#!/usr/bin/env python from socket import AF_INET, AF_INET6 import unittest from scapy.packet import Raw from scapy.layers.l2 import Ether, ARP, Dot1Q from scapy.layers.inet import IP, UDP, ICMP from scapy.layers.inet6 import IPv6, ICMPv6ND_NS, ICMPv6NDOptSrcLLAddr, \ ICMPv6ND_NA, ICMPv6EchoRequest from scapy.utils6 import in6_getnsma, in6_getnsmac from scapy.layers.vxlan import VXLAN from scapy.data import ETH_P_IP, ETH_P_IPV6, ETH_P_ARP from scapy.utils import inet_pton, inet_ntop from framework import VppTestCase, VppTestRunner from vpp_object import VppObject from vpp_interface import VppInterface from vpp_ip_route import VppIpRoute, VppRoutePath, VppIpTable, \ VppIpInterfaceAddress, VppIpInterfaceBind, find_route, FibPathProto, \ FibPathType from vpp_l2 import VppBridgeDomain, VppBridgeDomainPort, \ VppBridgeDomainArpEntry, VppL2FibEntry, find_bridge_domain_port, VppL2Vtr from vpp_sub_interface import L2_VTR_OP, VppDot1QSubint from vpp_ip import VppIpAddress, VppIpPrefix, DpoProto from vpp_papi import VppEnum, MACAddress from vpp_vxlan_gbp_tunnel import find_vxlan_gbp_tunnel, INDEX_INVALID, \ VppVxlanGbpTunnel from vpp_neighbor import VppNeighbor try: text_type = unicode except NameError: text_type = str NUM_PKTS = 67 def find_gbp_endpoint(test, sw_if_index=None, ip=None, mac=None, tep=None, sclass=None): if ip: vip = VppIpAddress(ip) if mac: vmac = MACAddress(mac) eps = test.vapi.gbp_endpoint_dump() for ep in eps: if tep: src = VppIpAddress(tep[0]) dst = VppIpAddress(tep[1]) if src != ep.endpoint.tun.src or dst != ep.endpoint.tun.dst: continue if sw_if_index: if ep.endpoint.sw_if_index != sw_if_index: continue if sclass: if ep.endpoint.sclass != sclass: continue if ip: for eip in ep.endpoint.ips: if vip == eip: return True if mac: if vmac.packed == ep.endpoint.mac: return True return False def find_gbp_vxlan(test, vni): ts = test.vapi.gbp_vxlan_tunnel_dump() for t in ts: if t.tunnel.vni == vni: return True return False class VppGbpEndpoint(VppObject): """ GBP Endpoint """ @property def mac(self): return str(self.vmac) @property def ip4(self): return self._ip4 @property def fip4(self): return self._fip4 @property def ip6(self): return self._ip6 @property def fip6(self): return self._fip6 @property def ips(self): return [self.ip4, self.ip6] @property def fips(self): return [self.fip4, self.fip6] def __init__(self, test, itf, epg, recirc, ip4, fip4, ip6, fip6, flags=0, tun_src="0.0.0.0", tun_dst="0.0.0.0", mac=True): self._test = test self.itf = itf self.epg = epg self.recirc = recirc self._ip4 = VppIpAddress(ip4) self._fip4 = VppIpAddress(fip4) self._ip6 = VppIpAddress(ip6) self._fip6 = VppIpAddress(fip6) if mac: self.vmac = MACAddress(self.itf.remote_mac) else: self.vmac = MACAddress("00:00:00:00:00:00") self.flags = flags self.tun_src = VppIpAddress(tun_src) self.tun_dst = VppIpAddress(tun_dst) def add_vpp_config(self): res = self._test.vapi.gbp_endpoint_add( self.itf.sw_if_index, [self.ip4.encode(), self.ip6.encode()], self.vmac.packed, self.epg.sclass, self.flags, self.tun_src.encode(), self.tun_dst.encode()) self.handle = res.handle self._test.registry.register(self, self._test.logger) def remove_vpp_config(self): self._test.vapi.gbp_endpoint_del(self.handle) def object_id(self): return "gbp-endpoint:[%d==%d:%s:%d]" % (self.handle, self.itf.sw_if_index, self.ip4.address, self.epg.sclass) def query_vpp_config(self): return find_gbp_endpoint(self._test, self.itf.sw_if_index, self.ip4.address) class VppGbpRecirc(VppObject): """ GBP Recirculation Interface """ def __init__(self, test, epg, recirc, is_ext=False): self._test = test self.recirc = recirc self.epg = epg self.is_ext = is_ext def add_vpp_config(self): self._test.vapi.gbp_recirc_add_del( 1, self.recirc.sw_if_index, self.epg.sclass, self.is_ext) self._test.registry.register(self, self._test.logger) def remove_vpp_config(self): self._test.vapi.gbp_recirc_add_del( 0, self.recirc.sw_if_index, self.epg.sclass, self.is_ext) def object_id(self): return "gbp-recirc:[%d]" % (self.recirc.sw_if_index) def query_vpp_config(self): rs = self._test.vapi.gbp_recirc_dump() for r in rs: if r.recirc.sw_if_index == self.recirc.sw_if_index: return True return False class VppGbpExtItf(VppObject): """ GBP ExtItfulation Interface """ def __init__(self, test, itf, bd, rd, anon=False): self._test = test self.itf = itf self.bd = bd self.rd = rd self.flags = 1 if anon else 0 def add_vpp_config(self): self._test.vapi.gbp_ext_itf_add_del( 1, self.itf.sw_if_index, self.bd.bd_id, self.rd.rd_id, self.flags) self._test.registry.register(self, self._test.logger) def remove_vpp_config(self): self._test.vapi.gbp_ext_itf_add_del( 0, self.itf.sw_if_index, self.bd.bd_id, self.rd.rd_id, self.flags) def object_id(self): return "gbp-ext-itf:[%d]%s" % (self.itf.sw_if_index, " [anon]" if self.flags else "") def query_vpp_config(self): rs = self._test.vapi.gbp_ext_itf_dump() for r in rs: if r.ext_itf.sw_if_index == self.itf.sw_if_index: return True return False class VppGbpSubnet(VppObject): """ GBP Subnet """ def __init__(self, test, rd, address, address_len, type, sw_if_index=None, sclass=None): self._test = test self.rd_id = rd.rd_id self.prefix = VppIpPrefix(address, address_len) self.type = type self.sw_if_index = sw_if_index self.sclass = sclass def add_vpp_config(self): self._test.vapi.gbp_subnet_add_del( 1, self.rd_id, self.prefix.encode(), self.type, sw_if_index=self.sw_if_index if self.sw_if_index else 0xffffffff, sclass=self.sclass if self.sclass else 0xffff) self._test.registry.register(self, self._test.logger) def remove_vpp_config(self): self._test.vapi.gbp_subnet_add_del( 0, self.rd_id, self.prefix.encode(), self.type) def object_id(self): return "gbp-subnet:[%d-%s]" % (self.rd_id, self.prefix) def query_vpp_config(self): ss = self._test.vapi.gbp_subnet_dump() for s in ss: if s.subnet.rd_id == self.rd_id and \ s.subnet.type == self.type and \ s.subnet.prefix == self.prefix: return True return False class VppGbpEndpointRetention(object): def __init__(self, remote_ep_timeout=0xffffffff): self.remote_ep_timeout = remote_ep_timeout def encode(self): return {'remote_ep_timeout': self.remote_ep_timeout} class VppGbpEndpointGroup(VppObject): """ GBP Endpoint Group """ def __init__(self, test, vnid, sclass, rd, bd, uplink, bvi, bvi_ip4, bvi_ip6=None, retention=VppGbpEndpointRetention()): self._test = test self.uplink = uplink self.bvi = bvi self.bvi_ip4 = VppIpAddress(bvi_ip4) self.bvi_ip6 = VppIpAddress(bvi_ip6) self.vnid = vnid self.bd = bd self.rd = rd self.sclass = sclass if 0 == self.sclass: self.sclass = 0xffff self.retention = retention def add_vpp_config(self): self._test.vapi.gbp_endpoint_group_add( self.vnid, self.sclass, self.bd.bd.bd_id, self.rd.rd_id, self.uplink.sw_if_index if self.uplink else INDEX_INVALID, self.retention.encode()) self._test.registry.register(self, self._test.logger) def remove_vpp_config(self): self._test.vapi.gbp_endpoint_group_del(self.sclass) def object_id(self): return "gbp-endpoint-group:[%d]" % (self.vnid) def query_vpp_config(self): epgs = self._test.vapi.gbp_endpoint_group_dump() for epg in epgs: if epg.epg.vnid == self.vnid: return True return False class VppGbpBridgeDomain(VppObject): """ GBP Bridge Domain """ def __init__(self, test, bd, rd, bvi, uu_fwd=None, bm_flood=None, learn=True, uu_drop=False, bm_drop=False, ucast_arp=False): self._test = test self.bvi = bvi self.uu_fwd = uu_fwd self.bm_flood = bm_flood self.bd = bd self.rd = rd e = VppEnum.vl_api_gbp_bridge_domain_flags_t self.flags = e.GBP_BD_API_FLAG_NONE if not learn: self.flags |= e.GBP_BD_API_FLAG_DO_NOT_LEARN if uu_drop: self.flags |= e.GBP_BD_API_FLAG_UU_FWD_DROP if bm_drop: self.flags |= e.GBP_BD_API_FLAG_MCAST_DROP if ucast_arp: self.flags |= e.GBP_BD_API_FLAG_UCAST_ARP def add_vpp_config(self): self._test.vapi.gbp_bridge_domain_add( self.bd.bd_id, self.rd.rd_id, self.flags, self.bvi.sw_if_index, self.uu_fwd.sw_if_index if self.uu_fwd else INDEX_INVALID, self.bm_flood.sw_if_index if self.bm_flood else INDEX_INVALID) self._test.registry.register(self, self._test.logger) def remove_vpp_config(self): self._test.vapi.gbp_bridge_domain_del(self.bd.bd_id) def object_id(self): return "gbp-bridge-domain:[%d]" % (self.bd.bd_id) def query_vpp_config(self): bds = self._test.vapi.gbp_bridge_domain_dump() for bd in bds: if bd.bd.bd_id == self.bd.bd_id: return True return False class VppGbpRouteDomain(VppObject): """ GBP Route Domain """ def __init__(self, test, rd_id, scope, t4, t6, ip4_uu=None, ip6_uu=None): self._test = test self.rd_id = rd_id self.scope = scope self.t4 = t4 self.t6 = t6 self.ip4_uu = ip4_uu self.ip6_uu = ip6_uu def add_vpp_config(self): self._test.vapi.gbp_route_domain_add( self.rd_id, self.scope, self.t4.table_id, self.t6.table_id, self.ip4_uu.sw_if_index if self.ip4_uu else INDEX_INVALID, self.ip6_uu.sw_if_index if self.ip6_uu else INDEX_INVALID) self._test.registry.register(self, self._test.logger) def remove_vpp_config(self): self._test.vapi.gbp_route_domain_del(self.rd_id) def object_id(self): return "gbp-route-domain:[%d]" % (self.rd_id) def query_vpp_config(self): rds = self._test.vapi.gbp_route_domain_dump() for rd in rds: if rd.rd.rd_id == self.rd_id: return True return False class VppGbpContractNextHop(): def __init__(self, mac, bd, ip, rd): self.mac = mac self.ip = ip self.bd = bd self.rd = rd def encode(self): return {'ip': self.ip.encode(), 'mac': self.mac.packed, 'bd_id': self.bd.bd.bd_id, 'rd_id': self.rd.rd_id} class VppGbpContractRule(): def __init__(self, action, hash_mode, nhs=None): self.action = action self.hash_mode = hash_mode self.nhs = [] if nhs is None else nhs def encode(self): nhs = [] for nh in self.nhs: nhs.append(nh.encode()) while len(nhs) < 8: nhs.append({}) return {'action': self.action, 'nh_set': { 'hash_mode': self.hash_mode, 'n_nhs': len(self.nhs), 'nhs': nhs}} def __repr__(self): return '' % ( self.action, self.hash_mode) class VppGbpContract(VppObject): """ GBP Contract """ def __init__(self, test, scope, sclass, dclass, acl_index, rules, allowed_ethertypes): self._test = test if not isinstance(rules, list): raise ValueError("'rules' must be a list.") if not isinstance(allowed_ethertypes, list): raise ValueError("'allowed_ethertypes' must be a list.") self.scope = scope self.acl_index = acl_index self.sclass = sclass self.dclass = dclass self.rules = rules self.allowed_ethertypes = allowed_ethertypes while (len(self.allowed_ethertypes) < 16): self.allowed_ethertypes.append(0) def add_vpp_config(self): rules = [] for r in self.rules: rules.append(r.encode()) r = self._test.vapi.gbp_contract_add_del( is_add=1, contract={ 'acl_index': self.acl_index, 'scope': self.scope, 'sclass': self.sclass, 'dclass': self.dclass, 'n_rules': len(rules), 'rules': rules, 'n_ether_types': len(self.allowed_ethertypes), 'allowed_ethertypes': self.allowed_ethertypes}) self.stats_index = r.stats_index self._test.registry.register(self, self._test.logger) def remove_vpp_config(self): self._test.vapi.gbp_contract_add_del( is_add=0, contract={ 'acl_index': self.acl_index, 'scope': self.scope, 'sclass': self.sclass, 'dclass': self.dclass, 'n_rules': 0, 'rules': [], 'n_ether_types': len(self.allowed_ethertypes), 'allowed_ethertypes': self.allowed_ethertypes}) def object_id(self): return "gbp-contract:[%d:%d:%d:%d]" % (self.scope, self.sclass, self.dclass, self.acl_index) def query_vpp_config(self): cs = self._test.vapi.gbp_contract_dump() for c in cs: if c.contract.scope == self.scope \ and c.contract.sclass == self.sclass \ and c.contract.dclass == self.dclass: return True return False def get_drop_stats(self): c = self._test.statistics.get_counter("/net/gbp/contract/drop") return c[0][self.stats_index] def get_permit_stats(self): c = self._test.statistics.get_counter("/net/gbp/contract/permit") return c[0][self.stats_index] class VppGbpVxlanTunnel(VppInterface): """ GBP VXLAN tunnel """ def __init__(self, test, vni, bd_rd_id, mode, src): super(VppGbpVxlanTunnel, self).__init__(test) self._test = test self.vni = vni self.bd_rd_id = bd_rd_id self.mode = mode self.src = src def add_vpp_config(self): r = self._test.vapi.gbp_vxlan_tunnel_add( self.vni, self.bd_rd_id, self.mode, self.src) self.set_sw_if_index(r.sw_if_index) self._test.registry.register(self, self._test.logger) def remove_vpp_config(self): self._test.vapi.gbp_vxlan_tunnel_del(self.vni) def object_id(self): return "gbp-vxlan:%d" % (self.sw_if_index) def query_vpp_config(self): return find_gbp_vxlan(self._test, self.vni) class VppGbpAcl(VppObject): """ GBP Acl """ def __init__(self, test): self._test = test self.acl_index = 4294967295 def create_rule(self, is_ipv6=0, permit_deny=0, proto=-1, s_prefix=0, s_ip=b'\x00\x00\x00\x00', sport_from=0, sport_to=65535, d_prefix=0, d_ip=b'\x00\x00\x00\x00', dport_from=0, dport_t
/*
 * Copyright (c) 2015 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.
 */
/*
 * error.c: VLIB error handler
 *
 * Copyright (c) 2008 Eliot Dresselhaus
 *
 * Permission is hereby granted, free of charge, to any person obtaining
 * a copy of this software and associated documentation files (the
 * "Software"), to deal in the Software without restriction, including
 * without limitation the rights to use, copy, modify, merge, publish,
 * distribute, sublicense, and/or sell copies of the Software, and to
 * permit persons to whom the Software is furnished to do so, subject to
 * the following conditions:
 *
 * The above copyright notice and this permission notice shall be
 * included in all copies or substantial portions of the Software.
 *
 *  THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
 *  EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
 *  MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
 *  NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
 *  LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
 *  OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
 *  WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
 */

