#!/usr/bin/env python3 import unittest import socket from framework import tag_fixme_vpp_workers from framework import VppTestCase, VppTestRunner from vpp_ip import DpoProto, INVALID_INDEX from vpp_ip_route import VppIpRoute, VppRoutePath, VppMplsRoute, \ VppMplsIpBind, VppIpMRoute, VppMRoutePath, \ VppIpTable, VppMplsTable, \ VppMplsLabel, MplsLspMode, find_mpls_route, \ FibPathProto, FibPathType, FibPathFlags, VppMplsLabel, MplsLspMode from vpp_mpls_tunnel_interface import VppMPLSTunnelInterface from vpp_papi import VppEnum import scapy.compat from scapy.packet import Raw from scapy.layers.l2 import Ether, ARP from scapy.layers.inet import IP, UDP, ICMP from scapy.layers.inet6 import IPv6, ICMPv6TimeExceeded from scapy.contrib.mpls import MPLS NUM_PKTS = 67 # scapy removed these attributes. # we asked that they be restored: https://github.com/secdev/scapy/pull/1878 # semantic names have more meaning than numbers. so here they are. ARP.who_has = 1 ARP.is_at = 2 def verify_filter(capture, sent): if not len(capture) == len(sent): # filter out any IPv6 RAs from the capture for p in capture: if p.haslayer(IPv6): capture.remove(p) return capture def verify_mpls_stack(tst, rx, mpls_labels): # the rx'd packet has the MPLS label popped eth = rx[Ether] tst.assertEqual(eth.type, 0x8847) rx_mpls = rx[MPLS] for ii in range(len(mpls_labels)): tst.assertEqual(rx_mpls.label, mpls_labels[ii].value) tst.assertEqual(rx_mpls.cos, mpls_labels[ii].exp) tst.assertEqual(rx_mpls.ttl, mpls_labels[ii].ttl) if ii == len(mpls_labels) - 1: tst.assertEqual(rx_mpls.s, 1) else: # not end of stack tst.assertEqual(rx_mpls.s, 0) # pop the label to expose the next rx_mpls = rx_mpls[MPLS].payload @tag_fixme_vpp_workers class TestMPLS(VppTestCase): """ MPLS Test Case """ @classmethod def setUpClass(cls): super(TestMPLS, cls).setUpClass() @classmethod def tearDownClass(cls): super(TestMPLS, cls).tearDownClass() def setUp(self): super(TestMPLS, self).setUp() # create 2 pg interfaces self.create_pg_interfaces(range(4)) # setup both interfaces # assign them different tables. table_id = 0 self.tables = [] tbl = VppMplsTable(self, 0) tbl.add_vpp_config() self.tables.append(tbl) for i in self.pg_interfaces: i.admin_up() if table_id != 0: tbl = VppIpTable(self, table_id) tbl.add_vpp_config() self.tables.append(tbl) tbl = VppIpTable(self, table_id, is_ip6=1) tbl.add_vpp_config() self.tables.append(tbl) i.set_table_ip4(table_id) i.set_table_ip6(table_id) i.config_ip4() i.resolve_arp() i.config_ip6() i.resolve_ndp() i.enable_mpls() table_id += 1 def tearDown(self): for i in self.pg_interfaces: i.unconfig_ip4() i.unconfig_ip6() i.set_table_ip4(0) i.set_table_ip6(0) i.disable_mpls() i.admin_down() super(TestMPLS, self).tearDown() # the default of 64 matches the IP packet TTL default def create_stream_labelled_ip4( self, src_if, mpls_labels, ping=0, ip_itf=None, dst_ip=None, chksum=None, ip_ttl=64, n=257): self.reset_packet_infos() pkts = [] for i in range(0, n): info = self.create_packet_info(src_if, src_if) payload = self.info_to_payload(info) p = Ether(dst=src_if.local_mac, src=src_if.remote_mac) for ii in range(len(mpls_labels)): p = p / MPLS(label=mpls_labels[ii].value, ttl=mpls_labels[ii].ttl, cos=mpls_labels[ii].exp) if not ping: if not dst_ip: p = (p / IP(src=src_if.local_ip4, dst=src_if.remote_ip4, ttl=ip_ttl) / UDP(sport=1234, dport=1234) / Raw(payload)) else: p = (p / IP(src=src_if.local_ip4, dst=dst_ip, ttl=ip_ttl) / UDP(sport=1234, dport=1234) / Raw(payload)) else: p = (p / IP(src=ip_itf.remote_ip4, dst=ip_itf.local_ip4, ttl=ip_ttl) / ICMP()) if chksum: p[IP].chksum = chksum info.data = p.copy() pkts.append(p) return pkts def create_stream_ip4(self, src_if, dst_ip, ip_ttl=64, ip_dscp=0, payload_size=None): self.reset_packet_infos() pkts = [] for i in range(0, 257): info = self.create_packet_info(src_if, src_if) payload = self.info_to_payload(info) p = (Ether(dst=src_if.local_mac, src=src_if.remote_mac) / IP(src=src_if.remote_ip4, dst=dst_ip, ttl=ip_ttl, tos=ip_dscp) / UDP(sport=1234, dport=1234) / Raw(payload)) info.data = p.copy() if payload_size: self.extend_packet(p, payload_size) pkts.append(p) return pkts def create_stream_ip6(self, src_if, dst_ip, ip_ttl=64, ip_dscp=0): self.reset_packet_infos() pkts = [] for i in range(0, 257): info = self.create_packet_info(src_if, src_if) payload = self.info_to_payload(info) p = (Ether(dst=src_if.local_mac, src=src_if.remote_mac) / IPv6(src=src_if.remote_ip6, dst=dst_ip, hlim=ip_ttl, tc=ip_dscp) / UDP(sport=1234, dport=1234) / Raw(payload)) info.data = p.copy() pkts.append(p) return pkts def create_stream_labelled_ip6(self, src_if, mpls_labels, hlim=64, dst_ip=None): if dst_ip is None: dst_ip = src_if.remote_ip6 self.reset_packet_infos() pkts = [] for i in range(0, 257): info = self.create_packet_info(src_if, src_if) payload = self.info_to_payload(info) p = Ether(dst=src_if.local_mac, src=src_if.remote_mac) for l in mpls_labels: p = p / MPLS(label=l.value, ttl=l.ttl, cos=l.exp) p = p / (IPv6(src=src_if.remote_ip6, dst=dst_ip, hlim=hlim) / UDP(sport=1234, dport=1234) / Raw(payload)) info.data = p.copy() pkts.append(p) return pkts def verify_capture_ip4(self, src_if, capture, sent, ping_resp=0, ip_ttl=None, ip_dscp=0): try: capture = verify_filter(capture, sent) self.assertEqual(len(capture), len(sent)) for i in range(len(capture)): tx = sent[i] rx = capture[i] # the rx'd packet has the MPLS label popped eth = rx[Ether] self.assertEqual(eth.type, 0x800) tx_ip = tx[IP] rx_ip = rx[IP] if not ping_resp: self.assertEqual(rx_ip.src, tx_ip.src) self.assertEqual(rx_ip.dst, tx_ip.dst) self.assertEqual(rx_ip.tos, ip_dscp) if not ip_ttl: # IP processing post pop has decremented the TTL self.assertEqual(rx_ip.ttl + 1, tx_ip.ttl) else: self.assertEqual(rx_ip.ttl, ip_ttl) else: self.assertEqual(rx_ip.src, tx_ip.dst) self.assertEqual(rx_ip.dst, tx_ip.src) except: raise def verify_capture_labelled_ip4(self, src_if, capture, sent, mpls_labels, ip_ttl=None): try: capture = verify_filter(capture, sent) self.assertEqual(len(capture), len(sent)) for i in range(len(capture)): tx = sent[i] rx = capture[i] tx_ip = tx[IP] rx_ip = rx[IP] verify_mpls_stack(self, rx, mpls_labels) self.assertEqual(rx_ip.src, tx_ip.src) self.assertEqual(rx_ip.dst, tx_ip.dst) if not ip_ttl: # IP processing post pop has decremented the TTL self.assertEqual(rx_ip.ttl + 1, tx_ip.ttl) else: self.assertEqual(rx_ip.ttl, ip_ttl) except: raise def verify_capture_labelled_ip6(self, src_if, capture, sent, mpls_labels, ip_ttl=None): try: capture = verify_filter(capture, sent) self.assertEqual(len(capture), len(sent)) for i in range(len(capture)): tx = sent[i] rx = capture[i] tx_ip = tx[IPv6] rx_ip = rx[IPv6] verify_mpls_stack(self, rx, mpls_labels) self.assertEqual(rx_ip.src, tx_ip.src) self.assertEqual(rx_ip.dst, tx_ip.dst) if not ip_ttl: # IP processing post pop has decremented the TTL self.assertEqual(rx_ip.hlim + 1, tx_ip.hlim) else: self.assertEqual(rx_ip.hlim, ip_ttl) except: raise def verify_capture_tunneled_ip4(self, src_if, capture, sent, mpls_labels): try: capture = verify_filter(capture, sent) self.assertEqual(len(capture), len(sent)) for i in range(len(capture)): tx = sent[i] rx = capture[i] tx_ip = tx[IP] rx_ip = rx[IP] verify_mpls_stack(self, rx, mpls_labels) self.assertEqual(rx_ip.src, tx_ip.src) self.assertEqual(rx_ip.dst, tx_ip.dst) # IP