/* zebra client * Copyright (C) 1997, 98, 99 Kunihiro Ishiguro * * This file is part of GNU Zebra. * * GNU Zebra is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the * Free Software Foundation; either version 2, or (at your option) any * later version. * * GNU Zebra is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; see the file COPYING; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include #include "command.h" #include "stream.h" #include "network.h" #include "prefix.h" #include "log.h" #include "sockunion.h" #include "zclient.h" #include "routemap.h" #include "thread.h" #include "queue.h" #include "memory.h" #include "lib/json.h" #include "lib/bfd.h" #include "filter.h" #include "mpls.h" #include "vxlan.h" #include "pbr.h" #include "bgpd/bgpd.h" #include "bgpd/bgp_route.h" #include "bgpd/bgp_attr.h" #include "bgpd/bgp_nexthop.h" #include "bgpd/bgp_zebra.h" #include "bgpd/bgp_fsm.h" #include "bgpd/bgp_debug.h" #include "bgpd/bgp_errors.h" #include "bgpd/bgp_mpath.h" #include "bgpd/bgp_nexthop.h" #include "bgpd/bgp_nht.h" #include "bgpd/bgp_bfd.h" #include "bgpd/bgp_label.h" #ifdef ENABLE_BGP_VNC #include "bgpd/rfapi/rfapi_backend.h" #include "bgpd/rfapi/vnc_export_bgp.h" #endif #include "bgpd/bgp_evpn.h" #include "bgpd/bgp_mplsvpn.h" #include "bgpd/bgp_labelpool.h" #include "bgpd/bgp_pbr.h" #include "bgpd/bgp_evpn_private.h" #include "bgpd/bgp_evpn_mh.h" #include "bgpd/bgp_mac.h" /* All information about zebra. */ struct zclient *zclient = NULL; /* Can we install into zebra? */ static inline bool bgp_install_info_to_zebra(struct bgp *bgp) { if (zclient->sock <= 0) return false; if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp)) { zlog_debug( "%s: No zebra instance to talk to, not installing information", __func__); return false; } return true; } int zclient_num_connects; /* Router-id update message from zebra. */ static int bgp_router_id_update(ZAPI_CALLBACK_ARGS) { struct prefix router_id; zebra_router_id_update_read(zclient->ibuf, &router_id); if (BGP_DEBUG(zebra, ZEBRA)) { char buf[PREFIX2STR_BUFFER]; prefix2str(&router_id, buf, sizeof(buf)); zlog_debug("Rx Router Id update VRF %u Id %s", vrf_id, buf); } bgp_router_id_zebra_bump(vrf_id, &router_id); return 0; } /* Nexthop update message from zebra. */ static int bgp_read_nexthop_update(ZAPI_CALLBACK_ARGS) { bgp_parse_nexthop_update(cmd, vrf_id); return 0; } static int bgp_read_import_check_update(ZAPI_CALLBACK_ARGS) { bgp_parse_nexthop_update(cmd, vrf_id); return 0; } /* Set or clear interface on which unnumbered neighbor is configured. This * would in turn cause BGP to initiate or turn off IPv6 RAs on this * interface. */ static void bgp_update_interface_nbrs(struct bgp *bgp, struct interface *ifp, struct interface *upd_ifp) { struct listnode *node, *nnode; struct peer *peer; for (ALL_LIST_ELEMENTS(bgp->peer, node, nnode, peer)) { if (peer->conf_if && (strcmp(peer->conf_if, ifp->name) == 0)) { if (upd_ifp) { peer->ifp = upd_ifp; bgp_zebra_initiate_radv(bgp, peer); } else { bgp_zebra_terminate_radv(bgp, peer); peer->ifp = upd_ifp; } } } } static int bgp_read_fec_update(int command, struct zclient *zclient, zebra_size_t length) { bgp_parse_fec_update(); return 0; } static void bgp_start_interface_nbrs(struct bgp *bgp, struct interface *ifp) { struct listnode *node, *nnode; struct peer *peer; for (ALL_LIST_ELEMENTS(bgp->peer, node, nnode, peer)) { if (peer->conf_if && (strcmp(peer->conf_if, ifp->name) == 0) && peer->status != Established) { if (peer_active(peer)) BGP_EVENT_ADD(peer, BGP_Stop); BGP_EVENT_ADD(peer, BGP_Start); } } } static void bgp_nbr_connected_add(struct bgp *bgp, struct nbr_connected *ifc) { struct listnode *node; struct connected *connected; struct interface *ifp; struct prefix *p; /* Kick-off the FSM for any relevant peers only if there is a * valid local address on the interface. */ ifp = ifc->ifp; for (ALL_LIST_ELEMENTS_RO(ifp->connected, node, connected)) { p = connected->address; if (p->family == AF_INET6 && IN6_IS_ADDR_LINKLOCAL(&p->u.prefix6)) break; } if (!connected) return; bgp_start_interface_nbrs(bgp, ifp); } static void bgp_nbr_connected_delete(struct bgp *bgp, struct nbr_connected *ifc, int del) { struct listnode *node, *nnode; struct peer *peer; struct interface *ifp; for (ALL_LIST_ELEMENTS(bgp->peer, node, nnode, peer)) { if (peer->conf_if && (strcmp(peer->conf_if, ifc->ifp->name) == 0)) { peer->last_reset = PEER_DOWN_NBR_ADDR_DEL; BGP_EVENT_ADD(peer, BGP_Stop); } } /* Free neighbor also, if we're asked to. */ if (del) { ifp = ifc->ifp; listnode_delete(ifp->nbr_connected, ifc); nbr_connected_free(ifc); } } static int bgp_ifp_destroy(struct interface *ifp) { struct bgp *bgp; bgp = bgp_lookup_by_vrf_id(ifp->vrf_id); if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx Intf del VRF %u IF %s", ifp->vrf_id, ifp->name); if (bgp) bgp_update_interface_nbrs(bgp, ifp, NULL); bgp_mac_del_mac_entry(ifp); return 0; } static int bgp_ifp_up(struct interface *ifp) { struct connected *c; struct nbr_connected *nc; struct listnode *node, *nnode; struct bgp *bgp; bgp = bgp_lookup_by_vrf_id(ifp->vrf_id); bgp_mac_add_mac_entry(ifp); if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx Intf up VRF %u IF %s", ifp->vrf_id, ifp->name); if (!bgp) return 0; for (ALL_LIST_ELEMENTS(ifp->connected, node, nnode, c)) bgp_connected_add(bgp, c); for (ALL_LIST_ELEMENTS(ifp->nbr_connected, node, nnode, nc)) bgp_nbr_connected_add(bgp, nc); return 0; } static int bgp_ifp_down(struct interface *ifp) { struct connected *c; struct nbr_connected *nc; struct listnode *node, *nnode; struct bgp *bgp; struct peer *peer; bgp = bgp_lookup_by_vrf_id(ifp->vrf_id); bgp_mac_del_mac_entry(ifp); if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx Intf down VRF %u IF %s", ifp->vrf_id, ifp->name); if (!bgp) return 0; for (ALL_LIST_ELEMENTS(ifp->connected, node, nnode, c)) bgp_connected_delete(bgp, c); for (ALL_LIST_ELEMENTS(ifp->nbr_connected, node, nnode, nc)) bgp_nbr_connected_delete(bgp, nc, 1); /* Fast external-failover */ if (!CHECK_FLAG(bgp->flags, BGP_FLAG_NO_FAST_EXT_FAILOVER)) { for (ALL_LIST_ELEMENTS(bgp->peer, node, nnode, peer)) { #if defined(HAVE_CUMULUS) /* Take down directly connected EBGP peers as well as * 1-hop BFD * tracked (directly connected) IBGP peers. */ if ((peer->ttl != BGP_DEFAULT_TTL) && (peer->gtsm_hops != BGP_GTSM_HOPS_CONNECTED) && (!peer->bfd_info || bgp_bfd_is_peer_multihop(peer))) #else /* Take down directly connected EBGP peers */ if ((peer->ttl != BGP_DEFAULT_TTL) && (peer->gtsm_hops != BGP_GTSM_HOPS_CONNECTED)) #endif continue; if (ifp == peer->nexthop.ifp) { BGP_EVENT_ADD(peer, BGP_Stop); peer->last_reset = PEER_DOWN_IF_DOWN; } } } return 0; } static int bgp_interface_address_add(ZAPI_CALLBACK_ARGS) { struct connected *ifc; struct bgp *bgp; bgp = bgp_lookup_by_vrf_id(vrf_id); ifc = zebra_interface_address_read(cmd, zclient->ibuf, vrf_id); if (ifc == NULL) return 0; if (bgp_debug_zebra(ifc->address)) { char buf[PREFIX2STR_BUFFER]; prefix2str(ifc->address, buf, sizeof(buf)); zlog_debug("Rx Intf address add VRF %u IF %s addr %s", vrf_id, ifc->ifp->name, buf); } if (!bgp) return 0; if (if_is_operative(ifc->ifp)) { bgp_connected_add(bgp, ifc); /* If we have learnt of any neighbors on this interface, * check to kick off any BGP interface-based neighbors, * but only if this is a link-local address. */ if (IN6_IS_ADDR_LINKLOCAL(&ifc->address->u.prefix6) && !list_isempty(ifc->ifp->nbr_connected)) bgp_start_interface_nbrs(bgp, ifc->ifp); } return 0; } static int bgp_interface_address_delete(ZAPI_CALLBACK_ARGS) { struct connected *ifc; struct bgp *bgp; bgp = bgp_lookup_by_vrf_id(vrf_id); ifc = zebra_interface_address_read(cmd, zclient->ibuf, vrf_id); if (ifc == NULL) return 0; if (bgp_debug_zebra(ifc->address)) { char buf[PREFIX2STR_BUFFER]; prefix2str(ifc->address, buf, sizeof(buf)); zlog_debug("Rx Intf address del VRF %u IF %s addr %s", vrf_id, ifc->ifp->name, buf); } if (bgp && if_is_operative(ifc->ifp)) { bgp_connected_delete(bgp, ifc); } connected_free(&ifc); return 0; } static int bgp_interface_nbr_address_add(ZAPI_CALLBACK_ARGS) { struct nbr_connected *ifc = NULL; struct bgp *bgp; ifc = zebra_interface_nbr_address_read(cmd, zclient->ibuf, vrf_id); if (ifc == NULL) return 0; if (bgp_debug_zebra(ifc->address)) { char buf[PREFIX2STR_BUFFER]; prefix2str(ifc->address, buf, sizeof(buf)); zlog_debug("Rx Intf neighbor add VRF %u IF %s addr %s", vrf_id, ifc->ifp->name, buf); } if (if_is_operative(ifc->ifp)) { bgp = bgp_lookup_by_vrf_id(vrf_id); if (bgp) bgp_nbr_connected_add(bgp, ifc); } return 0; } static int bgp_interface_nbr_address_delete(ZAPI_CALLBACK_ARGS) { struct nbr_connected *ifc = NULL; struct bgp *bgp; ifc = zebra_interface_nbr_address_read(cmd, zclient->ibuf, vrf_id); if (ifc == NULL) return 0; if (bgp_debug_zebra(ifc->address)) { char buf[PREFIX2STR_BUFFER]; prefix2str(ifc->address, buf, sizeof(buf)); zlog_debug("Rx Intf neighbor del VRF %u IF %s addr %s", vrf_id, ifc->ifp->name, buf); } if (if_is_operative(ifc->ifp)) { bgp = bgp_lookup_by_vrf_id(vrf_id); if (bgp) bgp_nbr_connected_delete(bgp, ifc, 0); } nbr_connected_free(ifc); return 0; } /* VRF update for an interface. */ static int bgp_interface_vrf_update(ZAPI_CALLBACK_ARGS) { struct interface *ifp; vrf_id_t new_vrf_id; struct connected *c; struct nbr_connected *nc; struct listnode *node, *nnode; struct bgp *bgp; struct peer *peer; ifp = zebra_interface_vrf_update_read(zclient->ibuf, vrf_id, &new_vrf_id); if (!ifp) return 0; if (BGP_DEBUG(zebra, ZEBRA) && ifp) zlog_debug("Rx Intf VRF change VRF %u IF %s NewVRF %u", vrf_id, ifp->name, new_vrf_id); bgp = bgp_lookup_by_vrf_id(vrf_id); if (bgp) { for (ALL_LIST_ELEMENTS(ifp->connected, node, nnode, c)) bgp_connected_delete(bgp, c); for (ALL_LIST_ELEMENTS(ifp->nbr_connected, node, nnode, nc)) bgp_nbr_connected_delete(bgp, nc, 1); /* Fast external-failover */ if (!CHECK_FLAG(bgp->flags, BGP_FLAG_NO_FAST_EXT_FAILOVER)) { for (ALL_LIST_ELEMENTS(bgp->peer, node, nnode, peer)) { if ((peer->ttl != BGP_DEFAULT_TTL) && (peer->gtsm_hops != BGP_GTSM_HOPS_CONNECTED)) continue; if (ifp == peer->nexthop.ifp) BGP_EVENT_ADD(peer, BGP_Stop); } } } if_update_to_new_vrf(ifp, new_vrf_id); bgp = bgp_lookup_by_vrf_id(new_vrf_id); if (!bgp) return 0; for (ALL_LIST_ELEMENTS(ifp->connected, node, nnode, c)) bgp_connected_add(bgp, c); for (ALL_LIST_ELEMENTS(ifp->nbr_connected, node, nnode, nc)) bgp_nbr_connected_add(bgp, nc); return 0; } /* Zebra route add and delete treatment. */ static int zebra_read_route(ZAPI_CALLBACK_ARGS) { enum nexthop_types_t nhtype; struct zapi_route api; union g_addr nexthop; ifindex_t ifindex; int add, i; struct bgp *bgp; bgp = bgp_lookup_by_vrf_id(vrf_id); if (!bgp) return 0; if (zapi_route_decode(zclient->ibuf, &api) < 0) return -1; /* we completely ignore srcdest routes for now. */ if (CHECK_FLAG(api.message, ZAPI_MESSAGE_SRCPFX)) return 0; /* ignore link-local address. */ if (api.prefix.family == AF_INET6 && IN6_IS_ADDR_LINKLOCAL(&api.prefix.u.prefix6)) return 0; nexthop = api.nexthops[0].gate; ifindex = api.nexthops[0].ifindex; nhtype = api.nexthops[0].type; add = (cmd == ZEBRA_REDISTRIBUTE_ROUTE_ADD); if (add) { /* * The ADD message is actually an UPDATE and there is no * explicit DEL * for a prior redistributed route, if any. So, perform an * implicit * DEL processing for the same redistributed route from any * other * source type. */ for (i = 0; i < ZEBRA_ROUTE_MAX; i++) { if (i != api.type) bgp_redistribute_delete(bgp, &api.prefix, i, api.instance); } /* Now perform the add/update. */ bgp_redistribute_add(bgp, &api.prefix, &nexthop, ifindex, nhtype, api.metric, api.type, api.instance, api.tag); } else { bgp_redistribute_delete(bgp, &api.prefix, api.type, api.instance); } if (bgp_debug_zebra(&api.prefix)) { char buf[2][PREFIX_STRLEN]; prefix2str(&api.prefix, buf[0], sizeof(buf[0])); if (add) { inet_ntop(api.prefix.family, &nexthop, buf[1], sizeof(buf[1])); zlog_debug( "Rx route ADD VRF %u %s[%d] %s nexthop %s (type %d if %u) metric %u tag %" ROUTE_TAG_PRI, vrf_id, zebra_route_string(api.type), api.instance, buf[0], buf[1], nhtype, ifindex, api.metric, api.tag); } else { zlog_debug( "Rx route DEL VRF %u %s[%d] %s", vrf_id, zebra_route_string(api.type), api.instance, buf[0]); } } return 0; } struct interface *if_lookup_by_ipv4(struct in_addr *addr, vrf_id_t vrf_id) { struct vrf *vrf; struct listnode *cnode; struct interface *ifp; struct connected *connected; struct prefix_ipv4 p; struct prefix *cp; vrf = vrf_lookup_by_id(vrf_id); if (!vrf) return NULL; p.family = AF_INET; p.prefix = *addr; p.prefixlen = IPV4_MAX_BITLEN; FOR_ALL_INTERFACES (vrf, ifp) { for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, connected)) { cp = connected->address; if (cp->family == AF_INET) if (prefix_match(cp, (struct prefix *)&p)) return ifp; } } return NULL; } struct interface *if_lookup_by_ipv4_exact(struct in_addr *addr, vrf_id_t vrf_id) { struct vrf *vrf; struct listnode *cnode; struct interface *ifp; struct connected *connected; struct prefix *cp; vrf = vrf_lookup_by_id(vrf_id); if (!vrf) return NULL; FOR_ALL_INTERFACES (vrf, ifp) { for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, connected)) { cp = connected->address; if (cp->family == AF_INET) if (IPV4_ADDR_SAME(&cp->u.prefix4, addr)) return ifp; } } return NULL; } struct interface *if_lookup_by_ipv6(struct in6_addr *addr, ifindex_t ifindex, vrf_id_t vrf_id) { struct vrf *vrf; struct listnode *cnode; struct interface *ifp; struct connected *connected; struct prefix_ipv6 p; struct prefix *cp; vrf = vrf_lookup_by_id(vrf_id); if (!vrf) return NULL; p.family = AF_INET6; p.prefix = *addr; p.prefixlen = IPV6_MAX_BITLEN; FOR_ALL_INTERFACES (vrf, ifp) { for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, connected)) { cp = connected->address; if (cp->family == AF_INET6) if (prefix_match(cp, (struct prefix *)&p)) { if (IN6_IS_ADDR_LINKLOCAL( &cp->u.prefix6)) { if (ifindex == ifp->ifindex) return ifp; } else return ifp; } } } return NULL; } struct interface *if_lookup_by_ipv6_exact(struct in6_addr *addr, ifindex_t ifindex, vrf_id_t vrf_id) { struct vrf *vrf; struct listnode *cnode; struct interface *ifp; struct connected *connected; struct prefix *cp; vrf = vrf_lookup_by_id(vrf_id); if (!vrf) return NULL; FOR_ALL_INTERFACES (vrf, ifp) { for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, connected)) { cp = connected->address; if (cp->family == AF_INET6) if (IPV6_ADDR_SAME(&cp->u.prefix6, addr)) { if (IN6_IS_ADDR_LINKLOCAL( &cp->u.prefix6)) { if (ifindex == ifp->ifindex) return ifp; } else return ifp; } } } return NULL; } static int if_get_ipv6_global(struct interface *ifp, struct in6_addr *addr) { struct listnode *cnode; struct connected *connected; struct prefix *cp; for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, connected)) { cp = connected->address; if (cp->family == AF_INET6) if (!IN6_IS_ADDR_LINKLOCAL(&cp->u.prefix6)) { memcpy(addr, &cp->u.prefix6, IPV6_MAX_BYTELEN); return 1; } } return 0; } static int if_get_ipv6_local(struct interface *ifp, struct in6_addr *addr) { struct listnode *cnode; struct connected *connected; struct prefix *cp; for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, connected)) { cp = connected->address; if (cp->family == AF_INET6) if (IN6_IS_ADDR_LINKLOCAL(&cp->u.prefix6)) { memcpy(addr, &cp->u.prefix6, IPV6_MAX_BYTELEN); return 1; } } return 0; } static int if_get_ipv4_address(struct interface *ifp, struct in_addr *addr) { struct listnode *cnode; struct connected *connected; struct prefix *cp; for (ALL_LIST_ELEMENTS_RO(ifp->connected, cnode, connected)) { cp = connected->address; if ((cp->family == AF_INET) && !ipv4_martian(&(cp->u.prefix4))) { *addr = cp->u.prefix4; return 1; } } return 0; } bool bgp_zebra_nexthop_set(union sockunion *local, union sockunion *remote, struct bgp_nexthop *nexthop, struct peer *peer) { int ret = 0; struct interface *ifp = NULL; memset(nexthop, 0, sizeof(struct bgp_nexthop)); if (!local) return false; if (!remote) return false; if (local->sa.sa_family == AF_INET) { nexthop->v4 = local->sin.sin_addr; if (peer->update_if) ifp = if_lookup_by_name(peer->update_if, peer->bgp->vrf_id); else ifp = if_lookup_by_ipv4_exact(&local->sin.sin_addr, peer->bgp->vrf_id); } if (local->sa.sa_family == AF_INET6) { memcpy(&nexthop->v6_global, &local->sin6.sin6_addr, IPV6_MAX_BYTELEN); if (IN6_IS_ADDR_LINKLOCAL(&local->sin6.sin6_addr)) { if (peer->conf_if || peer->ifname) ifp = if_lookup_by_name(peer->conf_if ? peer->conf_if : peer->ifname, peer->bgp->vrf_id); } else if (peer->update_if) ifp = if_lookup_by_name(peer->update_if, peer->bgp->vrf_id); else ifp = if_lookup_by_ipv6_exact(&local->sin6.sin6_addr, local->sin6.sin6_scope_id, peer->bgp->vrf_id); } if (!ifp) { /* * BGP views do not currently get proper data * from zebra( when attached ) to be able to * properly resolve nexthops, so give this * instance type a pass. */ if (peer->bgp->inst_type == BGP_INSTANCE_TYPE_VIEW) return true; /* * If we have no interface data but we have established * some connection w/ zebra than something has gone * terribly terribly wrong here, so say this failed * If we do not any zebra connection then not * having a ifp pointer is ok. */ return zclient_num_connects ? false : true; } nexthop->ifp = ifp; /* IPv4 connection, fetch and store IPv6 local address(es) if any. */ if (local->sa.sa_family == AF_INET) { /* IPv6 nexthop*/ ret = if_get_ipv6_global(ifp, &nexthop->v6_global); if (!ret) { /* There is no global nexthop. Use link-local address as * both the * global and link-local nexthop. In this scenario, the * expectation * for interop is that the network admin would use a * route-map to * specify the global IPv6 nexthop. */ if_get_ipv6_local(ifp, &nexthop->v6_global); memcpy(&nexthop->v6_local, &nexthop->v6_global, IPV6_MAX_BYTELEN); } else if_get_ipv6_local(ifp, &nexthop->v6_local); if (if_lookup_by_ipv4(&remote->sin.sin_addr, peer->bgp->vrf_id)) peer->shared_network = 1; else peer->shared_network = 0; } /* IPv6 connection, fetch and store IPv4 local address if any. */ if (local->sa.sa_family == AF_INET6) { struct interface *direct = NULL; /* IPv4 nexthop. */ ret = if_get_ipv4_address(ifp, &nexthop->v4); if (!ret && peer->local_id.s_addr != INADDR_ANY) nexthop->v4 = peer->local_id; /* Global address*/ if (!IN6_IS_ADDR_LINKLOCAL(&local->sin6.sin6_addr)) { memcpy(&nexthop->v6_global, &local->sin6.sin6_addr, IPV6_MAX_BYTELEN); /* If directory connected set link-local address. */ direct = if_lookup_by_ipv6(&remote->sin6.sin6_addr, remote->sin6.sin6_scope_id, peer->bgp->vrf_id); if (direct) if_get_ipv6_local(ifp, &nexthop->v6_local); } else /* Link-local address. */ { ret = if_get_ipv6_global(ifp, &nexthop->v6_global); /* If there is no global address. Set link-local address as global. I know this break RFC specification... */ /* In this scenario, the expectation for interop is that * the * network admin would use a route-map to specify the * global * IPv6 nexthop. */ if (!ret) memcpy(&nexthop->v6_global, &local->sin6.sin6_addr, IPV6_MAX_BYTELEN); /* Always set the link-local address */ memcpy(&nexthop->v6_local, &local->sin6.sin6_addr, IPV6_MAX_BYTELEN); } if (IN6_IS_ADDR_LINKLOCAL(&local->sin6.sin6_addr) || if_lookup_by_ipv6(&remote->sin6.sin6_addr, remote->sin6.sin6_scope_id, peer->bgp->vrf_id)) peer->shared_network = 1; else peer->shared_network = 0; } /* KAME stack specific treatment. */ #ifdef KAME if (IN6_IS_ADDR_LINKLOCAL(&nexthop->v6_global) && IN6_LINKLOCAL_IFINDEX(nexthop->v6_global)) { SET_IN6_LINKLOCAL_IFINDEX(nexthop->v6_global, 0); } if (IN6_IS_ADDR_LINKLOCAL(&nexthop->v6_local) && IN6_LINKLOCAL_IFINDEX(nexthop->v6_local)) { SET_IN6_LINKLOCAL_IFINDEX(nexthop->v6_local, 0); } #endif /* KAME */ /* If we have identified the local interface, there is no error for now. */ return true; } static struct in6_addr * bgp_path_info_to_ipv6_nexthop(struct bgp_path_info *path, ifindex_t *ifindex) { struct in6_addr *nexthop = NULL; /* Only global address nexthop exists. */ if (path->attr->mp_nexthop_len == BGP_ATTR_NHLEN_IPV6_GLOBAL || path->attr->mp_nexthop_len == BGP_ATTR_NHLEN_VPNV6_GLOBAL) { nexthop = &path->attr->mp_nexthop_global; if (IN6_IS_ADDR_LINKLOCAL(nexthop)) *ifindex = path->attr->nh_ifindex; } /* If both global and link-local address present. */ if (path->attr->mp_nexthop_len == BGP_ATTR_NHLEN_IPV6_GLOBAL_AND_LL || path->attr->mp_nexthop_len == BGP_ATTR_NHLEN_VPNV6_GLOBAL_AND_LL) { /* Check if route-map is set to prefer global over link-local */ if (path->attr->mp_nexthop_prefer_global) { nexthop = &path->attr->mp_nexthop_global; if (IN6_IS_ADDR_LINKLOCAL(nexthop)) *ifindex = path->attr->nh_ifindex; } else { /* Workaround for Cisco's nexthop bug. */ if (IN6_IS_ADDR_UNSPECIFIED( &path->attr->mp_nexthop_global) && path->peer->su_remote->sa.sa_family == AF_INET6) { nexthop = &path->peer->su_remote->sin6.sin6_addr; if (IN6_IS_ADDR_LINKLOCAL(nexthop)) *ifindex = path->peer->nexthop.ifp ->ifindex; } else { nexthop = &path->attr->mp_nexthop_local; if (IN6_IS_ADDR_LINKLOCAL(nexthop)) *ifindex = path->attr->nh_lla_ifindex; } } } return nexthop; } static bool bgp_table_map_apply(struct route_map *map, const struct prefix *p, struct bgp_path_info *path) { route_map_result_t ret; ret = route_map_apply(map, p, RMAP_BGP, path); bgp_attr_flush(path->attr); if (ret != RMAP_DENYMATCH) return true; if (bgp_debug_zebra(p)) { if (p->family == AF_INET) { char buf[2][INET_ADDRSTRLEN]; zlog_debug( "Zebra rmap deny: IPv4 route %s/%d nexthop %s", inet_ntop(AF_INET, &p->u.prefix4, buf[0], sizeof(buf[0])), p->prefixlen, inet_ntop(AF_INET, &path->attr->nexthop, buf[1], sizeof(buf[1]))); } if (p->family == AF_INET6) { char buf[2][INET6_ADDRSTRLEN]; ifindex_t ifindex; struct in6_addr *nexthop; nexthop = bgp_path_info_to_ipv6_nexthop(path, &ifindex); zlog_debug( "Zebra rmap deny: IPv6 route %s/%d nexthop %s", inet_ntop(AF_INET6, &p->u.prefix6, buf[0], sizeof(buf[0])), p->prefixlen, inet_ntop(AF_INET6, nexthop, buf[1], sizeof(buf[1]))); } } return false; } static struct thread *bgp_tm_thread_connect; static bool bgp_tm_status_connected; static bool bgp_tm_chunk_obtained; #define BGP_FLOWSPEC_TABLE_CHUNK 100000 static uint32_t bgp_tm_min, bgp_tm_max, bgp_tm_chunk_size; struct bgp *bgp_tm_bgp; static int bgp_zebra_tm_connect(struct thread *t) { struct zclient *zclient; int delay = 10, ret = 0; zclient = THREAD_ARG(t); if (bgp_tm_status_connected && zclient->sock > 0) delay = 60; else { bgp_tm_status_connected = false; ret = tm_table_manager_connect(zclient); } if (ret < 0) { zlog_info("Error connecting to table manager!"); bgp_tm_status_connected = false; } else { if (!bgp_tm_status_connected) zlog_debug("Connecting to table manager. Success"); bgp_tm_status_connected = true; if (!bgp_tm_chunk_obtained) { if (bgp_zebra_get_table_range(bgp_tm_chunk_size, &bgp_tm_min, &bgp_tm_max) >= 0) { bgp_tm_chunk_obtained = true; /* parse non installed entries */ bgp_zebra_announce_table(bgp_tm_bgp, AFI_IP, SAFI_FLOWSPEC); } } } thread_add_timer(bm->master, bgp_zebra_tm_connect, zclient, delay, &bgp_tm_thread_connect); return 0; } bool bgp_zebra_tm_chunk_obtained(void) { return bgp_tm_chunk_obtained; } uint32_t bgp_zebra_tm_get_id(void) { static int table_id; if (!bgp_tm_chunk_obtained) return ++table_id; return bgp_tm_min++; } void bgp_zebra_init_tm_connect(struct bgp *bgp) { int delay = 1; /* if already set, do nothing */ if (bgp_tm_thread_connect != NULL) return; bgp_tm_status_connected = false; bgp_tm_chunk_obtained = false; bgp_tm_min = bgp_tm_max = 0; bgp_tm_chunk_size = BGP_FLOWSPEC_TABLE_CHUNK; bgp_tm_bgp = bgp; thread_add_timer(bm->master, bgp_zebra_tm_connect, zclient, delay, &bgp_tm_thread_connect); } int bgp_zebra_get_table_range(uint32_t chunk_size, uint32_t *start, uint32_t *end) { int ret; if (!bgp_tm_status_connected) return -1; ret = tm_get_table_chunk(zclient, chunk_size, start, end); if (ret < 0) { flog_err(EC_BGP_TABLE_CHUNK, "BGP: Error getting table chunk %u", chunk_size); return -1; } zlog_info("BGP: Table Manager returns range from chunk %u is [%u %u]", chunk_size, *start, *end); return 0; } static bool update_ipv4nh_for_route_install(int nh_othervrf, struct bgp *nh_bgp, struct in_addr *nexthop, struct attr *attr, bool is_evpn, struct zapi_nexthop *api_nh) { api_nh->gate.ipv4 = *nexthop; api_nh->vrf_id = nh_bgp->vrf_id; /* Need to set fields appropriately for EVPN routes imported into * a VRF (which are programmed as onlink on l3-vni SVI) as well as * connected routes leaked into a VRF. */ if (is_evpn) { api_nh->type = NEXTHOP_TYPE_IPV4_IFINDEX; SET_FLAG(api_nh->flags, ZAPI_NEXTHOP_FLAG_ONLINK); api_nh->ifindex = nh_bgp->l3vni_svi_ifindex; } else if (nh_othervrf && api_nh->gate.ipv4.s_addr == INADDR_ANY) { api_nh->type = NEXTHOP_TYPE_IFINDEX; api_nh->ifindex = attr->nh_ifindex; } else api_nh->type = NEXTHOP_TYPE_IPV4; return true; } static bool update_ipv6nh_for_route_install(int nh_othervrf, struct bgp *nh_bgp, struct in6_addr *nexthop, ifindex_t ifindex, struct bgp_path_info *pi, struct bgp_path_info *best_pi, bool is_evpn, struct zapi_nexthop *api_nh) { struct attr *attr; attr = pi->attr; api_nh->vrf_id = nh_bgp->vrf_id; if (is_evpn) { api_nh->type = NEXTHOP_TYPE_IPV6_IFINDEX; SET_FLAG(api_nh->flags, ZAPI_NEXTHOP_FLAG_ONLINK); api_nh->ifindex = nh_bgp->l3vni_svi_ifindex; } else if (nh_othervrf) { if (IN6_IS_ADDR_UNSPECIFIED(nexthop)) { api_nh->type = NEXTHOP_TYPE_IFINDEX; api_nh->ifindex = attr->nh_ifindex; } else if (IN6_IS_ADDR_LINKLOCAL(nexthop)) { if (ifindex == 0) return false; api_nh->type = NEXTHOP_TYPE_IPV6_IFINDEX; api_nh->ifindex = ifindex; } else { api_nh->type = NEXTHOP_TYPE_IPV6; api_nh->ifindex = 0; } } else { if (IN6_IS_ADDR_LINKLOCAL(nexthop)) { if (pi == best_pi && attr->mp_nexthop_len == BGP_ATTR_NHLEN_IPV6_GLOBAL_AND_LL) if (pi->peer->nexthop.ifp) ifindex = pi->peer->nexthop.ifp->ifindex; if (!ifindex) { if (pi->peer->conf_if) ifindex = pi->peer->ifp->ifindex; else if (pi->peer->ifname) ifindex = ifname2ifindex( pi->peer->ifname, pi->peer->bgp->vrf_id); else if (pi->peer->nexthop.ifp) ifindex = pi->peer->nexthop.ifp->ifindex; } if (ifindex == 0) return false; api_nh->type = NEXTHOP_TYPE_IPV6_IFINDEX; api_nh->ifindex = ifindex; } else { api_nh->type = NEXTHOP_TYPE_IPV6; api_nh->ifindex = 0; } } if (nexthop) api_nh->gate.ipv6 = *nexthop; return true; } static bool bgp_zebra_use_nhop_weighted(struct bgp *bgp, struct attr *attr, uint64_t tot_bw, uint32_t *nh_weight) { uint32_t bw; uint64_t tmp; bw = attr->link_bw; /* zero link-bandwidth and link-bandwidth not present are treated * as the same situation. */ if (!bw) { /* the only situations should be if we're either told * to skip or use default weight. */ if (bgp->lb_handling == BGP_LINK_BW_SKIP_MISSING) return false; *nh_weight = BGP_ZEBRA_DEFAULT_NHOP_WEIGHT; } else { tmp = (uint64_t)bw * 100; *nh_weight = ((uint32_t)(tmp / tot_bw)); } return true; } void bgp_zebra_announce(struct bgp_dest *dest, const struct prefix *p, struct bgp_path_info *info, struct bgp *bgp, afi_t afi, safi_t safi) { struct zapi_route api = { 0 }; struct zapi_nexthop *api_nh; int nh_family; unsigned int valid_nh_count = 0; int has_valid_label = 0; uint8_t distance; struct peer *peer; struct bgp_path_info *mpinfo; uint32_t metric; struct attr local_attr; struct bgp_path_info local_info; struct bgp_path_info *mpinfo_cp = &local_info; route_tag_t tag; mpls_label_t label; int nh_othervrf = 0; char buf_prefix[PREFIX_STRLEN]; /* filled in if we are debugging */ bool is_evpn; int nh_updated; bool do_wt_ecmp; uint64_t cum_bw = 0; /* Don't try to install if we're not connected to Zebra or Zebra doesn't * know of this instance. */ if (!bgp_install_info_to_zebra(bgp)) return; if (bgp->main_zebra_update_hold) return; if (bgp_debug_zebra(p)) prefix2str(p, buf_prefix, sizeof(buf_prefix)); if (safi == SAFI_FLOWSPEC) { bgp_pbr_update_entry(bgp, bgp_dest_get_prefix(dest), info, afi, safi, true); return; } /* * vrf leaking support (will have only one nexthop) */ if (info->extra && info->extra->bgp_orig) nh_othervrf = 1; /* Make Zebra API structure. */ api.vrf_id = bgp->vrf_id; api.type = ZEBRA_ROUTE_BGP; api.safi = safi; api.prefix = *p; SET_FLAG(api.message, ZAPI_MESSAGE_NEXTHOP); peer = info->peer; if (info->type == ZEBRA_ROUTE_BGP && info->sub_type == BGP_ROUTE_IMPORTED) { /* Obtain peer from parent */ if (info->extra && info->extra->parent) peer = ((struct bgp_path_info *)(info->extra->parent)) ->peer; } tag = info->attr->tag; /* If the route's source is EVPN, flag as such. */ is_evpn = is_route_parent_evpn(info); if (is_evpn) SET_FLAG(api.flags, ZEBRA_FLAG_EVPN_ROUTE); if (peer->sort == BGP_PEER_IBGP || peer->sort == BGP_PEER_CONFED || info->sub_type == BGP_ROUTE_AGGREGATE) { SET_FLAG(api.flags, ZEBRA_FLAG_IBGP); SET_FLAG(api.flags, ZEBRA_FLAG_ALLOW_RECURSION); } if ((peer->sort == BGP_PEER_EBGP && peer->ttl != BGP_DEFAULT_TTL) || CHECK_FLAG(peer->flags, PEER_FLAG_DISABLE_CONNECTED_CHECK) || CHECK_FLAG(bgp->flags, BGP_FLAG_DISABLE_NH_CONNECTED_CHK)) SET_FLAG(api.flags, ZEBRA_FLAG_ALLOW_RECURSION); if (info->attr->rmap_table_id) { SET_FLAG(api.message, ZAPI_MESSAGE_TABLEID); api.tableid = info->attr->rmap_table_id; } if (CHECK_FLAG(info->attr->flag, ATTR_FLAG_BIT(BGP_ATTR_SRTE_COLOR))) SET_FLAG(api.message, ZAPI_MESSAGE_SRTE); /* Metric is currently based on the best-path only */ metric = info->attr->med; /* Determine if we're doing weighted ECMP or not */ do_wt_ecmp = bgp_path_info_mpath_chkwtd(bgp, info); if (do_wt_ecmp) cum_bw = bgp_path_info_mpath_cumbw(info); for (mpinfo = info; mpinfo; mpinfo = bgp_path_info_mpath_next(mpinfo)) { uint32_t nh_weight; if (valid_nh_count >= multipath_num) break; *mpinfo_cp = *mpinfo; nh_weight = 0; /* Get nexthop address-family */ if (p->family == AF_INET && !BGP_ATTR_NEXTHOP_AFI_IP6(mpinfo_cp->attr)) nh_family = AF_INET; else if (p->family == AF_INET6 || (p->family == AF_INET && BGP_ATTR_NEXTHOP_AFI_IP6(mpinfo_cp->attr))) nh_family = AF_INET6; else continue; /* If processing for weighted ECMP, determine the next hop's * weight. Based on user setting, we may skip the next hop * in some situations. */ if (do_wt_ecmp) { if (!bgp_zebra_use_nhop_weighted(bgp, mpinfo->attr, cum_bw, &nh_weight)) continue; } api_nh = &api.nexthops[valid_nh_count]; if (CHECK_FLAG(info->attr->flag, ATTR_FLAG_BIT(BGP_ATTR_SRTE_COLOR))) api_nh->srte_color = info->attr->srte_color; if (nh_family == AF_INET) { if (bgp_debug_zebra(&api.prefix)) { if (mpinfo->extra) { zlog_debug( "%s: p=%s, bgp_is_valid_label: %d", __func__, buf_prefix, bgp_is_valid_label( &mpinfo->extra ->label[0])); } else { zlog_debug( "%s: p=%s, extra is NULL, no label", __func__, buf_prefix); } } if (bgp->table_map[afi][safi].name) { /* Copy info and attributes, so the route-map apply doesn't modify the BGP route info. */ local_attr = *mpinfo->attr; mpinfo_cp->attr = &local_attr; } if (bgp->table_map[afi][safi].name) { if (!bgp_table_map_apply( bgp->table_map[afi][safi].map, p, mpinfo_cp)) continue; /* metric/tag is only allowed to be * overridden on 1st nexthop */ if (mpinfo == info) { metric = mpinfo_cp->attr->med; tag = mpinfo_cp->attr->tag; } } nh_updated = update_ipv4nh_for_route_install( nh_othervrf, nh_othervrf ? info->extra->bgp_orig : bgp, &mpinfo_cp->attr->nexthop, mpinfo_cp->attr, is_evpn, api_nh); } else { ifindex_t ifindex = IFINDEX_INTERNAL; struct in6_addr *nexthop; if (bgp->table_map[afi][safi].name) { /* Copy info and attributes, so the route-map apply doesn't modify the BGP route info. */ local_attr = *mpinfo->attr; mpinfo_cp->attr = &local_attr; } if (bgp->table_map[afi][safi].name) { /* Copy info and attributes, so the route-map apply doesn't modify the BGP route info. */ local_attr = *mpinfo->attr; mpinfo_cp->attr = &local_attr; if (!bgp_table_map_apply( bgp->table_map[afi][safi].map, p, mpinfo_cp)) continue; /* metric/tag is only allowed to be * overridden on 1st nexthop */ if (mpinfo == info) { metric = mpinfo_cp->attr->med; tag = mpinfo_cp->attr->tag; } } nexthop = bgp_path_info_to_ipv6_nexthop(mpinfo_cp, &ifindex); nh_updated = update_ipv6nh_for_route_install( nh_othervrf, nh_othervrf ? info->extra->bgp_orig : bgp, nexthop, ifindex, mpinfo, info, is_evpn, api_nh); } /* Did we get proper nexthop info to update zebra? */ if (!nh_updated) continue; if (mpinfo->extra && bgp_is_valid_label(&mpinfo->extra->label[0]) && !CHECK_FLAG(api.flags, ZEBRA_FLAG_EVPN_ROUTE)) { has_valid_label = 1; label = label_pton(&mpinfo->extra->label[0]); SET_FLAG(api_nh->flags, ZAPI_NEXTHOP_FLAG_LABEL); api_nh->label_num = 1; api_nh->labels[0] = label; } memcpy(&api_nh->rmac, &(mpinfo->attr->rmac), sizeof(struct ethaddr)); api_nh->weight = nh_weight; valid_nh_count++; } /* * When we create an aggregate route we must also * install a Null0 route in the RIB, so overwrite * what was written into api with a blackhole route */ if (info->sub_type == BGP_ROUTE_AGGREGATE) zapi_route_set_blackhole(&api, BLACKHOLE_NULL); else api.nexthop_num = valid_nh_count; SET_FLAG(api.message, ZAPI_MESSAGE_METRIC); api.metric = metric; if (tag) { SET_FLAG(api.message, ZAPI_MESSAGE_TAG); api.tag = tag; } distance = bgp_distance_apply(p, info, afi, safi, bgp); if (distance) { SET_FLAG(api.message, ZAPI_MESSAGE_DISTANCE); api.distance = distance; } if (bgp_debug_zebra(p)) { char prefix_buf[PREFIX_STRLEN]; char nh_buf[INET6_ADDRSTRLEN]; char eth_buf[ETHER_ADDR_STRLEN + 7] = {'\0'}; char buf1[ETHER_ADDR_STRLEN]; char label_buf[20]; int i; prefix2str(&api.prefix, prefix_buf, sizeof(prefix_buf)); zlog_debug("Tx route %s VRF %u %s metric %u tag %" ROUTE_TAG_PRI " count %d", valid_nh_count ? "add" : "delete", bgp->vrf_id, prefix_buf, api.metric, api.tag, api.nexthop_num); for (i = 0; i < api.nexthop_num; i++) { api_nh = &api.nexthops[i]; switch (api_nh->type) { case NEXTHOP_TYPE_IFINDEX: nh_buf[0] = '\0'; break; case NEXTHOP_TYPE_IPV4: case NEXTHOP_TYPE_IPV4_IFINDEX: nh_family = AF_INET; inet_ntop(nh_family, &api_nh->gate, nh_buf, sizeof(nh_buf)); break; case NEXTHOP_TYPE_IPV6: case NEXTHOP_TYPE_IPV6_IFINDEX: nh_family = AF_INET6; inet_ntop(nh_family, &api_nh->gate, nh_buf, sizeof(nh_buf)); break; case NEXTHOP_TYPE_BLACKHOLE: strlcpy(nh_buf, "blackhole", sizeof(nh_buf)); break; default: /* Note: add new nexthop case */ assert(0); break; } label_buf[0] = '\0'; eth_buf[0] = '\0'; if (has_valid_label && !CHECK_FLAG(api.flags, ZEBRA_FLAG_EVPN_ROUTE)) snprintf(label_buf, sizeof(label_buf), "label %u", api_nh->labels[0]); if (CHECK_FLAG(api.flags, ZEBRA_FLAG_EVPN_ROUTE) && !is_zero_mac(&api_nh->rmac)) snprintf(eth_buf, sizeof(eth_buf), " RMAC %s", prefix_mac2str(&api_nh->rmac, buf1, sizeof(buf1))); zlog_debug(" nhop [%d]: %s if %u VRF %u wt %u %s %s", i + 1, nh_buf, api_nh->ifindex, api_nh->vrf_id, api_nh->weight, label_buf, eth_buf); } } if (bgp_debug_zebra(p)) { int recursion_flag = 0; if (CHECK_FLAG(api.flags, ZEBRA_FLAG_ALLOW_RECURSION)) recursion_flag = 1; zlog_debug("%s: %s: announcing to zebra (recursion %sset)", __func__, buf_prefix, (recursion_flag ? "" : "NOT ")); } zclient_route_send(valid_nh_count ? ZEBRA_ROUTE_ADD : ZEBRA_ROUTE_DELETE, zclient, &api); } /* Announce all routes of a table to zebra */ void bgp_zebra_announce_table(struct bgp *bgp, afi_t afi, safi_t safi) { struct bgp_dest *dest; struct bgp_table *table; struct bgp_path_info *pi; /* Don't try to install if we're not connected to Zebra or Zebra doesn't * know of this instance. */ if (!bgp_install_info_to_zebra(bgp)) return; table = bgp->rib[afi][safi]; if (!table) return; for (dest = bgp_table_top(table); dest; dest = bgp_route_next(dest)) for (pi = bgp_dest_get_bgp_path_info(dest); pi; pi = pi->next) if (CHECK_FLAG(pi->flags, BGP_PATH_SELECTED) && (pi->type == ZEBRA_ROUTE_BGP && (pi->sub_type == BGP_ROUTE_NORMAL || pi->sub_type == BGP_ROUTE_IMPORTED))) bgp_zebra_announce(dest, bgp_dest_get_prefix(dest), pi, bgp, afi, safi); } /* Announce routes of any bgp subtype of a table to zebra */ void bgp_zebra_announce_table_all_subtypes(struct bgp *bgp, afi_t afi, safi_t safi) { struct bgp_dest *dest; struct bgp_table *table; struct bgp_path_info *pi; if (!bgp_install_info_to_zebra(bgp)) return; table = bgp->rib[afi][safi]; if (!table) return; for (dest = bgp_table_top(table); dest; dest = bgp_route_next(dest)) for (pi = bgp_dest_get_bgp_path_info(dest); pi; pi = pi->next) if (CHECK_FLAG(pi->flags, BGP_PATH_SELECTED) && pi->type == ZEBRA_ROUTE_BGP) bgp_zebra_announce(dest, bgp_dest_get_prefix(dest), pi, bgp, afi, safi); } void bgp_zebra_withdraw(const struct prefix *p, struct bgp_path_info *info, struct bgp *bgp, safi_t safi) { struct zapi_route api; struct peer *peer; /* Don't try to install if we're not connected to Zebra or Zebra doesn't * know of this instance. */ if (!bgp_install_info_to_zebra(bgp)) return; if (safi == SAFI_FLOWSPEC) { peer = info->peer; bgp_pbr_update_entry(peer->bgp, p, info, AFI_IP, safi, false); return; } memset(&api, 0, sizeof(api)); api.vrf_id = bgp->vrf_id; api.type = ZEBRA_ROUTE_BGP; api.safi = safi; api.prefix = *p; if (info->attr->rmap_table_id) { SET_FLAG(api.message, ZAPI_MESSAGE_TABLEID); api.tableid = info->attr->rmap_table_id; } /* If the route's source is EVPN, flag as such. */ if (is_route_parent_evpn(info)) SET_FLAG(api.flags, ZEBRA_FLAG_EVPN_ROUTE); if (bgp_debug_zebra(p)) { char buf[PREFIX_STRLEN]; prefix2str(&api.prefix, buf, sizeof(buf)); zlog_debug("Tx route delete VRF %u %s", bgp->vrf_id, buf); } zclient_route_send(ZEBRA_ROUTE_DELETE, zclient, &api); } /* Withdraw all entries in a BGP instances RIB table from Zebra */ void bgp_zebra_withdraw_table_all_subtypes(struct bgp *bgp, afi_t afi, safi_t safi) { struct bgp_dest *dest; struct bgp_table *table; struct bgp_path_info *pi; if (!bgp_install_info_to_zebra(bgp)) return; table = bgp->rib[afi][safi]; if (!table) return; for (dest = bgp_table_top(table); dest; dest = bgp_route_next(dest)) { for (pi = bgp_dest_get_bgp_path_info(dest); pi; pi = pi->next) { if (CHECK_FLAG(pi->flags, BGP_PATH_SELECTED) && (pi->type == ZEBRA_ROUTE_BGP)) bgp_zebra_withdraw(bgp_dest_get_prefix(dest), pi, bgp, safi); } } } struct bgp_redist *bgp_redist_lookup(struct bgp *bgp, afi_t afi, uint8_t type, unsigned short instance) { struct list *red_list; struct listnode *node; struct bgp_redist *red; red_list = bgp->redist[afi][type]; if (!red_list) return (NULL); for (ALL_LIST_ELEMENTS_RO(red_list, node, red)) if (red->instance == instance) return red; return NULL; } struct bgp_redist *bgp_redist_add(struct bgp *bgp, afi_t afi, uint8_t type, unsigned short instance) { struct list *red_list; struct bgp_redist *red; red = bgp_redist_lookup(bgp, afi, type, instance); if (red) return red; if (!bgp->redist[afi][type]) bgp->redist[afi][type] = list_new(); red_list = bgp->redist[afi][type]; red = XCALLOC(MTYPE_BGP_REDIST, sizeof(struct bgp_redist)); red->instance = instance; listnode_add(red_list, red); return red; } static void bgp_redist_del(struct bgp *bgp, afi_t afi, uint8_t type, unsigned short instance) { struct bgp_redist *red; red = bgp_redist_lookup(bgp, afi, type, instance); if (red) { listnode_delete(bgp->redist[afi][type], red); XFREE(MTYPE_BGP_REDIST, red); if (!bgp->redist[afi][type]->count) list_delete(&bgp->redist[afi][type]); } } /* Other routes redistribution into BGP. */ int bgp_redistribute_set(struct bgp *bgp, afi_t afi, int type, unsigned short instance, bool changed) { /* If redistribute options are changed call * bgp_redistribute_unreg() to reset the option and withdraw * the routes */ if (changed) bgp_redistribute_unreg(bgp, afi, type, instance); /* Return if already redistribute flag is set. */ if (instance) { if (redist_check_instance(&zclient->mi_redist[afi][type], instance)) return CMD_WARNING; redist_add_instance(&zclient->mi_redist[afi][type], instance); } else { if (vrf_bitmap_check(zclient->redist[afi][type], bgp->vrf_id)) return CMD_WARNING; #ifdef ENABLE_BGP_VNC if (EVPN_ENABLED(bgp) && type == ZEBRA_ROUTE_VNC_DIRECT) { vnc_export_bgp_enable( bgp, afi); /* only enables if mode bits cfg'd */ } #endif vrf_bitmap_set(zclient->redist[afi][type], bgp->vrf_id); } /* * Don't try to register if we're not connected to Zebra or Zebra * doesn't know of this instance. * * When we come up later well