#include <vlib/vlib.h>
#include <vppinfra/heap.h>

uword
vlib_error_drop_buffers (vlib_main_t * vm,
			 vlib_node_runtime_t * node,
			 u32 * buffers,
			 u32 next_buffer_stride,
			 u32 n_buffers,
			 u32 next_index,
			 u32 drop_error_node, u32 drop_error_code)
{
  u32 n_left_this_frame, n_buffers_left, *args, n_args_left;
  vlib_error_t drop_error;

  drop_error = vlib_error_set (drop_error_node, drop_error_code);

  n_buffers_left = n_buffers;
  while (n_buffers_left > 0)
    {
      vlib_get_next_frame (vm, node, next_index, args, n_args_left);

      n_left_this_frame = clib_min (n_buffers_left, n_args_left);
      n_buffers_left -= n_left_this_frame;
      n_args_left -= n_left_this_frame;

      while (n_left_this_frame >= 4)
	{
	  u32 bi0, bi1, bi2, bi3;
	  vlib_buffer_t *b0, *b1, *b2, *b3;

	  args[0] = bi0 = buffers[0];
	  args[1] = bi1 = buffers[1];
	  args[2] = bi2 = buffers[2];
	  args[3] = bi3 = buffers[3];

	  b0 = vlib_get_buffer (vm, bi0);
	  b1 = vlib_get_buffer (vm, bi1);
	  b2 = vlib_get_buffer (vm, bi2);
	  b3 = vlib_get_buffer (vm, bi3);

	  b0->error = drop_error;
	  b1->error = drop_error;
	  b2->error = drop_error;
	  b3->error = drop_error;

	  buffers += 4;
	  args += 4;
	  n_left_this_frame -= 4;
	}

      while (n_left_this_frame >= 1)
	{
	  u32 bi0;
	  vlib_buffer_t *b0;

	  args[0] = bi0 = buffers[0];

	  b0 = vlib_get_buffer (vm, bi0);
	  b0->error = drop_error;

	  buffers += 1;
	  args += 1;
	  n_left_this_frame -= 1;
	}

      vlib_put_next_frame (vm, node, next_index, n_args_left);
    }

  return n_buffers;
}

/* Convenience node to drop a vector of buffers with a "misc error". */
static uword
misc_drop_buffers (vlib_main_t * vm,
		   vlib_node_runtime_t * node, vlib_frame_t * frame)
{
  return vlib_error_drop_buffers (vm, node, vlib_frame_vector_args (frame),
				  /* buffer stride */ 1,
				  frame->n_vectors,
				  /* next */ 0,
				  node->node_index,
				  /* error */ 0);
}

static char *misc_drop_buffers_error_strings[] = {
  [0] = "misc. errors",
};

/* *INDENT-OFF* */
VLIB_REGISTER_NODE (misc_drop_buffers_node,static) = {
  .function = misc_drop_buffers,
  .name = "misc-drop-buffers",
  .vector_size = sizeof (u32),
  .n_errors = 1,
  .n_next_nodes = 1,
  .next_nodes = {
      "error-drop",
  },
  .error_strings = misc_drop_buffers_error_strings,
};
/* *INDENT-ON* */

void vlib_stats_register_error_index (u8 *, u64 *, u64)
  __attribute__ ((weak));
void
vlib_stats_register_error_index (u8 * notused, u64 * notused2, u64 notused3)
{
};

void vlib_stats_pop_heap2 (void *, u32, void *) __attribute__ ((weak));
void
vlib_stats_pop_heap2 (void *notused, u32 notused2, void *notused3)
{
};


/* Reserves given number of error codes for given node. */
void
vlib_register_errors (vlib_main_t * vm,
		      u32 node_index, u32 n_errors, char *error_strings[])
{
  vlib_error_main_t *em = &vm->error_main;
  vlib_node_t *n = vlib_get_node (vm, node_index);
  uword l;
  void *oldheap;
  void *vlib_stats_push_heap (void) __attribute__ ((weak));

  ASSERT (vlib_get_thread_index () == 0);

  /* Free up any previous error strings. */
  if (n->n_errors > 0)
    heap_dealloc (em->error_strings_heap, n->error_heap_handle);

  n->n_errors = n_errors;
  n->error_strings = error_strings;

  if (n_errors == 0)
    return;

  n->error_heap_index =
    heap_alloc (em->error_strings_heap, n_errors, n->error_heap_handle);

  l = vec_len (em->error_strings_heap);

  clib_memcpy (vec_elt_at_index (em->error_strings_heap, n->error_heap_index),
	       error_strings, n_errors * sizeof (error_strings[0]));

  vec_validate (vm->error_elog_event_types, l - 1);

  /* Switch to the stats segment ... */
  oldheap = vlib_stats_push_heap ();

  /* Allocate a counter/elog type for each error. */
  vec_validate (em->counters, l - 1);

  /* Zero counters for re-registrations of errors. */
  if (n->error_heap_index + n_errors <= vec_len (em->counters_last_clear))
    clib_memcpy (em->counters + n->error_heap_index,
		 em->counters_last_clear + n->error_heap_index,
		 n_errors * sizeof (em->counters[0]));
  else
    clib_memset (em->counters + n->error_heap_index,
		 0, n_errors * sizeof (em->counters[0]));

  /* Register counter indices in the stat segment directory */
  {
    int i;
    u8 *error_name;

    for (i = 0; i < n_errors; i++)
      {
	error_name = format (0, "/err/%v/%s%c", n->name, error_strings[i], 0);
	/* Note: error_name consumed by the following call */
	vlib_stats_register_error_index (error_name, em->counters,
					 n->error_heap_index + i);
      }
  }

  /* (re)register the em->counters base address, switch back to main heap */
  vlib_stats_pop_heap2 (em->counters, vm->thread_index, oldheap);

  {
    elog_event_type_t t;
    uword i;

    clib_memset (&t, 0, sizeof (t));
    for (i = 0; i < n_errors; i++)
      {
	t.format = (char *) format (0, "%v %s: %%d",
				    n->name, error_strings[i]);
	vm->error_elog_event_types[n->error_heap_index + i] = t;
      }
  }
}

static clib_error_t *
show_errors (vlib_main_t * vm,
	     unformat_input_t * input, vlib_cli_command_t * cmd)
{
  vlib_error_main_t *em = &vm->error_main;
  vlib_node_t *n;
  u32 code, i, ni;
  u64 c;
  int index = 0;
  int verbose = 0;
  u64 *sums = 0;

  if (unformat (input, "verbose %d", &verbose))
    ;
  else if (unformat (input, "verbose"))
    verbose = 1;

  vec_validate (sums, vec_len (em->counters));

  if (verbose)
    vlib_cli_output (vm, "%=10s%=40s%=20s%=6s", "Count", "Node", "Reason",
		     "Index");
  else
    vlib_cli_output (vm, "%=10s%=40s%=6s", "Count", "Node", "Reason");


  /* *INDENT-OFF* */
  foreach_vlib_main(({
    em = &this_vlib_main->error_main;

    if (verbose)
      vlib_cli_output(vm, "Thread %u (%v):", index,
                      vlib_worker_threads[index].name);

    for (ni = 0; ni < vec_len (this_vlib_main->node_main.nodes); ni++)
      {
	n = vlib_get_node (this_vlib_main, ni);
	for (code = 0; code < n->n_errors; code++)
	  {
	    i = n->error_heap_index + code;
	    c = em->counters[i];
	    if (i < vec_len (em->counters_last_clear))
	      c -= em->counters_last_clear[i];
	    sums[i] += c;

	    if (c == 0 && verbose < 2)
	      continue;

            if (verbose)
              vlib_cli_output (vm, "%10Ld%=40v%=20s%=6d", c, n->name,
                               em->error_strings_heap[i], i);
            else
              vlib_cli_output (vm, "%10d%=40v%s", c, n->name,
                               em->error_strings_heap[i]);
	  }
      }
    index++;
  }));
  /* *INDENT-ON* */

  if (verbose)
    vlib_cli_output (vm, "Total:");

  for (ni = 0; ni < vec_len (vm->node_main.nodes); ni++)
    {
      n = vlib_get_node (vm, ni);
      for (code = 0; code < n->n_errors; code++)
	{
	  i = n->error_heap_index + code;
	  if (sums[i])
	    {
	      if (verbose)
		vlib_cli_output (vm, "%10Ld%=40v%=20s%=10d", sums[i], n->name,
				 em->error_strings_heap[i], i);
	    }
	}
    }

  vec_free (sums);

  return 0;
}

/* *INDENT-OFF* */
VLIB_CLI_COMMAND (vlib_cli_show_errors) = {
  .path = "show errors",
  .short_help = "Show error counts",
  .function = show_errors,
};
/* *INDENT-ON* */

/* *INDENT-OFF* */
VLIB_CLI_COMMAND (cli_show_node_counters, static) = {
  .path = "show node counters",
  .short_help = "Show node counters",
  .function = show_errors,
};
/* *INDENT-ON* */

static clib_error_t *
clear_error_counters (vlib_main_t * vm,
		      unformat_input_t * input, vlib_cli_command_t * cmd)
{
  vlib_error_main_t *em;
  u32 i;

  /* *INDENT-OFF* */
  foreach_vlib_main(({
    em = &this_vlib_main->error_main;
    vec_validate (em->counters_last_clear, vec_len (em->counters) - 1);
    for (i = 0; i < vec_len (em->counters); i++)
      em->counters_last_clear[i] = em->counters[i];
  }));
  /* *INDENT-ON* */
  return 0;
}

/* *INDENT-OFF* */
VLIB_CLI_COMMAND (cli_clear_error_counters, static) = {
  .path = "clear errors",
  .short_help = "Clear error counters",
  .function = clear_error_counters,
};
/* *INDENT-ON* */

/* *INDENT-OFF* */
VLIB_CLI_COMMAND (cli_clear_node_counters, static) = {
  .path = "clear node counters",
  .short_help = "Clear node counters",
  .function = clear_error_counters,
};
/* *INDENT-ON* */

