr_key_len * 2 + tr_prf_key_len * 2 + salt_size * 2) keymat = self.calc_prfplus(prf, self.skeyseed, s, l) pos = 0 self.sk_d = keymat[:pos+prf_key_trunc] pos += prf_key_trunc self.sk_ai = keymat[pos:pos+integ_key_len] pos += integ_key_len self.sk_ar = keymat[pos:pos+integ_key_len] pos += integ_key_len self.sk_ei = keymat[pos:pos+encr_key_len + salt_size] pos += encr_key_len + salt_size self.sk_er = keymat[pos:pos+encr_key_len + salt_size] pos += encr_key_len + salt_size self.sk_pi = keymat[pos:pos+tr_prf_key_len] pos += tr_prf_key_len self.sk_pr = keymat[pos:pos+tr_prf_key_len] def generate_authmsg(self, prf, packet): if self.is_initiator: id = self.i_id nonce = self.r_nonce key = self.sk_pi data = bytes([self.id_type, 0, 0, 0]) + id id_hash = self.calc_prf(prf, key, data) return packet + nonce + id_hash def auth_init(self): prf = self.ike_prf_alg.mod() authmsg = self.generate_authmsg(prf, raw(self.init_req_packet)) if self.auth_method == 'shared-key': psk = self.calc_prf(prf, self.auth_data, KEY_PAD) self.auth_data = self.calc_prf(prf, psk, authmsg) elif self.auth_method == 'rsa-sig': self.auth_data = self.priv_key.sign(authmsg, padding.PKCS1v15(), hashes.SHA1()) else: raise TypeError('unknown auth method type!') def encrypt(self, data, aad=None): data = self.ike_crypto_alg.pad(data) return self.ike_crypto_alg.encrypt(data, self.my_cryptokey, aad) @property def peer_authkey(self): if self.is_initiator: return self.sk_ar return self.sk_ai @property def my_authkey(self): if self.is_initiator: return self.sk_ai return self.sk_ar @property def my_cryptokey(self): if self.is_initiator: return self.sk_ei return self.sk_er @property def peer_cryptokey(self): if self.is_initiator: return self.sk_er return self.sk_ei def concat(self, alg, key_len): return alg + '-' + str(key_len * 8) @property def vpp_ike_cypto_alg(self): return self.concat(self.ike_crypto, self.ike_crypto_key_len) @property def vpp_esp_cypto_alg(self): return self.concat(self.esp_crypto, self.esp_crypto_key_len) def verify_hmac(self, ikemsg): integ_trunc = self.ike_integ_alg.trunc_len exp_hmac = ikemsg[-integ_trunc:] data = ikemsg[:-integ_trunc] computed_hmac = self.compute_hmac(self.ike_integ_alg.mod(), self.peer_authkey, data) self.test.assertEqual(computed_hmac[:integ_trunc], exp_hmac) def compute_hmac(self, integ, key, data): h = self.ike_integ_alg.mac(key, integ, backend=default_backend()) h.update(data) return h.finalize() def decrypt(self, data, aad=None, icv=None): return self.ike_crypto_alg.decrypt(data, self.peer_cryptokey, aad, icv) def hmac_and_decrypt(self, ike): ep = ike[ikev2.IKEv2_payload_Encrypted] if self.ike_crypto == 'AES-GCM-16ICV': aad_len = len(ikev2.IKEv2_payload_Encrypted()) + len(ikev2.IKEv2()) ct = ep.load[:-GCM_ICV_SIZE] tag = ep.load[-GCM_ICV_SIZE:] return self.decrypt(ct, raw(ike)[:aad_len], tag) else: self.verify_hmac(raw(ike)) integ_trunc = self.ike_integ_alg.trunc_len # remove ICV and decrypt payload ct = ep.load[:-integ_trunc] return self.decrypt(ct) def generate_ts(self): c = self.child_sas[0] ts1 = ikev2.IPv4TrafficSelector( IP_protocol_ID=0, starting_address_v4=c.local_ts['start_addr'], ending_address_v4=c.local_ts['end_addr']) ts2 = ikev2.IPv4TrafficSelector( IP_protocol_ID=0, starting_address_v4=c.remote_ts['start_addr'], ending_address_v4=c.remote_ts['end_addr']) return ([ts1], [ts2]) def set_ike_props(self, crypto, crypto_key_len, integ, prf, dh): if crypto not in CRYPTO_ALGOS: raise TypeError('unsupported encryption algo %r' % crypto) self.ike_crypto = crypto self.ike_crypto_alg = CRYPTO_ALGOS[crypto] self.ike_crypto_key_len = crypto_key_len if integ not in AUTH_ALGOS: raise TypeError('unsupported auth algo %r' % integ) self.ike_integ = None if integ == 'NULL' else integ self.ike_integ_alg = AUTH_ALGOS[integ] if prf not in PRF_ALGOS: raise TypeError('unsupported prf algo %r' % prf) self.ike_prf = prf self.ike_prf_alg = PRF_ALGOS[prf] self.ike_dh = dh self.ike_group = DH[self.ike_dh] def set_esp_props(self, crypto, crypto_key_len, integ): self.esp_crypto_key_len = crypto_key_len if crypto not in CRYPTO_ALGOS: raise TypeError('unsupported encryption algo %r' % crypto) self.esp_crypto = crypto self.esp_crypto_alg = CRYPTO_ALGOS[crypto] if integ not in AUTH_ALGOS: raise TypeError('unsupported auth algo %r' % integ) self.esp_integ = None if integ == 'NULL' else integ self.esp_integ_alg = AUTH_ALGOS[integ] def crypto_attr(self, key_len): if self.ike_crypto in ['AES-CBC', 'AES-GCM-16ICV']: return (0x800e << 16 | key_len << 3, 12) else: raise Exception('unsupported attribute type') def ike_crypto_attr(self): return self.crypto_attr(self.ike_crypto_key_len) def esp_crypto_attr(self): return self.crypto_attr(self.esp_crypto_key_len) def compute_nat_sha1(self, ip, port): data = self.ispi + b'\x00' * 8 + ip + (port).to_bytes(2, 'big') digest = hashes.Hash(hashes.SHA1(), backend=default_backend()) digest.update(data) return digest.finalize() class TemplateResponder(VppTestCase): """ responder test template """ @classmethod def setUpClass(cls): import scapy.contrib.ikev2 as _ikev2 globals()['ikev2'] = _ikev2 super(TemplateResponder, cls).setUpClass() cls.create_pg_interfaces(range(2)) for i in cls.pg_interfaces: i.admin_up() i.config_ip4() i.resolve_arp() @classmethod def tearDownClass(cls): super(TemplateResponder, cls).tearDownClass() def setUp(self): super(TemplateResponder, self).setUp() self.config_tc() self.p.add_vpp_config() self.assertIsNotNone(self.p.query_vpp_config()) self.sa.generate_dh_data() def tearDown(self): super(TemplateResponder, self).tearDown() self.p.remove_vpp_config() self.assertIsNone(self.p.query_vpp_config()) def create_ike_msg(self, src_if, msg, sport=500, dport=500, natt=False): res = (Ether(dst=src_if.local_mac, src=src_if.remote_mac) / IP(src=src_if.remote_ip4, dst=src_if.local_ip4) / UDP(sport=sport, dport=dport)) if natt: # insert non ESP marker res = res / Raw(b'\x00' * 4) return res / msg def send_sa_init(self, behind_nat=False): tr_attr = self.sa.ike_crypto_attr() trans = (ikev2.IKEv2_payload_Transform(transform_type='Encryption', transform_id=self.sa.ike_crypto, length=tr_attr[1], key_length=tr_attr[0]) / ikev2.IKEv2_payload_Transform(transform_type='Integrity', transform_id=self.sa.ike_integ) / ikev2.IKEv2_payload_Transform(transform_type='PRF', transform_id=self.sa.ike_prf_alg.name) / ikev2.IKEv2_payload_Transform(transform_type='GroupDesc', transform_id=self.sa.ike_dh)) props = (ikev2.IKEv2_payload_Proposal(proposal=1, proto='IKEv2', trans_nb=4, trans=trans)) if behind_nat: next_payload = 'Notify' else: next_payload = None self.sa.init_req_packet = ( ikev2.IKEv2(init_SPI=self.sa.ispi, flags='Initiator', exch_type='IKE_SA_INIT') / ikev2.IKEv2_payload_SA(next_payload='KE', prop=props) / ikev2.IKEv2_payload_KE(next_payload='Nonce', group=self.sa.ike_dh, load=self.sa.dh_pub_key()) / ikev2.IKEv2_payload_Nonce(next_payload=next_payload, load=self.sa.i_nonce)) if behind_nat: src_nat = self.sa.compute_nat_sha1(b'\x0a\x0a\x0a\x01', self.sa.sport) nat_detection = ikev2.IKEv2_payload_Notify( type='NAT_DETECTION_SOURCE_IP', load=src_nat) self.sa.init_req_packet = self.sa.init_req_packet / nat_detection ike_msg = self.create_ike_msg(self.pg0, self.sa.init_req_packet, self.sa.sport, self.sa.dport, self.sa.natt) self.pg0.add_stream(ike_msg) self.pg0.enable_capture() self.pg_start() capture = self.pg0.get_capture(1) self.verify_sa_init(capture[0]) def send_sa_auth(self): tr_attr = self.sa.esp_crypto_attr() trans = (ikev2.IKEv2_payload_Transform(transform_type='Encryption', transform_id=self.sa.esp_crypto, length=tr_attr[1], key_length=tr_attr[0]) / ikev2.IKEv2_payload_Transform(transform_type='Integrity', transform_id=self.sa.esp_integ) / ikev2.IKEv2_payload_Transform( transform_type='Extended Sequence Number', transform_id='No ESN') / ikev2.IKEv2_payload_Transform( transform_type='Extended Sequence Number', transform_id='ESN')) props = (ikev2.IKEv2_payload_Proposal(proposal=1, proto='ESP', SPIsize=4, SPI=os.urandom(4), trans_nb=4, trans=trans)) tsi, tsr = self.sa.generate_ts() plain = (ikev2.IKEv2_payload_IDi(next_payload='IDr', IDtype=self.sa.id_type, load=self.sa.i_id) / ikev2.IKEv2_payload_IDr(next_payload='AUTH', IDtype=self.sa.id_type, load=self.sa.r_id) / ikev2.IKEv2_payload_AUTH(next_payload='SA', auth_type=AuthMethod.value(self.sa.auth_method), load=self.sa.auth_data) / ikev2.IKEv2_payload_SA(next_payload='TSi', prop=props) / ikev2.IKEv2_payload_TSi(next_payload='TSr', number_of_TSs=len(tsi), traffic_selector=tsi) / ikev2.IKEv2_payload_TSr(next_payload='Notify', number_of_TSs=len(tsr), traffic_selector=tsr) / ikev2.IKEv2_payload_Notify(type='INITIAL_CONTACT')) if self.sa.ike_crypto == 'AES-GCM-16ICV': data = self.sa.ike_crypto_alg.pad(raw(plain)) plen = len(data) + GCM_IV_SIZE + GCM_ICV_SIZE +\ len(ikev2.IKEv2_payload_Encrypted()) tlen = plen + len(ikev2.IKEv2()) # prepare aad data sk_p = ikev2.IKEv2_payload_Encrypted(next_payload='IDi', length=plen) sa_auth = (ikev2.IKEv2(init_SPI=self.sa.ispi, resp_SPI=self.sa.rspi, id=1, length=tlen, flags='Initiator', exch_type='IKE_AUTH')) sa_auth /= sk_p encr = self.sa.encrypt(raw(plain), raw(sa_auth)) sk_p = ikev2.IKEv2_payload_Encrypted(next_payload='IDi', length=plen, load=encr) sa_auth = (ikev2.IKEv2(init_SPI=self.sa.ispi, resp_SPI=self.sa.rspi, id=1, length=tlen, flags='Initiator', exch_type='IKE_AUTH')) sa_auth /= sk_p else: encr = self.sa.encrypt(raw(plain)) trunc_len = self.sa.ike_integ_alg.trunc_len