#!/usr/bin/env python3 import unittest from config import config from framework import VppTestCase, VppTestRunner from vpp_ip import DpoProto from vpp_ip_route import VppIpRoute, VppRoutePath, \ VppMplsTable, VppIpMRoute, VppMRoutePath, VppIpTable, \ MPLS_LABEL_INVALID, \ VppMplsLabel, FibPathProto, FibPathType from vpp_bier import BIER_HDR_PAYLOAD, VppBierImp, VppBierDispEntry, \ VppBierDispTable, VppBierTable, VppBierTableID, VppBierRoute from vpp_udp_encap import VppUdpEncap from vpp_papi import VppEnum import scapy.compat from scapy.packet import Raw from scapy.layers.l2 import Ether from scapy.layers.inet import IP, UDP from scapy.layers.inet6 import IPv6 from scapy.contrib.mpls import MPLS from scapy.contrib.bier import BIER, BIERLength, BIFT NUM_PKTS = 67 class TestBFIB(VppTestCase): """ BIER FIB Test Case """ def test_bfib(self): """ BFIB Unit Tests """ error = self.vapi.cli("test bier") if error: self.logger.critical(error) self.assertNotIn("Failed", error) class TestBier(VppTestCase): """ BIER Test Case """ def setUp(self): super(TestBier, self).setUp() # create 2 pg interfaces self.create_pg_interfaces(range(3)) # create the default MPLS table self.tables = [] tbl = VppMplsTable(self, 0) tbl.add_vpp_config() self.tables.append(tbl) tbl = VppIpTable(self, 10) tbl.add_vpp_config() self.tables.append(tbl) # setup both interfaces for i in self.pg_interfaces: if i == self.pg2: i.set_table_ip4(10) i.admin_up() i.config_ip4() i.resolve_arp() i.enable_mpls() def tearDown(self): for i in self.pg_interfaces: i.disable_mpls() i.unconfig_ip4() i.set_table_ip4(0) i.admin_down() super(TestBier, self).tearDown() def bier_midpoint(self, hdr_len_id, n_bytes, max_bp): """BIER midpoint""" # # Add a BIER table for sub-domain 0, set 0, and BSL 256 # bti = VppBierTableID(0, 0, hdr_len_id) bt = VppBierTable(self, bti, 77) bt.add_vpp_config() # # A packet with no bits set gets dropped # p = (Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / MPLS(label=77, ttl=255) / BIER(length=hdr_len_id) / IPv6(src=self.pg0.remote_ip6, dst=self.pg0.remote_ip6) / UDP(sport=1234, dport=1234) / Raw()) pkts = [p] self.send_and_assert_no_replies(self.pg0, pkts, "Empty Bit-String") # # Add a BIER route for each bit-position in the table via a different # next-hop. Testing whether the BIER walk and replicate forwarding # function works for all bit posisitons. # nh_routes = [] bier_routes = [] for i in range(1, max_bp+1): nh = "10.0.%d.%d" % (i / 255, i % 255) nh_routes.append( VppIpRoute(self, nh, 32, [VppRoutePath(self.pg1.remote_ip4, self.pg1.sw_if_index, labels=[VppMplsLabel(2000+i)])])) nh_routes[-1].add_vpp_config() bier_routes.append( VppBierRoute(self, bti, i, [VppRoutePath(nh, 0xffffffff, labels=[VppMplsLabel(100+i)])])) bier_routes[-1].add_vpp_config() # # A packet with all bits set gets replicated once for each bit # pkt_sizes = [64, 1400] for pkt_size in pkt_sizes: p = (Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / MPLS(label=77, ttl=255) / BIER(length=hdr_len_id, BitString=scapy.compat.chb(255)*n_bytes) / IPv6(src=self.pg0.remote_ip6, dst=self.pg0.remote_ip6) / UDP(sport=1234, dport=1234) / Raw(scapy.compat.chb(5) * pkt_size)) pkts = p self.pg0.add_stream(pkts) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg1.get_capture(max_bp) for rxp in rx: # # The packets are not required to be sent in bit-position order # when we setup the routes above we used the bit-position to # construct the out-label. so use that here to determine the BP # olabel = rxp[MPLS] bp = olabel.label - 2000 blabel = olabel[MPLS].payload self.assertEqual(blabel.label, 100+bp) self.assertEqual(blabel.ttl, 254) bier_hdr = blabel[MPLS].payload self.assertEqual(bier_hdr.id, 5) self.assertEqual(bier_hdr.version, 0) self.assertEqual(bier_hdr.length, hdr_len_id) self.assertEqual(bier_hdr.entropy, 0) self.assertEqual(bier_hdr.OAM, 0) self.assertEqual(bier_hdr.RSV, 0) self.assertEqual(bier_hdr.DSCP, 0) self.assertEqual(bier_hdr.Proto, 5) # The bit-string should consist only of the BP given by i. byte_array = [b'\0'] * (n_bytes) byte_val = scapy.compat.chb(1 << (bp - 1) % 8) byte_pos = n_bytes - (((bp - 1) // 8) + 1) byte_array[byte_pos] = byte_val bitstring = b''.join(byte_array) self.assertEqual(len(bitstring), len(bier_hdr.BitString)) self.assertEqual(bitstring, bier_hdr.BitString) # # cleanup. not strictly necessary, but it's much quicker this way # because the bier_fib_dump and ip_fib_dump will be empty when the # auto-cleanup kicks in # for br in bier_routes: br.remove_vpp_config() for nhr in nh_routes: nhr.remove_vpp_config() @unittest.skipUnless(config.extended, "part of extended tests") def test_bier_midpoint_1024(self): """BIER midpoint BSL:1024""" self.bier_midpoint(BIERLength.BIER_LEN_1024, 128, 1024) @unittest.skipUnless(config.extended, "part of extended tests") def test_bier_midpoint_512(self): """BIER midpoint BSL:512""" self.bier_midpoint(BIERLength.BIER_LEN_512, 64, 512) @unittest.skipUnless(config.extended, "part of extended tests") def test_bier_midpoint_256(self): """BIER midpoint BSL:256""" self.bier_midpoint(BIERLength.BIER_LEN_256, 32, 256) @unittest.skipUnless(config.extended, "part of extended tests") def test_bier_midpoint_128(self): """BIER midpoint BSL:128""" self.bier_midpoint(BIERLength.BIER_LEN_128, 16, 128) def test_bier_midpoint_64(self): """BIER midpoint BSL:64""" self.bier_midpoint(BIERLength.BIER_LEN_64, 8, 64) def test_bier_load_balance(self): """BIER load-balance""" # # Add a BIER table for sub-domain 0, set 0, and BSL 256 # bti = VppBierTableID(0, 0, BIERLength.BIER_LEN_64) bt = VppBierTable(self, bti, 77) bt.add_vpp_config() # # packets with varying entropy # pkts = [] for ii in range(257): pkts.append((Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / MPLS(label=77, ttl=255) / BIER(length=BIERLength.BIER_LEN_64, entropy=ii, BitString=scapy.compat.chb(255)*16) / IPv6(src=self.pg0.remote_ip6, 
/*
 * Copyright (c) 2016 Cisco and/or its affiliates.
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at:
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

