from scapy.layers.l2 import Ether, ARP
from scapy.layers.inet import IP, UDP
from scapy.layers.inet6 import IPv6
+from scapy.layers.vxlan import VXLAN
from scapy.contrib.wireguard import (
Wireguard,
WireguardResponse,
from vpp_ipip_tun_interface import VppIpIpTunInterface
from vpp_interface import VppInterface
+from vpp_pg_interface import is_ipv6_misc
from vpp_ip_route import VppIpRoute, VppRoutePath
+from vpp_l2 import VppBridgeDomain, VppBridgeDomainPort
+from vpp_vxlan_tunnel import VppVxlanTunnel
from vpp_object import VppObject
from vpp_papi import VppEnum
-from framework import tag_fixme_ubuntu2204, tag_fixme_debian11
-from framework import is_distro_ubuntu2204, is_distro_debian11
+from framework import is_distro_ubuntu2204, is_distro_debian11, tag_fixme_vpp_debug
from framework import VppTestCase
from re import compile
import unittest
HANDSHAKE_NUM_PER_PEER_UNTIL_UNDER_LOAD = 40
HANDSHAKE_NUM_BEFORE_RATELIMITING = 5
+HANDSHAKE_JITTER = 0.5
+
class VppWgPeer(VppObject):
def __init__(self, test, itf, endpoint, port, allowed_ips, persistent_keepalive=15):
self.endpoint = endpoint
self.port = port
- def add_vpp_config(self, is_ip6=False):
+ def add_vpp_config(self):
rv = self._test.vapi.wireguard_peer_add(
peer={
"public_key": self.public_key_bytes(),
self.allowed_ips.sort()
p.peer.allowed_ips.sort()
- for (a1, a2) in zip(self.allowed_ips, p.peer.allowed_ips):
+ for a1, a2 in zip(self.allowed_ips, p.peer.allowed_ips):
if str(a1) != str(a2):
return False
return True
if is_ip6 is False:
self._test.assertEqual(p[IP].src, self.itf.src)
self._test.assertEqual(p[IP].dst, self.endpoint)
+ self._test.assert_packet_checksums_valid(p)
else:
self._test.assertEqual(p[IPv6].src, self.itf.src)
self._test.assertEqual(p[IPv6].dst, self.endpoint)
+ self._test.assert_packet_checksums_valid(p, False)
self._test.assertEqual(p[UDP].sport, self.itf.port)
self._test.assertEqual(p[UDP].dport, self.port)
- self._test.assert_packet_checksums_valid(p)
def consume_init(self, p, tx_itf, is_ip6=False, is_mac2=False):
self.noise.set_as_responder()
def encrypt_transport(self, p):
return self.noise.encrypt(bytes(p))
- def validate_encapped(self, rxs, tx, is_ip6=False):
+ def validate_encapped(self, rxs, tx, is_tunnel_ip6=False, is_transport_ip6=False):
+ ret_rxs = []
for rx in rxs:
- if is_ip6 is False:
- rx = IP(self.decrypt_transport(rx, is_ip6=is_ip6))
-
+ rx = self.decrypt_transport(rx, is_tunnel_ip6)
+ if is_transport_ip6 is False:
+ rx = IP(rx)
# check the original packet is present
self._test.assertEqual(rx[IP].dst, tx[IP].dst)
self._test.assertEqual(rx[IP].ttl, tx[IP].ttl - 1)
else:
- rx = IPv6(self.decrypt_transport(rx, is_ip6=is_ip6))
-
+ rx = IPv6(rx)
# check the original packet is present
self._test.assertEqual(rx[IPv6].dst, tx[IPv6].dst)
self._test.assertEqual(rx[IPv6].hlim, tx[IPv6].hlim - 1)
+ ret_rxs.append(rx)
+ return ret_rxs
def want_events(self):
self._test.vapi.want_wireguard_peer_events(
self._test.assertEqual(rv.peer_index, self.index)
-@tag_fixme_ubuntu2204
-@tag_fixme_debian11
+def is_handshake_init(p):
+ wg_p = Wireguard(p[Raw])
+
+ return wg_p[Wireguard].message_type == 1
+
+
class TestWg(VppTestCase):
"""Wireguard Test Case"""
self.ratelimited6_err
)
+ def send_and_assert_no_replies_ignoring_init(
+ self, intf, pkts, remark="", timeout=None
+ ):
+ self.pg_send(intf, pkts)
+
+ def _filter_out_fn(p):
+ return is_ipv6_misc(p) or is_handshake_init(p)
+
+ try:
+ if not timeout:
+ timeout = 1
+ for i in self.pg_interfaces:
+ i.assert_nothing_captured(