resend if needed. */ if (!bgp_install_info_to_zebra(bgp)) return CMD_SUCCESS; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Tx redistribute add VRF %u afi %d %s %d", bgp->vrf_id, afi, zebra_route_string(type), instance); /* Send distribute add message to zebra. */ zebra_redistribute_send(ZEBRA_REDISTRIBUTE_ADD, zclient, afi, type, instance, bgp->vrf_id); return CMD_SUCCESS; } int bgp_redistribute_resend(struct bgp *bgp, afi_t afi, int type, unsigned short instance) { /* Don't try to send if we're not connected to Zebra or Zebra doesn't * know of this instance. */ if (!bgp_install_info_to_zebra(bgp)) return -1; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Tx redistribute del/add VRF %u afi %d %s %d", bgp->vrf_id, afi, zebra_route_string(type), instance); /* Send distribute add message to zebra. */ zebra_redistribute_send(ZEBRA_REDISTRIBUTE_DELETE, zclient, afi, type, instance, bgp->vrf_id); zebra_redistribute_send(ZEBRA_REDISTRIBUTE_ADD, zclient, afi, type, instance, bgp->vrf_id); return 0; } /* Redistribute with route-map specification. */ bool bgp_redistribute_rmap_set(struct bgp_redist *red, const char *name, struct route_map *route_map) { if (red->rmap.name && (strcmp(red->rmap.name, name) == 0)) return false; XFREE(MTYPE_ROUTE_MAP_NAME, red->rmap.name); /* Decrement the count for existing routemap and * increment the count for new route map. */ route_map_counter_decrement(red->rmap.map); red->rmap.name = XSTRDUP(MTYPE_ROUTE_MAP_NAME, name); red->rmap.map = route_map; route_map_counter_increment(red->rmap.map); return true; } /* Redistribute with metric specification. */ bool bgp_redistribute_metric_set(struct bgp *bgp, struct bgp_redist *red, afi_t afi, int type, uint32_t metric) { struct bgp_dest *dest; struct bgp_path_info *pi; if (red->redist_metric_flag && red->redist_metric == metric) return false; red->redist_metric_flag = 1; red->redist_metric = metric; for (dest = bgp_table_top(bgp->rib[afi][SAFI_UNICAST]); dest; dest = bgp_route_next(dest)) { for (pi = bgp_dest_get_bgp_path_info(dest); pi; pi = pi->next) { if (pi->sub_type == BGP_ROUTE_REDISTRIBUTE && pi->type == type && pi->instance == red->instance) { struct attr *old_attr; struct attr new_attr; new_attr = *pi->attr; new_attr.med = red->redist_metric; old_attr = pi->attr; pi->attr = bgp_attr_intern(&new_attr); bgp_attr_unintern(&old_attr); bgp_path_info_set_flag(dest, pi, BGP_PATH_ATTR_CHANGED); bgp_process(bgp, dest, afi, SAFI_UNICAST); } } } return true; } /* Unset redistribution. */ int bgp_redistribute_unreg(struct bgp *bgp, afi_t afi, int type, unsigned short instance) { struct bgp_redist *red; red = bgp_redist_lookup(bgp, afi, type, instance); if (!red) return CMD_SUCCESS; /* Return if zebra connection is disabled. */ if (instance) { if (!redist_check_instance(&zclient->mi_redist[afi][type], instance)) return CMD_WARNING; redist_del_instance(&zclient->mi_redist[afi][type], instance); } else { if (!vrf_bitmap_check(zclient->redist[afi][type], bgp->vrf_id)) return CMD_WARNING; vrf_bitmap_unset(zclient->redist[afi][type], bgp->vrf_id); } if (bgp_install_info_to_zebra(bgp)) { /* Send distribute delete message to zebra. */ if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Tx redistribute del VRF %u afi %d %s %d", bgp->vrf_id, afi, zebra_route_string(type), instance); zebra_redistribute_send(ZEBRA_REDISTRIBUTE_DELETE, zclient, afi, type, instance, bgp->vrf_id); } /* Withdraw redistributed routes from current BGP's routing table. */ bgp_redistribute_withdraw(bgp, afi, type, instance); return CMD_SUCCESS; } /* Unset redistribution. */ int bgp_redistribute_unset(struct bgp *bgp, afi_t afi, int type, unsigned short instance) { struct bgp_redist *red; /* * vnc and vpn->vrf checks must be before red check because * they operate within bgpd irrespective of zebra connection * status. red lookup fails if there is no zebra connection. */ #ifdef ENABLE_BGP_VNC if (EVPN_ENABLED(bgp) && type == ZEBRA_ROUTE_VNC_DIRECT) { vnc_export_bgp_disable(bgp, afi); } #endif red = bgp_redist_lookup(bgp, afi, type, instance); if (!red) return CMD_SUCCESS; bgp_redistribute_unreg(bgp, afi, type, instance); /* Unset route-map. */ XFREE(MTYPE_ROUTE_MAP_NAME, red->rmap.name); route_map_counter_decrement(red->rmap.map); red->rmap.map = NULL; /* Unset metric. */ red->redist_metric_flag = 0; red->redist_metric = 0; bgp_redist_del(bgp, afi, type, instance); return CMD_SUCCESS; } void bgp_redistribute_redo(struct bgp *bgp) { afi_t afi; int i; struct list *red_list; struct listnode *node; struct bgp_redist *red; for (afi = AFI_IP; afi < AFI_MAX; afi++) { for (i = 0; i < ZEBRA_ROUTE_MAX; i++) { red_list = bgp->redist[afi][i]; if (!red_list) continue; for (ALL_LIST_ELEMENTS_RO(red_list, node, red)) { bgp_redistribute_resend(bgp, afi, i, red->instance); } } } } /* Unset redistribute vrf bitmap during triggers like restart networking or delete VRFs */ void bgp_unset_redist_vrf_bitmaps(struct bgp *bgp, vrf_id_t old_vrf_id) { int i; afi_t afi; for (afi = AFI_IP; afi < AFI_MAX; afi++) for (i = 0; i < ZEBRA_ROUTE_MAX; i++) if (vrf_bitmap_check(zclient->redist[afi][i], old_vrf_id)) vrf_bitmap_unset(zclient->redist[afi][i], old_vrf_id); return; } void bgp_zclient_reset(void) { zclient_reset(zclient); } /* Register this instance with Zebra. Invoked upon connect (for * default instance) and when other VRFs are learnt (or created and * already learnt). */ void bgp_zebra_instance_register(struct bgp *bgp) { /* Don't try to register if we're not connected to Zebra */ if (!zclient || zclient->sock < 0) return; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Registering VRF %u", bgp->vrf_id); /* Register for router-id, interfaces, redistributed routes. */ zclient_send_reg_requests(zclient, bgp->vrf_id); /* For EVPN instance, register to learn about VNIs, if appropriate. */ if (bgp->advertise_all_vni) bgp_zebra_advertise_all_vni(bgp, 1); bgp_nht_register_nexthops(bgp); } /* Deregister this instance with Zebra. Invoked upon the instance * being deleted (default or VRF) and it is already registered. */ void bgp_zebra_instance_deregister(struct bgp *bgp) { /* Don't try to deregister if we're not connected to Zebra */ if (zclient->sock < 0) return; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Deregistering VRF %u", bgp->vrf_id); /* For EVPN instance, unregister learning about VNIs, if appropriate. */ if (bgp->advertise_all_vni) bgp_zebra_advertise_all_vni(bgp, 0); /* Deregister for router-id, interfaces, redistributed routes. */ zclient_send_dereg_requests(zclient, bgp->vrf_id); } void bgp_zebra_initiate_radv(struct bgp *bgp, struct peer *peer) { int ra_interval = BGP_UNNUM_DEFAULT_RA_INTERVAL; /* Don't try to initiate if we're not connected to Zebra */ if (zclient->sock < 0) return; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%u: Initiating RA for peer %s", bgp->vrf_id, peer->host); /* * If unnumbered peer (peer->ifp) call thru zapi to start RAs. * If we don't have an ifp pointer, call function to find the * ifps for a numbered enhe peer to turn RAs on. */ peer->ifp ? zclient_send_interface_radv_req(zclient, bgp->vrf_id, peer->ifp, 1, ra_interval) : bgp_nht_reg_enhe_cap_intfs(peer); } void bgp_zebra_terminate_radv(struct bgp *bgp, struct peer *peer) { /* Don't try to terminate if we're not connected to Zebra */ if (zclient->sock < 0) return; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%u: Terminating RA for peer %s", bgp->vrf_id, peer->host); /* * If unnumbered peer (peer->ifp) call thru zapi to stop RAs. * If we don't have an ifp pointer, call function to find the * ifps for a numbered enhe peer to turn RAs off. */ peer->ifp ? zclient_send_interface_radv_req(zclient, bgp->vrf_id, peer->ifp, 0, 0) : bgp_nht_dereg_enhe_cap_intfs(peer); } int bgp_zebra_advertise_subnet(struct bgp *bgp, int advertise, vni_t vni) { struct stream *s = NULL; /* Check socket. */ if (!zclient || zclient->sock < 0) return 0; /* Don't try to register if Zebra doesn't know of this instance. */ if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp)) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug( "%s: No zebra instance to talk to, cannot advertise subnet", __func__); return 0; } s = zclient->obuf; stream_reset(s); zclient_create_header(s, ZEBRA_ADVERTISE_SUBNET, bgp->vrf_id); stream_putc(s, advertise); stream_put3(s, vni); stream_putw_at(s, 0, stream_get_endp(s)); return zclient_send_message(zclient); } int bgp_zebra_advertise_svi_macip(struct bgp *bgp, int advertise, vni_t vni) { struct stream *s = NULL; /* Check socket. */ if (!zclient || zclient->sock < 0) return 0; /* Don't try to register if Zebra doesn't know of this instance. */ if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp)) return 0; s = zclient->obuf; stream_reset(s); zclient_create_header(s, ZEBRA_ADVERTISE_SVI_MACIP, bgp->vrf_id); stream_putc(s, advertise); stream_putl(s, vni); stream_putw_at(s, 0, stream_get_endp(s)); return zclient_send_message(zclient); } int bgp_zebra_advertise_gw_macip(struct bgp *bgp, int advertise, vni_t vni) { struct stream *s = NULL; /* Check socket. */ if (!zclient || zclient->sock < 0) return 0; /* Don't try to register if Zebra doesn't know of this instance. */ if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp)) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug( "%s: No zebra instance to talk to, not installing gw_macip", __func__); return 0; } s = zclient->obuf; stream_reset(s); zclient_create_header(s, ZEBRA_ADVERTISE_DEFAULT_GW, bgp->vrf_id); stream_putc(s, advertise); stream_putl(s, vni); stream_putw_at(s, 0, stream_get_endp(s)); return zclient_send_message(zclient); } int bgp_zebra_vxlan_flood_control(struct bgp *bgp, enum vxlan_flood_control flood_ctrl) { struct stream *s; /* Check socket. */ if (!zclient || zclient->sock < 0) return 0; /* Don't try to register if Zebra doesn't know of this instance. */ if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp)) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug( "%s: No zebra instance to talk to, not installing all