processing post pop has decremented the TTL self.assertEqual(rx_ip.ttl + 1, tx_ip.ttl) except: raise def verify_capture_labelled(self, src_if, capture, sent, mpls_labels): try: capture = verify_filter(capture, sent) self.assertEqual(len(capture), len(sent)) for i in range(len(capture)): rx = capture[i] verify_mpls_stack(self, rx, mpls_labels) except: raise def verify_capture_ip6(self, src_if, capture, sent, ip_hlim=None, ip_dscp=0): try: self.assertEqual(len(capture), len(sent)) for i in range(len(capture)): tx = sent[i] rx = capture[i] # the rx'd packet has the MPLS label popped eth = rx[Ether] self.assertEqual(eth.type, 0x86DD) tx_ip = tx[IPv6] rx_ip = rx[IPv6] self.assertEqual(rx_ip.src, tx_ip.src) self.assertEqual(rx_ip.dst, tx_ip.dst) self.assertEqual(rx_ip.tc, ip_dscp) # IP processing post pop has decremented the TTL if not ip_hlim: self.assertEqual(rx_ip.hlim + 1, tx_ip.hlim) else: self.assertEqual(rx_ip.hlim, ip_hlim) except: raise def verify_capture_ip6_icmp(self, src_if, capture, sent): try: # rate limited ICMP self.assertTrue(len(capture) <= len(sent)) for i in range(len(capture)): tx = sent[i] rx = capture[i] # the rx'd packet has the MPLS label popped eth = rx[Ether] self.assertEqual(eth.type, 0x86DD) tx_ip = tx[IPv6] rx_ip = rx[IPv6] self.assertEqual(rx_ip.dst, tx_ip.src) # ICMP sourced from the interface's address self.assertEqual(rx_ip.src, src_if.local_ip6) # hop-limit reset to 255 for IMCP packet self.assertEqual(rx_ip.hlim, 255) icmp = rx[ICMPv6TimeExceeded] except: raise def verify_capture_fragmented_labelled_ip4(self, src_if, capture, sent, mpls_labels, ip_ttl=None): try: capture = verify_filter(capture, sent) for i in range(len(capture)): tx = sent[0] rx = capture[i] tx_ip = tx[IP] rx_ip = rx[IP] verify_mpls_stack(self, rx, mpls_labels) self.assertEqual(rx_ip.src, tx_ip.src) self.assertEqual(rx_ip.dst, tx_ip.dst) if not ip_ttl: # IP processing post pop has decremented the TTL self.assertEqual(rx_ip.ttl + 1, tx_ip.ttl) else: self.assertEqual(rx_ip.ttl, ip_ttl) except: raise def test_swap(self): """ MPLS label swap tests """ # # A simple MPLS xconnect - eos label in label out # route_32_eos = VppMplsRoute(self, 32, 1, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(33)])]) route_32_eos.add_vpp_config() self.assertTrue( find_mpls_route(self, 0, 32, 1, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(33)])])) # # a stream that matches the route for 10.0.0.1 # PG0 is in the default table # tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(32, ttl=32, exp=1)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled(self.pg0, rx, tx, [VppMplsLabel(33, ttl=31, exp=1)]) self.assertEqual(route_32_eos.get_stats_to()['packets'], 257) # # A simple MPLS xconnect - non-eos label in label out # route_32_neos = VppMplsRoute(self, 32, 0, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(33)])]) route_32_neos.add_vpp_config() # # a stream that matches the route for 10.0.0.1 # PG0 is in the default table # tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(32, ttl=21, exp=7), VppMplsLabel(99)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled(self.pg0, rx, tx, [VppMplsLabel(33, ttl=20, exp=7), VppMplsLabel(99)]) self.assertEqual(route_32_neos.get_stats_to()['packets'], 257) # # A simple MPLS xconnect - non-eos label in label out, uniform mode # route_42_neos = VppMplsRoute( self, 42, 0, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(43, MplsLspMode.UNIFORM)])]) route_42_neos.add_vpp_config() tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(42, ttl=21, exp=7), VppMplsLabel(99)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled(self.pg0, rx, tx, [VppMplsLabel(43, ttl=20, exp=7), VppMplsLabel(99)]) # # An MPLS xconnect - EOS label in IP out # route_33_eos = VppMplsRoute(self, 33, 1, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[])]) route_33_eos.add_vpp_config() tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(33)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_ip4(self.pg0, rx, tx) # # disposed packets have an invalid IPv4 checksum # tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(33)], dst_ip=self.pg0.remote_ip4, n=65, chksum=1) self.send_and_assert_no_replies(self.pg0, tx, "Invalid Checksum") # # An MPLS xconnect - EOS label in IP out, uniform mode # route_3333_eos = VppMplsRoute( self, 3333, 1, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(3, MplsLspMode.UNIFORM)])]) route_3333_eos.add_vpp_config() tx = self.create_stream_labelled_ip4( self.pg0, [VppMplsLabel(3333, ttl=55, exp=3)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_ip4(self.pg0, rx, tx, ip_ttl=54, ip_dscp=0x60) tx = self.create_stream_labelled_ip4( self.pg0, [VppMplsLabel(3333, ttl=66, exp=4)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_ip4(self.pg0, rx, tx, ip_ttl=65, ip_dscp=0x80) # # An MPLS xconnect - EOS label in IPv6 out # route_333_eos = VppMplsRoute( self, 333, 1, [VppRoutePath(self.pg0.remote_ip6, self.pg0.sw_if_index, labels=[])], eos_proto=FibPathProto.FIB_PATH_NH_PROTO_IP6) route_333_eos.add_vpp_config() tx = self.create_stream_labelled_ip6(self.pg0, [VppMplsLabel(333)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_ip6(self.pg0, rx, tx) # # disposed packets have an TTL expired # tx = self.create_stream_labelled_ip6(self.pg0, [VppMplsLabel(333, ttl=64)], dst_ip=self.pg1.remote_ip6, hlim=1) rx = self.send_and_expect_some(self.pg0, tx, self.pg0) self.verify_capture_ip6_icmp(self.pg0, rx, tx) # # An MPLS xconnect - EOS label in IPv6 out w imp-null # route_334_eos = VppMplsRoute( self, 334, 1, [VppRoutePath(self.pg0.remote_ip6, self.pg0.sw_if_index, labels=[VppMplsLabel(3)])], eos_proto=FibPathProto.FIB_PATH_NH_PROTO_IP6) route_334_eos.add_vpp_config() tx = self.create_stream_labelled_ip6(self.pg0, [VppMplsLabel(334, ttl=64)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_ip6(self.pg0, rx, tx) # # An MPLS xconnect - EOS label in IPv6 out w imp-null in uniform mode # route_335_eos = VppMplsRoute( self, 335, 1, [VppRoutePath(self.pg0.remote_ip6, self.pg0.sw_if_index, labels=[VppMplsLabel(3, MplsLspMode.UNIFORM)])], eos_proto=FibPathProto.FIB_PATH_NH_PROTO_IP6) route_335_eos.add_vpp_config() tx = self.create_stream_labelled_ip6( self.pg0, [VppMplsLabel(335, ttl=27, exp=4)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_ip6(self.pg0, rx, tx, ip_hlim=26, ip_dscp=0x80) # # disposed packets have an TTL expired # tx = self.create_stream_labelled_ip6(self.pg0, [VppMplsLabel(334)], dst_ip=self.pg1.remote_ip6, hlim=0) rx = self.send_and_expect_some(self.pg0, tx, self.pg0) self.verify_capture_ip6_icmp(self.pg0, rx, tx) # # An MPLS xconnect - non-EOS label in IP out - an invalid configuration # so this traffic should be dropped. # route_33_neos = VppMplsRoute(self, 33, 0, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[])]) route_33_neos.add_vpp_config() tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(33), VppMplsLabel(99)]) self.send_and_assert_no_replies( self.pg0, tx, "MPLS non-EOS packets popped and forwarded") # # A recursive EOS x-connect, which resolves through another x-connect # in pipe mode # route_34_eos = VppMplsRoute(self, 34, 1, [VppRoutePath("0.0.0.0", 0xffffffff, nh_via_label=32, labels=[VppMplsLabel(44), VppMplsLabel(45)])]) route_34_eos.add_vpp_config() self.logger.info(self.vapi.cli("sh