+ timeout=timeout, remark=remark, filter_out_fn=_filter_out_fn
+ )
+ timeout = 0.1
+ finally:
+ pass
+
def test_wg_interface(self):
"""Simple interface creation"""
port = 12312
self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
if is_resp:
+ # skip the first automatic handshake
+ self.pg1.get_capture(1, timeout=HANDSHAKE_JITTER)
+
# prepare and send a handshake initiation
# expect the peer to send a handshake response
init = peer_1.mk_handshake(self.pg1, is_ip6=is_ip6)
# reset noise to be able to turn into initiator later
peer_1.noise_reset()
else:
+ # skip the first automatic handshake
+ self.pg1.get_capture(1, timeout=HANDSHAKE_JITTER)
+
# prepare and send a bunch of handshake initiations
# expect to switch to under load state
init = peer_1.mk_handshake(self.pg1, is_ip6=is_ip6)
).add_vpp_config()
self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
+ # skip the first automatic handshake
+ self.pg1.get_capture(1, timeout=HANDSHAKE_JITTER)
+
# prepare and send a bunch of handshake initiations
# expect to switch to under load state
init = peer_1.mk_handshake(self.pg1)
).add_vpp_config()
self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
+ # skip the first automatic handshake
+ self.pg1.get_capture(1, timeout=HANDSHAKE_JITTER)
+
# prepare and send a bunch of handshake initiations
# expect to switch to under load state
init = peer_1.mk_handshake(self.pg1, is_ip6=is_ip6)
).add_vpp_config()
self.assertEqual(len(self.vapi.wireguard_peers_dump()), 2)
+ # skip the first automatic handshake
+ self.pg1.get_capture(NUM_PEERS, timeout=HANDSHAKE_JITTER)
+
# (peer_1) prepare and send a bunch of handshake initiations
# expect not to switch to under load state
init_1 = peer_1.mk_handshake(self.pg1)
rxs = self.send_and_expect(self.pg1, [init_2], self.pg1)
peer_2.consume_cookie(rxs[0])
- # (peer_1) prepare and send a bunch of handshake initiations with correct mac2
- # expect no ratelimiting and a handshake response
+ # (peer_1) (peer_2) prepare and send a bunch of handshake initiations with correct mac2
+ # expect a handshake response and then ratelimiting
+ PEER_1_NUM_TO_REJECT = 2
+ PEER_2_NUM_TO_REJECT = 5
init_1 = peer_1.mk_handshake(self.pg1)
- txs = [init_1] * HANDSHAKE_NUM_BEFORE_RATELIMITING
- rxs = self.send_and_expect_some(self.pg1, txs, self.pg1)
- self.assertEqual(
- self.base_ratelimited4_err,
- self.statistics.get_err_counter(self.ratelimited4_err),
- )
-
- # (peer_1) verify the response
- peer_1.consume_response(rxs[0])
- peer_1.noise_reset()
-
- # (peer_1) send another two handshake initiations with correct mac2
- # expect ratelimiting
- # (peer_2) prepare and send a handshake initiation with correct mac2
- # expect no ratelimiting and a handshake response
+ txs = [init_1] * (HANDSHAKE_NUM_BEFORE_RATELIMITING + PEER_1_NUM_TO_REJECT)
init_2 = peer_2.mk_handshake(self.pg1)
- txs = [init_1, init_2, init_1]
+ txs += [init_2] * (HANDSHAKE_NUM_BEFORE_RATELIMITING + PEER_2_NUM_TO_REJECT)
rxs = self.send_and_expect_some(self.pg1, txs, self.pg1)
- # (peer_1) verify ratelimiting
- self.assertEqual(
- self.base_ratelimited4_err + 2,
- self.statistics.get_err_counter(self.ratelimited4_err),
+ self.assertTrue(
+ self.base_ratelimited4_err + PEER_1_NUM_TO_REJECT
+ < self.statistics.get_err_counter(self.ratelimited4_err)
+ <= self.base_ratelimited4_err + PEER_1_NUM_TO_REJECT + PEER_2_NUM_TO_REJECT
)
- # (peer_2) verify the response
- peer_2.consume_response(rxs[0])
+ # (peer_1) (peer_2) verify the response
+ peer_1.consume_response(rxs[0])
+ peer_2.consume_response(rxs[1])