/*
 * fd.io coding-style-patch-verification: ON
 *
 * Local Variables:
 * eval: (c-set-style "gnu")
 * End:
 */
nd_expect(self.pg2, p * NUM_PKTS, self.pg0) self.assertTrue(find_gbp_endpoint(self, vx_tun_l2_1.sw_if_index, mac=l['mac'])) # # static EP cannot reach the learnt EPs since there is no contract # only test 1 EP as the others could timeout # p = (Ether(src=ep.mac, dst=l['mac']) / IP(dst=learnt[0]['ip'], src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_assert_no_replies(self.pg0, [p]) # # refresh the entries after the check for no replies above # for l in learnt: # a packet with an sclass from a known EPG p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[1].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=99, gpid=113, flags=0x88, gpflags='A') / Ether(src=l['mac'], dst=ep.mac) / IP(src=l['ip'], dst=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rx = self.send_and_expect(self.pg2, p * NUM_PKTS, self.pg0) self.assertTrue(find_gbp_endpoint(self, vx_tun_l2_1.sw_if_index, mac=l['mac'])) # # Add the contract so they can talk # acl = VppGbpAcl(self) rule = acl.create_rule(permit_deny=1, proto=17) rule2 = acl.create_rule(is_ipv6=1, permit_deny=1, proto=17) acl_index = acl.add_vpp_config([rule, rule2]) c1 = VppGbpContract( self, 401, epg_220.sclass, epg_330.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c1.add_vpp_config() for l in learnt: p = (Ether(src=ep.mac, dst=l['mac']) / IP(dst=l['ip'], src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_expect(self.pg0, [p], self.pg2) # # send UU packets from the local EP # self.logger.info(self.vapi.cli("sh gbp bridge")) self.logger.info(self.vapi.cli("sh bridge-domain 1 detail")) p_uu = (Ether(src=ep.mac, dst="00:11:11:11:11:11") / IP(dst="10.0.0.133", src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(ep.itf, [p_uu], gbd1.uu_fwd) self.logger.info(self.vapi.cli("sh bridge 1 detail")) p_bm = (Ether(src=ep.mac, dst="ff:ff:ff:ff:ff:ff") / IP(dst="10.0.0.133", src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect_only(ep.itf, [p_bm], tun_bm.mcast_itf) for rx in rxs: self.assertEqual(rx[IP].src, self.pg4.local_ip4) self.assertEqual(rx[IP].dst, "239.1.1.1") self.assertEqual(rx[UDP].dport, 48879) # the UDP source port is a random value for hashing self.assertEqual(rx[VXLAN].gpid, 112) self.assertEqual(rx[VXLAN].vni, 88) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) self.assertFalse(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) acl = VppGbpAcl(self) rule = acl.create_rule(permit_deny=1, proto=17) rule2 = acl.create_rule(is_ipv6=1, permit_deny=1, proto=17) acl_index = acl.add_vpp_config([rule, rule2]) c2 = VppGbpContract( self, 401, epg_330.sclass, epg_220.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c2.add_vpp_config() for l in learnt: self.wait_for_ep_timeout(vx_tun_l2_1.sw_if_index, mac=l['mac']) # # Check v6 Endpoints learning # for l in learnt: # a packet with an sclass from a known EPG p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[1].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=99, gpid=113, flags=0x88) / Ether(src=l['mac'], dst=ep.mac) / IPv6(src=l['ip6'], dst=ep.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rx = self.send_and_expect(self.pg2, p * NUM_PKTS, self.pg0) rx = self.send_and_expect(self.pg2, p * NUM_PKTS, self.pg0) self.assertTrue(find_gbp_endpoint( self, vx_tun_l2_1.sw_if_index, ip=l['ip6'], tep=[self.pg2.local_ip4, self.pg2.remote_hosts[1].ip4])) self.logger.info(self.vapi.cli("sh int")) self.logger.info(self.vapi.cli("sh vxlan-gbp tunnel")) self.logger.info(self.vapi.cli("sh gbp vxlan")) self.logger.info(self.vapi.cli("sh gbp endpoint")) self.logger.info(self.vapi.cli("sh gbp interface")) # # EP moves to a different TEP # for l in learnt: # a packet with an sclass from a known EPG p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[2].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=99, gpid=113, flags=0x88) / Ether(src=l['mac'], dst=ep.mac) / IPv6(src=l['ip6'], dst=ep.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rx = self.send_and_expect(self.pg2, p * 1, self.pg0) rx = self.send_and_expect(self.pg2, p * NUM_PKTS, self.pg0) self.assertTrue(find_gbp_endpoint( self, vx_tun_l2_1.sw_if_index, sclass=113, mac=l['mac'], tep=[self.pg2.local_ip4, self.pg2.remote_hosts[2].ip4])) # # v6 remote EP reachability # for l in learnt: p = (Ether(src=ep.mac, dst=l['mac']) / IPv6(dst=l['ip6'], src=ep.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * NUM_PKTS, self.pg2) for rx in rxs: self.assertEqual(rx[IP].src, self.pg2.local_ip4) self.assertEqual(rx[IP].dst, self.pg2.remote_hosts[2].ip4) self.assertEqual(rx[UDP].dport, 48879) # the UDP source port is a random value for hashing self.assertEqual(rx[VXLAN].gpid, 112) self.assertEqual(rx[VXLAN].vni, 99) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) self.assertEqual(rx[IPv6].dst, l['ip6']) # # EP changes sclass # for l in learnt: # a packet with an sclass from a known EPG p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[2].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=99, gpid=112, flags=0x88) / Ether(src=l['mac'], dst=ep.mac) / IPv6(src=l['ip6'], dst=ep.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rx = self.send_and_expect(self.pg2, p * 1, self.pg0) rx = self.send_and_expect(self.pg2, p * NUM_PKTS, self.pg0) self.assertTrue(find_gbp_endpoint( self, vx_tun_l2_1.sw_if_index, mac=l['mac'], sclass=112, tep=[self.pg2.local_ip4, self.pg2.remote_hosts[2].ip4])) # # check reachability and contract intra-epg # allow_intra_class = self.statistics.get_err_counter( '/err/gbp-policy-mac/allow-intra-sclass') for l in learnt: p = (Ether(src=ep.mac, dst=l['mac']) / IPv6(dst=l['ip6'], src=ep.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * NUM_PKTS, self.pg2) for rx in rxs: self.assertEqual(rx[IP].src, self.pg2.local_ip4) self.assertEqual(rx[IP].dst, self.pg2.remote_hosts[2].ip4) self.assertEqual(rx[UDP].dport, 48879) self.assertEqual(rx[VXLAN].gpid, 112) self.assertEqual(rx[VXLAN].vni, 99) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) self.assertEqual(rx[IPv6].dst, l['ip6']) allow_intra_class += NUM_PKTS self.assert_error_counter_equal( '/err/gbp-policy-mac/allow-intra-sclass', allow_intra_class) # # clean up # for l in learnt: self.wait_for_ep_timeout(vx_tun_l2_1.sw_if_index, mac=l['mac']) self.pg2.unconfig_ip4() self.pg3.unconfig_ip4() self.pg4.unconfig_ip4() def test_gbp_contract(self): """ GBP Contracts """ # # Route Domains # gt4 = VppIpTable(self, 0) gt4.add_vpp_config() gt6 = VppIpTable(self, 0, is_ip6=True) gt6.add_vpp_config() rd0 = VppGbpRouteDomain(self, 0, 400, gt4, gt6, None, None) rd0.add_vpp_config() # # Bridge Domains # bd1 = VppBridgeDomain(self, 1, arp_term=0) bd2 = VppBridgeDomain(self, 2, arp_term=0) bd1.add_vpp_config() bd2.add_vpp_config() gbd1 = VppGbpBridgeDomain(self, bd1, rd0, self.loop0) gbd2 = VppGbpBridgeDomain(self, bd2, rd0, self.loop1) gbd1.add_vpp_config() gbd2.add_vpp_config() # # 3 EPGs, 2 of which share a BD. # epgs = [VppGbpEndpointGroup(self, 220, 1220, rd0, gbd1, None, self.loop0, "10.0.0.128", "2001:10::128"), VppGbpEndpointGroup(self, 221, 1221, rd0, gbd1, None, self.loop0, "10.0.1.128", "2001:10:1::128"), VppGbpEndpointGroup(self, 222, 1222, rd0, gbd2, None, self.loop1, "10.0.2.128", "2001:10:2::128")] # # 4 end-points, 2 in the same subnet, 3 in the same BD # eps = [VppGbpEndpoint(self, self.pg0, epgs[0], None, "10.0.0.1", "11.0.0.1", "2001:10::1", "3001::1"), VppGbpEndpoint(self, self.pg1, epgs[0], None, "10.0.0.2", "11.0.0.2", "2001:10::2", "3001::2"), VppGbpEndpoint(self, self.pg2, epgs[1], None, "10.0.1.1", "11.0.0.3", "2001:10:1::1", "3001::3"), VppGbpEndpoint(self, self.pg3, epgs[2], None, "10.0.2.1", "11.0.0.4", "2001:10:2::1", "3001::4")] # # Config related to each of the EPGs # for epg in epgs: # IP config on the BVI interfaces if epg != epgs[1]: VppIpInterfaceBind(self, epg.bvi, epg.rd.t4).add_vpp_config() VppIpInterfaceBind(self, epg.bvi, epg.rd.t6).add_vpp_config() self.vapi.sw_interface_set_mac_address( epg.bvi.sw_if_index, self.router_mac.packed) if_ip4 = VppIpInterfaceAddress(self, epg.bvi, epg.bvi_ip4, 32) if_ip6 = VppIpInterfaceAddress(self, epg.bvi, epg.bvi_ip6, 128) if_ip4.add_vpp_config() if_ip6.add_vpp_config() # add the BD ARP termination entry for BVI IP epg.bd_arp_ip4 = VppBridgeDomainArpEntry(self, epg.bd.bd, str(self.router_mac), epg.bvi_ip4.address) epg.bd_arp_ip4.add_vpp_config() # EPG in VPP epg.add_vpp_config() # # config ep # for ep in eps: ep.add_vpp_config() self.logger.info(self.vapi.cli("show gbp endpoint")) self.logger.info(self.vapi.cli("show interface")) self.logger.info(self.vapi.cli("show br")) # # Intra epg allowed without contract # pkt_intra_epg_220_to_220 = (Ether(src=self.pg0.remote_mac, dst=self.pg1.remote_mac) / IP(src=eps[0].ip4.address, dst=eps[1].ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_expect_bridged(self.pg0, pkt_intra_epg_220_to_220 * 65, self.pg1) pkt_intra_epg_220_to_220 = (Ether(src=self.pg0.remote_mac, dst=self.pg1.remote_mac) / IPv6(src=eps[0].ip6.address, dst=eps[1].ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_expect_bridged6(self.pg0, pkt_intra_epg_220_to_220 * 65, self.pg1) # # Inter epg denied without contract # pkt_inter_epg_220_to_221 = (Ether(src=self.pg0.remote_mac, dst=self.pg2.remote_mac) / IP(src=eps[0].ip4.address, dst=eps[2].ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_assert_no_replies(self.pg0, pkt_inter_epg_220_to_221) # # A uni-directional contract from EPG 220 -> 221 # acl = VppGbpAcl(self) rule = acl.create_rule(permit_deny=1, proto=17) rule2 = acl.create_rule(is_ipv6=1, permit_deny=1, proto=17) rule3 = acl.create_rule(permit_deny=1, proto=1) acl_index = acl.add_vpp_config([rule, rule2, rule3]) c1 = VppGbpContract( self, 400, epgs[0].sclass, epgs[1].sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c1.add_vpp_config() self.send_and_expect_bridged(eps[0].itf, pkt_inter_epg_220_to_221 * 65, eps[2].itf) pkt_inter_epg_220_to_222 = (Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src=eps[0].ip4.address, dst=eps[3].ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_assert_no_replies(eps[0].itf, pkt_inter_epg_220_to_222 * 65) # # ping router IP in different BD # pkt_router_ping_220_to_221 = (Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src=eps[0].ip4.address, dst=epgs[1].bvi_ip4.address) / ICMP(type='echo-request')) self.send_and_expect(self.pg0, [pkt_router_ping_220_to_221], self.pg0) pkt_router_ping_220_to_221 = (Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IPv6(src=eps[0].ip6.address, dst=epgs[1].bvi_ip6.address) / ICMPv6EchoRequest()) self.send_and_expect(self.pg0, [pkt_router_ping_220_to_221], self.pg0) # # contract for the return direction # c2 = VppGbpContract( self, 400, epgs[1].sclass, epgs[0].sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c2.add_vpp_config() self.send_and_expect_bridged(eps[0].itf, pkt_inter_epg_220_to_221 * 65, eps[2].itf) pkt_inter_epg_221_to_220 = (Ether(src=self.pg2.remote_mac, dst=self.pg0.remote_mac) / IP(src=eps[2].ip4.address, dst=eps[0].ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_expect_bridged(eps[2].itf, pkt_inter_epg_221_to_220 * 65, eps[0].itf) pkt_inter_epg_221_to_220 = (Ether(src=self.pg2.remote_mac, dst=str(self.router_mac)) / IP(src=eps[2].ip4.address, dst=eps[0].ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_expect_routed(eps[2].itf, pkt_inter_epg_221_to_220 * 65, eps[0].itf, str(self.router_mac)) pkt_inter_epg_221_to_220 = (Ether(src=self.pg2.remote_mac, dst=str(self.router_mac)) / IPv6(src=eps[2].ip6.address, dst=eps[0].ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_expect_routed6(eps[2].itf, pkt_inter_epg_221_to_220 * 65, eps[0].itf, str(self.router_mac)) # # contract between 220 and 222 uni-direction # c3 = VppGbpContract( self, 400, epgs[0].sclass, epgs[2].sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c3.add_vpp_config() self.send_and_expect(eps[0].itf, pkt_inter_epg_220_to_222 * 65, eps[3].itf) c3.remove_vpp_config() c1.remove_vpp_config() c2.remove_vpp_config() acl.remove_vpp_config() def test_gbp_bd_drop_flags(self): """ GBP BD drop flags """ # # IP tables # gt4 = VppIpTable(self, 1) gt4.add_vpp_config() gt6 = VppIpTable(self, 1, is_ip6=True) gt6.add_vpp_config() rd1 = VppGbpRouteDomain(self, 1, 401, gt4, gt6) rd1.add_vpp_config() # # a GBP bridge domain with a BVI only # bd1 = VppBridgeDomain(self, 1) bd1.add_vpp_config() gbd1 = VppGbpBridgeDomain(self, bd1, rd1, self.loop0, None, None, uu_drop=True, bm_drop=True) gbd1.add_vpp_config() self.logger.info(self.vapi.cli("sh bridge 1 detail")) self.logger.info(self.vapi.cli("sh gbp bridge")) # ... and has a /32 applied ip_addr = VppIpInterfaceAddress(self, gbd1.bvi, "10.0.0.128", 32) ip_addr.add_vpp_config() # # The Endpoint-group # epg_220 = VppGbpEndpointGroup(self, 220, 112, rd1, gbd1, None, self.loop0, "10.0.0.128", "2001:10::128", VppGbpEndpointRetention(2)) epg_220.add_vpp_config() ep = VppGbpEndpoint(self, self.pg0, epg_220, None, "10.0.0.127", "11.0.0.127", "2001:10::1", "3001::1") ep.add_vpp_config() # # send UU/BM packet from the local EP with UU drop and BM drop enabled # in bd # self.logger.info(self.vapi.cli("sh bridge 1 detail")) self.logger.info(self.vapi.cli("sh gbp bridge")) p_uu = (Ether(src=ep.mac, dst="00:11:11:11:11:11") / IP(dst="10.0.0.133", src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_assert_no_replies(ep.itf, [p_uu]) p_bm = (Ether(src=ep.mac, dst="ff:ff:ff:ff:ff:ff") / IP(dst="10.0.0.133", src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_assert_no_replies(ep.itf, [p_bm]) self.pg3.unconfig_ip4() self.logger.info(self.vapi.cli("sh int")) def test_gbp_bd_arp_flags(self): """ GBP BD arp flags """ # # IP tables # gt4 = VppIpTable(self, 1) gt4.add_vpp_config() gt6 = VppIpTable(self, 1, is_ip6=True) gt6.add_vpp_config() rd1 = VppGbpRouteDomain(self, 1, 401, gt4, gt6) rd1.add_vpp_config() # # Pg4 hosts the IP6 UU-flood VXLAN tunnel # self.pg4.config_ip4() self.pg4.resolve_arp() # # Add a mcast destination VXLAN-GBP tunnel for B&M traffic # tun_uu = VppVxlanGbpTunnel(self, self.pg4.local_ip4, "239.1.1.1", 