/**
 * @brief Glean Adjacency
 *
 * A gleean adjacency represent the need to discover new peers on an
 * attached link. Packets that hit a glean adjacency will generate an
 * ARP/ND packet addessesed to the packet's destination address.
 * Note this is different to an incomplete neighbour adjacency, which
 * does not send ARP/ND requests to the packet's destination address,
 * but instead to the next-hop address of the adjacency itself.
 */

#ifndef __ADJ_GLEAN_H__
#define __ADJ_GLEAN_H__

#include <vnet/adj/adj_types.h>

/**
 * @brief
 *  Add (and lock) a new or lock an existing glean adjacency
 *
 * @param proto
 *  The protocol for the neighbours that we wish to glean
 *
 * @param sw_if_index
 *  The interface on which to glean
 *
 * @param nh_addr
 *  the address applied to the interface on which to glean. This
 *  as the source address in packets when the ARP/ND packet is sent
 */
extern adj_index_t adj_glean_add_or_lock(fib_protocol_t proto,
                                         vnet_link_t linkt,
					 u32 sw_if_index,
					 const fib_prefix_t *conn);

/**
 * @brief Get an existing glean
 *
 * @return INVALID if it does not exist
 */
extern adj_index_t adj_glean_get(fib_protocol_t proto,
                                 u32 sw_if_index,
                                 const ip46_address_t *nh_addr);

/**
 * adj_glean_update_rewrite
 *
 * Called by an adjacency provider (an interface type) to configure
 * a glean adj (i.e. and adjacency linked to a connected prefix) to
 * its default behaviour.
 * Other interface types (i.e. 6RD tunnels) can can choose not to use
 * glean behaviour on an adjacency liked to a connected prefix.
 */
extern void adj_glean_update_rewrite(adj_index_t adj_index);
extern void adj_glean_update_rewrite_itf(u32 sw_if_index);

/**
 * Return the source address from the glean
 */
const ip46_address_t *adj_glean_get_src(fib_protocol_t proto,
                                        u32 sw_if_index,
                                        const ip46_address_t *nh_addr);

/**
 * @brief Format/display a glean adjacency.
 */
extern u8* format_adj_glean(u8* s, va_list *ap);

/**
 * Walk all the gleans on an interface
 */
extern void adj_glean_walk (u32 sw_if_index,
                            adj_walk_cb_t,
                            void *);

/**
 * @brief
 *  Module initialisation
 */
extern void adj_glean_module_init(void);

/**
 * @brief
 *  Return the size of the adjacency database. for testing purposes
 */
extern u32 adj_glean_db_size(void);