# clear up under load state
self.sleep(UNDER_LOAD_INTERVAL)
rxs = self.send_and_expect(self.pg0, [p], self.pg1)
# verify the data packet
- peer_1.validate_encapped(rxs, p, is_ip6=is_ip6)
+ peer_1.validate_encapped(rxs, p, is_tunnel_ip6=is_ip6, is_transport_ip6=is_ip6)
# remove configs
r1.remove_vpp_config()
self._test_wg_peer_roaming_on_data_tmpl(is_async=True, is_ip6=True)
def test_wg_peer_resp(self):
- """Send handshake response"""
+ """Send handshake response IPv4 tunnel"""
port = 12323
# Create interfaces
peer_1.remove_vpp_config()
wg0.remove_vpp_config()
+ def test_wg_peer_resp_ipv6(self):
+ """Send handshake response IPv6 tunnel"""
+ port = 12323
+
+ # Create interfaces
+ wg0 = VppWgInterface(self, self.pg1.local_ip6, port).add_vpp_config()
+ wg0.admin_up()
+ wg0.config_ip4()
+
+ self.pg_enable_capture(self.pg_interfaces)
+ self.pg_start()
+
+ peer_1 = VppWgPeer(
+ self, wg0, self.pg1.remote_ip6, port + 1, ["10.11.3.0/24"]
+ ).add_vpp_config()
+ self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
+
+ r1 = VppIpRoute(
+ self, "10.11.3.0", 24, [VppRoutePath("10.11.3.1", wg0.sw_if_index)]
+ ).add_vpp_config()
+
+ # wait for the peer to send a handshake
+ rx = self.pg1.get_capture(1, timeout=2)
+
+ # consume the handshake in the noise protocol and
+ # generate the response
+ resp = peer_1.consume_init(rx[0], self.pg1, is_ip6=True)
+
+ # send the response, get keepalive
+ rxs = self.send_and_expect(self.pg1, [resp], self.pg1)
+
+ for rx in rxs:
+ b = peer_1.decrypt_transport(rx, True)
+ self.assertEqual(0, len(b))
+
+ # send a packets that are routed into the tunnel
+ p = (
+ Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac)
+ / IP(src=self.pg0.remote_ip4, dst="10.11.3.2")
+ / UDP(sport=555, dport=556)
+ / Raw(b"\x00" * 80)
+ )
+
+ rxs = self.send_and_expect(self.pg0, p * 2, self.pg1)
+ peer_1.validate_encapped(rxs, p, True)
+
+ # send packets into the tunnel, expect to receive them on
+ # the other side
+ p = [
+ (
+ peer_1.mk_tunnel_header(self.pg1, True)
+ / Wireguard(message_type=4, reserved_zero=0)
+ / WireguardTransport(
+ receiver_index=peer_1.sender,
+ counter=ii,
+ encrypted_encapsulated_packet=peer_1.encrypt_transport(
+ (
+ IP(src="10.11.3.1", dst=self.pg0.remote_ip4, ttl=20)
+ / UDP(sport=222, dport=223)
+ / Raw()
+ )
+ ),
+ )
+ )
+ for ii in range(255)
+ ]
+
+ rxs = self.send_and_expect(self.pg1, p, self.pg0)
+
+ for rx in rxs:
+ self.assertEqual(rx[IP].dst, self.pg0.remote_ip4)
+ self.assertEqual(rx[IP].ttl, 19)
+
+ r1.remove_vpp_config()
+ peer_1.remove_vpp_config()
+ wg0.remove_vpp_config()
+
def test_wg_peer_v4o4(self):
"""Test v4o4"""
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_kp4_err + 1, self.statistics.get_err_counter(self.kp4_error)
)
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_peer4_out_err + 1,
self.statistics.get_err_counter(self.peer4_out_err),
# send a handsake from the peer with an invalid MAC
p = peer_1.mk_handshake(self.pg1)
p[WireguardInitiation].mac1 = b"foobar"
- self.send_and_assert_no_replies(self.pg1, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg1, [p])
self.assertEqual(
self.base_mac4_err + 1, self.statistics.get_err_counter(self.mac4_error)
)
p = peer_1.mk_handshake(
self.pg1, False, X25519PrivateKey.generate().public_key()
)
- self.send_and_assert_no_replies(self.pg1, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg1, [p])
self.assertEqual(
self.base_peer4_in_err + 1,
self.statistics.get_err_counter(self.peer4_in_err),