vni", __func__); return 0; } s = zclient->obuf; stream_reset(s); zclient_create_header(s, ZEBRA_VXLAN_FLOOD_CONTROL, bgp->vrf_id); stream_putc(s, flood_ctrl); stream_putw_at(s, 0, stream_get_endp(s)); return zclient_send_message(zclient); } int bgp_zebra_advertise_all_vni(struct bgp *bgp, int advertise) { struct stream *s; /* Check socket. */ if (!zclient || zclient->sock < 0) return 0; /* Don't try to register if Zebra doesn't know of this instance. */ if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp)) return 0; s = zclient->obuf; stream_reset(s); zclient_create_header(s, ZEBRA_ADVERTISE_ALL_VNI, bgp->vrf_id); stream_putc(s, advertise); /* Also inform current BUM handling setting. This is really * relevant only when 'advertise' is set. */ stream_putc(s, bgp->vxlan_flood_ctrl); stream_putw_at(s, 0, stream_get_endp(s)); return zclient_send_message(zclient); } int bgp_zebra_dup_addr_detection(struct bgp *bgp) { struct stream *s; /* Check socket. */ if (!zclient || zclient->sock < 0) return 0; /* Don't try to register if Zebra doesn't know of this instance. */ if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp)) return 0; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("dup addr detect %s max_moves %u time %u freeze %s freeze_time %u", bgp->evpn_info->dup_addr_detect ? "enable" : "disable", bgp->evpn_info->dad_max_moves, bgp->evpn_info->dad_time, bgp->evpn_info->dad_freeze ? "enable" : "disable", bgp->evpn_info->dad_freeze_time); s = zclient->obuf; stream_reset(s); zclient_create_header(s, ZEBRA_DUPLICATE_ADDR_DETECTION, bgp->vrf_id); stream_putl(s, bgp->evpn_info->dup_addr_detect); stream_putl(s, bgp->evpn_info->dad_time); stream_putl(s, bgp->evpn_info->dad_max_moves); stream_putl(s, bgp->evpn_info->dad_freeze); stream_putl(s, bgp->evpn_info->dad_freeze_time); stream_putw_at(s, 0, stream_get_endp(s)); return zclient_send_message(zclient); } static int rule_notify_owner(ZAPI_CALLBACK_ARGS) { uint32_t seqno, priority, unique; enum zapi_rule_notify_owner note; struct bgp_pbr_action *bgp_pbra; struct bgp_pbr_rule *bgp_pbr = NULL; char ifname[INTERFACE_NAMSIZ + 1]; if (!zapi_rule_notify_decode(zclient->ibuf, &seqno, &priority, &unique, ifname, ¬e)) return -1; bgp_pbra = bgp_pbr_action_rule_lookup(vrf_id, unique); if (!bgp_pbra) { /* look in bgp pbr rule */ bgp_pbr = bgp_pbr_rule_lookup(vrf_id, unique); if (!bgp_pbr && note != ZAPI_RULE_REMOVED) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Fail to look BGP rule (%u)", __func__, unique); return 0; } } switch (note) { case ZAPI_RULE_FAIL_INSTALL: if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received RULE_FAIL_INSTALL", __func__); if (bgp_pbra) { bgp_pbra->installed = false; bgp_pbra->install_in_progress = false; } else { bgp_pbr->installed = false; bgp_pbr->install_in_progress = false; } break; case ZAPI_RULE_INSTALLED: if (bgp_pbra) { bgp_pbra->installed = true; bgp_pbra->install_in_progress = false; } else { struct bgp_path_info *path; struct bgp_path_info_extra *extra; bgp_pbr->installed = true; bgp_pbr->install_in_progress = false; bgp_pbr->action->refcnt++; /* link bgp_info to bgp_pbr */ path = (struct bgp_path_info *)bgp_pbr->path; extra = bgp_path_info_extra_get(path); listnode_add_force(&extra->bgp_fs_iprule, bgp_pbr); } if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received RULE_INSTALLED", __func__); break; case ZAPI_RULE_FAIL_REMOVE: case ZAPI_RULE_REMOVED: if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received RULE REMOVED", __func__); break; } return 0; } static int ipset_notify_owner(ZAPI_CALLBACK_ARGS) { uint32_t unique; enum zapi_ipset_notify_owner note; struct bgp_pbr_match *bgp_pbim; if (!zapi_ipset_notify_decode(zclient->ibuf, &unique, ¬e)) return -1; bgp_pbim = bgp_pbr_match_ipset_lookup(vrf_id, unique); if (!bgp_pbim) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Fail to look BGP match ( %u, ID %u)", __func__, note, unique); return 0; } switch (note) { case ZAPI_IPSET_FAIL_INSTALL: if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received IPSET_FAIL_INSTALL", __func__); bgp_pbim->installed = false; bgp_pbim->install_in_progress = false; break; case ZAPI_IPSET_INSTALLED: bgp_pbim->installed = true; bgp_pbim->install_in_progress = false; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received IPSET_INSTALLED", __func__); break; case ZAPI_IPSET_FAIL_REMOVE: case ZAPI_IPSET_REMOVED: if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received IPSET REMOVED", __func__); break; } return 0; } static int ipset_entry_notify_owner(ZAPI_CALLBACK_ARGS) { uint32_t unique; char ipset_name[ZEBRA_IPSET_NAME_SIZE]; enum zapi_ipset_entry_notify_owner note; struct bgp_pbr_match_entry *bgp_pbime; if (!zapi_ipset_entry_notify_decode( zclient->ibuf, &unique, ipset_name, ¬e)) return -1; bgp_pbime = bgp_pbr_match_ipset_entry_lookup(vrf_id, ipset_name, unique); if (!bgp_pbime) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug( "%s: Fail to look BGP match entry (%u, ID %u)", __func__, note, unique); return 0; } switch (note) { case ZAPI_IPSET_ENTRY_FAIL_INSTALL: if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received IPSET_ENTRY_FAIL_INSTALL", __func__); bgp_pbime->installed = false; bgp_pbime->install_in_progress = false; break; case ZAPI_IPSET_ENTRY_INSTALLED: { struct bgp_path_info *path; struct bgp_path_info_extra *extra; bgp_pbime->installed = true; bgp_pbime->install_in_progress = false; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received IPSET_ENTRY_INSTALLED", __func__); /* link bgp_path_info to bpme */ path = (struct bgp_path_info *)bgp_pbime->path; extra = bgp_path_info_extra_get(path); listnode_add_force(&extra->bgp_fs_pbr, bgp_pbime); } break; case ZAPI_IPSET_ENTRY_FAIL_REMOVE: case ZAPI_IPSET_ENTRY_REMOVED: if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received IPSET_ENTRY_REMOVED", __func__); break; } return 0; } static int iptable_notify_owner(ZAPI_CALLBACK_ARGS) { uint32_t unique; enum zapi_iptable_notify_owner note; struct bgp_pbr_match *bgpm; if (!zapi_iptable_notify_decode( zclient->ibuf, &unique, ¬e)) return -1; bgpm = bgp_pbr_match_iptable_lookup(vrf_id, unique); if (!bgpm) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Fail to look BGP iptable (%u %u)", __func__, note, unique); return 0; } switch (note) { case ZAPI_IPTABLE_FAIL_INSTALL: if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received IPTABLE_FAIL_INSTALL", __func__); bgpm->installed_in_iptable = false; bgpm->install_iptable_in_progress = false; break; case ZAPI_IPTABLE_INSTALLED: bgpm->installed_in_iptable = true; bgpm->install_iptable_in_progress = false; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received IPTABLE_INSTALLED", __func__); bgpm->action->refcnt++; break; case ZAPI_IPTABLE_FAIL_REMOVE: case ZAPI_IPTABLE_REMOVED: if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: Received IPTABLE REMOVED", __func__); break; } return 0; } /* this function is used to forge ip rule, * - either for iptable/ipset using fwmark id * - or for sample ip rule cmd */ static void bgp_encode_pbr_rule_action(struct stream *s, struct bgp_pbr_action *pbra, struct bgp_pbr_rule *pbr) { struct prefix pfx; uint8_t fam = AF_INET; if (pbra->nh.type == NEXTHOP_TYPE_IPV6) fam = AF_INET6; stream_putl(s, 0); /* seqno unused */ if (pbr) stream_putl(s, pbr->priority); else stream_putl(s, 0); /* ruleno unused - priority change * ruleno permits distinguishing various FS PBR entries * - FS PBR entries based on ipset/iptables * - FS PBR entries based on iprule * the latter may contain default routing information injected by FS */ if (pbr) stream_putl(s, pbr->unique); else stream_putl(s, pbra->unique); if (pbr && pbr->flags & MATCH_IP_SRC_SET) memcpy(&pfx, &(pbr->src), sizeof(struct prefix)); else { memset(&pfx, 0, sizeof(pfx)); pfx.family = fam; } stream_putc(s, pfx.family); stream_putc(s, pfx.prefixlen); stream_put(s, &pfx.u.prefix, prefix_blen(&pfx)); stream_putw(s, 0); /* src port */ if (pbr && pbr->flags & MATCH_IP_DST_SET) memcpy(&pfx, &(pbr->dst), sizeof(struct prefix)); else { memset(&pfx, 0, sizeof(pfx)); pfx.family = fam; } stream_putc(s, pfx.family); stream_putc(s, pfx.prefixlen); stream_put(s, &pfx.u.prefix, prefix_blen(&pfx)); stream_putw(s, 0); /* dst port */ /* if pbr present, fwmark is not used */ if (pbr) stream_putl(s, 0); else stream_putl(s, pbra->fwmark); /* fwmark */ stream_putl(s, pbra->table_id); stream_putl(s, 0); /* ifindex unused */ } static void bgp_encode_pbr_ipset_match(struct stream *s, struct bgp_pbr_match *pbim) { stream_putl(s, pbim->unique); stream_putl(s, pbim->type); stream_putc(s, pbim->family); stream_put(s, pbim->ipset_name, ZEBRA_IPSET_NAME_SIZE); } static void bgp_encode_pbr_ipset_entry_match(struct stream *s, struct bgp_pbr_match_entry *pbime) { stream_putl(s, pbime->unique); /* check that back pointer is not null */ stream_put(s, pbime->backpointer->ipset_name, ZEBRA_IPSET_NAME_SIZE); stream_putc(s, pbime->src.family); stream_putc(s, pbime->src.prefixlen); stream_put(s, &pbime->src.u.prefix, prefix_blen(&pbime->src)); stream_putc(s, pbime->dst.family); stream_putc(s, pbime->dst.prefixlen); stream_put(s, &pbime->dst.u.prefix, prefix_blen(&pbime->dst)); stream_putw(s, pbime->src_port_min); stream_putw(s, pbime->src_port_max); stream_putw(s, pbime->dst_port_min); stream_putw(s, pbime->dst_port_max); stream_putc(s, pbime->proto); } static void bgp_encode_pbr_iptable_match(struct stream *s, struct bgp_pbr_action *bpa, struct bgp_pbr_match *pbm) { stream_putl(s, pbm->unique2); stream_putl(s, pbm->type); stream_putl(s, pbm->flags); /* TODO: correlate with what is contained * into bgp_pbr_action. * currently only forward supported */ if (bpa->nh.type == NEXTHOP_TYPE_BLACKHOLE) stream_putl(s, ZEBRA_IPTABLES_DROP); else stream_putl(s, ZEBRA_IPTABLES_FORWARD); stream_putl(s, bpa->fwmark); stream_put(s, pbm->ipset_name, ZEBRA_IPSET_NAME_SIZE); stream_putc(s, pbm->family); stream_putw(s, pbm->pkt_len_min); stream_putw(s, pbm->pkt_len_max); stream_putw(s, pbm->tcp_flags); stream_putw(s, pbm->tcp_mask_flags); stream_putc(s, pbm->dscp_value); stream_putc(s, pbm->fragment); stream_putc(s, pbm->protocol); stream_putw(s, pbm->flow_label); } /* BGP