#endif
self.bier_e2e(BIERLength.BIER_LEN_512, 64, 512) @unittest.skipUnless(config.extended, "part of extended tests") def test_bier_e2e_256(self): """ BIER end-to-end BSL:256""" self.bier_e2e(BIERLength.BIER_LEN_256, 32, 256) @unittest.skipUnless(config.extended, "part of extended tests") def test_bier_e2e_128(self): """ BIER end-to-end BSL:128""" self.bier_e2e(BIERLength.BIER_LEN_128, 16, 128) def test_bier_e2e_64(self): """ BIER end-to-end BSL:64""" self.bier_e2e(BIERLength.BIER_LEN_64, 8, 64) def test_bier_head_o_udp(self): """BIER head over UDP""" MRouteItfFlags = VppEnum.vl_api_mfib_itf_flags_t MRouteEntryFlags = VppEnum.vl_api_mfib_entry_flags_t # # Add a BIER table for sub-domain 1, set 0, and BSL 256 # bti = VppBierTableID(1, 0, BIERLength.BIER_LEN_256) bt = VppBierTable(self, bti, 77) bt.add_vpp_config() # # 1 bit positions via 1 next hops # nh1 = "10.0.0.1" ip_route = VppIpRoute(self, nh1, 32, [VppRoutePath(self.pg1.remote_ip4, self.pg1.sw_if_index, labels=[VppMplsLabel(2001)])]) ip_route.add_vpp_config() udp_encap = VppUdpEncap(self, self.pg0.local_ip4, nh1, 330, 8138) udp_encap.add_vpp_config() bier_route = VppBierRoute( self, bti, 1, [VppRoutePath("0.0.0.0", 0xFFFFFFFF, type=FibPathType.FIB_PATH_TYPE_UDP_ENCAP, next_hop_id=udp_encap.id)]) bier_route.add_vpp_config() # # An 2 imposition objects with all bit-positions set # only use the second, but creating 2 tests with a non-zero # value index in the route add # bi = VppBierImp(self, bti, 333, scapy.compat.chb(0xff) * 32) bi.add_vpp_config() bi2 = VppBierImp(self, bti, 334, scapy.compat.chb(0xff) * 32) bi2.add_vpp_config() # # Add a multicast route that will forward into the BIER doamin # route_ing_232_1_1_1 = VppIpMRoute( self, "0.0.0.0", "232.1.1.1", 32, MRouteEntryFlags.MFIB_API_ENTRY_FLAG_NONE, paths=[VppMRoutePath(self.pg0.sw_if_index, MRouteItfFlags.MFIB_API_ITF_FLAG_ACCEPT), VppMRoutePath(0xffffffff, MRouteItfFlags.MFIB_API_ITF_FLAG_FORWARD, proto=FibPathProto.FIB_PATH_NH_PROTO_BIER, type=FibPathType.FIB_PATH_TYPE_BIER_IMP, bier_imp=bi2.bi_index)]) route_ing_232_1_1_1.add_vpp_config() # # inject a packet an IP. We expect it to be BIER and UDP encapped, # p = (Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / IP(src="1.1.1.1", dst="232.1.1.1") / UDP(sport=1234, dport=1234)) self.pg0.add_stream([p]) self.pg_enable_capture(self.pg_interfaces) self.pg_start() rx = self.pg1.get_capture(1) # # Encap Stack is, eth, IP, UDP, BIFT, BIER # self.assertEqual(rx[0][IP].src, self.pg0.local_ip4) self.assertEqual(rx[0][IP].dst, nh1) self.assertEqual(rx[0][UDP].sport, 330) self.assertEqual(rx[0][UDP].dport, 8138) self.assertEqual(rx[0][BIFT].bsl, BIERLength.BIER_LEN_256) self.assertEqual(rx[0][BIFT].sd, 1) self.assertEqual(rx[0][BIFT].set, 0) self.assertEqual(rx[0][BIFT].ttl, 64) self.assertEqual(rx[0][BIER].length, 2) def test_bier_tail_o_udp(self): """BIER Tail over UDP""" MRouteItfFlags = VppEnum.vl_api_mfib_itf_flags_t MRouteEntryFlags = VppEnum.vl_api_mfib_entry_flags_t # # Add a BIER table for sub-domain 0, set 0, and BSL 256 # bti = VppBierTableID(1, 0, BIERLength.BIER_LEN_256) bt = VppBierTable(self, bti, MPLS_LABEL_INVALID) bt.add_vpp_config() # # disposition table # bdt = VppBierDispTable(self, 8) bdt.add_vpp_config() # # BIER route in table that's for-us # bier_route_1 = VppBierRoute( self, bti, 1, [VppRoutePath("0.0.0.0", 0xffffffff, proto=FibPathProto.FIB_PATH_NH_PROTO_BIER, nh_table_id=8)]) bier_route_1.add_vpp_config() # # An entry in the disposition table # bier_de_1 = VppBierDispEntry(self, bdt.id, 99, BIER_HDR_PAYLOAD.BIER_HDR_PROTO_IPV4, FibPathProto.FIB_PATH_NH_PROTO_BIER, "0.0.0.0", 0, rpf_id=8192) bier_de_1.add_vpp_config() # # A multicast route to forward post BIER disposition # route_eg_232_1_1_1 = VppIpMRoute( self, "0.0.0.0", "232.1.1.1", 32, MRouteEntryFlags.MFIB_API_ENTRY_FLAG_NONE, paths=[VppMRoutePath(self.pg1.sw_if_index, MRouteItfFlags.MFIB_API_ITF_FLAG_FORWARD)]) route_eg_232_1_1_1.add_vpp_config() route_eg_232_1_1_1.update_rpf_id(8192) # # A packet with all bits set gets spat out to BP:1 # p = (Ether(dst=self.pg0.local_mac, src=self.pg0.remote_mac) / IP(src=self.pg0.remote_ip4, dst=self.pg0.local_ip4) / UDP(sport=333, dport=8138) / BIFT(sd=1, set=0, bsl=2, ttl=255) / BIER(length=BIERLength.BIER_LEN_256, BitString=scapy.compat.chb(255)*32, BFRID=99) / IP(src="1.1.1.1", dst="232.1.1.1") / UDP(sport=1234, dport=1234) / Raw()) rx = self.send_and_expect(self.pg0, [p], self.pg1) if __name__ == '__main__': unittest.main(testRunner=VppTestRunner)