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_kp4_err + 2, self.statistics.get_err_counter(self.kp4_error)
)
peer_1 = VppWgPeer(
self, wg0, self.pg1.remote_ip6, port + 1, ["1::3:0/112"]
- ).add_vpp_config(True)
+ ).add_vpp_config()
self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
r1 = VppIpRoute(
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_kp6_err + 1, self.statistics.get_err_counter(self.kp6_error)
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_peer6_out_err + 1,
self.statistics.get_err_counter(self.peer6_out_err),
# send a handsake from the peer with an invalid MAC
p = peer_1.mk_handshake(self.pg1, True)
p[WireguardInitiation].mac1 = b"foobar"
- self.send_and_assert_no_replies(self.pg1, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg1, [p])
self.assertEqual(
self.base_mac6_err + 1, self.statistics.get_err_counter(self.mac6_error)
p = peer_1.mk_handshake(
self.pg1, True, X25519PrivateKey.generate().public_key()
)
- self.send_and_assert_no_replies(self.pg1, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg1, [p])
self.assertEqual(
self.base_peer6_in_err + 1,
self.statistics.get_err_counter(self.peer6_in_err),
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_kp6_err + 2, self.statistics.get_err_counter(self.kp6_error)
)
peer_1 = VppWgPeer(
self, wg0, self.pg1.remote_ip4, port + 1, ["1::3:0/112"]
- ).add_vpp_config(True)
+ ).add_vpp_config()
self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
r1 = VppIpRoute(
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_kp6_err + 1, self.statistics.get_err_counter(self.kp6_error)
)
# send a handsake from the peer with an invalid MAC
p = peer_1.mk_handshake(self.pg1)
p[WireguardInitiation].mac1 = b"foobar"
- self.send_and_assert_no_replies(self.pg1, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg1, [p])
self.assertEqual(
self.base_mac4_err + 1, self.statistics.get_err_counter(self.mac4_error)
p = peer_1.mk_handshake(
self.pg1, False, X25519PrivateKey.generate().public_key()
)
- self.send_and_assert_no_replies(self.pg1, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg1, [p])
self.assertEqual(
self.base_peer4_in_err + 1,
self.statistics.get_err_counter(self.peer4_in_err),
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_kp6_err + 2, self.statistics.get_err_counter(self.kp6_error)
)
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_kp4_err + 1, self.statistics.get_err_counter(self.kp4_error)
)
# send a handsake from the peer with an invalid MAC
p = peer_1.mk_handshake(self.pg1, True)
p[WireguardInitiation].mac1 = b"foobar"
- self.send_and_assert_no_replies(self.pg1, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg1, [p])
self.assertEqual(
self.base_mac6_err + 1, self.statistics.get_err_counter(self.mac6_error)
)
p = peer_1.mk_handshake(
self.pg1, True, X25519PrivateKey.generate().public_key()
)
- self.send_and_assert_no_replies(self.pg1, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg1, [p])
self.assertEqual(
self.base_peer6_in_err + 1,
self.statistics.get_err_counter(self.peer6_in_err),
/ UDP(sport=555, dport=556)
/ Raw()
)
- self.send_and_assert_no_replies(self.pg0, [p])
+ self.send_and_assert_no_replies_ignoring_init(self.pg0, [p])
self.assertEqual(
self.base_kp4_err + 2, self.statistics.get_err_counter(self.kp4_error)
)
self.pg0.generate_remote_hosts(NUM_IFS)
self.pg0.configure_ipv4_neighbors()
+ self.pg_enable_capture(self.pg_interfaces)
+ self.pg_start()
+
# Create interfaces with a peer on each
peers = []
routes = []
self.assertEqual(len(self.vapi.wireguard_peers_dump()), NUM_IFS)