mpls fib 34")) tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(34, ttl=3)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled(self.pg0, rx, tx, [VppMplsLabel(33), VppMplsLabel(44), VppMplsLabel(45, ttl=2)]) self.assertEqual(route_34_eos.get_stats_to()['packets'], 257) self.assertEqual(route_32_neos.get_stats_via()['packets'], 257) # # A recursive EOS x-connect, which resolves through another x-connect # in uniform mode # route_35_eos = VppMplsRoute( self, 35, 1, [VppRoutePath("0.0.0.0", 0xffffffff, nh_via_label=42, labels=[VppMplsLabel(44)])]) route_35_eos.add_vpp_config() tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(35, ttl=3)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled(self.pg0, rx, tx, [VppMplsLabel(43, ttl=2), VppMplsLabel(44, ttl=2)]) # # A recursive non-EOS x-connect, which resolves through another # x-connect # route_34_neos = VppMplsRoute(self, 34, 0, [VppRoutePath("0.0.0.0", 0xffffffff, nh_via_label=32, labels=[VppMplsLabel(44), VppMplsLabel(46)])]) route_34_neos.add_vpp_config() tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(34, ttl=45), VppMplsLabel(99)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) # it's the 2nd (counting from 0) label in the stack that is swapped self.verify_capture_labelled(self.pg0, rx, tx, [VppMplsLabel(33), VppMplsLabel(44), VppMplsLabel(46, ttl=44), VppMplsLabel(99)]) # # an recursive IP route that resolves through the recursive non-eos # x-connect # ip_10_0_0_1 = VppIpRoute(self, "10.0.0.1", 32, [VppRoutePath("0.0.0.0", 0xffffffff, nh_via_label=34, labels=[VppMplsLabel(55)])]) ip_10_0_0_1.add_vpp_config() tx = self.create_stream_ip4(self.pg0, "10.0.0.1") rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(33), VppMplsLabel(44), VppMplsLabel(46), VppMplsLabel(55)]) self.assertEqual(ip_10_0_0_1.get_stats_to()['packets'], 257) ip_10_0_0_1.remove_vpp_config() route_34_neos.remove_vpp_config() route_34_eos.remove_vpp_config() route_33_neos.remove_vpp_config() route_33_eos.remove_vpp_config() route_32_neos.remove_vpp_config() route_32_eos.remove_vpp_config() def test_bind(self): """ MPLS Local Label Binding test """ # # Add a non-recursive route with a single out label # route_10_0_0_1 = VppIpRoute(self, "10.0.0.1", 32, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(45)])]) route_10_0_0_1.add_vpp_config() # bind a local label to the route binding = VppMplsIpBind(self, 44, "10.0.0.1", 32) binding.add_vpp_config() # non-EOS stream tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(44), VppMplsLabel(99)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled(self.pg0, rx, tx, [VppMplsLabel(45, ttl=63), VppMplsLabel(99)]) # EOS stream tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(44)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled(self.pg0, rx, tx, [VppMplsLabel(45, ttl=63)]) # IP stream tx = self.create_stream_ip4(self.pg0, "10.0.0.1") rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(45)]) # # cleanup # binding.remove_vpp_config() route_10_0_0_1.remove_vpp_config() def test_imposition(self): """ MPLS label imposition test """ # # Add a non-recursive route with a single out label # route_10_0_0_1 = VppIpRoute(self, "10.0.0.1", 32, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(32)])]) route_10_0_0_1.add_vpp_config() # # a stream that matches the route for 10.0.0.1 # PG0 is in the default table # tx = self.create_stream_ip4(self.pg0, "10.0.0.1") rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(32)]) # # Add a non-recursive route with a 3 out labels # route_10_0_0_2 = VppIpRoute(self, "10.0.0.2", 32, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(32), VppMplsLabel(33), VppMplsLabel(34)])]) route_10_0_0_2.add_vpp_config() tx = self.create_stream_ip4(self.pg0, "10.0.0.2", ip_ttl=44, ip_dscp=0xff) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(32), VppMplsLabel(33), VppMplsLabel(34)], ip_ttl=43) # # Add a non-recursive route with a single out label in uniform mode # route_10_0_0_3 = VppIpRoute( self, "10.0.0.3", 32, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(32, mode=MplsLspMode.UNIFORM)])]) route_10_0_0_3.add_vpp_config() tx = self.create_stream_ip4(self.pg0, "10.0.0.3", ip_ttl=54, ip_dscp=0xbe) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(32, ttl=53, exp=5)]) # # Add a IPv6 non-recursive route with a single out label in # uniform mode # route_2001_3 = VppIpRoute( self, "2001::3", 128, [VppRoutePath(self.pg0.remote_ip6, self.pg0.sw_if_index, labels=[VppMplsLabel(32, mode=MplsLspMode.UNIFORM)])]) route_2001_3.add_vpp_config() tx = self.create_stream_ip6(self.pg0, "2001::3", ip_ttl=54, ip_dscp=0xbe) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip6(self.pg0, rx, tx, [VppMplsLabel(32, ttl=53, exp=5)]) # # add a recursive path, with output label, via the 1 label route # route_11_0_0_1 = VppIpRoute(self, "11.0.0.1", 32, [VppRoutePath("10.0.0.1", 0xffffffff, labels=[VppMplsLabel(44)])]) route_11_0_0_1.add_vpp_config() # # a stream that matches the route for 11.0.0.1, should pick up # the label stack for 11.0.0.1 and 10.0.0.1 # tx = self.create_stream_ip4(self.pg0, "11.0.0.1") rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(32), VppMplsLabel(44)]) self.assertEqual(route_11_0_0_1.get_stats_to()['packets'], 257) # # add a recursive path, with 2 labels, via the 3 label route # route_11_0_0_2 = VppIpRoute(self, "11.0.0.2", 32, [VppRoutePath("10.0.0.2", 0xffffffff, labels=[VppMplsLabel(44), VppMplsLabel(45)])]) route_11_0_0_2.add_vpp_config() # # a stream that matches the route for 11.0.0.1, should pick up # the label stack for 11.0.0.1 and 10.0.0.1 # tx = self.create_stream_ip4(self.pg0, "11.0.0.2") rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(32), VppMplsLabel(33), VppMplsLabel(34), VppMplsLabel(44), VppMplsLabel(45)]) self.assertEqual(route_11_0_0_2.get_stats_to()['packets'], 257) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(32), VppMplsLabel(33), VppMplsLabel(34), VppMplsLabel(44), VppMplsLabel(45)]) self.assertEqual(route_11_0_0_2.get_stats_to()['packets'], 514) # # cleanup # route_11_0_0_2.remove_vpp_config() route_11_0_0_1.remove_vpp_config() route_10_0_0_2.remove_vpp_config() route_10_0_0_1.remove_vpp_config() def test_imposition_fragmentation(self): """ MPLS label imposition fragmentation test """ # # Add a ipv4 non-recursive route with a single out label # route_10_0_0_1 = VppIpRoute(self, "10.0.0.1", 32, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(32)])]) route_10_0_0_1.add_vpp_config() # # a stream that matches the route for 10.0.0.1 # PG0 is in the default table # tx = self.create_stream_ip4(self.pg0, "10.0.0.1") for i in range(0, 257): self.extend_packet(tx[i], 10000) # # 5 fragments per packet (257*5=1285) # rx = self.send_and_expect(self.pg0, tx, self.pg0, 1285) self.verify_capture_fragmented_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(32)]) # # cleanup # route_10_0_0_1.remove_vpp_config() def test_tunnel_pipe(self): """ MPLS Tunnel Tests - Pipe """ # # Create a tunnel with two out labels # mpls_tun = VppMPLSTunnelInterface( self, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(44), VppMplsLabel(46)])]) mpls_tun.add_vpp_config() mpls_tun.admin_up() # # add an unlabelled route through the new tunnel # route_10_0_0_3 = VppIpRoute(self, "10.0.0.3", 32, [VppRoutePath("0.0.0.0", mpls_tun._sw_if_index)]) route_10_0_0_3.add_vpp_config() self.vapi.cli("clear trace") tx = self.create_stream_ip4(self.pg0, "10.0.0.3") self.pg0.add_stream(tx) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg0.get_capture() self.verify_capture_tunneled_ip4(self.pg0, rx, tx, [VppMplsLabel(44), VppMplsLabel(46)]) # # add a labelled route through the new tunnel # route_10_0_0_4 = VppIpRoute(self, "10.0.0.4", 32, [VppRoutePath("0.0.0.0", mpls_tun._sw_if_index, labels=[33])]) route_10_0_0_4.add_vpp_config() self.vapi.cli("clear trace") tx = self.create_stream_ip4(self.pg0, "10.0.0.4") self.pg0.add_stream(tx) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg0.get_capture() self.verify_capture_tunneled_ip4(self.pg0, rx, tx, [VppMplsLabel(44), VppMplsLabel(46), VppMplsLabel(33, ttl=255)]) # # change tunnel's MTU to a low value # mpls_tun.set_l3_mtu(1200) # send IP into the tunnel to be fragmented tx = self.create_stream_ip4(self.pg0, "10.0.0.3", payload_size=1500) rx = self.send_and_expect(self.pg0, tx, self.pg0, len(tx)*2) fake_tx = [] for p in tx: fake_tx.append(p) fake_tx.append(p) self.verify_capture_tunneled_ip4(self.pg0, rx, fake_tx, [VppMplsLabel(44), VppMplsLabel(46)]) # send MPLS into the tunnel to be fragmented tx = self.create_stream_ip4(self.pg0, "10.0.0.4", payload_size=1500) rx = self.send_and_expect(self.pg0, tx, self.pg0, len(tx)*2) fake_tx = [] for p in tx: fake_tx.append(p) fake_tx.append(p) self.verify_capture_tunneled_ip4(self.pg0, rx, fake_tx, [VppMplsLabel(44), VppMplsLabel(46), VppMplsLabel(33, ttl=255)]) def test_tunnel_uniform(self): """ MPLS Tunnel Tests - Uniform """ # # Create a tunnel with a single out label # The label stack is specified here from outer to inner # mpls_tun = VppMPLSTunnelInterface( self, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(44, ttl=32), VppMplsLabel(46, MplsLspMode.UNIFORM)])]) mpls_tun.add_vpp_config() mpls_tun.admin_up() # # add an unlabelled route through the new tunnel # route_10_0_0_3 = VppIpRoute(self, "10.0.0.3", 32, [VppRoutePath("0.0.0.0", mpls_tun._sw_if_index)]) route_10_0_0_3.add_vpp_config() self.vapi.cli("clear trace") tx = self.create_stream_ip4(self.pg0, "10.0.0.3", ip_ttl=24) self.pg0.add_stream(tx) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg0.get_capture() self.verify_capture_tunneled_ip4(self.pg0, rx, tx, [VppMplsLabel(44, ttl=32), VppMplsLabel(46, ttl=23)]) # # add a labelled route through the new tunnel # route_10_0_0_4 = VppIpRoute( self, "10.0.0.4", 32, [VppRoutePath("0.0.0.0", mpls_tun._sw_if_index, labels=[VppMplsLabel(33, ttl=47)])]) route_10_0_0_4.add_vpp_config() self.vapi.cli("clear trace") tx = self.create_stream_ip4(self.pg0, "10.0.0.4") self.pg0.add_stream(tx) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg0.get_capture() self.verify_capture_tunneled_ip4(self.pg0, rx, tx, [VppMplsLabel(44, ttl=32), VppMplsLabel(46, ttl=47), VppMplsLabel(33, ttl=47)]) def test_mpls_tunnel_many(self): """ MPLS Multiple Tunnels """ for ii in range(100): mpls_tun = VppMPLSTunnelInterface( self, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(44, ttl=32), VppMplsLabel(46, MplsLspMode.UNIFORM)])]) mpls_tun.add_vpp_config() mpls_tun.admin_up() for ii in range(100): mpls_tun = VppMPLSTunnelInterface( self, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(44, ttl=32), VppMplsLabel(46, MplsLspMode.UNIFORM)])], is_l2=1) mpls_tun.add_vpp_config() mpls_tun.admin_up() def test_v4_exp_null(self): """ MPLS V4 Explicit NULL test """ # # The first test case has an MPLS TTL of 0 # all packet should be dropped # tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(0, ttl=0)]) self.send_and_assert_no_replies(self.pg0, tx, "MPLS TTL=0 packets forwarded") # # a stream with a non-zero MPLS TTL # PG0 is in the default table # tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(0)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_ip4(self.pg0, rx, tx) # # a stream with a non-zero MPLS TTL # PG1 is in table 1 # we are ensuring the post-pop lookup occurs in the VRF table # tx = self.create_stream_labelled_ip4(self.pg1, [VppMplsLabel(0)]) rx = self.send_and_expect(self.pg1, tx, self.pg1) self.verify_capture_ip4(self.pg1, rx, tx) def test_v6_exp_null(self): """ MPLS V6 Explicit NULL test """ # # a stream with a non-zero MPLS TTL # PG0 is in the default table # tx = self.create_stream_labelled_ip6(self.pg0, [VppMplsLabel(2)]) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_ip6(self.pg0, rx, tx) # # a stream with a non-zero MPLS TTL # PG1 is in table 1 # we are ensuring the post-pop lookup occurs in the VRF table # tx = self.create_stream_labelled_ip6(self.pg1, [VppMplsLabel(2)]) rx = self.send_and_expect(self.pg1, tx, self.pg1) self.verify_capture_ip6(self.pg0, rx, tx) def test_deag(self): """ MPLS Deagg """ # # A de-agg route - next-hop lookup in default table # route_34_eos = VppMplsRoute(self, 34, 1, [VppRoutePath("0.0.0.0", 0xffffffff, nh_table_id=0)]) route_34_eos.add_vpp_config() # # ping an interface in the default table # PG0 is in the default table # tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(34)], ping=1, ip_itf=self.pg0) rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_ip4(self.pg0, rx, tx, ping_resp=1) # # A de-agg route - next-hop lookup in non-default table # route_35_eos = VppMplsRoute(self, 35, 1, [VppRoutePath("0.0.0.0", 0xffffffff, nh_table_id=1)]) route_35_eos.add_vpp_config() # # ping an interface in the non-default table # PG0 is in the default table. packet arrive labelled in the # default table and egress unlabelled in the non-default # tx = self.create_stream_labelled_ip4( self.pg0, [VppMplsLabel(35)], ping=1, ip_itf=self.pg1) rx = self.send_and_expect(self.pg0, tx, self.pg1) self.verify_capture_ip4(self.pg1, rx, tx, ping_resp=1) # # Double pop # route_36_neos = VppMplsRoute(self, 36, 0, [VppRoutePath("0.0.0.0", 0xffffffff)]) route_36_neos.add_vpp_config() tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(36), VppMplsLabel(35)], ping=1, ip_itf=self.pg1) rx = self.send_and_expect(self.pg0, tx, self.pg1) self.verify_capture_ip4(self.pg1, rx, tx, ping_resp=1) route_36_neos.remove_vpp_config() route_35_eos.remove_vpp_config() route_34_eos.remove_vpp_config() def test_interface_rx(self): """ MPLS Interface Receive """ # # Add a non-recursive route that will forward the traffic # post-interface-rx # route_10_0_0_1 = VppIpRoute(self, "10.0.0.1", 32, table_id=1, paths=[VppRoutePath(self.pg1.remote_ip4, self.pg1.sw_if_index)]) route_10_0_0_1.add_vpp_config() # # An interface receive label that maps traffic to RX on interface # pg1 # by injecting the packet in on pg0, which is in table 0 # doing an interface-rx on pg1 and matching a route in table 1 # if the packet egresses, then we must have swapped to pg1 # so as to have matched the route in table 1 # route_34_eos = VppMplsRoute( self, 34, 1, [VppRoutePath("0.0.0.0", self.pg1.sw_if_index, type=FibPathType.FIB_PATH_TYPE_INTERFACE_RX)]) route_34_eos.add_vpp_config() # # ping an interface in the default table # PG0 is in the default table # tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(34)], dst_ip="10.0.0.1") rx = self.send_and_expect(self.pg0, tx, self.pg1) self.verify_capture_ip4(self.pg1, rx, tx) def test_mcast_mid_point(self): """ MPLS Multicast Mid Point """ # # Add a non-recursive route that will forward the traffic # post-interface-rx # route_10_0_0_1 = VppIpRoute(self, "10.0.0.1", 32, table_id=1, paths=[VppRoutePath(self.pg1.remote_ip4, self.pg1.sw_if_index)]) route_10_0_0_1.add_vpp_config() # # Add a mcast entry that replicate to pg2 and pg3 # and replicate to a interface-rx (like a bud node would) # route_3400_eos = VppMplsRoute( self, 3400, 1, [VppRoutePath(self.pg2.remote_ip4, self.pg2.sw_if_index, labels=[VppMplsLabel(3401)]), VppRoutePath(self.pg3.remote_ip4, self.pg3.sw_if_index, labels=[VppMplsLabel(3402)]), VppRoutePath("0.0.0.0", self.pg1.sw_if_index, type=FibPathType.FIB_PATH_TYPE_INTERFACE_RX)], is_multicast=1) route_3400_eos.add_vpp_config() # # ping an interface in the default table # PG0 is in the default table # self.vapi.cli("clear trace") tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(3400, ttl=64)], n=257, dst_ip="10.0.0.1") self.pg0.add_stream(tx) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg1.get_capture(257) self.verify_capture_ip4(self.pg1, rx, tx) rx = self.pg2.get_capture(257) self.verify_capture_labelled(self.pg2, rx, tx, [VppMplsLabel(3401, ttl=63)]) rx = self.pg3.get_capture(257) self.verify_capture_labelled(self.pg3, rx, tx, [VppMplsLabel(3402, ttl=63)]) def test_mcast_head(self): """ MPLS Multicast Head-end """ MRouteItfFlags = VppEnum.vl_api_mfib_itf_flags_t MRouteEntryFlags = VppEnum.vl_api_mfib_entry_flags_t # # Create a multicast tunnel with two replications # mpls_tun = VppMPLSTunnelInterface( self, [VppRoutePath(self.pg2.remote_ip4, self.pg2.sw_if_index, labels=[VppMplsLabel(42)]), VppRoutePath(self.pg3.remote_ip4, self.pg3.sw_if_index, labels=[VppMplsLabel(43)])], is_multicast=1) mpls_tun.add_vpp_config() mpls_tun.admin_up() # # add an unlabelled route through the new tunnel # route_10_0_0_3 = VppIpRoute(self, "10.0.0.3", 32, [VppRoutePath("0.0.0.0", mpls_tun._sw_if_index)]) route_10_0_0_3.add_vpp_config() self.vapi.cli("clear trace") tx = self.create_stream_ip4(self.pg0, "10.0.0.3") self.pg0.add_stream(tx) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg2.get_capture(257) self.verify_capture_tunneled_ip4(self.pg0, rx, tx, [VppMplsLabel(42)]) rx = self.pg3.get_capture(257) self.verify_capture_tunneled_ip4(self.pg0, rx, tx, [VppMplsLabel(43)]) # # An an IP multicast route via the tunnel # A (*,G). # one accepting interface, pg0, 1 forwarding interface via the tunnel # route_232_1_1_1 = VppIpMRoute( self, "0.0.0.0", "232.1.1.1", 32, MRouteEntryFlags.MFIB_API_ENTRY_FLAG_NONE, [VppMRoutePath(self.pg0.sw_if_index, MRouteItfFlags.MFIB_API_ITF_FLAG_ACCEPT), VppMRoutePath(mpls_tun._sw_if_index, MRouteItfFlags.MFIB_API_ITF_FLAG_FORWARD)]) route_232_1_1_1.add_vpp_config() self.logger.info(self.vapi.cli("sh ip mfib index 0")) self.vapi.cli("clear trace") tx = self.create_stream_ip4(self.pg0, "232.1.1.1") self.pg0.add_stream(tx) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg2.get_capture(257) self.verify_capture_tunneled_ip4(self.pg0, rx, tx, [VppMplsLabel(42)]) rx = self.pg3.get_capture(257) self.verify_capture_tunneled_ip4(self.pg0, rx, tx, [VppMplsLabel(43)]) def test_mcast_ip4_tail(self): """ MPLS IPv4 Multicast Tail """ MRouteItfFlags = VppEnum.vl_api_mfib_itf_flags_t MRouteEntryFlags = VppEnum.vl_api_mfib_entry_flags_t # # Add a multicast route that will forward the traffic # post-disposition # route_232_1_1_1 = VppIpMRoute( self, "0.0.0.0", "232.1.1.1", 32, MRouteEntryFlags.MFIB_API_ENTRY_FLAG_NONE, table_id=1, paths=[VppMRoutePath(self.pg1.sw_if_index, MRouteItfFlags.MFIB_API_ITF_FLAG_FORWARD)]) route_232_1_1_1.add_vpp_config() # # An interface receive label that maps traffic to RX on interface # pg1 # by injecting the packet in on pg0, which is in table 0 # doing an rpf-id and matching a route in table 1 # if the packet egresses, then we must have matched the route in # table 1 # route_34_eos = VppMplsRoute( self, 34, 1, [VppRoutePath("0.0.0.0", 0xffffffff, nh_table_id=1, rpf_id=55)], is_multicast=1, eos_proto=FibPathProto.FIB_PATH_NH_PROTO_IP4) route_34_eos.add_vpp_config() # # Drop due to interface lookup miss # self.vapi.cli("clear trace") tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(34)], dst_ip="232.1.1.1", n=1) self.send_and_assert_no_replies(self.pg0, tx, "RPF-ID drop none") # # set the RPF-ID of the entry to match the input packet's # route_232_1_1_1.update_rpf_id(55) self.logger.info(self.vapi.cli("sh ip mfib index 1 232.1.1.1")) tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(34)], dst_ip="232.1.1.1") rx = self.send_and_expect(self.pg0, tx, self.pg1) self.verify_capture_ip4(self.pg1, rx, tx) # # disposed packets have an invalid IPv4 checksum # tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(34)], dst_ip="232.1.1.1", n=65, chksum=1) self.send_and_assert_no_replies(self.pg0, tx, "Invalid Checksum") # # set the RPF-ID of the entry to not match the input packet's # route_232_1_1_1.update_rpf_id(56) tx = self.create_stream_labelled_ip4(self.pg0, [VppMplsLabel(34)], dst_ip="232.1.1.1") self.send_and_assert_no_replies(self.pg0, tx, "RPF-ID drop 56") def test_mcast_ip6_tail(self): """ MPLS IPv6 Multicast Tail """ MRouteItfFlags = VppEnum.vl_api_mfib_itf_flags_t MRouteEntryFlags = VppEnum.vl_api_mfib_entry_flags_t # # Add a multicast route that will forward the traffic # post-disposition # route_ff = VppIpMRoute( self, "::", "ff01::1", 32, MRouteEntryFlags.MFIB_API_ENTRY_FLAG_NONE, table_id=1, paths=[VppMRoutePath(self.pg1.sw_if_index, MRouteItfFlags.MFIB_API_ITF_FLAG_FORWARD, proto=FibPathProto.FIB_PATH_NH_PROTO_IP6)]) route_ff.add_vpp_config() # # An interface receive label that maps traffic to RX on interface # pg1 # by injecting the packet in on pg0, which is in table 0 # doing an rpf-id and matching a route in table 1 # if the packet egresses, then we must have matched the route in # table 1 # route_34_eos = VppMplsRoute( self, 34, 1, [VppRoutePath("::", 0xffffffff, nh_table_id=1, rpf_id=55)], is_multicast=1, eos_proto=FibPathProto.FIB_PATH_NH_PROTO_IP6) route_34_eos.add_vpp_config() # # Drop due to interface lookup miss # tx = self.create_stream_labelled_ip6(self.pg0, [VppMplsLabel(34)], dst_ip="ff01::1") self.send_and_assert_no_replies(self.pg0, tx, "RPF Miss") # # set the RPF-ID of the entry to match the input packet's # route_ff.update_rpf_id(55) tx = self.create_stream_labelled_ip6(self.pg0, [VppMplsLabel(34)], dst_ip="ff01::1") rx = self.send_and_expect(self.pg0, tx, self.pg1) self.verify_capture_ip6(self.pg1, rx, tx) # # disposed packets have hop-limit = 1 # tx = self.create_stream_labelled_ip6(self.pg0, [VppMplsLabel(34)], dst_ip="ff01::1", hlim=1) rx = self.send_and_expect_some(self.pg0, tx, self.pg0) self.verify_capture_ip6_icmp(self.pg0, rx, tx) # # set the RPF-ID of the entry to not match the input packet's # route_ff.update_rpf_id(56) tx = self.create_stream_labelled_ip6(self.pg0, [VppMplsLabel(34)], dst_ip="ff01::1") self.send_and_assert_no_replies(self.pg0, tx, "RPF-ID drop 56") def test_6pe(self): """ MPLS 6PE """ # # Add a non-recursive route with a single out label # route_10_0_0_1 = VppIpRoute(self, "10.0.0.1", 32, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(45)])]) route_10_0_0_1.add_vpp_config() # bind a local label to the route binding = VppMplsIpBind(self, 44, "10.0.0.1", 