88, mcast_itf=self.pg4) tun_uu.add_vpp_config() # # a GBP bridge domain with a BVI and a UU-flood interface # bd1 = VppBridgeDomain(self, 1) bd1.add_vpp_config() gbd1 = VppGbpBridgeDomain(self, bd1, rd1, self.loop0, tun_uu, None, ucast_arp=True) gbd1.add_vpp_config() # ... and has a /32 applied ip_addr = VppIpInterfaceAddress(self, gbd1.bvi, "10.0.0.128", 32) ip_addr.add_vpp_config() # # The Endpoint-group # epg_220 = VppGbpEndpointGroup(self, 220, 112, rd1, gbd1, None, self.loop0, "10.0.0.128", "2001:10::128", VppGbpEndpointRetention(2)) epg_220.add_vpp_config() ep = VppGbpEndpoint(self, self.pg0, epg_220, None, "10.0.0.127", "11.0.0.127", "2001:10::1", "3001::1") ep.add_vpp_config() # # send ARP packet from the local EP expect it on the uu interface # self.logger.info(self.vapi.cli("sh bridge 1 detail")) self.logger.info(self.vapi.cli("sh gbp bridge")) p_arp = (Ether(src=ep.mac, dst="ff:ff:ff:ff:ff:ff") / ARP(op="who-has", psrc=ep.ip4.address, pdst="10.0.0.99", hwsrc=ep.mac, hwdst="ff:ff:ff:ff:ff:ff")) self.send_and_expect(ep.itf, [p_arp], self.pg4) self.pg4.unconfig_ip4() def test_gbp_learn_vlan_l2(self): """ GBP L2 Endpoint w/ VLANs""" ep_flags = VppEnum.vl_api_gbp_endpoint_flags_t learnt = [{'mac': '00:00:11:11:11:01', 'ip': '10.0.0.1', 'ip6': '2001:10::2'}, {'mac': '00:00:11:11:11:02', 'ip': '10.0.0.2', 'ip6': '2001:10::3'}] # # IP tables # gt4 = VppIpTable(self, 1) gt4.add_vpp_config() gt6 = VppIpTable(self, 1, is_ip6=True) gt6.add_vpp_config() rd1 = VppGbpRouteDomain(self, 1, 401, gt4, gt6) rd1.add_vpp_config() # # Pg2 hosts the vxlan tunnel, hosts on pg2 to act as TEPs # self.pg2.config_ip4() self.pg2.resolve_arp() self.pg2.generate_remote_hosts(4) self.pg2.configure_ipv4_neighbors() self.pg3.config_ip4() self.pg3.resolve_arp() # # The EP will be on a vlan sub-interface # vlan_11 = VppDot1QSubint(self, self.pg0, 11) vlan_11.admin_up() self.vapi.l2_interface_vlan_tag_rewrite( sw_if_index=vlan_11.sw_if_index, vtr_op=L2_VTR_OP.L2_POP_1, push_dot1q=11) bd_uu_fwd = VppVxlanGbpTunnel(self, self.pg3.local_ip4, self.pg3.remote_ip4, 116) bd_uu_fwd.add_vpp_config() # # a GBP bridge domain with a BVI and a UU-flood interface # The BD is marked as do not learn, so no endpoints are ever # learnt in this BD. # bd1 = VppBridgeDomain(self, 1) bd1.add_vpp_config() gbd1 = VppGbpBridgeDomain(self, bd1, rd1, self.loop0, bd_uu_fwd, learn=False) gbd1.add_vpp_config() self.logger.info(self.vapi.cli("sh bridge 1 detail")) self.logger.info(self.vapi.cli("sh gbp bridge")) # ... and has a /32 applied ip_addr = VppIpInterfaceAddress(self, gbd1.bvi, "10.0.0.128", 32) ip_addr.add_vpp_config() # # The Endpoint-group in which we are learning endpoints # epg_220 = VppGbpEndpointGroup(self, 220, 441, rd1, gbd1, None, self.loop0, "10.0.0.128", "2001:10::128", VppGbpEndpointRetention(2)) epg_220.add_vpp_config() # # The VXLAN GBP tunnel is a bridge-port and has L2 endpoint # learning enabled # vx_tun_l2_1 = VppGbpVxlanTunnel( self, 99, bd1.bd_id, VppEnum.vl_api_gbp_vxlan_tunnel_mode_t.GBP_VXLAN_TUNNEL_MODE_L2, self.pg2.local_ip4) vx_tun_l2_1.add_vpp_config() # # A static endpoint that the learnt endpoints are trying to # talk to # ep = VppGbpEndpoint(self, vlan_11, epg_220, None, "10.0.0.127", "11.0.0.127", "2001:10::1", "3001::1") ep.add_vpp_config() self.assertTrue(find_route(self, ep.ip4.address, 32, table_id=1)) # # Send to the static EP # for ii, l in enumerate(learnt): # a packet with an sclass from a known EPG # arriving on an unknown TEP p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[1].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=99, gpid=441, flags=0x88) / Ether(src=l['mac'], dst=ep.mac) / IP(src=l['ip'], dst=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg2, [p], self.pg0) # # packet to EP has the EP's vlan tag # for rx in rxs: self.assertEqual(rx[Dot1Q].vlan, 11) # # the EP is not learnt since the BD setting prevents it # also no TEP too # self.assertFalse(find_gbp_endpoint(self, vx_tun_l2_1.sw_if_index, mac=l['mac'])) self.assertEqual(INDEX_INVALID, find_vxlan_gbp_tunnel( self, self.pg2.local_ip4, self.pg2.remote_hosts[1].ip4, 99)) self.assertEqual(len(self.vapi.gbp_endpoint_dump()), 1) # # static to remotes # we didn't learn the remotes so they are sent to the UU-fwd # for l in learnt: p = (Ether(src=ep.mac, dst=l['mac']) / Dot1Q(vlan=11) / IP(dst=l['ip'], src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 17, self.pg3) for rx in rxs: self.assertEqual(rx[IP].src, self.pg3.local_ip4) self.assertEqual(rx[IP].dst, self.pg3.remote_ip4) self.assertEqual(rx[UDP].dport, 48879) # the UDP source port is a random value for hashing self.assertEqual(rx[VXLAN].gpid, 441) self.assertEqual(rx[VXLAN].vni, 116) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) self.assertFalse(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) self.pg2.unconfig_ip4() self.pg3.unconfig_ip4() def test_gbp_learn_l3(self): """ GBP L3 Endpoint Learning """ self.vapi.cli("set logging class gbp level debug") ep_flags = VppEnum.vl_api_gbp_endpoint_flags_t routed_dst_mac = "00:0c:0c:0c:0c:0c" routed_src_mac = "00:22:bd:f8:19:ff" learnt = [{'mac': '00:00:11:11:11:02', 'ip': '10.0.1.2', 'ip6': '2001:10::2'}, {'mac': '00:00:11:11:11:03', 'ip': '10.0.1.3', 'ip6': '2001:10::3'}] # # IP tables # t4 = VppIpTable(self, 1) t4.add_vpp_config() t6 = VppIpTable(self, 1, True) t6.add_vpp_config() tun_ip4_uu = VppVxlanGbpTunnel(self, self.pg4.local_ip4, self.pg4.remote_ip4, 114) tun_ip6_uu = VppVxlanGbpTunnel(self, self.pg4.local_ip4, self.pg4.remote_ip4, 116) tun_ip4_uu.add_vpp_config() tun_ip6_uu.add_vpp_config() rd1 = VppGbpRouteDomain(self, 2, 401, t4, t6, tun_ip4_uu, tun_ip6_uu) rd1.add_vpp_config() self.loop0.set_mac(self.router_mac) # # Bind the BVI to the RD # VppIpInterfaceBind(self, self.loop0, t4).add_vpp_config() VppIpInterfaceBind(self, self.loop0, t6).add_vpp_config() # # Pg2 hosts the vxlan tunnel # hosts on pg2 to act as TEPs # pg3 is BD uu-fwd # pg4 is RD uu-fwd # self.pg2.config_ip4() self.pg2.resolve_arp() self.pg2.generate_remote_hosts(4) self.pg2.configure_ipv4_neighbors() self.pg3.config_ip4() self.pg3.resolve_arp() self.pg4.config_ip4() self.pg4.resolve_arp() # # a GBP bridge domain with a BVI and a UU-flood interface # bd1 = VppBridgeDomain(self, 1) bd1.add_vpp_config() gbd1 = VppGbpBridgeDomain(self, bd1, rd1, self.loop0, self.pg3) gbd1.add_vpp_config() self.logger.info(self.vapi.cli("sh bridge 1 detail")) self.logger.info(self.vapi.cli("sh gbp bridge")) self.logger.info(self.vapi.cli("sh gbp route")) # ... and has a /32 and /128 applied ip4_addr = VppIpInterfaceAddress(self, gbd1.bvi, "10.0.0.128", 32) ip4_addr.add_vpp_config() ip6_addr = VppIpInterfaceAddress(self, gbd1.bvi, "2001:10::128", 128) ip6_addr.add_vpp_config() # # The Endpoint-group in which we are learning endpoints # epg_220 = VppGbpEndpointGroup(self, 220, 441, rd1, gbd1, None, self.loop0, "10.0.0.128", "2001:10::128", VppGbpEndpointRetention(2)) epg_220.add_vpp_config() # # The VXLAN GBP tunnel is in L3 mode with learning enabled # vx_tun_l3 = VppGbpVxlanTunnel( self, 101, rd1.rd_id, VppEnum.vl_api_gbp_vxlan_tunnel_mode_t.GBP_VXLAN_TUNNEL_MODE_L3, self.pg2.local_ip4) vx_tun_l3.add_vpp_config() # # A static endpoint that the learnt endpoints are trying to # talk to # ep = VppGbpEndpoint(self, self.pg0, epg_220, None, "10.0.0.127", "11.0.0.127", "2001:10::1", "3001::1") ep.add_vpp_config() # # learn some remote IPv4 EPs # for ii, l in enumerate(learnt): # a packet with an sclass from a known EPG # arriving on an unknown TEP p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[1].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=101, gpid=441, flags=0x88) / Ether(src=l['mac'], dst="00:00:00:11:11:11") / IP(src=l['ip'], dst=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rx = self.send_and_expect(self.pg2, [p], self.pg0) # the new TEP tep1_sw_if_index = find_vxlan_gbp_tunnel( self, self.pg2.local_ip4, self.pg2.remote_hosts[1].ip4, vx_tun_l3.vni) self.assertNotEqual(INDEX_INVALID, tep1_sw_if_index) # endpoint learnt via the parent GBP-vxlan interface self.assertTrue(find_gbp_endpoint(self, vx_tun_l3._sw_if_index, ip=l['ip'])) # # Static IPv4 EP replies to learnt # for l in learnt: p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IP(dst=l['ip'], src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 1, self.pg2) for rx in rxs: self.assertEqual(rx[IP].src, self.pg2.local_ip4) self.assertEqual(rx[IP].dst, self.pg2.remote_hosts[1].ip4) self.assertEqual(rx[UDP].dport, 48879) # the UDP source port is a random value for hashing self.assertEqual(rx[VXLAN].gpid, 441) self.assertEqual(rx[VXLAN].vni, 101) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertEqual(inner[Ether].src, routed_src_mac) self.assertEqual(inner[Ether].dst, routed_dst_mac) self.assertEqual(inner[IP].src, ep.ip4.address) self.assertEqual(inner[IP].dst, l['ip']) for l in learnt: self.assertFalse(find_gbp_endpoint(self, tep1_sw_if_index, ip=l['ip'])) # # learn some remote IPv6 EPs # for ii, l in enumerate(learnt): # a packet with an sclass from a known EPG # arriving on an unknown TEP p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[1].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=101, gpid=441, flags=0x88) / Ether(src=l['mac'], dst="00:00:00:11:11:11") / IPv6(src=l['ip6'], dst=ep.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rx = self.send_and_expect(self.pg2, [p], self.pg0) # the new TEP tep1_sw_if_index = find_vxlan_gbp_tunnel( self, self.pg2.local_ip4, self.pg2.remote_hosts[1].ip4, vx_tun_l3.vni) self.assertNotEqual(INDEX_INVALID, tep1_sw_if_index) self.logger.info(self.vapi.cli("show gbp bridge")) self.logger.info(self.vapi.cli("show vxlan-gbp tunnel")) self.logger.info(self.vapi.cli("show gbp vxlan")) self.logger.info(self.vapi.cli("show int addr")) # endpoint learnt via the TEP self.assertTrue(find_gbp_endpoint(self, ip=l['ip6'])) self.logger.info(self.vapi.cli("show gbp endpoint")) self.logger.info(self.vapi.cli("show ip fib index 1 %s" % l['ip'])) # # Static EP replies to learnt # for l in learnt: p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IPv6(dst=l['ip6'], src=ep.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * NUM_PKTS, self.pg2) for rx in rxs: self.assertEqual(rx[IP].src, self.pg2.local_ip4) self.assertEqual(rx[IP].dst, self.pg2.remote_hosts[1].ip4) self.assertEqual(rx[UDP].dport, 48879) # the UDP source port is a random value for hashing self.assertEqual(rx[VXLAN].gpid, 441) self.assertEqual(rx[VXLAN].vni, 101) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertEqual(inner[Ether].src, routed_src_mac) self.assertEqual(inner[Ether].dst, routed_dst_mac) self.assertEqual(inner[IPv6].src, ep.ip6.address) self.assertEqual(inner[IPv6].dst, l['ip6']) self.logger.info(self.vapi.cli("sh gbp endpoint")) for l in learnt: self.wait_for_ep_timeout(ip=l['ip']) # # Static sends to unknown EP with no route # p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IP(dst="10.0.0.99", src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_assert_no_replies(self.pg0, [p]) # # Add a route to static EP's v4 and v6 subnet # se_10_24 = VppGbpSubnet( self, rd1, "10.0.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_TRANSPORT) se_10_24.add_vpp_config() # # static pings router # p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IP(dst=epg_220.bvi_ip4.address, src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_expect(self.pg0, p * NUM_PKTS, self.pg0) p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IPv6(dst=epg_220.bvi_ip6.address, src=ep.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) self.send_and_expect(self.pg0, p * NUM_PKTS, self.pg0) # # packets to address in the subnet are sent on the uu-fwd # p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IP(dst="10.0.0.99", src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, [p], self.pg4) for rx in rxs: self.assertEqual(rx[IP].src, self.pg4.local_ip4) self.assertEqual(rx[IP].dst, self.pg4.remote_ip4) self.assertEqual(rx[UDP].dport, 48879) # the UDP source port is a random value for hashing self.assertEqual(rx[VXLAN].gpid, 441) self.assertEqual(rx[VXLAN].vni, 114) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # policy is not applied to packets sent to the uu-fwd interfaces self.assertFalse(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) # # learn some remote IPv4 EPs # for ii, l in enumerate(learnt): # a packet with an sclass from a known EPG # arriving on an unknown TEP p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[2].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=101, gpid=441, flags=0x88) / Ether(src=l['mac'], dst="00:00:00:11:11:11") / IP(src=l['ip'], dst=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rx = self.send_and_expect(self.pg2, [p], self.pg0) # the new TEP tep1_sw_if_index = find_vxlan_gbp_tunnel( self, self.pg2.local_ip4, self.pg2.remote_hosts[2].ip4, vx_tun_l3.vni) self.assertNotEqual(INDEX_INVALID, tep1_sw_if_index) # endpoint learnt via the parent GBP-vxlan interface self.assertTrue(find_gbp_endpoint(self, vx_tun_l3._sw_if_index, ip=l['ip'])) # # Add a remote endpoint from the API # rep_88 = VppGbpEndpoint(self, vx_tun_l3, epg_220, None, "10.0.0.88", "11.0.0.88", "2001:10::88", "3001::88", ep_flags.GBP_API_ENDPOINT_FLAG_REMOTE, self.pg2.local_ip4, self.pg2.remote_hosts[2].ip4, mac=None) rep_88.add_vpp_config() # # Add a remote endpoint from the API that matches an existing one # this is a lower priority, hence the packet is sent to the DP leanrt # TEP # rep_2 = VppGbpEndpoint(self, vx_tun_l3, epg_220, None, learnt[0]['ip'], "11.0.0.101", learnt[0]['ip6'], "3001::101", ep_flags.GBP_API_ENDPOINT_FLAG_REMOTE, self.pg2.local_ip4, self.pg2.remote_hosts[1].ip4, mac=None) rep_2.add_vpp_config() # # Add a route to the learned EP's v4 subnet # packets should be send on the v4/v6 uu=fwd interface resp. # se_10_1_24 = VppGbpSubnet( self, rd1, "10.0.1.