+ # skip the first automatic handshake
+ self.pg1.get_capture(NUM_IFS, timeout=HANDSHAKE_JITTER)
+
for i in range(NUM_IFS):
# send a valid handsake init for which we expect a response
p = peers[i].mk_handshake(self.pg1)
self.assertEqual(len(self.vapi.wireguard_peers_dump()), NUM_PEERS * 2)
+ # skip the first automatic handshake
+ self.pg1.get_capture(NUM_PEERS, timeout=HANDSHAKE_JITTER)
+ self.pg2.get_capture(NUM_PEERS, timeout=HANDSHAKE_JITTER)
+
# Want events from the first perr of wg0
# and from all wg1 peers
peers_0[0].want_events()
wg1.want_events()
for i in range(NUM_PEERS):
- # send a valid handsake init for which we expect a response
+ # wg0 peers: send a valid handsake init for which we expect a response
p = peers_0[i].mk_handshake(self.pg1)
rx = self.send_and_expect(self.pg1, [p], self.pg1)
peers_0[i].consume_response(rx[0])
+
+ # wg0 peers: send empty packet, it means successful connection (WIREGUARD_PEER_ESTABLISHED)
+ keepalive = peers_0[i].encrypt_transport(0)
+ p = peers_0[i].mk_tunnel_header(self.pg1) / (
+ Wireguard(message_type=4, reserved_zero=0)
+ / WireguardTransport(
+ receiver_index=peers_0[i].sender,
+ counter=0,
+ encrypted_encapsulated_packet=keepalive,
+ )
+ )
+ self.send_and_assert_no_replies(self.pg1, [p])
+
+ # wg0 peers: wait for established flag
if i == 0:
peers_0[0].wait_event(ESTABLISHED_FLAG)
+ # wg1 peers: send a valid handsake init for which we expect a response
p = peers_1[i].mk_handshake(self.pg2)
rx = self.send_and_expect(self.pg2, [p], self.pg2)
peers_1[i].consume_response(rx[0])
+ # wg1 peers: send empty packet, it means successful connection (WIREGUARD_PEER_ESTABLISHED)
+ keepalive = peers_1[i].encrypt_transport(0)
+ p = peers_1[i].mk_tunnel_header(self.pg2) / (
+ Wireguard(message_type=4, reserved_zero=0)
+ / WireguardTransport(
+ receiver_index=peers_1[i].sender,
+ counter=0,
+ encrypted_encapsulated_packet=keepalive,
+ )
+ )
+ self.send_and_assert_no_replies(self.pg2, [p])
+
+ # wg1 peers: wait for established flag
wg1.wait_events(ESTABLISHED_FLAG, [peers_1[0].index, peers_1[1].index])
# remove routes
wg0.remove_vpp_config()
wg1.remove_vpp_config()
+ def test_wg_sending_handshake_when_admin_down(self):
+ """Sending handshake when admin down"""
+ port = 12323
+
+ # create wg interface
+ wg0 = VppWgInterface(self, self.pg1.local_ip4, port).add_vpp_config()
+ wg0.config_ip4()
+
+ # create a peer
+ peer_1 = VppWgPeer(
+ self, wg0, self.pg1.remote_ip4, port + 1, ["10.11.3.0/24"]
+ ).add_vpp_config()
+ self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
+
+ self.pg_enable_capture(self.pg_interfaces)
+ self.pg_start()
+
+ # wait for the peer to send a handshake initiation
+ # expect no handshakes
+ for i in range(2):
+ self.pg1.assert_nothing_captured(remark="handshake packet(s) sent")
+
+ self.pg_enable_capture(self.pg_interfaces)
+ self.pg_start()
+
+ # administratively enable the wg interface
+ # expect the peer to send a handshake initiation
+ wg0.admin_up()
+ rxs = self.pg1.get_capture(1, timeout=2)
+ peer_1.consume_init(rxs[0], self.pg1)
+
+ self.pg_enable_capture(self.pg_interfaces)
+ self.pg_start()
+
+ # administratively disable the wg interface
+ # expect no handshakes
+ wg0.admin_down()
+ for i in range(6):
+ self.pg1.assert_nothing_captured(remark="handshake packet(s) sent")
+
+ # remove configs
+ peer_1.remove_vpp_config()
+ wg0.remove_vpp_config()
+
+ def test_wg_sending_data_when_admin_down(self):
+ """Sending data when admin down"""
+ port = 12323
+
+ # create wg interface