plen = len(encr) + len(ikev2.IKEv2_payload_Encrypted()) + trunc_len tlen = plen + len(ikev2.IKEv2()) sk_p = ikev2.IKEv2_payload_Encrypted(next_payload='IDi', length=plen, load=encr) sa_auth = (ikev2.IKEv2(init_SPI=self.sa.ispi, resp_SPI=self.sa.rspi, id=1, length=tlen, flags='Initiator', exch_type='IKE_AUTH')) sa_auth /= sk_p integ_data = raw(sa_auth) hmac_data = self.sa.compute_hmac(self.sa.ike_integ_alg.mod(), self.sa.my_authkey, integ_data) sa_auth = sa_auth / Raw(hmac_data[:trunc_len]) assert(len(sa_auth) == tlen) packet = self.create_ike_msg(self.pg0, sa_auth, self.sa.sport, self.sa.dport, self.sa.natt) self.pg0.add_stream(packet) self.pg0.enable_capture() self.pg_start() capture = self.pg0.get_capture(1) self.verify_sa_auth(capture[0]) def get_ike_header(self, packet): try: ih = packet[ikev2.IKEv2] except IndexError as e: # this is a workaround for getting IKEv2 layer as both ikev2 and # ipsec register for port 4500 esp = packet[ESP] ih = self.verify_and_remove_non_esp_marker(esp) return ih def verify_sa_init(self, packet): ih = self.get_ike_header(packet) self.assertEqual(ih.exch_type, 34) self.assertTrue('Response' in ih.flags) self.assertEqual(ih.init_SPI, self.sa.ispi) self.assertNotEqual(ih.resp_SPI, 0) self.sa.rspi = ih.resp_SPI try: sa = ih[ikev2.IKEv2_payload_SA] self.sa.r_nonce = ih[ikev2.IKEv2_payload_Nonce].load self.sa.r_dh_data = ih[ikev2.IKEv2_payload_KE].load except IndexError as e: self.logger.error("unexpected reply: SA/Nonce/KE payload found!") self.logger.error(ih.show()) raise self.sa.complete_dh_data() self.sa.calc_keys() self.sa.auth_init() def verify_and_remove_non_esp_marker(self, packet): if self.sa.natt: # if we are in nat traversal mode check for non esp marker # and remove it data = raw(packet) self.assertEqual(data[:4], b'\x00' * 4) return ikev2.IKEv2(data[4:]) else: return packet def verify_udp(self, udp): self.assertEqual(udp.sport, self.sa.sport) self.assertEqual(udp.dport, self.sa.dport) def verify_sa_auth(self, packet): ike = self.get_ike_header(packet) udp = packet[UDP] self.verify_udp(udp) plain = self.sa.hmac_and_decrypt(ike) self.sa.calc_child_keys() def verify_child_sas(self): sas = self.vapi.ipsec_sa_dump() self.assertEqual(len(sas), 2) sa0 = sas[0].entry sa1 = sas[1].entry c = self.sa.child_sas[0] vpp_crypto_alg = self.vpp_enums[self.sa.vpp_esp_cypto_alg] self.assertEqual(sa0.crypto_algorithm, vpp_crypto_alg) self.assertEqual(sa1.crypto_algorithm, vpp_crypto_alg) if self.sa.esp_integ is None: vpp_integ_alg = 0 else: vpp_integ_alg = self.vpp_enums[self.sa.esp_integ] self.assertEqual(sa0.integrity_algorithm, vpp_integ_alg) self.assertEqual(sa1.integrity_algorithm, vpp_integ_alg) # verify crypto keys self.assertEqual(sa0.crypto_key.length, len(c.sk_er)) self.assertEqual(sa1.crypto_key.length, len(c.sk_ei)) self.assertEqual(sa0.crypto_key.data[:len(c.sk_er)], c.sk_er) self.assertEqual(sa1.crypto_key.data[:len(c.sk_ei)], c.sk_ei) # verify integ keys if vpp_integ_alg: self.assertEqual(sa0.integrity_key.length, len(c.sk_ar)) self.assertEqual(sa1.integrity_key.length, len(c.sk_ai)) self.assertEqual(sa0.integrity_key.data[:len(c.sk_ar)], c.sk_ar) self.assertEqual(sa1.integrity_key.data[:len(c.sk_ai)], c.sk_ai) else: self.assertEqual(sa0.salt.to_bytes(4, 'little'), c.salt_er) self.assertEqual(sa1.salt.to_bytes(4, 'little'), c.salt_ei) def test_responder(self): self.send_sa_init(self.sa.natt) self.send_sa_auth() self.verify_child_sas() class Ikev2Params(object): def config_params(self, params={}): ec = VppEnum.vl_api_ipsec_crypto_alg_t ei = VppEnum.vl_api_ipsec_integ_alg_t self.vpp_enums = { 'AES-CBC-128': ec.IPSEC_API_CRYPTO_ALG_AES_CBC_128, 'AES-CBC-192': ec.IPSEC_API_CRYPTO_ALG_AES_CBC_192, 'AES-CBC-256': ec.IPSEC_API_CRYPTO_ALG_AES_CBC_256, 'AES-GCM-16ICV-128': ec.IPSEC_API_CRYPTO_ALG_AES_GCM_128, 'AES-GCM-16ICV-192': ec.IPSEC_API_CRYPTO_ALG_AES_GCM_192, 'AES-GCM-16ICV-256': ec.IPSEC_API_CRYPTO_ALG_AES_GCM_256, 'HMAC-SHA1-96': ei.IPSEC_API_INTEG_ALG_SHA1_96, 'SHA2-256-128': ei.IPSEC_API_INTEG_ALG_SHA_256_128, 'SHA2-384-192': ei.IPSEC_API_INTEG_ALG_SHA_384_192, 'SHA2-512-256': ei.IPSEC_API_INTEG_ALG_SHA_512_256} is_natt = 'natt' in params and params['natt'] or False self.p = Profile(self, 'pr1') if 'auth' in params and params['auth'] == 'rsa-sig': auth_method = 'rsa-sig' work_dir = os.getenv('BR') + '/../src/plugins/ikev2/test/certs/' self.vapi.ikev2_set_local_key( key_file=work_dir + params['server-key']) client_file = work_dir + params['client-cert'] server_pem = open(work_dir + params['server-cert']).read() client_priv = open(work_dir + params['client-key']).read() client_priv = load_pem_private_key(str.encode(client_priv), None, default_backend()) self.peer_cert = x509.load_pem_x509_certificate( str.encode(server_pem), default_backend()) self.p.add_auth(method='rsa-sig', data=str.encode(client_file)) auth_data = None else: auth_data = b'$3cr3tpa$$w0rd' self.p.add_auth(method='shared-key', data=auth_data) auth_method = 'shared-key' client_priv = None self.p.add_local_id(id_type='fqdn', data=b'vpp.home') self.p.add_remote_id(id_type='fqdn', data=b'roadwarrior.example.com') self.p.add_local_ts(start_addr='10.10.10.0', end_addr='10.10.10.255') self.p.add_remote_ts(start_addr='10.0.0.0', end_addr='10.0.0.255') self.sa = IKEv2SA(self, i_id=self.p.remote_id['data'], r_id=self.p.local_id['data'], id_type=self.p.local_id['id_type'], natt=is_natt, priv_key=client_priv, auth_method=auth_method, auth_data=auth_data, local_ts=self.p.remote_ts, remote_ts=self.p.local_ts) ike_crypto = ('AES-CBC', 32) if 'ike-crypto' not in params else\ params['ike-crypto'] ike_integ = 'HMAC-SHA1-96' if 'ike-integ' not in params else\ params['ike-integ'] ike_dh = '2048MODPgr' if 'ike-dh' not in params else params['ike-dh'] esp_crypto = ('AES-CBC', 32) if 'esp-crypto' not in params else\ params['esp-crypto'] esp_integ = 'HMAC-SHA1-96' if 'esp-integ' not in params else\ params['esp-integ'] self.sa.set_ike_props( crypto=ike_crypto[0], crypto_key_len=ike_crypto[1], integ=ike_integ, prf='PRF_HMAC_SHA2_256', dh=ike_dh) self.sa.set_esp_props( crypto=esp_crypto[0], crypto_key_len=esp_crypto[1], integ=esp_integ) class TestApi(VppTestCase): """ Test IKEV2 API """ @classmethod def setUpClass(cls): super(TestApi, cls).setUpClass() @classmethod def