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_TRANSPORT) se_10_1_24.add_vpp_config() self.logger.info(self.vapi.cli("show gbp endpoint")) ips = ["10.0.0.88", learnt[0]['ip']] for ip in ips: p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IP(dst=ip, src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * NUM_PKTS, self.pg2) for rx in rxs: self.assertEqual(rx[IP].src, self.pg2.local_ip4) self.assertEqual(rx[IP].dst, self.pg2.remote_hosts[2].ip4) self.assertEqual(rx[UDP].dport, 48879) # the UDP source port is a random value for hashing self.assertEqual(rx[VXLAN].gpid, 441) self.assertEqual(rx[VXLAN].vni, 101) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertEqual(inner[Ether].src, routed_src_mac) self.assertEqual(inner[Ether].dst, routed_dst_mac) self.assertEqual(inner[IP].src, ep.ip4.address) self.assertEqual(inner[IP].dst, ip) # # remove the API remote EPs, only API sourced is gone, the DP # learnt one remains # rep_88.remove_vpp_config() rep_2.remove_vpp_config() self.assertTrue(find_gbp_endpoint(self, ip=rep_2.ip4.address)) p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IP(src=ep.ip4.address, dst=rep_2.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, [p], self.pg2) self.assertFalse(find_gbp_endpoint(self, ip=rep_88.ip4.address)) p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IP(src=ep.ip4.address, dst=rep_88.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, [p], self.pg4) # # to appease the testcase we cannot have the registered EP still # present (because it's DP learnt) when the TC ends so wait until # it is removed # self.wait_for_ep_timeout(ip=rep_88.ip4.address) self.wait_for_ep_timeout(ip=rep_2.ip4.address) # # Same as above, learn a remote EP via CP and DP # this time remove the DP one first. expect the CP data to remain # rep_3 = VppGbpEndpoint(self, vx_tun_l3, epg_220, None, "10.0.1.4", "11.0.0.103", "2001::10:3", "3001::103", ep_flags.GBP_API_ENDPOINT_FLAG_REMOTE, self.pg2.local_ip4, self.pg2.remote_hosts[1].ip4, mac=None) rep_3.add_vpp_config() p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[2].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=101, gpid=441, flags=0x88) / Ether(src=l['mac'], dst="00:00:00:11:11:11") / IP(src="10.0.1.4", dst=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg2, p * NUM_PKTS, self.pg0) self.assertTrue(find_gbp_endpoint(self, vx_tun_l3._sw_if_index, ip=rep_3.ip4.address, tep=[self.pg2.local_ip4, self.pg2.remote_hosts[2].ip4])) p = (Ether(src=ep.mac, dst=self.loop0.local_mac) / IP(dst="10.0.1.4", src=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * NUM_PKTS, self.pg2) # host 2 is the DP learned TEP for rx in rxs: self.assertEqual(rx[IP].src, self.pg2.local_ip4) self.assertEqual(rx[IP].dst, self.pg2.remote_hosts[2].ip4) self.wait_for_ep_timeout(ip=rep_3.ip4.address, tep=[self.pg2.local_ip4, self.pg2.remote_hosts[2].ip4]) rxs = self.send_and_expect(self.pg0, p * NUM_PKTS, self.pg2) # host 1 is the CP learned TEP for rx in rxs: self.assertEqual(rx[IP].src, self.pg2.local_ip4) self.assertEqual(rx[IP].dst, self.pg2.remote_hosts[1].ip4) # # shutdown with learnt endpoint present # p = (Ether(src=self.pg2.remote_mac, dst=self.pg2.local_mac) / IP(src=self.pg2.remote_hosts[1].ip4, dst=self.pg2.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=101, gpid=441, flags=0x88) / Ether(src=l['mac'], dst="00:00:00:11:11:11") / IP(src=learnt[1]['ip'], dst=ep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rx = self.send_and_expect(self.pg2, [p], self.pg0) # endpoint learnt via the parent GBP-vxlan interface self.assertTrue(find_gbp_endpoint(self, vx_tun_l3._sw_if_index, ip=l['ip'])) # # TODO # remote endpoint becomes local # self.pg2.unconfig_ip4() self.pg3.unconfig_ip4() self.pg4.unconfig_ip4() def test_gbp_redirect(self): """ GBP Endpoint Redirect """ self.vapi.cli("set logging class gbp level debug") ep_flags = VppEnum.vl_api_gbp_endpoint_flags_t routed_dst_mac = "00:0c:0c:0c:0c:0c" routed_src_mac = "00:22:bd:f8:19:ff" learnt = [{'mac': '00:00:11:11:11:02', 'ip': '10.0.1.2', 'ip6': '2001:10::2'}, {'mac': '00:00:11:11:11:03', 'ip': '10.0.1.3', 'ip6': '2001:10::3'}] # # IP tables # t4 = VppIpTable(self, 1) t4.add_vpp_config() t6 = VppIpTable(self, 1, True) t6.add_vpp_config() rd1 = VppGbpRouteDomain(self, 2, 402, t4, t6) rd1.add_vpp_config() self.loop0.set_mac(self.router_mac) # # Bind the BVI to the RD # VppIpInterfaceBind(self, self.loop0, t4).add_vpp_config() VppIpInterfaceBind(self, self.loop0, t6).add_vpp_config() # # Pg7 hosts a BD's UU-fwd # self.pg7.config_ip4() self.pg7.resolve_arp() # # a GBP bridge domains for the EPs # bd1 = VppBridgeDomain(self, 1) bd1.add_vpp_config() gbd1 = VppGbpBridgeDomain(self, bd1, rd1, self.loop0) gbd1.add_vpp_config() bd2 = VppBridgeDomain(self, 2) bd2.add_vpp_config() gbd2 = VppGbpBridgeDomain(self, bd2, rd1, self.loop1) gbd2.add_vpp_config() # ... and has a /32 and /128 applied ip4_addr = VppIpInterfaceAddress(self, gbd1.bvi, "10.0.0.128", 32) ip4_addr.add_vpp_config() ip6_addr = VppIpInterfaceAddress(self, gbd1.bvi, "2001:10::128", 128) ip6_addr.add_vpp_config() ip4_addr = VppIpInterfaceAddress(self, gbd2.bvi, "10.0.1.128", 32) ip4_addr.add_vpp_config() ip6_addr = VppIpInterfaceAddress(self, gbd2.bvi, "2001:11::128", 128) ip6_addr.add_vpp_config() # # The Endpoint-groups in which we are learning endpoints # epg_220 = VppGbpEndpointGroup(self, 220, 440, rd1, gbd1, None, gbd1.bvi, "10.0.0.128", "2001:10::128", VppGbpEndpointRetention(2)) epg_220.add_vpp_config() epg_221 = VppGbpEndpointGroup(self, 221, 441, rd1, gbd2, None, gbd2.bvi, "10.0.1.128", "2001:11::128", VppGbpEndpointRetention(2)) epg_221.add_vpp_config() epg_222 = VppGbpEndpointGroup(self, 222, 442, rd1, gbd1, None, gbd1.bvi, "10.0.2.128", "2001:12::128", VppGbpEndpointRetention(2)) epg_222.add_vpp_config() # # a GBP bridge domains for the SEPs # bd_uu1 = VppVxlanGbpTunnel(self, self.pg7.local_ip4, self.pg7.remote_ip4, 116) bd_uu1.add_vpp_config() bd_uu2 = VppVxlanGbpTunnel(self, self.pg7.local_ip4, self.pg7.remote_ip4, 117) bd_uu2.add_vpp_config() bd3 = VppBridgeDomain(self, 3) bd3.add_vpp_config() gbd3 = VppGbpBridgeDomain(self, bd3, rd1, self.loop2, bd_uu1, learn=False) gbd3.add_vpp_config() bd4 = VppBridgeDomain(self, 4) bd4.add_vpp_config() gbd4 = VppGbpBridgeDomain(self, bd4, rd1, self.loop3, bd_uu2, learn=False) gbd4.add_vpp_config() # # EPGs in which the service endpoints exist # epg_320 = VppGbpEndpointGroup(self, 320, 550, rd1, gbd3, None, gbd1.bvi, "12.0.0.128", "4001:10::128", VppGbpEndpointRetention(2)) epg_320.add_vpp_config() epg_321 = VppGbpEndpointGroup(self, 321, 551, rd1, gbd4, None, gbd2.bvi, "12.0.1.128", "4001:11::128", VppGbpEndpointRetention(2)) epg_321.add_vpp_config() # # three local endpoints # ep1 = VppGbpEndpoint(self, self.pg0, epg_220, None, "10.0.0.1", "11.0.0.1", "2001:10::1", "3001:10::1") ep1.add_vpp_config() ep2 = VppGbpEndpoint(self, self.pg1, epg_221, None, "10.0.1.1", "11.0.1.1", "2001:11::1", "3001:11::1") ep2.add_vpp_config() ep3 = VppGbpEndpoint(self, self.pg2, epg_222, None, "10.0.2.2", "11.0.2.2", "2001:12::1", "3001:12::1") ep3.add_vpp_config() # # service endpoints # sep1 = VppGbpEndpoint(self, self.pg3, epg_320, None, "12.0.0.1", "13.0.0.1", "4001:10::1", "5001:10::1") sep1.add_vpp_config() sep2 = VppGbpEndpoint(self, self.pg4, epg_320, None, "12.0.0.2", "13.0.0.2", "4001:10::2", "5001:10::2") sep2.add_vpp_config() sep3 = VppGbpEndpoint(self, self.pg5, epg_321, None, "12.0.1.1", "13.0.1.1", "4001:11::1", "5001:11::1") sep3.add_vpp_config() # this EP is not installed immediately sep4 = VppGbpEndpoint(self, self.pg6, epg_321, None, "12.0.1.2", "13.0.1.2", "4001:11::2", "5001:11::2") # # an L2 switch packet between local EPs in different EPGs # different dest ports on each so the are LB hashed differently # p4 = [(Ether(src=ep1.mac, dst=ep3.mac) / IP(src=ep1.ip4.address, dst=ep3.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)), (Ether(src=ep3.mac, dst=ep1.mac) / IP(src=ep3.ip4.address, dst=ep1.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100))] p6 = [(Ether(src=ep1.mac, dst=ep3.mac) / IPv6(src=ep1.ip6.address, dst=ep3.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)), (Ether(src=ep3.mac, dst=ep1.mac) / IPv6(src=ep3.ip6.address, dst=ep1.ip6.address) / UDP(sport=1234, dport=1230) / Raw('\xa5' * 100))] # should be dropped since no contract yet self.send_and_assert_no_replies(self.pg0, [p4[0]]) self.send_and_assert_no_replies(self.pg0, [p6[0]]) # # Add a contract with a rule to load-balance redirect via SEP1 and SEP2 # one of the next-hops is via an EP that is not known # acl = VppGbpAcl(self) rule4 = acl.create_rule(permit_deny=1, proto=17) rule6 = acl.create_rule(is_ipv6=1, permit_deny=1, proto=17) acl_index = acl.add_vpp_config([rule4, rule6]) # # test the src-ip hash mode # c1 = VppGbpContract( self, 402, epg_220.sclass, epg_222.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [VppGbpContractNextHop(sep1.vmac, sep1.epg.bd, sep1.ip4, sep1.epg.rd), VppGbpContractNextHop(sep2.vmac, sep2.epg.bd, sep2.ip4, sep2.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [VppGbpContractNextHop(sep3.vmac, sep3.epg.bd, sep3.ip6, sep3.epg.rd), VppGbpContractNextHop(sep4.vmac, sep4.epg.bd, sep4.ip6, sep4.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]) c1.add_vpp_config() c2 = VppGbpContract( self, 402, epg_222.sclass, epg_220.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [VppGbpContractNextHop(sep1.vmac, sep1.epg.bd, sep1.ip4, sep1.epg.rd), VppGbpContractNextHop(sep2.vmac, sep2.epg.bd, sep2.ip4, sep2.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [VppGbpContractNextHop(sep3.vmac, sep3.epg.bd, sep3.ip6, sep3.epg.rd), VppGbpContractNextHop(sep4.vmac, sep4.epg.bd, sep4.ip6, sep4.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]) c2.add_vpp_config() # # send again with the contract preset, now packets arrive # at SEP1 or SEP2 depending on the hashing # rxs = self.send_and_expect(self.pg0, p4[0] * 17, sep1.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep1.mac) self.assertEqual(rx[IP].src, ep1.ip4.address) self.assertEqual(rx[IP].dst, ep3.ip4.address) rxs = self.send_and_expect(self.pg2, p4[1] * 17, sep2.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep2.mac) self.assertEqual(rx[IP].src, ep3.ip4.address) self.assertEqual(rx[IP].dst, ep1.ip4.address) rxs = self.send_and_expect(self.pg0, p6[0] * 17, self.pg7) for rx in rxs: self.assertEqual(rx[Ether].src, self.pg7.local_mac) self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) self.assertEqual(rx[VXLAN].vni, 117) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # redirect policy has been applied self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertEqual(inner[Ether].src, routed_src_mac) self.assertEqual(inner[Ether].dst, sep4.mac) self.assertEqual(inner[IPv6].src, ep1.ip6.address) self.assertEqual(inner[IPv6].dst, ep3.ip6.address) rxs = self.send_and_expect(self.pg2, p6[1] * 17, sep3.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep3.mac) self.assertEqual(rx[IPv6].src, ep3.ip6.address) self.assertEqual(rx[IPv6].dst, ep1.ip6.address) # # programme the unknown EP # sep4.add_vpp_config() rxs = self.send_and_expect(self.pg0, p6[0] * 17, sep4.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep4.mac) self.assertEqual(rx[IPv6].src, ep1.ip6.address) self.assertEqual(rx[IPv6].dst, ep3.ip6.address) # # and revert back to unprogrammed # sep4.remove_vpp_config() rxs = self.send_and_expect(self.pg0, p6[0] * 17, self.pg7) for rx in rxs: self.assertEqual(rx[Ether].src, self.pg7.local_mac) self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) self.assertEqual(rx[VXLAN].vni, 117) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # redirect policy has been applied self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertEqual(inner[Ether].src, routed_src_mac) self.assertEqual(inner[Ether].dst, sep4.mac) self.assertEqual(inner[IPv6].src, ep1.ip6.address) self.assertEqual(inner[IPv6].dst, ep3.ip6.address) c1.remove_vpp_config() c2.remove_vpp_config() # # test the symmetric hash mode # c1 = VppGbpContract( self, 402, epg_220.sclass, epg_222.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SYMMETRIC, [VppGbpContractNextHop(sep1.vmac, sep1.epg.bd, sep1.ip4, sep1.epg.rd), VppGbpContractNextHop(sep2.vmac, sep2.epg.bd, sep2.ip4, sep2.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SYMMETRIC, [VppGbpContractNextHop(sep3.vmac, sep3.epg.bd, sep3.ip6, sep3.epg.rd), VppGbpContractNextHop(sep4.vmac, sep4.epg.bd, sep4.ip6, sep4.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]) c1.add_vpp_config() c2 = VppGbpContract( self, 402, epg_222.sclass, epg_220.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SYMMETRIC, [VppGbpContractNextHop(sep1.vmac, sep1.epg.bd, sep1.ip4, sep1.epg.rd), VppGbpContractNextHop(sep2.vmac, sep2.epg.bd, sep2.ip4, sep2.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SYMMETRIC, [VppGbpContractNextHop(sep3.vmac, sep3.epg.bd, sep3.ip6, sep3.epg.rd), VppGbpContractNextHop(sep4.vmac, sep4.epg.bd, sep4.ip6, sep4.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]) c2.add_vpp_config() # # send again with the contract preset, now packets arrive # at SEP1 for both directions # rxs = self.send_and_expect(self.pg0, p4[0] * 17, sep1.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep1.mac) self.assertEqual(rx[IP].src, ep1.ip4.address) self.assertEqual(rx[IP].dst, ep3.ip4.address) rxs = self.send_and_expect(self.pg2, p4[1] * 17, sep1.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep1.mac) self.assertEqual(rx[IP].src, ep3.ip4.address) self.assertEqual(rx[IP].dst, ep1.ip4.address) # # programme the unknown EP for the L3 tests # sep4.add_vpp_config() # # an L3 switch packet between local EPs in different EPGs # different dest ports on each so the are LB hashed differently # p4 = [(Ether(src=ep1.mac, dst=str(self.router_mac)) / IP(src=ep1.ip4.address, dst=ep2.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)), (Ether(src=ep2.mac, dst=str(self.router_mac)) / IP(src=ep2.ip4.address, dst=ep1.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100))] p6 = [(Ether(src=ep1.mac, dst=str(self.router_mac)) / IPv6(src=ep1.ip6.address, dst=ep2.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)), (Ether(src=ep2.mac, dst=str(self.router_mac)) / IPv6(src=ep2.ip6.address, dst=ep1.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100))] c3 = VppGbpContract( self, 402, epg_220.sclass, epg_221.