+ wg0 = VppWgInterface(self, self.pg1.local_ip4, port).add_vpp_config()
+ wg0.admin_up()
+ wg0.config_ip4()
+
+ self.pg_enable_capture(self.pg_interfaces)
+ self.pg_start()
+
+ # create a peer
+ peer_1 = VppWgPeer(
+ self, wg0, self.pg1.remote_ip4, port + 1, ["10.11.3.0/24"]
+ ).add_vpp_config()
+ self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
+
+ # create a route to rewrite traffic into the wg interface
+ r1 = VppIpRoute(
+ self, "10.11.3.0", 24, [VppRoutePath("10.11.3.1", wg0.sw_if_index)]
+ ).add_vpp_config()
+
+ # wait for the peer to send a handshake initiation
+ rxs = self.pg1.get_capture(1, timeout=2)
+
+ # prepare and send a handshake response
+ # expect a keepalive message
+ resp = peer_1.consume_init(rxs[0], self.pg1)
+ rxs = self.send_and_expect(self.pg1, [resp], self.pg1)
+
+ # verify the keepalive message
+ b = peer_1.decrypt_transport(rxs[0])
+ self.assertEqual(0, len(b))
+
+ # prepare and send a packet that will be rewritten into the wg interface
+ # expect a data packet sent
+ p = (
+ Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac)
+ / IP(src=self.pg0.remote_ip4, dst="10.11.3.2")
+ / UDP(sport=555, dport=556)
+ / Raw()
+ )
+ rxs = self.send_and_expect(self.pg0, [p], self.pg1)
+
+ # verify the data packet
+ peer_1.validate_encapped(rxs, p)
+
+ # administratively disable the wg interface
+ wg0.admin_down()
+
+ # send a packet that will be rewritten into the wg interface
+ # expect no data packets sent
+ self.send_and_assert_no_replies(self.pg0, [p])
+
+ # administratively enable the wg interface
+ # expect the peer to send a handshake initiation
+ wg0.admin_up()
+ peer_1.noise_reset()
+ rxs = self.pg1.get_capture(1, timeout=2)
+ resp = peer_1.consume_init(rxs[0], self.pg1)
+
+ # send a packet that will be rewritten into the wg interface
+ # expect no data packets sent because the peer is not initiated
+ self.send_and_assert_no_replies(self.pg0, [p])
+ self.assertEqual(
+ self.base_kp4_err + 1, self.statistics.get_err_counter(self.kp4_error)
+ )
+
+ # send a handshake response and expect a keepalive message
+ rxs = self.send_and_expect(self.pg1, [resp], self.pg1)
+
+ # verify the keepalive message
+ b = peer_1.decrypt_transport(rxs[0])
+ self.assertEqual(0, len(b))
+
+ # send a packet that will be rewritten into the wg interface
+ # expect a data packet sent
+ rxs = self.send_and_expect(self.pg0, [p], self.pg1)
+
+ # verify the data packet
+ peer_1.validate_encapped(rxs, p)
+
+ # remove configs
+ r1.remove_vpp_config()
+ peer_1.remove_vpp_config()
+ wg0.remove_vpp_config()
+
+ def _test_wg_large_packet_tmpl(self, is_async, is_ip6):
+ self.vapi.wg_set_async_mode(is_async)
+ port = 12323
+
+ # create wg interface
+ if is_ip6:
+ wg0 = VppWgInterface(self, self.pg1.local_ip6, port).add_vpp_config()
+ wg0.admin_up()
+ wg0.config_ip6()
+ else:
+ wg0 = VppWgInterface(self, self.pg1.local_ip4, port).add_vpp_config()
+ wg0.admin_up()
+ wg0.config_ip4()
+
+ self.pg_enable_capture(self.pg_interfaces)
+ self.pg_start()
+
+ # create a peer
+ if is_ip6:
+ peer_1 = VppWgPeer(
+ self, wg0, self.pg1.remote_ip6, port + 1, ["1::3:0/112"]
+ ).add_vpp_config()
+ else:
+ peer_1 = VppWgPeer(
+ self, wg0, self.pg1.remote_ip4, port + 1, ["10.11.3.0/24"]
+ ).add_vpp_config()
+ self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
+
+ # create a route to rewrite traffic into the wg interface
+ if is_ip6:
+ r1 = VppIpRoute(
+ self, "1::3:0", 112, [VppRoutePath("1::3:1", wg0.sw_if_index)]
+ ).add_vpp_config()
+ else:
+ r1 = VppIpRoute(