has established connection with Zebra. */ static void bgp_zebra_connected(struct zclient *zclient) { struct bgp *bgp; zclient_num_connects++; /* increment even if not responding */ /* At this point, we may or may not have BGP instances configured, but * we're only interested in the default VRF (others wouldn't have learnt * the VRF from Zebra yet.) */ bgp = bgp_get_default(); if (!bgp) return; bgp_zebra_instance_register(bgp); /* Send the client registration */ bfd_client_sendmsg(zclient, ZEBRA_BFD_CLIENT_REGISTER, bgp->vrf_id); /* tell label pool that zebra is connected */ bgp_lp_event_zebra_up(); /* TODO - What if we have peers and networks configured, do we have to * kick-start them? */ BGP_GR_ROUTER_DETECT_AND_SEND_CAPABILITY_TO_ZEBRA(bgp, bgp->peer); } static int bgp_zebra_process_local_es_add(ZAPI_CALLBACK_ARGS) { esi_t esi; struct bgp *bgp = NULL; struct stream *s = NULL; char buf[ESI_STR_LEN]; struct in_addr originator_ip; uint8_t active; bgp = bgp_lookup_by_vrf_id(vrf_id); if (!bgp) return 0; s = zclient->ibuf; stream_get(&esi, s, sizeof(esi_t)); originator_ip.s_addr = stream_get_ipv4(s); active = stream_getc(s); if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx add ESI %s originator-ip %s active %u", esi_to_str(&esi, buf, sizeof(buf)), inet_ntoa(originator_ip), active); bgp_evpn_local_es_add(bgp, &esi, originator_ip, active); return 0; } static int bgp_zebra_process_local_es_del(ZAPI_CALLBACK_ARGS) { esi_t esi; struct bgp *bgp = NULL; struct stream *s = NULL; char buf[ESI_STR_LEN]; memset(&esi, 0, sizeof(esi_t)); bgp = bgp_lookup_by_vrf_id(vrf_id); if (!bgp) return 0; s = zclient->ibuf; stream_get(&esi, s, sizeof(esi_t)); if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx del ESI %s", esi_to_str(&esi, buf, sizeof(buf))); bgp_evpn_local_es_del(bgp, &esi); return 0; } static int bgp_zebra_process_local_es_evi(ZAPI_CALLBACK_ARGS) { esi_t esi; vni_t vni; struct bgp *bgp; struct stream *s; char buf[ESI_STR_LEN]; bgp = bgp_lookup_by_vrf_id(vrf_id); if (!bgp) return 0; s = zclient->ibuf; stream_get(&esi, s, sizeof(esi_t)); vni = stream_getl(s); if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx %s ESI %s VNI %u", ZEBRA_VNI_ADD ? "add" : "del", esi_to_str(&esi, buf, sizeof(buf)), vni); if (cmd == ZEBRA_LOCAL_ES_EVI_ADD) bgp_evpn_local_es_evi_add(bgp, &esi, vni); else bgp_evpn_local_es_evi_del(bgp, &esi, vni); return 0; } static int bgp_zebra_process_local_l3vni(ZAPI_CALLBACK_ARGS) { int filter = 0; char buf[ETHER_ADDR_STRLEN]; vni_t l3vni = 0; struct ethaddr svi_rmac, vrr_rmac = {.octet = {0} }; struct in_addr originator_ip; struct stream *s; ifindex_t svi_ifindex; bool is_anycast_mac = false; char buf1[ETHER_ADDR_STRLEN]; memset(&svi_rmac, 0, sizeof(struct ethaddr)); memset(&originator_ip, 0, sizeof(struct in_addr)); s = zclient->ibuf; l3vni = stream_getl(s); if (cmd == ZEBRA_L3VNI_ADD) { stream_get(&svi_rmac, s, sizeof(struct ethaddr)); originator_ip.s_addr = stream_get_ipv4(s); stream_get(&filter, s, sizeof(int)); svi_ifindex = stream_getl(s); stream_get(&vrr_rmac, s, sizeof(struct ethaddr)); is_anycast_mac = stream_getl(s); if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx L3-VNI ADD VRF %s VNI %u RMAC svi-mac %s vrr-mac %s filter %s svi-if %u", vrf_id_to_name(vrf_id), l3vni, prefix_mac2str(&svi_rmac, buf, sizeof(buf)), prefix_mac2str(&vrr_rmac, buf1, sizeof(buf1)), filter ? "prefix-routes-only" : "none", svi_ifindex); bgp_evpn_local_l3vni_add(l3vni, vrf_id, &svi_rmac, &vrr_rmac, originator_ip, filter, svi_ifindex, is_anycast_mac); } else { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx L3-VNI DEL VRF %s VNI %u", vrf_id_to_name(vrf_id), l3vni); bgp_evpn_local_l3vni_del(l3vni, vrf_id); } return 0; } static int bgp_zebra_process_local_vni(ZAPI_CALLBACK_ARGS) { struct stream *s; vni_t vni; struct bgp *bgp; struct in_addr vtep_ip = {INADDR_ANY}; vrf_id_t tenant_vrf_id = VRF_DEFAULT; struct in_addr mcast_grp = {INADDR_ANY}; s = zclient->ibuf; vni = stream_getl(s); if (cmd == ZEBRA_VNI_ADD) { vtep_ip.s_addr = stream_get_ipv4(s); stream_get(&tenant_vrf_id, s, sizeof(vrf_id_t)); mcast_grp.s_addr = stream_get_ipv4(s); } bgp = bgp_lookup_by_vrf_id(vrf_id); if (!bgp) return 0; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx VNI %s VRF %s VNI %u tenant-vrf %s", (cmd == ZEBRA_VNI_ADD) ? "add" : "del", vrf_id_to_name(vrf_id), vni, vrf_id_to_name(tenant_vrf_id)); if (cmd == ZEBRA_VNI_ADD) return bgp_evpn_local_vni_add( bgp, vni, vtep_ip.s_addr != INADDR_ANY ? vtep_ip : bgp->router_id, tenant_vrf_id, mcast_grp); else return bgp_evpn_local_vni_del(bgp, vni); } static int bgp_zebra_process_local_macip(ZAPI_CALLBACK_ARGS) { struct stream *s; vni_t vni; struct bgp *bgp; struct ethaddr mac; struct ipaddr ip; int ipa_len; char buf[ETHER_ADDR_STRLEN]; char buf1[INET6_ADDRSTRLEN]; uint8_t flags = 0; uint32_t seqnum = 0; int state = 0; char buf2[ESI_STR_LEN]; esi_t esi; memset(&ip, 0, sizeof(ip)); s = zclient->ibuf; vni = stream_getl(s); stream_get(&mac.octet, s, ETH_ALEN); ipa_len = stream_getl(s); if (ipa_len != 0 && ipa_len != IPV4_MAX_BYTELEN && ipa_len != IPV6_MAX_BYTELEN) { flog_err(EC_BGP_MACIP_LEN, "%u:Recv MACIP %s with invalid IP addr length %d", vrf_id, (cmd == ZEBRA_MACIP_ADD) ? "Add" : "Del", ipa_len); return -1; } if (ipa_len) { ip.ipa_type = (ipa_len == IPV4_MAX_BYTELEN) ? IPADDR_V4 : IPADDR_V6; stream_get(&ip.ip.addr, s, ipa_len); } if (cmd == ZEBRA_MACIP_ADD) { flags = stream_getc(s); seqnum = stream_getl(s); stream_get(&esi, s, sizeof(esi_t)); } else { state = stream_getl(s); } bgp = bgp_lookup_by_vrf_id(vrf_id); if (!bgp) return 0; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%u:Recv MACIP %s f 0x%x MAC %s IP %s VNI %u seq %u state %d ESI %s", vrf_id, (cmd == ZEBRA_MACIP_ADD) ? "Add" : "Del", flags, prefix_mac2str(&mac, buf, sizeof(buf)), ipaddr2str(&ip, buf1, sizeof(buf1)), vni, seqnum, state, esi_to_str(&esi, buf2, sizeof(buf2))); if (cmd == ZEBRA_MACIP_ADD) return bgp_evpn_local_macip_add(bgp, vni, &mac, &ip, flags, seqnum, &esi); else return bgp_evpn_local_macip_del(bgp, vni, &mac, &ip, state); } static void bgp_zebra_process_local_ip_prefix(ZAPI_CALLBACK_ARGS) { struct stream *s = NULL; struct bgp *bgp_vrf = NULL; struct prefix p; char buf[PREFIX_STRLEN]; memset(&p, 0, sizeof(struct prefix)); s = zclient->ibuf; stream_get(&p, s, sizeof(struct prefix)); bgp_vrf = bgp_lookup_by_vrf_id(vrf_id); if (!bgp_vrf) return; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Recv prefix %s %s on vrf %s", prefix2str(&p, buf, sizeof(buf)), (cmd == ZEBRA_IP_PREFIX_ROUTE_ADD) ? "ADD" : "DEL", vrf_id_to_name(vrf_id)); if (cmd == ZEBRA_IP_PREFIX_ROUTE_ADD) { if (p.family == AF_INET) bgp_evpn_advertise_type5_route(bgp_vrf, &p, NULL, AFI_IP, SAFI_UNICAST); else bgp_evpn_advertise_type5_route(bgp_vrf, &p, NULL, AFI_IP6, SAFI_UNICAST); } else { if (p.family == AF_INET) bgp_evpn_withdraw_type5_route(bgp_vrf, &p, AFI_IP, SAFI_UNICAST); else bgp_evpn_withdraw_type5_route(bgp_vrf, &p, AFI_IP6, SAFI_UNICAST); } } static void bgp_zebra_process_label_chunk(ZAPI_CALLBACK_ARGS) { struct stream *s = NULL; uint8_t response_keep; uint32_t first; uint32_t last; uint8_t proto; unsigned short instance; s = zclient->ibuf; STREAM_GETC(s, proto); STREAM_GETW(s, instance); STREAM_GETC(s, response_keep); STREAM_GETL(s, first); STREAM_GETL(s, last); if (zclient->redist_default != proto) { flog_err(EC_BGP_LM_ERROR, "Got LM msg with wrong proto %u", proto); return; } if (zclient->instance != instance) { flog_err(EC_BGP_LM_ERROR, "Got LM msg with wrong instance %u", proto); return; } if (first > last || first < MPLS_LABEL_UNRESERVED_MIN || last > MPLS_LABEL_UNRESERVED_MAX) { flog_err(EC_BGP_LM_ERROR, "%s: Invalid Label chunk: %u - %u", __func__, first, last); return; } if (BGP_DEBUG(zebra, ZEBRA)) { zlog_debug("Label Chunk assign: %u - %u (%u) ", first, last, response_keep); } bgp_lp_event_chunk(response_keep, first, last); stream_failure: /* for STREAM_GETX */ return; } extern struct zebra_privs_t bgpd_privs; static int bgp_ifp_create(struct interface *ifp) { struct bgp *bgp; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("Rx Intf add VRF %u IF %s", ifp->vrf_id, ifp->name); bgp = bgp_lookup_by_vrf_id(ifp->vrf_id); if (!bgp) return 0; bgp_mac_add_mac_entry(ifp); bgp_update_interface_nbrs(bgp, ifp, ifp); return 0; } void bgp_zebra_init(struct thread_master *master, unsigned short instance) { zclient_num_connects = 0; if_zapi_callbacks(bgp_ifp_create, bgp_ifp_up, bgp_ifp_down, bgp_ifp_destroy); /* Set default values. */ zclient = zclient_new(master, &zclient_options_default); zclient_init(zclient, ZEBRA_ROUTE_BGP, 0, &bgpd_privs); zclient->zebra_connected = bgp_zebra_connected; zclient->router_id_update = bgp_router_id_update; zclient->interface_address_add = bgp_interface_address_add; zclient->interface_address_delete = bgp_interface_address_delete; zclient->interface_nbr_address_add = bgp_interface_nbr_address_add; zclient->interface_nbr_address_delete = bgp_interface_nbr_address_delete; zclient->interface_vrf_update = bgp_interface_vrf_update; zclient->redistribute_route_add = zebra_read_route; zclient->redistribute_route_del = zebra_read_route; zclient->nexthop_update = bgp_read_nexthop_update; zclient->import_check_update = bgp_read_import_check_update; zclient->fec_update = bgp_read_fec_update; zclient->local_es_add = bgp_zebra_process_local_es_add; zclient->local_es_del = bgp_zebra_process_local_es_del; zclient->local_vni_add = bgp_zebra_process_local_vni; zclient->local_es_evi_add = bgp_zebra_process_local_es_evi; zclient->local_es_evi_del = bgp_zebra_process_local_es_evi; zclient->local_vni_del = bgp_zebra_process_local_vni; zclient->local_macip_add = bgp_zebra_process_local_macip; zclient->local_macip_del = bgp_zebra_process_local_macip; zclient->local_l3vni_add = bgp_zebra_process_local_l3vni; zclient->local_l3vni_del = bgp_zebra_process_local_l3vni; zclient->local_ip_prefix_add = bgp_zebra_process_local_ip_prefix; zclient->local_ip_prefix_del = bgp_zebra_process_local_ip_prefix; zclient->label_chunk = bgp_zebra_process_label_chunk; zclient->rule_notify_owner = rule_notify_owner; zclient->ipset_notify_owner = ipset_notify_owner; zclient->ipset_entry_notify_owner = ipset_entry_notify_owner; zclient->iptable_notify_owner = iptable_notify_owner; zclient->instance = instance; } void bgp_zebra_destroy(void) { if (zclient == NULL) return; zclient_stop(zclient); zclient_free(zclient); zclient = NULL; } int bgp_zebra_num_connects(void) { return zclient_num_connects; } void bgp_send_pbr_rule_action(struct bgp_pbr_action *pbra, struct bgp_pbr_rule *pbr, bool install) { struct stream *s; if (pbra->install_in_progress && !pbr) return; if (pbr && pbr->install_in_progress) return; if (BGP_DEBUG(zebra, ZEBRA)) { if (pbr) zlog_debug("%s: table %d (ip rule) %d", __func__, pbra->table_id, install); else zlog_debug("%s: table %d fwmark %d %d", __func__, pbra->table_id, pbra->fwmark, install); } s = zclient->obuf; stream_reset(s); zclient_create_header(s, install ? ZEBRA_RULE_ADD : ZEBRA_RULE_DELETE, VRF_DEFAULT); stream_putl(s, 1); /* send one pbr action */ bgp_encode_pbr_rule_action(s, pbra, pbr); stream_putw_at(s, 0, stream_get_endp(s)); if (!zclient_send_message(zclient) && install) { if (!pbr) pbra->install_in_progress = true; else pbr->install_in_progress = true; } } void bgp_send_pbr_ipset_match(struct bgp_pbr_match *pbrim, bool install) { struct stream *s; if (pbrim->install_in_progress) return; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: name %s type %d %d, ID %u", __func__, pbrim->ipset_name, pbrim->type, install, pbrim->unique); s = zclient->obuf; stream_reset(s); zclient_create_header(s, install ? ZEBRA_IPSET_CREATE : ZEBRA_IPSET_DESTROY, VRF_DEFAULT); stream_putl(s, 1); /* send one pbr action */ bgp_encode_pbr_ipset_match(s, pbrim); stream_putw_at(s, 0, stream_get_endp(s)); if (!zclient_send_message(zclient) && install) pbrim->install_in_progress = true; } void bgp_send_pbr_ipset_entry_match(struct bgp_pbr_match_entry *pbrime, bool install) { struct stream *s; if (pbrime->install_in_progress) return; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: name %s %d %d, ID %u", __func__, pbrime->backpointer->ipset_name, pbrime->unique, install, pbrime->unique); s = zclient->obuf; stream_reset(s); zclient_create_header(s, install ? ZEBRA_IPSET_ENTRY_ADD : ZEBRA_IPSET_ENTRY_DELETE, VRF_DEFAULT); stream_putl(s, 1); /* send one pbr action */ bgp_encode_pbr_ipset_entry_match(s, pbrime); stream_putw_at(s, 0, stream_get_endp(s)); if (!zclient_send_message(zclient) && install) pbrime->install_in_progress = true; } static void bgp_encode_pbr_interface_list(struct bgp *bgp, struct stream *s, uint8_t family) { struct bgp_pbr_config *bgp_pbr_cfg = bgp->bgp_pbr_cfg; struct bgp_pbr_interface_head *head; struct bgp_pbr_interface *pbr_if; struct interface *ifp; if (!bgp_pbr_cfg) return; if (family == AF_INET) head = &(bgp_pbr_cfg->ifaces_by_name_ipv4); else head = &(bgp_pbr_cfg->ifaces_by_name_ipv6); RB_FOREACH (pbr_if, bgp_pbr_interface_head, head) { ifp = if_lookup_by_name(pbr_if->name, bgp->vrf_id); if (ifp) stream_putl(s, ifp->ifindex); } } static int bgp_pbr_get_ifnumber(struct bgp *bgp, uint8_t family) { struct bgp_pbr_config *bgp_pbr_cfg = bgp->bgp_pbr_cfg; struct bgp_pbr_interface_head *head; struct bgp_pbr_interface *pbr_if; int cnt = 0; if (!bgp_pbr_cfg) return 0; if (family == AF_INET) head = &(bgp_pbr_cfg->ifaces_by_name_ipv4); else head = &(bgp_pbr_cfg->ifaces_by_name_ipv6); RB_FOREACH (pbr_if, bgp_pbr_interface_head, head) { if (if_lookup_by_name(pbr_if->name, bgp->vrf_id)) cnt++; } return cnt; } void bgp_send_pbr_iptable(struct bgp_pbr_action *pba, struct bgp_pbr_match *pbm, bool install) { struct stream *s; int ret = 0; int nb_interface; if (pbm->install_iptable_in_progress) return; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("%s: name %s type %d mark %d %d, ID %u", __func__, pbm->ipset_name, pbm->type, pba->fwmark, install, pbm->unique2); s = zclient->obuf; stream_reset(s); zclient_create_header(s, install ? ZEBRA_IPTABLE_ADD : ZEBRA_IPTABLE_DELETE, VRF_DEFAULT); bgp_encode_pbr_iptable_match(s, pba, pbm); nb_interface = bgp_pbr_get_ifnumber(pba->bgp, pbm->family); stream_putl(s, nb_interface); if (nb_interface) bgp_encode_pbr_interface_list(pba->bgp, s, pbm->family); stream_putw_at(s, 0, stream_get_endp(s)); ret = zclient_send_message(zclient); if (install) { if (ret) pba->refcnt++; else pbm->install_iptable_in_progress = true; } } /* inject in table a default route to: * - if nexthop IP is present : to this nexthop * - if vrf is different from local : to the matching VRF */ void bgp_zebra_announce_default(struct bgp *bgp, struct nexthop *nh, afi_t afi, uint32_t table_id, bool announce) { struct zapi_nexthop *api_nh; struct zapi_route api; struct prefix p; if (!nh || (nh->type != NEXTHOP_TYPE_IPV4 && nh->type != NEXTHOP_TYPE_IPV6) || nh->vrf_id == VRF_UNKNOWN) return; memset(&p, 0, sizeof(struct prefix)); if (afi != AFI_IP && afi != AFI_IP6) return; p.family = afi2family(afi); memset(&api, 0, sizeof(api)); api.vrf_id = bgp->vrf_id; api.type = ZEBRA_ROUTE_BGP; api.safi = SAFI_UNICAST; api.prefix = p; api.tableid = table_id; api.nexthop_num = 1; SET_FLAG(api.message, ZAPI_MESSAGE_TABLEID); SET_FLAG(api.message, ZAPI_MESSAGE_NEXTHOP); api_nh = &api.nexthops[0]; api.distance = ZEBRA_EBGP_DISTANCE_DEFAULT; SET_FLAG(api.message, ZAPI_MESSAGE_DISTANCE); /* redirect IP */ if (afi == AFI_IP && nh->gate.ipv4.s_addr != INADDR_ANY) { char buff[PREFIX_STRLEN]; api_nh->vrf_id = nh->vrf_id; api_nh->gate.ipv4 = nh->gate.ipv4; api_nh->type = NEXTHOP_TYPE_IPV4; inet_ntop(AF_INET, &(nh->gate.ipv4), buff, INET_ADDRSTRLEN); if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("BGP: %s default route to %s table %d (redirect IP)", announce ? "adding" : "withdrawing", buff, table_id); zclient_route_send(announce ? ZEBRA_ROUTE_ADD : ZEBRA_ROUTE_DELETE, zclient, &api); } else if (afi == AFI_IP6 && memcmp(&nh->gate.ipv6, &in6addr_any, sizeof(struct in6_addr))) { char buff[PREFIX_STRLEN]; api_nh->vrf_id = nh->vrf_id; memcpy(&api_nh->gate.ipv6, &nh->gate.ipv6, sizeof(struct in6_addr)); api_nh->type = NEXTHOP_TYPE_IPV6; inet_ntop(AF_INET6, &(nh->gate.ipv6), buff, INET_ADDRSTRLEN); if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("BGP: %s default route to %s table %d (redirect IP)", announce ? "adding" : "withdrawing", buff, table_id); zclient_route_send(announce ? ZEBRA_ROUTE_ADD : ZEBRA_ROUTE_DELETE, zclient, &api); } else if (nh->vrf_id != bgp->vrf_id) { struct vrf *vrf; struct interface *ifp; vrf = vrf_lookup_by_id(nh->vrf_id); if (!vrf) return; /* create default route with interface * with nexthop-vrf */ ifp = if_lookup_by_name_all_vrf(vrf->name); if (!ifp) return; api_nh->vrf_id = nh->vrf_id; api_nh->type = NEXTHOP_TYPE_IFINDEX; api_nh->ifindex = ifp->ifindex; if (BGP_DEBUG(zebra, ZEBRA)) zlog_info("BGP: %s default route to %s table %d (redirect VRF)", announce ? "adding" : "withdrawing", vrf->name, table_id); zclient_route_send(announce ? ZEBRA_ROUTE_ADD : ZEBRA_ROUTE_DELETE, zclient, &api); return; } } /* Send capabilities to RIB */ int bgp_zebra_send_capabilities(struct bgp *bgp, bool disable) { struct zapi_cap api; int ret = BGP_GR_SUCCESS; if (zclient == NULL) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("zclient invalid"); return BGP_GR_FAILURE; } /* Check if the client is connected */ if ((zclient->sock < 0) || (zclient->t_connect)) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("client not connected"); return BGP_GR_FAILURE; } /* Check if capability is already sent. If the flag force is set * send the capability since this can be initial bgp configuration */ memset(&api, 0, sizeof(struct zapi_cap)); if (disable) { api.cap = ZEBRA_CLIENT_GR_DISABLE; api.vrf_id = bgp->vrf_id; } else { api.cap = ZEBRA_CLIENT_GR_CAPABILITIES; api.stale_removal_time = bgp->rib_stale_time; api.vrf_id = bgp->vrf_id; } if (zclient_capabilities_send(ZEBRA_CLIENT_CAPABILITIES, zclient, &api) < 0) { zlog_err("error sending capability"); ret = BGP_GR_FAILURE; } else { if (disable) bgp->present_zebra_gr_state = ZEBRA_GR_DISABLE; else bgp->present_zebra_gr_state = ZEBRA_GR_ENABLE; if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("send capabilty success"); ret = BGP_GR_SUCCESS; } return ret; } /* Send route update pesding or completed status to RIB for the * specific AFI, SAFI */ int bgp_zebra_update(afi_t afi, safi_t safi, vrf_id_t vrf_id, int type) { struct zapi_cap api = {0}; if (zclient == NULL) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("zclient == NULL, invalid"); return BGP_GR_FAILURE; } /* Check if the client is connected */ if ((zclient->sock < 0) || (zclient->t_connect)) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("client not connected"); return BGP_GR_FAILURE; } api.afi = afi; api.safi = safi; api.vrf_id = vrf_id; api.cap = type; if (zclient_capabilities_send(ZEBRA_CLIENT_CAPABILITIES, zclient, &api) < 0) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("error sending capability"); return BGP_GR_FAILURE; } return BGP_GR_SUCCESS; } /* Send RIB stale timer update */ int bgp_zebra_stale_timer_update(struct bgp *bgp) { struct zapi_cap api; if (zclient == NULL) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("zclient invalid"); return BGP_GR_FAILURE; } /* Check if the client is connected */ if ((zclient->sock < 0) || (zclient->t_connect)) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("client not connected"); return BGP_GR_FAILURE; } memset(&api, 0, sizeof(struct zapi_cap)); api.cap = ZEBRA_CLIENT_RIB_STALE_TIME; api.stale_removal_time = bgp->rib_stale_time; api.vrf_id = bgp->vrf_id; if (zclient_capabilities_send(ZEBRA_CLIENT_CAPABILITIES, zclient, &api) < 0) { if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("error sending capability"); return BGP_GR_FAILURE; } if (BGP_DEBUG(zebra, ZEBRA)) zlog_debug("send capabilty success"); return BGP_GR_SUCCESS; }