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SYMMETRIC, [VppGbpContractNextHop(sep1.vmac, sep1.epg.bd, sep1.ip4, sep1.epg.rd), VppGbpContractNextHop(sep2.vmac, sep2.epg.bd, sep2.ip4, sep2.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SYMMETRIC, [VppGbpContractNextHop(sep3.vmac, sep3.epg.bd, sep3.ip6, sep3.epg.rd), VppGbpContractNextHop(sep4.vmac, sep4.epg.bd, sep4.ip6, sep4.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]) c3.add_vpp_config() rxs = self.send_and_expect(self.pg0, p4[0] * 17, sep1.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep1.mac) self.assertEqual(rx[IP].src, ep1.ip4.address) self.assertEqual(rx[IP].dst, ep2.ip4.address) # # learn a remote EP in EPG 221 # packets coming from unknown remote EPs will be leant & redirected # vx_tun_l3 = VppGbpVxlanTunnel( self, 444, rd1.rd_id, VppEnum.vl_api_gbp_vxlan_tunnel_mode_t.GBP_VXLAN_TUNNEL_MODE_L3, self.pg2.local_ip4) vx_tun_l3.add_vpp_config() c4 = VppGbpContract( self, 402, epg_221.sclass, epg_220.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [VppGbpContractNextHop(sep1.vmac, sep1.epg.bd, sep1.ip4, sep1.epg.rd), VppGbpContractNextHop(sep2.vmac, sep2.epg.bd, sep2.ip4, sep2.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [VppGbpContractNextHop(sep3.vmac, sep3.epg.bd, sep3.ip6, sep3.epg.rd), VppGbpContractNextHop(sep4.vmac, sep4.epg.bd, sep4.ip6, sep4.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]) c4.add_vpp_config() p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=444, gpid=441, flags=0x88) / Ether(src="00:22:22:22:22:33", dst=str(self.router_mac)) / IP(src="10.0.0.88", dst=ep1.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) # unknown remote EP to local EP redirected rxs = self.send_and_expect(self.pg7, [p], sep1.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep1.mac) self.assertEqual(rx[IP].src, "10.0.0.88") self.assertEqual(rx[IP].dst, ep1.ip4.address) # endpoint learnt via the parent GBP-vxlan interface self.assertTrue(find_gbp_endpoint(self, vx_tun_l3._sw_if_index, ip="10.0.0.88")) p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=444, gpid=441, flags=0x88) / Ether(src="00:22:22:22:22:33", dst=str(self.router_mac)) / IPv6(src="2001:10::88", dst=ep1.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) # unknown remote EP to local EP redirected (ipv6) rxs = self.send_and_expect(self.pg7, [p], sep3.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep3.mac) self.assertEqual(rx[IPv6].src, "2001:10::88") self.assertEqual(rx[IPv6].dst, ep1.ip6.address) # endpoint learnt via the parent GBP-vxlan interface self.assertTrue(find_gbp_endpoint(self, vx_tun_l3._sw_if_index, ip="2001:10::88")) # # L3 switch from local to remote EP # p4 = [(Ether(src=ep1.mac, dst=str(self.router_mac)) / IP(src=ep1.ip4.address, dst="10.0.0.88") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100))] p6 = [(Ether(src=ep1.mac, dst=str(self.router_mac)) / IPv6(src=ep1.ip6.address, dst="2001:10::88") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100))] rxs = self.send_and_expect(self.pg0, p4[0] * 17, sep1.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep1.mac) self.assertEqual(rx[IP].src, ep1.ip4.address) self.assertEqual(rx[IP].dst, "10.0.0.88") rxs = self.send_and_expect(self.pg0, p6[0] * 17, sep4.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep4.mac) self.assertEqual(rx[IPv6].src, ep1.ip6.address) self.assertEqual(rx[IPv6].dst, "2001:10::88") # # test the dst-ip hash mode # c5 = VppGbpContract( self, 402, epg_220.sclass, epg_221.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_DST_IP, [VppGbpContractNextHop(sep1.vmac, sep1.epg.bd, sep1.ip4, sep1.epg.rd), VppGbpContractNextHop(sep2.vmac, sep2.epg.bd, sep2.ip4, sep2.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_DST_IP, [VppGbpContractNextHop(sep3.vmac, sep3.epg.bd, sep3.ip6, sep3.epg.rd), VppGbpContractNextHop(sep4.vmac, sep4.epg.bd, sep4.ip6, sep4.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]) c5.add_vpp_config() rxs = self.send_and_expect(self.pg0, p4[0] * 17, sep1.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep1.mac) self.assertEqual(rx[IP].src, ep1.ip4.address) self.assertEqual(rx[IP].dst, "10.0.0.88") rxs = self.send_and_expect(self.pg0, p6[0] * 17, sep3.itf) for rx in rxs: self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep3.mac) self.assertEqual(rx[IPv6].src, ep1.ip6.address) self.assertEqual(rx[IPv6].dst, "2001:10::88") # # a programmed remote SEP in EPG 320 # # gbp vxlan tunnel for the remote SEP vx_tun_l3_sep = VppGbpVxlanTunnel( self, 555, rd1.rd_id, VppEnum.vl_api_gbp_vxlan_tunnel_mode_t.GBP_VXLAN_TUNNEL_MODE_L3, self.pg2.local_ip4) vx_tun_l3_sep.add_vpp_config() # remote SEP sep5 = VppGbpEndpoint(self, vx_tun_l3_sep, epg_320, None, "12.0.0.10", "13.0.0.10", "4001:10::10", "5001:10::10", ep_flags.GBP_API_ENDPOINT_FLAG_REMOTE, self.pg7.local_ip4, self.pg7.remote_ip4, mac=None) sep5.add_vpp_config() # # local l3out redirect tests # # add local l3out # the external bd self.loop4.set_mac(self.router_mac) VppIpInterfaceBind(self, self.loop4, t4).add_vpp_config() VppIpInterfaceBind(self, self.loop4, t6).add_vpp_config() ebd = VppBridgeDomain(self, 100) ebd.add_vpp_config() gebd = VppGbpBridgeDomain(self, ebd, rd1, self.loop4, None, None) gebd.add_vpp_config() # the external epg eepg = VppGbpEndpointGroup(self, 888, 765, rd1, gebd, None, gebd.bvi, "10.1.0.128", "2001:10:1::128", VppGbpEndpointRetention(2)) eepg.add_vpp_config() # add subnets to BVI VppIpInterfaceAddress( self, gebd.bvi, "10.1.0.128", 24).add_vpp_config() VppIpInterfaceAddress( self, gebd.bvi, "2001:10:1::128", 64).add_vpp_config() # ... which are L3-out subnets VppGbpSubnet(self, rd1, "10.1.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=765).add_vpp_config() VppGbpSubnet(self, rd1, "2001:10:1::128", 64, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=765).add_vpp_config() # external endpoints VppL2Vtr(self, self.vlan_100, L2_VTR_OP.L2_POP_1).add_vpp_config() eep1 = VppGbpEndpoint(self, self.vlan_100, eepg, None, "10.1.0.1", "11.1.0.1", "2001:10:1::1", "3001:10:1::1", ep_flags.GBP_API_ENDPOINT_FLAG_EXTERNAL) eep1.add_vpp_config() VppL2Vtr(self, self.vlan_101, L2_VTR_OP.L2_POP_1).add_vpp_config() eep2 = VppGbpEndpoint(self, self.vlan_101, eepg, None, "10.1.0.2", "11.1.0.2", "2001:10:1::2", "3001:10:1::2", ep_flags.GBP_API_ENDPOINT_FLAG_EXTERNAL) eep2.add_vpp_config() # external subnets reachable though eep1 and eep2 respectively VppIpRoute(self, "10.220.0.0", 24, [VppRoutePath(eep1.ip4.address, eep1.epg.bvi.sw_if_index)], table_id=t4.table_id).add_vpp_config() VppGbpSubnet(self, rd1, "10.220.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4220).add_vpp_config() VppIpRoute(self, "10:220::", 64, [VppRoutePath(eep1.ip6.address, eep1.epg.bvi.sw_if_index)], table_id=t6.table_id).add_vpp_config() VppGbpSubnet(self, rd1, "10:220::", 64, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4220).add_vpp_config() VppIpRoute(self, "10.221.0.0", 24, [VppRoutePath(eep2.ip4.address, eep2.epg.bvi.sw_if_index)], table_id=t4.table_id).add_vpp_config() VppGbpSubnet(self, rd1, "10.221.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4221).add_vpp_config() VppIpRoute(self, "10:221::", 64, [VppRoutePath(eep2.ip6.address, eep2.epg.bvi.sw_if_index)], table_id=t6.table_id).add_vpp_config() VppGbpSubnet(self, rd1, "10:221::", 64, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4221).add_vpp_config() # # l3out redirect to remote (known, then unknown) SEP # # packets from 1 external subnet to the other p = [(Ether(src=eep1.mac, dst=self.router_mac) / Dot1Q(vlan=100) / IP(src="10.220.0.17", dst="10.221.0.65") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)), (Ether(src=eep1.mac, dst=self.router_mac) / Dot1Q(vlan=100) / IPv6(src="10:220::17", dst="10:221::65") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100))] # packets should be dropped in absence of contract self.send_and_assert_no_replies(self.pg0, p) # contract redirecting to sep5 VppGbpContract( self, 402, 4220, 4221, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_DST_IP, [VppGbpContractNextHop(sep5.vmac, sep5.epg.bd, sep5.ip4, sep5.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_DST_IP, [VppGbpContractNextHop(sep5.vmac, sep5.epg.bd, sep5.ip6, sep5.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]).add_vpp_config() rxs = self.send_and_expect(self.pg0, p, self.pg7) for rx, tx in zip(rxs, p): self.assertEqual(rx[Ether].src, self.pg7.local_mac) self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) # this should use the programmed remote leaf TEP self.assertEqual(rx[VXLAN].vni, 555) self.assertEqual(rx[VXLAN].gpid, 4220) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # redirect policy has been applied self.assertTrue(rx[VXLAN].gpflags.A) self.assertTrue(rx[VXLAN].gpflags.D) rxip = rx[VXLAN][Ether].payload txip = tx[Dot1Q].payload self.assertEqual(rxip.src, txip.src) self.assertEqual(rxip.dst, txip.dst) # remote SEP: it is now an unknown remote SEP and should go # to spine proxy sep5.remove_vpp_config() rxs = self.send_and_expect(self.pg0, p, self.pg7) for rx, tx in zip(rxs, p): self.assertEqual(rx[Ether].src, self.pg7.local_mac) self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) # this should use the spine proxy TEP self.assertEqual(rx[VXLAN].vni, epg_320.bd.uu_fwd.vni) self.assertEqual(rx[VXLAN].gpid, 4220) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # redirect policy has been applied self.assertTrue(rx[VXLAN].gpflags.A) self.assertTrue(rx[VXLAN].gpflags.D) rxip = rx[VXLAN][Ether].payload txip = tx[Dot1Q].payload self.assertEqual(rxip.src, txip.src) self.assertEqual(rxip.dst, txip.dst) # # l3out redirect to local SEP # # change the contract between l3out to redirect to local SEPs # instead of remote SEP VppGbpContract( self, 402, 4220, 4221, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_DST_IP, [VppGbpContractNextHop(sep1.vmac, sep1.epg.bd, sep1.ip4, sep1.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_DST_IP, [VppGbpContractNextHop(sep1.vmac, sep1.epg.bd, sep1.ip6, sep1.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]).add_vpp_config() rxs = self.send_and_expect(self.pg0, p, sep1.itf) for rx, tx in zip(rxs, p): self.assertEqual(rx[Ether].src, routed_src_mac) self.assertEqual(rx[Ether].dst, sep1.mac) rxip = rx[Ether].payload txip = tx[Ether].payload self.assertEqual(rxip.src, txip.src) self.assertEqual(rxip.dst, txip.dst) # # redirect remote EP to remote (known then unknown) SEP # # remote SEP known again sep5.add_vpp_config() # contract to redirect to learnt SEP VppGbpContract( self, 402, epg_221.sclass, epg_222.sclass, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_DST_IP, [VppGbpContractNextHop(sep5.vmac, sep5.epg.bd, sep5.ip4, sep5.epg.rd)]), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_REDIRECT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_DST_IP, [VppGbpContractNextHop(sep5.vmac, sep5.epg.bd, sep5.ip6, sep5.epg.rd)])], [ETH_P_IP, ETH_P_IPV6]).add_vpp_config() # packets from unknown EP 221 to known EP in EPG 222 # should be redirected to known remote SEP base = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=444, gpid=441, flags=0x88) / Ether(src="00:22:22:22:22:44", dst=str(self.router_mac))) p = [(base / IP(src="10.0.1.100", dst=ep3.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)), (base / IPv6(src="2001:10::100", dst=ep3.ip6.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100))] # unknown remote EP to local EP redirected to known remote SEP rxs = self.send_and_expect(self.pg7, p, self.pg7) for rx, tx in zip(rxs, p): self.assertEqual(rx[Ether].src, self.pg7.local_mac) self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) # this should use the programmed remote leaf TEP self.assertEqual(rx[VXLAN].vni, 555) self.assertEqual(rx[VXLAN].gpid, epg_221.sclass) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # redirect policy has been applied self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) rxip = rx[VXLAN][Ether].payload txip = tx[VXLAN][Ether].payload self.assertEqual(rxip.src, txip.src) self.assertEqual(rxip.dst, txip.dst) # endpoint learnt via the parent GBP-vxlan interface self.assertTrue(find_gbp_endpoint(self, vx_tun_l3._sw_if_index, ip="10.0.1.100")) self.assertTrue(find_gbp_endpoint(self, vx_tun_l3._sw_if_index, ip="2001:10::100")) # remote SEP: it is now an unknown remote SEP and should go # to spine proxy sep5.remove_vpp_config() # remote EP (coming from spine proxy) to local EP redirected to # known remote SEP rxs = self.send_and_expect(self.pg7, p, self.pg7) for rx, tx in zip(rxs, p): self.assertEqual(rx[Ether].src, self.pg7.local_mac) self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) # this should use the spine proxy TEP self.assertEqual(rx[VXLAN].vni, epg_320.bd.uu_fwd.vni) self.assertEqual(rx[VXLAN].gpid, epg_221.sclass) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # redirect policy has been applied self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) rxip = rx[VXLAN][Ether].payload txip = tx[VXLAN][Ether].payload self.assertEqual(rxip.src, txip.src) self.assertEqual(rxip.dst, txip.dst) # # cleanup # self.pg7.unconfig_ip4() def test_gbp_l3_out(self): """ GBP L3 Out """ ep_flags = VppEnum.vl_api_gbp_endpoint_flags_t self.vapi.cli("set logging class gbp level debug") routed_dst_mac = "00:0c:0c:0c:0c:0c" routed_src_mac = "00:22:bd:f8:19:ff" # # IP tables # t4 = VppIpTable(self, 1) t4.add_vpp_config() t6 = VppIpTable(self, 1, True) t6.add_vpp_config() rd1 = VppGbpRouteDomain(self, 2, 55, t4, t6) rd1.add_vpp_config() self.loop0.set_mac(self.router_mac) # # Bind the BVI to the RD # VppIpInterfaceBind(self, self.loop0, t4).add_vpp_config() VppIpInterfaceBind(self, self.loop0, t6).add_vpp_config() # # Pg7 hosts a BD's BUM # Pg1 some other l3 interface # self.pg7.config_ip4() self.pg7.resolve_arp() # # a multicast vxlan-gbp tunnel for broadcast in the BD # tun_bm = VppVxlanGbpTunnel(self, self.pg7.local_ip4, "239.1.1.1", 88, mcast_itf=self.pg7) tun_bm.add_vpp_config() # # a GBP external bridge domains for the EPs # bd1 = VppBridgeDomain(self, 1) bd1.add_vpp_config() gbd1 = VppGbpBridgeDomain(self, bd1, rd1, self.loop0, None, tun_bm) gbd1.add_vpp_config() # # The Endpoint-groups in which the external endpoints exist # epg_220 = VppGbpEndpointGroup(self, 220, 113, rd1, gbd1, None, gbd1.bvi, "10.0.0.128", "2001:10::128", VppGbpEndpointRetention(2)) epg_220.add_vpp_config() # the BVIs have the subnets applied ... ip4_addr = VppIpInterfaceAddress(self, gbd1.bvi, "10.0.0.128", 24) ip4_addr.add_vpp_config() ip6_addr = VppIpInterfaceAddress(self, gbd1.bvi, "2001:10::128", 64) ip6_addr.add_vpp_config() # ... which are L3-out subnets l3o_1 = VppGbpSubnet( self, rd1, "10.0.