+ self, "10.11.3.0", 24, [VppRoutePath("10.11.3.1", wg0.sw_if_index)]
+ ).add_vpp_config()
-@tag_fixme_ubuntu2204
-@tag_fixme_debian11
+ # wait for the peer to send a handshake initiation
+ rxs = self.pg1.get_capture(1, timeout=2)
+
+ # prepare and send a handshake response
+ # expect a keepalive message
+ resp = peer_1.consume_init(rxs[0], self.pg1, is_ip6=is_ip6)
+ rxs = self.send_and_expect(self.pg1, [resp], self.pg1)
+
+ # verify the keepalive message
+ b = peer_1.decrypt_transport(rxs[0], is_ip6=is_ip6)
+ self.assertEqual(0, len(b))
+
+ # prepare and send data packets
+ # expect to receive them decrypted
+ if is_ip6:
+ ip_header = IPv6(src="1::3:1", dst=self.pg0.remote_ip6, hlim=20)
+ else:
+ ip_header = IP(src="10.11.3.1", dst=self.pg0.remote_ip4, ttl=20)
+ packet_len_opts = (
+ 2500, # two buffers
+ 1500, # one buffer
+ 4500, # three buffers
+ 1910 if is_ip6 else 1950, # auth tag is not contiguous
+ )
+ txs = []
+ for l in packet_len_opts:
+ txs.append(
+ peer_1.mk_tunnel_header(self.pg1, is_ip6=is_ip6)
+ / Wireguard(message_type=4, reserved_zero=0)
+ / WireguardTransport(
+ receiver_index=peer_1.sender,
+ counter=len(txs),
+ encrypted_encapsulated_packet=peer_1.encrypt_transport(
+ ip_header / UDP(sport=222, dport=223) / Raw(b"\xfe" * l)
+ ),
+ )
+ )
+ rxs = self.send_and_expect(self.pg1, txs, self.pg0)
+
+ # verify decrypted packets
+ for i, l in enumerate(packet_len_opts):
+ if is_ip6:
+ self.assertEqual(rxs[i][IPv6].dst, self.pg0.remote_ip6)
+ self.assertEqual(rxs[i][IPv6].hlim, ip_header.hlim - 1)
+ else:
+ self.assertEqual(rxs[i][IP].dst, self.pg0.remote_ip4)
+ self.assertEqual(rxs[i][IP].ttl, ip_header.ttl - 1)
+ self.assertEqual(len(rxs[i][Raw]), l)
+ self.assertEqual(bytes(rxs[i][Raw]), b"\xfe" * l)
+
+ # prepare and send packets that will be rewritten into the wg interface
+ # expect data packets sent
+ if is_ip6:
+ ip_header = IPv6(src=self.pg0.remote_ip6, dst="1::3:2")
+ else:
+ ip_header = IP(src=self.pg0.remote_ip4, dst="10.11.3.2")
+ packet_len_opts = (
+ 2500, # two buffers
+ 1500, # one buffer
+ 4500, # three buffers
+ 1980 if is_ip6 else 2000, # no free space to write auth tag
+ )
+ txs = []
+ for l in packet_len_opts:
+ txs.append(
+ Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac)
+ / ip_header
+ / UDP(sport=555, dport=556)
+ / Raw(b"\xfe" * l)
+ )
+ rxs = self.send_and_expect(self.pg0, txs, self.pg1)
+
+ # verify the data packets
+ rxs_decrypted = peer_1.validate_encapped(
+ rxs, ip_header, is_tunnel_ip6=is_ip6, is_transport_ip6=is_ip6
+ )
+
+ for i, l in enumerate(packet_len_opts):
+ self.assertEqual(len(rxs_decrypted[i][Raw]), l)
+ self.assertEqual(bytes(rxs_decrypted[i][Raw]), b"\xfe" * l)
+
+ # remove configs
+ r1.remove_vpp_config()
+ peer_1.remove_vpp_config()
+ wg0.remove_vpp_config()
+
+ def test_wg_large_packet_v4_sync(self):
+ """Large packet (v4, sync)"""
+ self._test_wg_large_packet_tmpl(is_async=False, is_ip6=False)
+
+ def test_wg_large_packet_v6_sync(self):
+ """Large packet (v6, sync)"""
+ self._test_wg_large_packet_tmpl(is_async=False, is_ip6=True)
+
+ def test_wg_large_packet_v4_async(self):
+ """Large packet (v4, async)"""
+ self._test_wg_large_packet_tmpl(is_async=True, is_ip6=False)
+
+ def test_wg_large_packet_v6_async(self):
+ """Large packet (v6, async)"""
+ self._test_wg_large_packet_tmpl(is_async=True, is_ip6=True)
+
+ def test_wg_lack_of_buf_headroom(self):
+ """Lack of buffer's headroom (v6 vxlan over v6 wg)"""
+ port = 12323
+
+ # create wg interface
+ wg0 = VppWgInterface(self, self.pg1.local_ip6, port).add_vpp_config()
