blob: 39f71438ab0a3470cf9d583758c1b35ae456f9c1 [file] [log] [blame]
#!/usr/bin/env python
import abc
import six
from scapy.layers.l2 import Ether, Raw
from scapy.layers.inet import IP, UDP
from util import ip4_range
@six.add_metaclass(abc.ABCMeta)
class BridgeDomain(object):
""" Bridge domain abstraction """
@property
def frame_request(self):
""" Ethernet frame modeling a generic request """
return (Ether(src='00:00:00:00:00:01', dst='00:00:00:00:00:02') /
IP(src='1.2.3.4', dst='4.3.2.1') /
UDP(sport=10000, dport=20000) /
Raw('\xa5' * 100))
@property
def frame_reply(self):
""" Ethernet frame modeling a generic reply """
return (Ether(src='00:00:00:00:00:02', dst='00:00:00:00:00:01') /
IP(src='4.3.2.1', dst='1.2.3.4') /
UDP(sport=20000, dport=10000) /
Raw('\xa5' * 100))
@abc.abstractmethod
def ip_range(self, start, end):
""" range of remote ip's """
pass
@abc.abstractmethod
def encap_mcast(self, pkt, src_ip, src_mac, vni):
""" Encapsulate mcast packet """
pass
@abc.abstractmethod
def encapsulate(self, pkt, vni):
""" Encapsulate packet """
pass
@abc.abstractmethod
def decapsulate(self, pkt):
""" Decapsulate packet """
pass
@abc.abstractmethod
def check_encapsulation(self, pkt, vni, local_only=False):
""" Verify the encapsulation """
pass
def assert_eq_pkts(self, pkt1, pkt2):
""" Verify the Ether, IP, UDP, payload are equal in both
packets
"""
self.assertEqual(pkt1[Ether].src, pkt2[Ether].src)
self.assertEqual(pkt1[Ether].dst, pkt2[Ether].dst)
self.assertEqual(pkt1[IP].src, pkt2[IP].src)
self.assertEqual(pkt1[IP].dst, pkt2[IP].dst)
self.assertEqual(pkt1[UDP].sport, pkt2[UDP].sport)
self.assertEqual(pkt1[UDP].dport, pkt2[UDP].dport)
self.assertEqual(pkt1[Raw], pkt2[Raw])
def test_decap(self):
""" Decapsulation test
Send encapsulated frames from pg0
Verify receipt of decapsulated frames on pg1
"""
encapsulated_pkt = self.encapsulate(self.frame_request,
self.single_tunnel_bd)
self.pg0.add_stream([encapsulated_pkt, ])
self.pg1.enable_capture()
self.pg_start()
# Pick first received frame and check if it's the non-encapsulated
# frame
out = self.pg1.get_capture(1)
pkt = out[0]
self.assert_eq_pkts(pkt, self.frame_request)
def test_encap(self):
""" Encapsulation test
Send frames from pg1
Verify receipt of encapsulated frames on pg0
"""
self.pg1.add_stream([self.frame_reply])
self.pg0.enable_capture()
self.pg_start()
# Pick first received frame and check if it's correctly encapsulated.
out = self.pg0.get_capture(1)
pkt = out[0]
self.check_encapsulation(pkt, self.single_tunnel_bd)
payload = self.decapsulate(pkt)
self.assert_eq_pkts(payload, self.frame_reply)
def test_ucast_flood(self):
""" Unicast flood test
Send frames from pg3
Verify receipt of encapsulated frames on pg0
"""
self.pg3.add_stream([self.frame_reply])
self.pg0.enable_capture()
self.pg_start()
# Get packet from each tunnel and assert it's correctly encapsulated.
out = self.pg0.get_capture(self.n_ucast_tunnels)
for pkt in out:
self.check_encapsulation(pkt, self.ucast_flood_bd, True)
payload = self.decapsulate(pkt)
self.assert_eq_pkts(payload, self.frame_reply)
def test_mcast_flood(self):
""" Multicast flood test
Send frames from pg2
Verify receipt of encapsulated frames on pg0
"""
self.pg2.add_stream([self.frame_reply])
self.pg0.enable_capture()
self.pg_start()
# Pick first received frame and check if it's correctly encapsulated.
out = self.pg0.get_capture(1)
pkt = out[0]
self.check_encapsulation(pkt, self.mcast_flood_bd,
local_only=False, mcast_pkt=True)
payload = self.decapsulate(pkt)
self.assert_eq_pkts(payload, self.frame_reply)
def test_mcast_rcv(self):
""" Multicast receive test
Send 20 encapsulated frames from pg0 only 10 match unicast tunnels
Verify receipt of 10 decap frames on pg2
"""
mac = self.pg0.remote_mac
ip_range_start = 10
ip_range_end = 30
mcast_stream = [
self.encap_mcast(self.frame_request, ip, mac, self.mcast_flood_bd)
for ip in self.ip_range(ip_range_start, ip_range_end)]
self.pg0.add_stream(mcast_stream)
self.pg2.enable_capture()
self.pg_start()
out = self.pg2.get_capture(10)
for pkt in out:
self.assert_eq_pkts(pkt, self.frame_request)