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=113) l3o_1.add_vpp_config() # # an external interface attached to the outside world and the # external BD # VppL2Vtr(self, self.vlan_100, L2_VTR_OP.L2_POP_1).add_vpp_config() VppL2Vtr(self, self.vlan_101, L2_VTR_OP.L2_POP_1).add_vpp_config() vlan_144 = VppDot1QSubint(self, self.pg0, 144) vlan_144.admin_up() # vlan_102 is not poped # # an unicast vxlan-gbp for inter-RD traffic # vx_tun_l3 = VppGbpVxlanTunnel( self, 444, rd1.rd_id, VppEnum.vl_api_gbp_vxlan_tunnel_mode_t.GBP_VXLAN_TUNNEL_MODE_L3, self.pg2.local_ip4) vx_tun_l3.add_vpp_config() # # External Endpoints # eep1 = VppGbpEndpoint(self, self.vlan_100, epg_220, None, "10.0.0.1", "11.0.0.1", "2001:10::1", "3001::1", ep_flags.GBP_API_ENDPOINT_FLAG_EXTERNAL) eep1.add_vpp_config() eep2 = VppGbpEndpoint(self, self.vlan_101, epg_220, None, "10.0.0.2", "11.0.0.2", "2001:10::2", "3001::2", ep_flags.GBP_API_ENDPOINT_FLAG_EXTERNAL) eep2.add_vpp_config() eep3 = VppGbpEndpoint(self, self.vlan_102, epg_220, None, "10.0.0.3", "11.0.0.3", "2001:10::3", "3001::3", ep_flags.GBP_API_ENDPOINT_FLAG_EXTERNAL) eep3.add_vpp_config() # # A remote external endpoint # rep = VppGbpEndpoint(self, vx_tun_l3, epg_220, None, "10.0.0.101", "11.0.0.101", "2001:10::101", "3001::101", ep_flags.GBP_API_ENDPOINT_FLAG_REMOTE, self.pg7.local_ip4, self.pg7.remote_ip4, mac=None) rep.add_vpp_config() # # EP1 impersonating EP3 is dropped # p = (Ether(src=eep1.mac, dst="ff:ff:ff:ff:ff:ff") / Dot1Q(vlan=100) / ARP(op="who-has", psrc="10.0.0.3", pdst="10.0.0.128", hwsrc=eep1.mac, hwdst="ff:ff:ff:ff:ff:ff")) self.send_and_assert_no_replies(self.pg0, p) # # ARP packet from External EPs are accepted and replied to # p_arp = (Ether(src=eep1.mac, dst="ff:ff:ff:ff:ff:ff") / Dot1Q(vlan=100) / ARP(op="who-has", psrc=eep1.ip4.address, pdst="10.0.0.128", hwsrc=eep1.mac, hwdst="ff:ff:ff:ff:ff:ff")) rxs = self.send_and_expect(self.pg0, p_arp * 1, self.pg0) # # ARP packet from host in remote subnet are accepted and replied to # p_arp = (Ether(src=eep3.mac, dst="ff:ff:ff:ff:ff:ff") / Dot1Q(vlan=102) / ARP(op="who-has", psrc=eep3.ip4.address, pdst="10.0.0.128", hwsrc=eep3.mac, hwdst="ff:ff:ff:ff:ff:ff")) rxs = self.send_and_expect(self.pg0, p_arp * 1, self.pg0) # # packets destined to unknown addresses in the BVI's subnet # are ARP'd for # p4 = (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.0.0.1", dst="10.0.0.88") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) p6 = (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IPv6(src="2001:10::1", dst="2001:10::88") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p4 * 1, self.pg7) for rx in rxs: self.assertEqual(rx[Ether].src, self.pg7.local_mac) # self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, "239.1.1.1") self.assertEqual(rx[VXLAN].vni, 88) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # policy was applied to the original IP packet self.assertEqual(rx[VXLAN].gpid, 113) self.assertTrue(rx[VXLAN].gpflags.A) self.assertFalse(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertTrue(inner.haslayer(ARP)) # # remote to external # p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=444, gpid=113, flags=0x88) / Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src="10.0.0.101", dst="10.0.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg7, p * 1, self.pg0) # # local EP pings router # p = (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src=eep1.ip4.address, dst="10.0.0.128") / ICMP(type='echo-request')) rxs = self.send_and_expect(self.pg0, p * 1, self.pg0) for rx in rxs: self.assertEqual(rx[Ether].src, str(self.router_mac)) self.assertEqual(rx[Ether].dst, eep1.mac) self.assertEqual(rx[Dot1Q].vlan, 100) # # local EP pings other local EP # p = (Ether(src=eep1.mac, dst=eep2.mac) / Dot1Q(vlan=100) / IP(src=eep1.ip4.address, dst=eep2.ip4.address) / ICMP(type='echo-request')) rxs = self.send_and_expect(self.pg0, p * 1, self.pg0) for rx in rxs: self.assertEqual(rx[Ether].src, eep1.mac) self.assertEqual(rx[Ether].dst, eep2.mac) self.assertEqual(rx[Dot1Q].vlan, 101) # # local EP pings router w/o vlan tag poped # p = (Ether(src=eep3.mac, dst=str(self.router_mac)) / Dot1Q(vlan=102) / IP(src=eep3.ip4.address, dst="10.0.0.128") / ICMP(type='echo-request')) rxs = self.send_and_expect(self.pg0, p * 1, self.pg0) for rx in rxs: self.assertEqual(rx[Ether].src, str(self.router_mac)) self.assertEqual(rx[Ether].dst, self.vlan_102.remote_mac) # # A ip4 subnet reachable through the external EP1 # ip_220 = VppIpRoute(self, "10.220.0.0", 24, [VppRoutePath(eep1.ip4.address, eep1.epg.bvi.sw_if_index)], table_id=t4.table_id) ip_220.add_vpp_config() l3o_220 = VppGbpSubnet( self, rd1, "10.220.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4220) l3o_220.add_vpp_config() # # An ip6 subnet reachable through the external EP1 # ip6_220 = VppIpRoute(self, "10:220::", 64, [VppRoutePath(eep1.ip6.address, eep1.epg.bvi.sw_if_index)], table_id=t6.table_id) ip6_220.add_vpp_config() l3o6_220 = VppGbpSubnet( self, rd1, "10:220::", 64, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4220) l3o6_220.add_vpp_config() # # A subnet reachable through the external EP2 # ip_221 = VppIpRoute(self, "10.221.0.0", 24, [VppRoutePath(eep2.ip4.address, eep2.epg.bvi.sw_if_index)], table_id=t4.table_id) ip_221.add_vpp_config() l3o_221 = VppGbpSubnet( self, rd1, "10.221.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4221) l3o_221.add_vpp_config() # # ping between hosts in remote subnets # dropped without a contract # p = (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.221.0.1") / ICMP(type='echo-request')) self.send_and_assert_no_replies(self.pg0, p * 1) # # contract for the external nets to communicate # acl = VppGbpAcl(self) rule4 = acl.create_rule(permit_deny=1, proto=17) rule6 = acl.create_rule(is_ipv6=1, permit_deny=1, proto=17) acl_index = acl.add_vpp_config([rule4, rule6]) # # A contract with the wrong scope is not matched # c_44 = VppGbpContract( self, 44, 4220, 4221, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, [])], [ETH_P_IP, ETH_P_IPV6]) c_44.add_vpp_config() self.send_and_assert_no_replies(self.pg0, p * 1) c1 = VppGbpContract( self, 55, 4220, 4221, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c1.add_vpp_config() # # Contracts allowing ext-net 200 to talk with external EPs # c2 = VppGbpContract( self, 55, 4220, 113, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c2.add_vpp_config() c3 = VppGbpContract( self, 55, 113, 4220, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c3.add_vpp_config() # # ping between hosts in remote subnets # p = (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.221.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 1, self.pg0) for rx in rxs: self.assertEqual(rx[Ether].src, str(self.router_mac)) self.assertEqual(rx[Ether].dst, eep2.mac) self.assertEqual(rx[Dot1Q].vlan, 101) # we did not learn these external hosts self.assertFalse(find_gbp_endpoint(self, ip="10.220.0.1")) self.assertFalse(find_gbp_endpoint(self, ip="10.221.0.1")) # # from remote external EP to local external EP # p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=444, gpid=113, flags=0x88) / Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src="10.0.0.101", dst="10.220.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg7, p * 1, self.pg0) # # ping from an external host to the remote external EP # p = (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst=rep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 1, self.pg7) for rx in rxs: self.assertEqual(rx[Ether].src, self.pg7.local_mac) # self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) self.assertEqual(rx[VXLAN].vni, 444) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # the sclass of the ext-net the packet came from self.assertEqual(rx[VXLAN].gpid, 4220) # policy was applied to the original IP packet self.assertTrue(rx[VXLAN].gpflags.A) # since it's an external host the reciever should not learn it self.assertTrue(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertEqual(inner[IP].src, "10.220.0.1") self.assertEqual(inner[IP].dst, rep.ip4.address) # # An external subnet reachable via the remote external EP # # # first the VXLAN-GBP tunnel over which it is reached # vx_tun_r1 = VppVxlanGbpTunnel( self, self.pg7.local_ip4, self.pg7.remote_ip4, 445, mode=(VppEnum.vl_api_vxlan_gbp_api_tunnel_mode_t. VXLAN_GBP_API_TUNNEL_MODE_L3)) vx_tun_r1.add_vpp_config() VppIpInterfaceBind(self, vx_tun_r1, t4).add_vpp_config() self.logger.info(self.vapi.cli("sh vxlan-gbp tunnel")) # # then the special adj to resolve through on that tunnel # n1 = VppNeighbor(self, vx_tun_r1.sw_if_index, "00:0c:0c:0c:0c:0c", self.pg7.remote_ip4) n1.add_vpp_config() # # the route via the adj above # ip_222 = VppIpRoute(self, "10.222.0.0", 24, [VppRoutePath(self.pg7.remote_ip4, vx_tun_r1.sw_if_index)], table_id=t4.table_id) ip_222.add_vpp_config() l3o_222 = VppGbpSubnet( self, rd1, "10.222.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4222) l3o_222.add_vpp_config() # # ping between hosts in local and remote external subnets # dropped without a contract # p = (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.222.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_assert_no_replies(self.pg0, p * 1) # # Add contracts ext-nets for 220 -> 222 # c4 = VppGbpContract( self, 55, 4220, 4222, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c4.add_vpp_config() # # ping from host in local to remote external subnets # p = (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.222.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 3, self.pg7) for rx in rxs: self.assertEqual(rx[Ether].src, self.pg7.local_mac) self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) self.assertEqual(rx[VXLAN].vni, 445) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # the sclass of the ext-net the packet came from self.assertEqual(rx[VXLAN].gpid, 4220) # policy was applied to the original IP packet self.assertTrue(rx[VXLAN].gpflags.A) # since it's an external host the reciever should not learn it self.assertTrue(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertEqual(inner[Ether].dst, "00:0c:0c:0c:0c:0c") self.assertEqual(inner[IP].src, "10.220.0.1") self.assertEqual(inner[IP].dst, "10.222.0.1") # # make the external subnet ECMP # vx_tun_r2 = VppVxlanGbpTunnel( self, self.pg7.local_ip4, self.pg7.remote_ip4, 446, mode=(VppEnum.vl_api_vxlan_gbp_api_tunnel_mode_t. VXLAN_GBP_API_TUNNEL_MODE_L3)) vx_tun_r2.add_vpp_config() VppIpInterfaceBind(self, vx_tun_r2, t4).add_vpp_config() self.logger.info(self.vapi.cli("sh vxlan-gbp tunnel")) n2 = VppNeighbor(self, vx_tun_r2.sw_if_index, "00:0c:0c:0c:0c:0c", self.pg7.remote_ip4) n2.add_vpp_config() ip_222.modify([VppRoutePath(self.pg7.remote_ip4, vx_tun_r1.sw_if_index), VppRoutePath(self.pg7.remote_ip4, vx_tun_r2.sw_if_index)]) # # now expect load-balance # p = [(Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.222.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)), (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.222.0.1") / UDP(sport=1222, dport=1235) / Raw('\xa5' * 100))] rxs = self.send_and_expect(self.pg0, p, self.pg7) self.assertEqual(rxs[0][VXLAN].vni, 445) self.assertEqual(rxs[1][VXLAN].vni, 446) # # Same LB test for v6 # n3 = VppNeighbor(self, vx_tun_r1.sw_if_index, "00:0c:0c:0c:0c:0c", self.pg7.remote_ip6) n3.add_vpp_config() n4 = VppNeighbor(self, vx_tun_r2.sw_if_index, "00:0c:0c:0c:0c:0c", self.pg7.remote_ip6) n4.add_vpp_config() ip_222_6 = VppIpRoute(self, "10:222::", 64, [VppRoutePath(self.pg7.remote_ip6, vx_tun_r1.sw_if_index), VppRoutePath(self.pg7.remote_ip6, vx_tun_r2.sw_if_index)], table_id=t6.table_id) ip_222_6.add_vpp_config() l3o_222_6 = VppGbpSubnet( self, rd1, "10:222::", 64, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4222) l3o_222_6.add_vpp_config() p = [(Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IPv6(src="10:220::1", dst="10:222::1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)), (Ether(src=eep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IPv6(src="10:220::1", dst="10:222::1") / UDP(sport=7777, dport=8881) / Raw('\xa5' * 100))] self.logger.info(self.vapi.cli("sh ip6 fib 10:222::1")) rxs = self.send_and_expect(self.pg0, p, self.pg7) self.assertEqual(rxs[0][VXLAN].vni, 445) self.assertEqual(rxs[1][VXLAN].vni, 446) # # ping from host in remote to local external subnets # there's no contract for this, but the A bit is set. # p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=445, gpid=4222, flags=0x88, gpflags='A') / Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src="10.222.0.1", dst="10.220.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg7, p * 3, self.pg0) self.assertFalse(find_gbp_endpoint(self, ip="10.222.0.1")) # # ping from host in remote to remote external subnets # this is dropped by reflection check. # p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=445, gpid=4222, flags=0x88, gpflags='A') / Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src="10.222.0.1", dst="10.222.0.2") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_assert_no_replies(self.pg7, p * 3) p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=445, gpid=4222, flags=0x88, gpflags='A') / Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IPv6(src="10:222::1", dst="10:222::2") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_assert_no_replies(self.pg7, p * 3) # # local EP # lep1 = VppGbpEndpoint(self, vlan_144, epg_220, None, "10.0.0.44", "11.0.0.44", "2001:10::44", "3001::44") lep1.add_vpp_config() # # local EP to local ip4 external subnet # p = (Ether(src=lep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=144) / IP(src=lep1.ip4.address, dst="10.220.