tearDownClass(cls): super(TestApi, cls).tearDownClass() def tearDown(self): super(TestApi, self).tearDown() self.p1.remove_vpp_config() self.p2.remove_vpp_config() r = self.vapi.ikev2_profile_dump() self.assertEqual(len(r), 0) def configure_profile(self, cfg): p = Profile(self, cfg['name']) p.add_local_id(id_type=cfg['loc_id'][0], data=cfg['loc_id'][1]) p.add_remote_id(id_type=cfg['rem_id'][0], data=cfg['rem_id'][1]) p.add_local_ts(**cfg['loc_ts']) p.add_remote_ts(**cfg['rem_ts']) p.add_responder(cfg['responder']) p.add_ike_transforms(cfg['ike_ts']) p.add_esp_transforms(cfg['esp_ts']) p.add_auth(**cfg['auth']) p.set_udp_encap(cfg['udp_encap']) p.set_ipsec_over_udp_port(cfg['ipsec_over_udp_port']) if 'lifetime_data' in cfg: p.set_lifetime_data(cfg['lifetime_data']) if 'tun_itf' in cfg: p.set_tunnel_interface(cfg['tun_itf']) p.add_vpp_config() return p def test_profile_api(self): """ test profile dump API """ loc_ts = { 'proto': 8, 'start_port': 1, 'end_port': 19, 'start_addr': '3.3.3.2', 'end_addr': '3.3.3.3', } rem_ts = { 'proto': 9, 'start_port': 10, 'end_port': 119, 'start_addr': '4.5.76.80', 'end_addr': '2.3.4.6', } conf = { 'p1': { 'name': 'p1', 'loc_id': ('fqdn', b'vpp.home'), 'rem_id': ('fqdn', b'roadwarrior.example.com'), 'loc_ts': loc_ts, 'rem_ts': rem_ts, 'responder': {'sw_if_index': 0, 'ip4': '5.6.7.8'}, 'ike_ts': { 'crypto_alg': 20, 'crypto_key_size': 32, 'integ_alg': 1, 'dh_group': 1}, 'esp_ts': { 'crypto_alg': 13, 'crypto_key_size': 24, 'integ_alg': 2}, 'auth': {'method': 'shared-key', 'data': b'sharedkeydata'}, 'udp_encap': True, 'ipsec_over_udp_port': 4501, 'lifetime_data': { 'lifetime': 123, 'lifetime_maxdata': 20192, 'lifetime_jitter': 9, 'handover': 132}, }, 'p2': { 'name': 'p2', 'loc_id': ('ip4-addr', b'192.168.2.1'), 'rem_id': ('ip4-addr', b'192.168.2.2'), 'loc_ts': loc_ts, 'rem_ts': rem_ts, 'responder': {'sw_if_index': 4, 'ip4': '5.6.7.99'}, 'ike_ts': { 'crypto_alg': 12, 'crypto_key_size': 16, 'integ_alg': 3, 'dh_group': 3}, 'esp_ts': { 'crypto_alg': 9, 'crypto_key_size': 24, 'integ_alg': 4}, 'auth': {'method': 'shared-key', 'data': b'sharedkeydata'}, 'udp_encap': False, 'ipsec_over_udp_port': 4600, 'tun_itf': 0} } self.p1 = self.configure_profile(conf['p1']) self.p2 = self.configure_profile(conf['p2']) r = self.vapi.ikev2_profile_dump() self.assertEqual(len(r), 2) self.verify_profile(r[0].profile, conf['p1']) self.verify_profile(r[1].profile, conf['p2']) def verify_id(self, api_id, cfg_id): self.assertEqual(api_id.type, IDType.value(cfg_id[0])) self.assertEqual(bytes(api_id.data, 'ascii'), cfg_id[1]) def verify_ts(self, api_ts, cfg_ts): self.assertEqual(api_ts.protocol_id, cfg_ts['proto']) self.assertEqual(api_ts.start_port, cfg_ts['start_port']) self.assertEqual(api_ts.end_port, cfg_ts['end_port']) self.assertEqual(api_ts.start_addr, IPv4Address(cfg_ts['start_addr'])) self.assertEqual(api_ts.end_addr, IPv4Address(cfg_ts['end_addr'])) def verify_responder(self, api_r, cfg_r): self.assertEqual(api_r.sw_if_index, cfg_r['sw_if_index']) self.assertEqual(api_r.ip4, IPv4Address(cfg_r['ip4'])) def