32) binding.add_vpp_config() # # a labelled v6 route that resolves through the v4 # route_2001_3 = VppIpRoute( self, "2001::3", 128, [VppRoutePath("10.0.0.1", INVALID_INDEX, labels=[VppMplsLabel(32)])]) route_2001_3.add_vpp_config() tx = self.create_stream_ip6(self.pg0, "2001::3") rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip6(self.pg0, rx, tx, [VppMplsLabel(45), VppMplsLabel(32)]) # # and a v4 recursive via the v6 # route_20_3 = VppIpRoute( self, "20.0.0.3", 32, [VppRoutePath("2001::3", INVALID_INDEX, labels=[VppMplsLabel(99)])]) route_20_3.add_vpp_config() tx = self.create_stream_ip4(self.pg0, "20.0.0.3") rx = self.send_and_expect(self.pg0, tx, self.pg0) self.verify_capture_labelled_ip4(self.pg0, rx, tx, [VppMplsLabel(45), VppMplsLabel(32), VppMplsLabel(99)]) def test_attached(self): """ Attach Routes with Local Label """ # # test that if a local label is associated with an attached/connected # prefix, that we can reach hosts in the prefix. # binding = VppMplsIpBind(self, 44, self.pg0._local_ip4_subnet, self.pg0.local_ip4_prefix_len) binding.add_vpp_config() tx = (Ether(src=self.pg1.remote_mac, dst=self.pg1.local_mac) / MPLS(label=44, ttl=64) / IP(src=self.pg0.remote_ip4, dst=self.pg0.remote_ip4) / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) rxs = self.send_and_expect(self.pg0, [tx], self.pg0) for rx in rxs: # if there's an ARP then the label is linked to the glean # which is wrong. self.assertFalse(rx.haslayer(ARP)) # it should be unicasted to the host self.assertEqual(rx[Ether].dst, self.pg0.remote_mac) self.assertEqual(rx[IP].dst, self.pg0.remote_ip4) class TestMPLSDisabled(VppTestCase): """ MPLS disabled """ @classmethod def setUpClass(cls): super(TestMPLSDisabled, cls).setUpClass() @classmethod def tearDownClass(cls): super(TestMPLSDisabled, cls).tearDownClass() def setUp(self): super(TestMPLSDisabled, self).setUp() # create 2 pg interfaces self.create_pg_interfaces(range(2)) self.tbl = VppMplsTable(self, 0) self.tbl.add_vpp_config() # PG0 is MPLS enabled self.pg0.admin_up() self.pg0.config_ip4() self.pg0.resolve_arp() self.pg0.enable_mpls() # PG 1 is not MPLS enabled self.pg1.admin_up() def tearDown(self): for i in self.pg_interfaces: i.unconfig_ip4() i.admin_down() self.pg0.disable_mpls() super(TestMPLSDisabled, self).tearDown() def test_mpls_disabled(self): """ MPLS Disabled """ self.logger.info(self.vapi.cli("show mpls interface")) self.logger.info(self.vapi.cli("show mpls interface pg1")) self.logger.info(self.vapi.cli("show mpls interface pg0")) tx = (Ether(src=self.pg1.remote_mac, dst=self.pg1.local_mac) / MPLS(label=32, ttl=64) / IPv6(src="2001::1", dst=self.pg0.remote_ip6) / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) # # A simple MPLS xconnect - eos label in label out # route_32_eos = VppMplsRoute(self, 32, 1, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[33])]) route_32_eos.add_vpp_config() # # PG1 does not forward IP traffic # self.send_and_assert_no_replies(self.pg1, tx, "MPLS disabled") # # MPLS enable PG1 # self.pg1.enable_mpls() self.logger.info(self.vapi.cli("show mpls interface")) self.logger.info(self.vapi.cli("show mpls interface pg1")) # # Now we get packets through # self.pg1.add_stream(tx) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg0.get_capture(1) # # Disable PG1 # self.pg1.disable_mpls() # # PG1 does not forward IP traffic # self.send_and_assert_no_replies(self.pg1, tx, "IPv6 disabled") self.send_and_assert_no_replies(self.pg1, tx, "IPv6 disabled") class TestMPLSPIC(VppTestCase): """ MPLS Prefix-Independent Convergence (PIC) edge convergence """ @classmethod def setUpClass(cls): super(TestMPLSPIC, cls).setUpClass() @classmethod def tearDownClass(cls): super(TestMPLSPIC, cls).tearDownClass() def setUp(self): super(TestMPLSPIC, self).setUp() # create 2 pg interfaces self.create_pg_interfaces(range(4)) mpls_tbl = VppMplsTable(self, 0) mpls_tbl.add_vpp_config() tbl4 = VppIpTable(self, 1) tbl4.add_vpp_config() tbl6 = VppIpTable(self, 1, is_ip6=1) tbl6.add_vpp_config() # core links self.pg0.admin_up() self.pg0.config_ip4() self.pg0.resolve_arp() self.pg0.enable_mpls() self.pg1.admin_up() self.pg1.config_ip4() self.pg1.resolve_arp() self.pg1.enable_mpls() # VRF (customer facing) link self.pg2.admin_up() self.pg2.set_table_ip4(1) self.pg2.config_ip4() self.pg2.resolve_arp() self.pg2.set_table_ip6(1) self.pg2.config_ip6() self.pg2.resolve_ndp() self.pg3.admin_up() self.pg3.set_table_ip4(1) self.pg3.config_ip4() self.pg3.resolve_arp() self.pg3.set_table_ip6(1) self.pg3.config_ip6() self.pg3.resolve_ndp() def tearDown(self): self.pg0.disable_mpls() self.pg1.disable_mpls() for i in self.pg_interfaces: i.unconfig_ip4() i.unconfig_ip6() i.set_table_ip4(0) i.set_table_ip6(0) i.admin_down() super(TestMPLSPIC, self).tearDown() def test_mpls_ibgp_pic(self): """ MPLS iBGP Prefix-Independent Convergence (PIC) edge convergence 1) setup many iBGP VPN routes via a pair of iBGP peers. 2) Check EMCP forwarding to these peers 3) withdraw the IGP route to one of these peers. 4) check forwarding continues to the remaining peer """ # # IGP+LDP core routes # core_10_0_0_45 = VppIpRoute(self, "10.0.0.45", 32, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[45])]) core_10_0_0_45.add_vpp_config() core_10_0_0_46 = VppIpRoute(self, "10.0.0.46", 32, [VppRoutePath(self.pg1.remote_ip4, self.pg1.sw_if_index, labels=[46])]) core_10_0_0_46.add_vpp_config() # # Lot's of VPN routes. We need more the 64 so VPP will build # the fast convergence indirection # vpn_routes = [] pkts = [] for ii in range(NUM_PKTS): dst = "192.168.1.%d" % ii vpn_routes.append(VppIpRoute( self, dst, 32, [VppRoutePath( "10.0.0.45", 0xffffffff, labels=[145], flags=FibPathFlags.FIB_PATH_FLAG_RESOLVE_VIA_HOST), VppRoutePath( "10.0.0.46", 0xffffffff, labels=[146], flags=FibPathFlags.FIB_PATH_FLAG_RESOLVE_VIA_HOST)], table_id=1)) vpn_routes[ii].add_vpp_config() pkts.append(Ether(dst=self.pg2.local_mac, src=self.pg2.remote_mac) / IP(src=self.pg2.remote_ip4, dst=dst) / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) # # Send the packet stream (one pkt to each VPN route) # - expect a 50-50 split of the traffic # self.pg2.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg0._get_capture(NUM_PKTS) rx1 = self.pg1._get_capture(NUM_PKTS) # not testing the LB hashing algorithm so we're not concerned # with the split ratio, just as long as neither is 0 self.assertNotEqual(0, len(rx0)) self.assertNotEqual(0, len(rx1)) self.assertEqual(len(pkts), len(rx0) + len(rx1), "Expected all (%s) packets across both ECMP paths. " "rx0: %s rx1: %s." % (len(pkts), len(rx0), len(rx1))) # # use a test CLI command to stop the FIB walk process, this # will prevent the FIB converging the VPN routes and thus allow # us to probe the interim (post-fail, pre-converge) state # self.vapi.ppcli("test fib-walk-process disable") # # Withdraw one of the IGP routes # core_10_0_0_46.remove_vpp_config() # # now all packets should be forwarded through the remaining peer # self.vapi.ppcli("clear trace") self.pg2.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg0.get_capture(NUM_PKTS) self.assertEqual(len(pkts), len(rx0), "Expected all (%s) packets across single path. " "rx0: %s." % (len(pkts), len(rx0))) # # enable the FIB walk process to converge the FIB # self.vapi.ppcli("test fib-walk-process enable") # # packets should still be forwarded through the remaining peer # self.pg2.