+ wg0.admin_up()
+ wg0.config_ip6()
+
+ self.pg_enable_capture(self.pg_interfaces)
+ self.pg_start()
+
+ # create a peer
+ peer_1 = VppWgPeer(
+ self, wg0, self.pg1.remote_ip6, port + 1, ["::/0"]
+ ).add_vpp_config()
+ self.assertEqual(len(self.vapi.wireguard_peers_dump()), 1)
+
+ # create a route to enable communication between wg interface addresses
+ r1 = VppIpRoute(
+ self, wg0.remote_ip6, 128, [VppRoutePath("0.0.0.0", wg0.sw_if_index)]
+ ).add_vpp_config()
+
+ # wait for the peer to send a handshake initiation
+ rxs = self.pg1.get_capture(1, timeout=2)
+
+ # prepare and send a handshake response
+ # expect a keepalive message
+ resp = peer_1.consume_init(rxs[0], self.pg1, is_ip6=True)
+ rxs = self.send_and_expect(self.pg1, [resp], self.pg1)
+
+ # verify the keepalive message
+ b = peer_1.decrypt_transport(rxs[0], is_ip6=True)
+ self.assertEqual(0, len(b))
+
+ # create vxlan interface over the wg interface
+ vxlan0 = VppVxlanTunnel(self, src=wg0.local_ip6, dst=wg0.remote_ip6, vni=1111)
+ vxlan0.add_vpp_config()
+
+ # create bridge domain
+ bd1 = VppBridgeDomain(self, bd_id=1)
+ bd1.add_vpp_config()
+
+ # add the vxlan interface and pg0 to the bridge domain
+ bd1_ports = (
+ VppBridgeDomainPort(self, bd1, vxlan0).add_vpp_config(),
+ VppBridgeDomainPort(self, bd1, self.pg0).add_vpp_config(),
+ )
+
+ # prepare and send packets that will be rewritten into the vxlan interface
+ # expect they to be rewritten into the wg interface then and data packets sent
+ tx = (
+ Ether(dst="00:00:00:00:00:01", src="00:00:00:00:00:02")
+ / IPv6(src="::1", dst="::2", hlim=20)
+ / UDP(sport=1111, dport=1112)
+ / Raw(b"\xfe" * 1900)
+ )
+ rxs = self.send_and_expect(self.pg0, [tx] * 5, self.pg1)
+
+ # verify the data packet
+ for rx in rxs:
+ rx_decrypted = IPv6(peer_1.decrypt_transport(rx, is_ip6=True))
+
+ self.assertEqual(rx_decrypted[VXLAN].vni, vxlan0.vni)
+ inner = rx_decrypted[VXLAN].payload
+
+ # check the original packet is present
+ self.assertEqual(inner[IPv6].dst, tx[IPv6].dst)
+ self.assertEqual(inner[IPv6].hlim, tx[IPv6].hlim)
+ self.assertEqual(len(inner[Raw]), len(tx[Raw]))
+ self.assertEqual(bytes(inner[Raw]), bytes(tx[Raw]))
+
+ # remove configs
+ for bdp in bd1_ports:
+ bdp.remove_vpp_config()
+ bd1.remove_vpp_config()
+ vxlan0.remove_vpp_config()
+ r1.remove_vpp_config()
+ peer_1.remove_vpp_config()
+ wg0.remove_vpp_config()
+
+
+@tag_fixme_vpp_debug
class WireguardHandoffTests(TestWg):
"""Wireguard Tests in multi worker setup"""
wg0.admin_up()
wg0.config_ip4()
+ self.pg_enable_capture(self.pg_interfaces)
+ self.pg_start()
+
peer_1 = VppWgPeer(
self, wg0, self.pg1.remote_ip4, port + 1, ["10.11.2.0/24", "10.11.3.0/24"]
).add_vpp_config()
self, "10.11.3.0", 24, [VppRoutePath("10.11.3.1", wg0.sw_if_index)]
).add_vpp_config()
+ # skip the first automatic handshake
+ self.pg1.get_capture(1, timeout=HANDSHAKE_JITTER)
+
# send a valid handsake init for which we expect a response
p = peer_1.mk_handshake(self.pg1)
self.assertEqual(rx[IP].ttl, 19)
# send a packets that are routed into the tunnel
- # from owrker 0
+ # from worker 0
rxs = self.send_and_expect(self.pg0, pe * 255, self.pg1, worker=0)
peer_1.validate_encapped(rxs, pe)
self.assertEqual(0, len(b))
# prepare and send a packet that will be rewritten into the wg interface
- # expect a data packet sent to the new endpoint
+ # expect a data packet sent
p = (
Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac)
/ IP(src=self.pg0.remote_ip4, dst="10.11.3.2")
Code Review / vpp.git / blobdiff