verify_transforms(self, api_ts, cfg_ts): self.assertEqual(api_ts.crypto_alg, cfg_ts['crypto_alg']) self.assertEqual(api_ts.crypto_key_size, cfg_ts['crypto_key_size']) self.assertEqual(api_ts.integ_alg, cfg_ts['integ_alg']) def verify_ike_transforms(self, api_ts, cfg_ts): self.verify_transforms(api_ts, cfg_ts) self.assertEqual(api_ts.dh_group, cfg_ts['dh_group']) def verify_esp_transforms(self, api_ts, cfg_ts): self.verify_transforms(api_ts, cfg_ts) def verify_auth(self, api_auth, cfg_auth): self.assertEqual(api_auth.method, AuthMethod.value(cfg_auth['method'])) self.assertEqual(api_auth.data, cfg_auth['data']) self.assertEqual(api_auth.data_len, len(cfg_auth['data'])) def verify_lifetime_data(self, p, ld): self.assertEqual(p.lifetime, ld['lifetime']) self.assertEqual(p.lifetime_maxdata, ld['lifetime_maxdata']) self.assertEqual(p.lifetime_jitter, ld['lifetime_jitter']) self.assertEqual(p.handover, ld['handover']) def verify_profile(self, ap, cp): self.assertEqual(ap.name, cp['name']) self.assertEqual(ap.udp_encap, cp['udp_encap']) self.verify_id(ap.loc_id, cp['loc_id']) self.verify_id(ap.rem_id, cp['rem_id']) self.verify_ts(ap.loc_ts, cp['loc_ts']) self.verify_ts(ap.rem_ts, cp['rem_ts']) self.verify_responder(ap.responder, cp['responder']) self.verify_ike_transforms(ap.ike_ts, cp['ike_ts']) self.verify_esp_transforms(ap.esp_ts, cp['esp_ts']) self.verify_auth(ap.auth, cp['auth']) if 'lifetime_data' in cp: self.verify_lifetime_data(ap, cp['lifetime_data']) self.assertEqual(ap.ipsec_over_udp_port, cp['ipsec_over_udp_port']) if 'tun_itf' in cp: self.assertEqual(ap.tun_itf, cp['tun_itf']) else: self.assertEqual(ap.tun_itf, 0xffffffff) class TestResponderNATT(TemplateResponder, Ikev2Params): """ test ikev2 responder - nat traversal """ def config_tc(self): self.config_params( {'natt': True}) class TestResponderPsk(TemplateResponder, Ikev2Params): """ test ikev2 responder - pre shared key auth """ def config_tc(self): self.config_params() class TestResponderRsaSign(TemplateResponder, Ikev2Params): """ test ikev2 responder - cert based auth """ def config_tc(self): self.config_params({ 'auth': 'rsa-sig', 'server-key': 'server-key.pem', 'client-key': 'client-key.pem', 'client-cert': 'client-cert.pem', 'server-cert': 'server-cert.pem'}) class Test_IKE_AES_CBC_128_SHA256_128_MODP2048_ESP_AES_CBC_192_SHA_384_192\ (TemplateResponder, Ikev2Params): """ IKE:AES_CBC_128_SHA256_128,DH=modp2048 ESP:AES_CBC_192_SHA_384_192 """ def config_tc(self): self.config_params({ 'ike-crypto': ('AES-CBC', 16), 'ike-integ': 'SHA2-256-128', 'esp-crypto': ('AES-CBC', 24), 'esp-integ': 'SHA2-384-192', 'ike-dh': '2048MODPgr'}) class TestAES_CBC_128_SHA256_128_MODP3072_ESP_AES_GCM_16\ (TemplateResponder, Ikev2Params): """ IKE:AES_CBC_128_SHA256_128,DH=modp3072 ESP:AES_GCM_16 """ def config_tc(self): self.config_params({ 'ike-crypto': ('AES-CBC', 32), 'ike-integ': 'SHA2-256-128', 'esp-crypto': ('AES-GCM-16ICV', 32), 'esp-integ': 'NULL', 'ike-dh': '3072MODPgr'}) class Test_IKE_AES_GCM_16_256(TemplateResponder, Ikev2Params): """ IKE:AES_GCM_16_256 """ def config_tc(self): self.config_params({ 'ike-crypto': ('AES-GCM-16ICV', 32), 'ike-integ': 'NULL', 'ike-dh': '2048MODPgr'}) if __name__ == '__main__': unittest.main(testRunner=VppTestRunner)