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg0.get_capture(NUM_PKTS) self.assertEqual(len(pkts), len(rx0), "Expected all (%s) packets across single path. " "rx0: %s." % (len(pkts), len(rx0))) # # Add the IGP route back and we return to load-balancing # core_10_0_0_46.add_vpp_config() self.pg2.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg0._get_capture(NUM_PKTS) rx1 = self.pg1._get_capture(NUM_PKTS) self.assertNotEqual(0, len(rx0)) self.assertNotEqual(0, len(rx1)) self.assertEqual(len(pkts), len(rx0) + len(rx1), "Expected all (%s) packets across both ECMP paths. " "rx0: %s rx1: %s." % (len(pkts), len(rx0), len(rx1))) def test_mpls_ebgp_pic(self): """ MPLS eBGP Prefix-Independent Convergence (PIC) edge convergence 1) setup many eBGP VPN routes via a pair of eBGP peers. 2) Check EMCP forwarding to these peers 3) withdraw one eBGP path - expect LB across remaining eBGP """ # # Lot's of VPN routes. We need more the 64 so VPP will build # the fast convergence indirection # vpn_routes = [] vpn_bindings = [] pkts = [] for ii in range(NUM_PKTS): dst = "192.168.1.%d" % ii local_label = 1600 + ii vpn_routes.append(VppIpRoute( self, dst, 32, [VppRoutePath( self.pg2.remote_ip4, 0xffffffff, nh_table_id=1, flags=FibPathFlags.FIB_PATH_FLAG_RESOLVE_VIA_ATTACHED), VppRoutePath( self.pg3.remote_ip4, 0xffffffff, nh_table_id=1, flags=FibPathFlags.FIB_PATH_FLAG_RESOLVE_VIA_ATTACHED)], table_id=1)) vpn_routes[ii].add_vpp_config() vpn_bindings.append(VppMplsIpBind(self, local_label, dst, 32, ip_table_id=1)) vpn_bindings[ii].add_vpp_config() pkts.append(Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / MPLS(label=local_label, ttl=64) / IP(src=self.pg0.remote_ip4, dst=dst) / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) # # Send the packet stream (one pkt to each VPN route) # - expect a 50-50 split of the traffic # self.pg0.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg2._get_capture(NUM_PKTS) rx1 = self.pg3._get_capture(NUM_PKTS) # not testing the LB hashing algorithm so we're not concerned # with the split ratio, just as long as neither is 0 self.assertNotEqual(0, len(rx0)) self.assertNotEqual(0, len(rx1)) self.assertEqual(len(pkts), len(rx0) + len(rx1), "Expected all (%s) packets across both ECMP paths. " "rx0: %s rx1: %s." % (len(pkts), len(rx0), len(rx1))) # # use a test CLI command to stop the FIB walk process, this # will prevent the FIB converging the VPN routes and thus allow # us to probe the interim (post-fail, pre-converge) state # self.vapi.ppcli("test fib-walk-process disable") # # withdraw the connected prefix on the interface. # self.pg2.unconfig_ip4() # # now all packets should be forwarded through the remaining peer # self.pg0.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg3.get_capture(NUM_PKTS) self.assertEqual(len(pkts), len(rx0), "Expected all (%s) packets across single path. " "rx0: %s." % (len(pkts), len(rx0))) # # enable the FIB walk process to converge the FIB # self.vapi.ppcli("test fib-walk-process enable") # # packets should still be forwarded through the remaining peer # self.pg0.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg3.get_capture(NUM_PKTS) self.assertEqual(len(pkts), len(rx0), "Expected all (%s) packets across single path. " "rx0: %s." % (len(pkts), len(rx0))) # # put the connected routes back # self.pg2.config_ip4() self.pg2.resolve_arp() self.pg0.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg2._get_capture(NUM_PKTS) rx1 = self.pg3._get_capture(NUM_PKTS) self.assertNotEqual(0, len(rx0)) self.assertNotEqual(0, len(rx1)) self.assertEqual(len(pkts), len(rx0) + len(rx1), "Expected all (%s) packets across both ECMP paths. " "rx0: %s rx1: %s." % (len(pkts), len(rx0), len(rx1))) def test_mpls_v6_ebgp_pic(self): """ MPLSv6 eBGP Prefix-Independent Convergence (PIC) edge convergence 1) setup many eBGP VPNv6 routes via a pair of eBGP peers 2) Check EMCP forwarding to these peers 3) withdraw one eBGP path - expect LB across remaining eBGP """ # # Lot's of VPN routes. We need more the 64 so VPP will build # the fast convergence indirection # vpn_routes = [] vpn_bindings = [] pkts = [] for ii in range(NUM_PKTS): dst = "3000::%d" % ii local_label = 1600 + ii vpn_routes.append(VppIpRoute( self, dst, 128, [VppRoutePath( self.pg2.remote_ip6, 0xffffffff, nh_table_id=1, flags=FibPathFlags.FIB_PATH_FLAG_RESOLVE_VIA_ATTACHED), VppRoutePath( self.pg3.remote_ip6, 0xffffffff, nh_table_id=1, flags=FibPathFlags.FIB_PATH_FLAG_RESOLVE_VIA_ATTACHED)], table_id=1)) vpn_routes[ii].add_vpp_config() vpn_bindings.append(VppMplsIpBind(self, local_label, dst, 128, ip_table_id=1)) vpn_bindings[ii].add_vpp_config() pkts.append(Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / MPLS(label=local_label, ttl=64) / IPv6(src=self.pg0.remote_ip6, dst=dst) / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) self.logger.info(self.vapi.cli("sh ip6 fib %s" % dst)) self.pg0.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg2._get_capture(NUM_PKTS) rx1 = self.pg3._get_capture(NUM_PKTS) self.assertNotEqual(0, len(rx0)) self.assertNotEqual(0, len(rx1)) self.assertEqual(len(pkts), len(rx0) + len(rx1), "Expected all (%s) packets across both ECMP paths. " "rx0: %s rx1: %s." % (len(pkts), len(rx0), len(rx1))) # # use a test CLI command to stop the FIB walk process, this # will prevent the FIB converging the VPN routes and thus allow # us to probe the interim (post-fail, pre-converge) state # self.vapi.ppcli("test fib-walk-process disable") # # withdraw the connected prefix on the interface. # and shutdown the interface so the ND cache is flushed. # self.pg2.unconfig_ip6() self.pg2.admin_down() # # now all packets should be forwarded through the remaining peer # self.pg0.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg3.get_capture(NUM_PKTS) self.assertEqual(len(pkts), len(rx0), "Expected all (%s) packets across single path. " "rx0: %s." % (len(pkts), len(rx0))) # # enable the FIB walk process to converge the FIB # self.vapi.ppcli("test fib-walk-process enable") self.pg0.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg3.get_capture(NUM_PKTS) self.assertEqual(len(pkts), len(rx0), "Expected all (%s) packets across single path. " "rx0: %s." % (len(pkts), len(rx0))) # # put the connected routes back # self.logger.info(self.vapi.cli("sh log")) self.pg2.admin_up() self.pg2.config_ip6() self.pg2.resolve_ndp() self.pg0.