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 1, self.pg0) for rx in rxs: self.assertEqual(rx[Ether].src, str(self.router_mac)) self.assertEqual(rx[Ether].dst, eep1.mac) self.assertEqual(rx[Dot1Q].vlan, 100) # # local EP to local ip6 external subnet # p = (Ether(src=lep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=144) / IPv6(src=lep1.ip6.address, dst="10:220::1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 1, self.pg0) for rx in rxs: self.assertEqual(rx[Ether].src, str(self.router_mac)) self.assertEqual(rx[Ether].dst, eep1.mac) self.assertEqual(rx[Dot1Q].vlan, 100) # # ip4 and ip6 subnets that load-balance # ip_20 = VppIpRoute(self, "10.20.0.0", 24, [VppRoutePath(eep1.ip4.address, eep1.epg.bvi.sw_if_index), VppRoutePath(eep2.ip4.address, eep2.epg.bvi.sw_if_index)], table_id=t4.table_id) ip_20.add_vpp_config() l3o_20 = VppGbpSubnet( self, rd1, "10.20.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4220) l3o_20.add_vpp_config() ip6_20 = VppIpRoute(self, "10:20::", 64, [VppRoutePath(eep1.ip6.address, eep1.epg.bvi.sw_if_index), VppRoutePath(eep2.ip6.address, eep2.epg.bvi.sw_if_index)], table_id=t6.table_id) ip6_20.add_vpp_config() l3o6_20 = VppGbpSubnet( self, rd1, "10:20::", 64, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4220) l3o6_20.add_vpp_config() self.logger.info(self.vapi.cli("sh ip fib 10.20.0.1")) self.logger.info(self.vapi.cli("sh ip6 fib 10:20::1")) # two ip6 packets whose port are chosen so they load-balance p = [(Ether(src=lep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=144) / IPv6(src=lep1.ip6.address, dst="10:20::1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)), (Ether(src=lep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=144) / IPv6(src=lep1.ip6.address, dst="10:20::1") / UDP(sport=124, dport=1230) / Raw('\xa5' * 100))] rxs = self.send_and_expect(self.pg0, p, self.pg0, 2) self.assertEqual(rxs[0][Dot1Q].vlan, 101) self.assertEqual(rxs[1][Dot1Q].vlan, 100) # two ip4 packets whose port are chosen so they load-balance p = [(Ether(src=lep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=144) / IP(src=lep1.ip4.address, dst="10.20.0.1") / UDP(sport=1235, dport=1235) / Raw('\xa5' * 100)), (Ether(src=lep1.mac, dst=str(self.router_mac)) / Dot1Q(vlan=144) / IP(src=lep1.ip4.address, dst="10.20.0.1") / UDP(sport=124, dport=1230) / Raw('\xa5' * 100))] rxs = self.send_and_expect(self.pg0, p, self.pg0, 2) self.assertEqual(rxs[0][Dot1Q].vlan, 101) self.assertEqual(rxs[1][Dot1Q].vlan, 100) # # cleanup # ip_222.remove_vpp_config() self.pg7.unconfig_ip4() self.vlan_101.set_vtr(L2_VTR_OP.L2_DISABLED) self.vlan_100.set_vtr(L2_VTR_OP.L2_DISABLED) def test_gbp_anon_l3_out(self): """ GBP Anonymous L3 Out """ ep_flags = VppEnum.vl_api_gbp_endpoint_flags_t self.vapi.cli("set logging class gbp level debug") routed_dst_mac = "00:0c:0c:0c:0c:0c" routed_src_mac = "00:22:bd:f8:19:ff" # # IP tables # t4 = VppIpTable(self, 1) t4.add_vpp_config() t6 = VppIpTable(self, 1, True) t6.add_vpp_config() rd1 = VppGbpRouteDomain(self, 2, 55, t4, t6) rd1.add_vpp_config() self.loop0.set_mac(self.router_mac) # # Bind the BVI to the RD # VppIpInterfaceBind(self, self.loop0, t4).add_vpp_config() VppIpInterfaceBind(self, self.loop0, t6).add_vpp_config() # # Pg7 hosts a BD's BUM # Pg1 some other l3 interface # self.pg7.config_ip4() self.pg7.resolve_arp() # # a GBP external bridge domains for the EPs # bd1 = VppBridgeDomain(self, 1) bd1.add_vpp_config() gbd1 = VppGbpBridgeDomain(self, bd1, rd1, self.loop0, None, None) gbd1.add_vpp_config() # # The Endpoint-groups in which the external endpoints exist # epg_220 = VppGbpEndpointGroup(self, 220, 113, rd1, gbd1, None, gbd1.bvi, "10.0.0.128", "2001:10::128", VppGbpEndpointRetention(2)) epg_220.add_vpp_config() # the BVIs have the subnet applied ... ip4_addr = VppIpInterfaceAddress(self, gbd1.bvi, "10.0.0.128", 24) ip4_addr.add_vpp_config() # ... which is an Anonymous L3-out subnets l3o_1 = VppGbpSubnet( self, rd1, "10.0.0.0", 24, VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_ANON_L3_OUT, sclass=113) l3o_1.add_vpp_config() # # an external interface attached to the outside world and the # external BD # VppL2Vtr(self, self.vlan_100, L2_VTR_OP.L2_POP_1).add_vpp_config() VppL2Vtr(self, self.vlan_101, L2_VTR_OP.L2_POP_1).add_vpp_config() # # vlan_100 and vlan_101 are anonymous l3-out interfaces # ext_itf = VppGbpExtItf(self, self.vlan_100, bd1, rd1, anon=True) ext_itf.add_vpp_config() ext_itf = VppGbpExtItf(self, self.vlan_101, bd1, rd1, anon=True) ext_itf.add_vpp_config() # # an unicast vxlan-gbp for inter-RD traffic # vx_tun_l3 = VppGbpVxlanTunnel( self, 444, rd1.rd_id, VppEnum.vl_api_gbp_vxlan_tunnel_mode_t.GBP_VXLAN_TUNNEL_MODE_L3, self.pg2.local_ip4) vx_tun_l3.add_vpp_config() # # A remote external endpoint # rep = VppGbpEndpoint(self, vx_tun_l3, epg_220, None, "10.0.0.201", "11.0.0.201", "2001:10::201", "3001::101", ep_flags.GBP_API_ENDPOINT_FLAG_REMOTE, self.pg7.local_ip4, self.pg7.remote_ip4, mac=None) rep.add_vpp_config() # # ARP packet from host in external subnet are accepted, flooded and # replied to. We expect 2 packets: # - APR request flooded over the other vlan subif # - ARP reply from BVI # p_arp = (Ether(src=self.vlan_100.remote_mac, dst="ff:ff:ff:ff:ff:ff") / Dot1Q(vlan=100) / ARP(op="who-has", psrc="10.0.0.100", pdst="10.0.0.128", hwsrc=self.vlan_100.remote_mac, hwdst="ff:ff:ff:ff:ff:ff")) rxs = self.send_and_expect(self.pg0, p_arp * 1, self.pg0, n_rx=2) p_arp = (Ether(src=self.vlan_101.remote_mac, dst="ff:ff:ff:ff:ff:ff") / Dot1Q(vlan=101) / ARP(op="who-has", psrc='10.0.0.101', pdst="10.0.0.128", hwsrc=self.vlan_101.remote_mac, hwdst="ff:ff:ff:ff:ff:ff")) rxs = self.send_and_expect(self.pg0, p_arp * 1, self.pg0, n_rx=2) # # remote to external # p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=vx_tun_l3.vni, gpid=epg_220.sclass, flags=0x88) / Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src=str(rep.ip4), dst="10.0.0.100") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg7, p * 1, self.pg0) # # local EP pings router # p = (Ether(src=self.vlan_100.remote_mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.0.0.100", dst="10.0.0.128") / ICMP(type='echo-request')) rxs = self.send_and_expect(self.pg0, p * 1, self.pg0) for rx in rxs: self.assertEqual(rx[Ether].src, str(self.router_mac)) self.assertEqual(rx[Ether].dst, self.vlan_100.remote_mac) self.assertEqual(rx[Dot1Q].vlan, 100) # # local EP pings other local EP # p = (Ether(src=self.vlan_100.remote_mac, dst=self.vlan_101.remote_mac) / Dot1Q(vlan=100) / IP(src="10.0.0.100", dst="10.0.0.101") / ICMP(type='echo-request')) rxs = self.send_and_expect(self.pg0, p * 1, self.pg0) for rx in rxs: self.assertEqual(rx[Ether].src, self.vlan_100.remote_mac) self.assertEqual(rx[Ether].dst, self.vlan_101.remote_mac) self.assertEqual(rx[Dot1Q].vlan, 101) # # A subnet reachable through an external router on vlan 100 # ip_220 = VppIpRoute(self, "10.220.0.0", 24, [VppRoutePath("10.0.0.100", epg_220.bvi.sw_if_index)], table_id=t4.table_id) ip_220.add_vpp_config() l3o_220 = VppGbpSubnet( self, rd1, "10.220.0.0", 24, # note: this a "regular" L3 out subnet (not connected) VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4220) l3o_220.add_vpp_config() # # A subnet reachable through an external router on vlan 101 # ip_221 = VppIpRoute(self, "10.221.0.0", 24, [VppRoutePath("10.0.0.101", epg_220.bvi.sw_if_index)], table_id=t4.table_id) ip_221.add_vpp_config() l3o_221 = VppGbpSubnet( self, rd1, "10.221.0.0", 24, # note: this a "regular" L3 out subnet (not connected) VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4221) l3o_221.add_vpp_config() # # ping between hosts in remote subnets # dropped without a contract # p = (Ether(src=self.vlan_100.remote_mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.221.0.1") / ICMP(type='echo-request')) rxs = self.send_and_assert_no_replies(self.pg0, p * 1) # # contract for the external nets to communicate # acl = VppGbpAcl(self) rule4 = acl.create_rule(permit_deny=1, proto=17) rule6 = acl.create_rule(is_ipv6=1, permit_deny=1, proto=17) acl_index = acl.add_vpp_config([rule4, rule6]) c1 = VppGbpContract( self, 55, 4220, 4221, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c1.add_vpp_config() # # Contracts allowing ext-net 200 to talk with external EPs # c2 = VppGbpContract( self, 55, 4220, 113, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c2.add_vpp_config() c3 = VppGbpContract( self, 55, 113, 4220, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c3.add_vpp_config() # # ping between hosts in remote subnets # p = (Ether(src=self.vlan_100.remote_mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.221.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 1, self.pg0) for rx in rxs: self.assertEqual(rx[Ether].src, str(self.router_mac)) self.assertEqual(rx[Ether].dst, self.vlan_101.remote_mac) self.assertEqual(rx[Dot1Q].vlan, 101) # we did not learn these external hosts self.assertFalse(find_gbp_endpoint(self, ip="10.220.0.1")) self.assertFalse(find_gbp_endpoint(self, ip="10.221.0.1")) # # from remote external EP to local external EP # p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=444, gpid=113, flags=0x88) / Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src=rep.ip4.address, dst="10.220.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg7, p * 1, self.pg0) # # ping from an external host to the remote external EP # p = (Ether(src=self.vlan_100.remote_mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst=rep.ip4.address) / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 1, self.pg7) for rx in rxs: self.assertEqual(rx[Ether].src, self.pg7.local_mac) # self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) self.assertEqual(rx[VXLAN].vni, 444) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # the sclass of the ext-net the packet came from self.assertEqual(rx[VXLAN].gpid, 4220) # policy was applied to the original IP packet self.assertTrue(rx[VXLAN].gpflags.A) # since it's an external host the reciever should not learn it self.assertTrue(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertEqual(inner[IP].src, "10.220.0.1") self.assertEqual(inner[IP].dst, rep.ip4.address) # # An external subnet reachable via the remote external EP # # # first the VXLAN-GBP tunnel over which it is reached # vx_tun_r = VppVxlanGbpTunnel( self, self.pg7.local_ip4, self.pg7.remote_ip4, 445, mode=(VppEnum.vl_api_vxlan_gbp_api_tunnel_mode_t. VXLAN_GBP_API_TUNNEL_MODE_L3)) vx_tun_r.add_vpp_config() VppIpInterfaceBind(self, vx_tun_r, t4).add_vpp_config() self.logger.info(self.vapi.cli("sh vxlan-gbp tunnel")) # # then the special adj to resolve through on that tunnel # n1 = VppNeighbor(self, vx_tun_r.sw_if_index, "00:0c:0c:0c:0c:0c", self.pg7.remote_ip4) n1.add_vpp_config() # # the route via the adj above # ip_222 = VppIpRoute(self, "10.222.0.0", 24, [VppRoutePath(self.pg7.remote_ip4, vx_tun_r.sw_if_index)], table_id=t4.table_id) ip_222.add_vpp_config() l3o_222 = VppGbpSubnet( self, rd1, "10.222.0.0", 24, # note: this a "regular" l3out subnet (not connected) VppEnum.vl_api_gbp_subnet_type_t.GBP_API_SUBNET_L3_OUT, sclass=4222) l3o_222.add_vpp_config() # # ping between hosts in local and remote external subnets # dropped without a contract # p = (Ether(src=self.vlan_100.remote_mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.222.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_assert_no_replies(self.pg0, p * 1) # # Add contracts ext-nets for 220 -> 222 # c4 = VppGbpContract( self, 55, 4220, 4222, acl_index, [VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, []), VppGbpContractRule( VppEnum.vl_api_gbp_rule_action_t.GBP_API_RULE_PERMIT, VppEnum.vl_api_gbp_hash_mode_t.GBP_API_HASH_MODE_SRC_IP, [])], [ETH_P_IP, ETH_P_IPV6]) c4.add_vpp_config() # # ping from host in local to remote external subnets # p = (Ether(src=self.vlan_100.remote_mac, dst=str(self.router_mac)) / Dot1Q(vlan=100) / IP(src="10.220.0.1", dst="10.222.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg0, p * 3, self.pg7) for rx in rxs: self.assertEqual(rx[Ether].src, self.pg7.local_mac) self.assertEqual(rx[Ether].dst, self.pg7.remote_mac) self.assertEqual(rx[IP].src, self.pg7.local_ip4) self.assertEqual(rx[IP].dst, self.pg7.remote_ip4) self.assertEqual(rx[VXLAN].vni, 445) self.assertTrue(rx[VXLAN].flags.G) self.assertTrue(rx[VXLAN].flags.Instance) # the sclass of the ext-net the packet came from self.assertEqual(rx[VXLAN].gpid, 4220) # policy was applied to the original IP packet self.assertTrue(rx[VXLAN].gpflags.A) # since it's an external host the reciever should not learn it self.assertTrue(rx[VXLAN].gpflags.D) inner = rx[VXLAN].payload self.assertEqual(inner[Ether].dst, "00:0c:0c:0c:0c:0c") self.assertEqual(inner[IP].src, "10.220.0.1") self.assertEqual(inner[IP].dst, "10.222.0.1") # # ping from host in remote to local external subnets # there's no contract for this, but the A bit is set. # p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=445, gpid=4222, flags=0x88, gpflags='A') / Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src="10.222.0.1", dst="10.220.0.1") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_expect(self.pg7, p * 3, self.pg0) self.assertFalse(find_gbp_endpoint(self, ip="10.222.0.1")) # # ping from host in remote to remote external subnets # this is dropped by reflection check. # p = (Ether(src=self.pg7.remote_mac, dst=self.pg7.local_mac) / IP(src=self.pg7.remote_ip4, dst=self.pg7.local_ip4) / UDP(sport=1234, dport=48879) / VXLAN(vni=445, gpid=4222, flags=0x88, gpflags='A') / Ether(src=self.pg0.remote_mac, dst=str(self.router_mac)) / IP(src="10.222.0.1", dst="10.222.0.2") / UDP(sport=1234, dport=1234) / Raw('\xa5' * 100)) rxs = self.send_and_assert_no_replies(self.pg7, p * 3) # # cleanup # self.vlan_101.set_vtr(L2_VTR_OP.L2_DISABLED) self.vlan_100.set_vtr(L2_VTR_OP.L2_DISABLED) self.pg7.unconfig_ip4() if __name__ == '__main__': unittest.main(testRunner=VppTestRunner)