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx0 = self.pg2._get_capture(NUM_PKTS) rx1 = self.pg3._get_capture(NUM_PKTS) self.assertNotEqual(0, len(rx0)) self.assertNotEqual(0, len(rx1)) self.assertEqual(len(pkts), len(rx0) + len(rx1), "Expected all (%s) packets across both ECMP paths. " "rx0: %s rx1: %s." % (len(pkts), len(rx0), len(rx1))) class TestMPLSL2(VppTestCase): """ MPLS-L2 """ @classmethod def setUpClass(cls): super(TestMPLSL2, cls).setUpClass() @classmethod def tearDownClass(cls): super(TestMPLSL2, cls).tearDownClass() def setUp(self): super(TestMPLSL2, self).setUp() # create 2 pg interfaces self.create_pg_interfaces(range(2)) # create the default MPLS table self.tables = [] tbl = VppMplsTable(self, 0) tbl.add_vpp_config() self.tables.append(tbl) # use pg0 as the core facing interface, don't resolve ARP self.pg0.admin_up() self.pg0.config_ip4() self.pg0.enable_mpls() # use the other 2 for customer facing L2 links for i in self.pg_interfaces[1:]: i.admin_up() def tearDown(self): for i in self.pg_interfaces[1:]: i.admin_down() self.pg0.disable_mpls() self.pg0.unconfig_ip4() self.pg0.admin_down() super(TestMPLSL2, self).tearDown() def verify_capture_tunneled_ethernet(self, capture, sent, mpls_labels): capture = verify_filter(capture, sent) self.assertEqual(len(capture), len(sent)) for i in range(len(capture)): tx = sent[i] rx = capture[i] # the MPLS TTL is 255 since it enters a new tunnel verify_mpls_stack(self, rx, mpls_labels) tx_eth = tx[Ether] rx_eth = Ether(scapy.compat.raw(rx[MPLS].payload)) self.assertEqual(rx_eth.src, tx_eth.src) self.assertEqual(rx_eth.dst, tx_eth.dst) def verify_arp_req(self, rx, smac, sip, dip): ether = rx[Ether] self.assertEqual(ether.dst, "ff:ff:ff:ff:ff:ff") self.assertEqual(ether.src, smac) arp = rx[ARP] self.assertEqual(arp.hwtype, 1) self.assertEqual(arp.ptype, 0x800) self.assertEqual(arp.hwlen, 6) self.assertEqual(arp.plen, 4) self.assertEqual(arp.op, ARP.who_has) self.assertEqual(arp.hwsrc, smac) self.assertEqual(arp.hwdst, "00:00:00:00:00:00") self.assertEqual(arp.psrc, sip) self.assertEqual(arp.pdst, dip) def test_vpws(self): """ Virtual Private Wire Service """ # # Create an MPLS tunnel that pushes 1 label # For Ethernet over MPLS the uniform mode is irrelevant since ttl/cos # information is not in the packet, but we test it works anyway # mpls_tun_1 = VppMPLSTunnelInterface( self, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(42, MplsLspMode.UNIFORM)])], is_l2=1) mpls_tun_1.add_vpp_config() mpls_tun_1.admin_up() # # Create a label entry to for 55 that does L2 input to the tunnel # route_55_eos = VppMplsRoute( self, 55, 1, [VppRoutePath("0.0.0.0", mpls_tun_1.sw_if_index, type=FibPathType.FIB_PATH_TYPE_INTERFACE_RX, proto=FibPathProto.FIB_PATH_NH_PROTO_ETHERNET)], eos_proto=FibPathProto.FIB_PATH_NH_PROTO_ETHERNET) route_55_eos.add_vpp_config() # # Cross-connect the tunnel with one of the customers L2 interfaces # self.vapi.sw_interface_set_l2_xconnect(self.pg1.sw_if_index, mpls_tun_1.sw_if_index, enable=1) self.vapi.sw_interface_set_l2_xconnect(mpls_tun_1.sw_if_index, self.pg1.sw_if_index, enable=1) # # inject a packet from the core # pcore = (Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / MPLS(label=55, ttl=64) / Ether(dst="00:00:de:ad:ba:be", src="00:00:de:ad:be:ef") / IP(src="10.10.10.10", dst="11.11.11.11") / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) tx0 = pcore * NUM_PKTS rx0 = self.send_and_expect(self.pg0, tx0, self.pg1) payload = pcore[MPLS].payload self.assertEqual(rx0[0][Ether].dst, payload[Ether].dst) self.assertEqual(rx0[0][Ether].src, payload[Ether].src) # # Inject a packet from the customer/L2 side # there's no resolved ARP entry so the first packet we see should be # an ARP request # tx1 = pcore[MPLS].payload rx1 = self.send_and_expect(self.pg1, [tx1], self.pg0) self.verify_arp_req(rx1[0], self.pg0.local_mac, self.pg0.local_ip4, self.pg0.remote_ip4) # # resolve the ARP entries and send again # self.pg0.resolve_arp() tx1 = pcore[MPLS].payload * NUM_PKTS rx1 = self.send_and_expect(self.pg1, tx1, self.pg0) self.verify_capture_tunneled_ethernet(rx1, tx1, [VppMplsLabel(42)]) def test_vpls(self): """ Virtual Private LAN Service """ # we skipped this in the setup self.pg0.resolve_arp() # # Create a L2 MPLS tunnels # mpls_tun1 = VppMPLSTunnelInterface( self, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(42)])], is_l2=1) mpls_tun1.add_vpp_config() mpls_tun1.admin_up() mpls_tun2 = VppMPLSTunnelInterface( self, [VppRoutePath(self.pg0.remote_ip4, self.pg0.sw_if_index, labels=[VppMplsLabel(43)])], is_l2=1) mpls_tun2.add_vpp_config() mpls_tun2.admin_up() # # Create a label entries, 55 and 56, that do L2 input to the tunnel # the latter includes a Psuedo Wire Control Word # route_55_eos = VppMplsRoute( self, 55, 1, [VppRoutePath("0.0.0.0", mpls_tun1.sw_if_index, type=FibPathType.FIB_PATH_TYPE_INTERFACE_RX, proto=FibPathProto.FIB_PATH_NH_PROTO_ETHERNET)], eos_proto=FibPathProto.FIB_PATH_NH_PROTO_ETHERNET) route_56_eos = VppMplsRoute( self, 56, 1, [VppRoutePath("0.0.0.0", mpls_tun2.sw_if_index, type=FibPathType.FIB_PATH_TYPE_INTERFACE_RX, flags=FibPathFlags.FIB_PATH_FLAG_POP_PW_CW, proto=FibPathProto.FIB_PATH_NH_PROTO_ETHERNET)], eos_proto=FibPathProto.FIB_PATH_NH_PROTO_ETHERNET) # move me route_56_eos.add_vpp_config() route_55_eos.add_vpp_config() self.logger.info(self.vapi.cli("sh mpls fib 56")) # # add to tunnel to the customers bridge-domain # self.vapi.sw_interface_set_l2_bridge( rx_sw_if_index=mpls_tun1.sw_if_index, bd_id=1) self.vapi.sw_interface_set_l2_bridge( rx_sw_if_index=mpls_tun2.sw_if_index, bd_id=1) self.vapi.sw_interface_set_l2_bridge( rx_sw_if_index=self.pg1.sw_if_index, bd_id=1) # # Packet from host on the customer interface to each host # reachable over the core, and vice-versa # p_cust1 = (Ether(dst="00:00:de:ad:ba:b1", src="00:00:de:ad:be:ef") / IP(src="10.10.10.10", dst="11.11.11.11") / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) p_cust2 = (Ether(dst="00:00:de:ad:ba:b2", src="00:00:de:ad:be:ef") / IP(src="10.10.10.10", dst="11.11.11.12") / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) p_core1 = (Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / MPLS(label=55, ttl=64) / Ether(src="00:00:de:ad:ba:b1", dst="00:00:de:ad:be:ef") / IP(dst="10.10.10.10", src="11.11.11.11") / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) p_core2 = (Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / MPLS(label=56, ttl=64) / Raw(b'\x01' * 4) / # PW CW Ether(src="00:00:de:ad:ba:b2", dst="00:00:de:ad:be:ef") / IP(dst="10.10.10.10", src="11.11.11.12") / UDP(sport=1234, dport=1234) / Raw(b'\xa5' * 100)) # # The BD is learning, so send in one of each packet to learn # # 2 packets due to BD flooding rx = self.send_and_expect(self.pg1, p_cust1, self.pg0, n_rx=2) rx = self.send_and_expect(self.pg1, p_cust2, self.pg0, n_rx=2) # we've learnt this so expect it be be forwarded not flooded rx = self.send_and_expect(self.pg0, [p_core1], self.pg1) self.assertEqual(rx[0][Ether].dst, p_cust1[Ether].src) self.assertEqual(rx[0][Ether].src, p_cust1[Ether].dst) rx = self.send_and_expect(self.pg0, [p_core2], self.pg1) self.assertEqual(rx[0][Ether].dst, p_cust2[Ether].src) self.assertEqual(rx[0][Ether].src, p_cust2[Ether].dst) # # now a stream in each direction from each host # rx = self.send_and_expect(self.pg1, p_cust1 * NUM_PKTS, self.pg0) self.verify_capture_tunneled_ethernet(rx, p_cust1 * NUM_PKTS, [VppMplsLabel(42)]) rx = self.send_and_expect(self.pg1, p_cust2 * NUM_PKTS, self.pg0) self.verify_capture_tunneled_ethernet(rx, p_cust2 * NUM_PKTS, [VppMplsLabel(43)]) rx = self.send_and_expect(self.pg0, p_core1 * NUM_PKTS, self.pg1) rx = self.send_and_expect(self.pg0, p_core2 * NUM_PKTS, self.pg1) # # remove interfaces from customers bridge-domain # self.vapi.sw_interface_set_l2_bridge( rx_sw_if_index=mpls_tun1.sw_if_index, bd_id=1, enable=0) self.vapi.sw_interface_set_l2_bridge( rx_sw_if_index=mpls_tun2.sw_if_index, bd_id=1, enable=0) self.vapi.sw_interface_set_l2_bridge( rx_sw_if_index=self.pg1.sw_if_index, bd_id=1, enable=0) if __name__ == '__main__': unittest.main(testRunner=VppTestRunner)