/* BGP nexthop scan * Copyright (C) 2000 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 "thread.h" #include "prefix.h" #include "zclient.h" #include "stream.h" #include "network.h" #include "log.h" #include "memory.h" #include "hash.h" #include "jhash.h" #include "nexthop.h" #include "queue.h" #include "filter.h" #include "bgpd/bgpd.h" #include "bgpd/bgp_table.h" #include "bgpd/bgp_route.h" #include "bgpd/bgp_attr.h" #include "bgpd/bgp_nexthop.h" #include "bgpd/bgp_nht.h" #include "bgpd/bgp_debug.h" #include "bgpd/bgp_damp.h" #include "bgpd/bgp_fsm.h" #include "bgpd/bgp_vty.h" DEFINE_MTYPE_STATIC(BGPD, MARTIAN_STRING, "BGP Martian Address Intf String"); char *bnc_str(struct bgp_nexthop_cache *bnc, char *buf, int size) { prefix2str(&(bnc->node->p), buf, size); return buf; } void bnc_nexthop_free(struct bgp_nexthop_cache *bnc) { nexthops_free(bnc->nexthop); } struct bgp_nexthop_cache *bnc_new(void) { struct bgp_nexthop_cache *bnc; bnc = XCALLOC(MTYPE_BGP_NEXTHOP_CACHE, sizeof(struct bgp_nexthop_cache)); LIST_INIT(&(bnc->paths)); return bnc; } void bnc_free(struct bgp_nexthop_cache *bnc) { bnc_nexthop_free(bnc); XFREE(MTYPE_BGP_NEXTHOP_CACHE, bnc); } /* Reset and free all BGP nexthop cache. */ static void bgp_nexthop_cache_reset(struct bgp_table *table) { struct bgp_node *rn; struct bgp_nexthop_cache *bnc; for (rn = bgp_table_top(table); rn; rn = bgp_route_next(rn)) { bnc = bgp_node_get_bgp_nexthop_info(rn); if (!bnc) continue; while (!LIST_EMPTY(&(bnc->paths))) { struct bgp_path_info *path = LIST_FIRST(&(bnc->paths)); path_nh_map(path, bnc, false); } bnc_free(bnc); bgp_node_set_bgp_nexthop_info(rn, NULL); bgp_unlock_node(rn); } } static void *bgp_tip_hash_alloc(void *p) { const struct in_addr *val = (const struct in_addr *)p; struct tip_addr *addr; addr = XMALLOC(MTYPE_TIP_ADDR, sizeof(struct tip_addr)); addr->refcnt = 0; addr->addr.s_addr = val->s_addr; return addr; } static void bgp_tip_hash_free(void *addr) { XFREE(MTYPE_TIP_ADDR, addr); } static unsigned int bgp_tip_hash_key_make(const void *p) { const struct tip_addr *addr = p; return jhash_1word(addr->addr.s_addr, 0); } static bool bgp_tip_hash_cmp(const void *p1, const void *p2) { const struct tip_addr *addr1 = p1; const struct tip_addr *addr2 = p2; return addr1->addr.s_addr == addr2->addr.s_addr; } void bgp_tip_hash_init(struct bgp *bgp) { bgp->tip_hash = hash_create(bgp_tip_hash_key_make, bgp_tip_hash_cmp, "BGP TIP hash"); } void bgp_tip_hash_destroy(struct bgp *bgp) { if (bgp->tip_hash == NULL) return; hash_clean(bgp->tip_hash, bgp_tip_hash_free); hash_free(bgp->tip_hash); bgp->tip_hash = NULL; } void bgp_tip_add(struct bgp *bgp, struct in_addr *tip) { struct tip_addr tmp; struct tip_addr *addr; tmp.addr = *tip; addr = hash_get(bgp->tip_hash, &tmp, bgp_tip_hash_alloc); if (!addr) return; addr->refcnt++; } void bgp_tip_del(struct bgp *bgp, struct in_addr *tip) { struct tip_addr tmp; struct tip_addr *addr; tmp.addr = *tip; addr = hash_lookup(bgp->tip_hash, &tmp); /* may have been deleted earlier by bgp_interface_down() */ if (addr == NULL) return; addr->refcnt--; if (addr->refcnt == 0) { hash_release(bgp->tip_hash, addr); XFREE(MTYPE_TIP_ADDR, addr); } } /* BGP own address structure */ struct bgp_addr { struct prefix p; struct list *ifp_name_list; }; static void show_address_entry(struct hash_bucket *bucket, void *args) { struct vty *vty = (struct vty *)args; struct bgp_addr *addr = (struct bgp_addr *)bucket->data; char *name; struct listnode *node; char str[INET6_ADDRSTRLEN] = {0}; vty_out(vty, "addr: %s, count: %d : ", inet_ntop(addr->p.family, &(addr->p.u.prefix), str, INET6_ADDRSTRLEN), addr->ifp_name_list->count); for (ALL_LIST_ELEMENTS_RO(addr->ifp_name_list, node, name)) { vty_out(vty, " %s,", name); } vty_out(vty, "\n"); } void bgp_nexthop_show_address_hash(struct vty *vty, struct bgp *bgp) { hash_iterate(bgp->address_hash, (void (*)(struct hash_bucket *, void *))show_address_entry, vty); } static void bgp_address_hash_string_del(void *val) { char *data = val; XFREE(MTYPE_MARTIAN_STRING, data); } static void *bgp_address_hash_alloc(void *p) { struct bgp_addr *copy_addr = p; struct bgp_addr *addr = NULL; addr = XMALLOC(MTYPE_BGP_ADDR, sizeof(struct bgp_addr)); prefix_copy(&addr->p, ©_addr->p); addr->ifp_name_list = list_new(); addr->ifp_name_list->del = bgp_address_hash_string_del; return addr; } static void bgp_address_hash_free(void *data) { struct bgp_addr *addr = data; list_delete(&addr->ifp_name_list); XFREE(MTYPE_BGP_ADDR, addr); } static unsigned int bgp_address_hash_key_make(const void *p) { const struct bgp_addr *addr = p; return prefix_hash_key(&addr->p); } static bool bgp_address_hash_cmp(const void *p1, const void *p2) { const struct bgp_addr *addr1 = p1; const struct bgp_addr *addr2 = p2; return prefix_same(&addr1->p, &addr2->p); } void bgp_address_init(struct bgp *bgp) { bgp->address_hash = hash_create(bgp_address_hash_key_make, bgp_address_hash_cmp, "BGP Connected Address Hash"); } void bgp_address_destroy(struct bgp *bgp) { if (bgp->address_hash == NULL) return; hash_clean(bgp->address_hash, bgp_address_hash_free); hash_free(bgp->address_hash); bgp->address_hash = NULL; } static void bgp_address_add(struct bgp *bgp, struct connected *ifc, struct prefix *p) { struct bgp_addr tmp; struct bgp_addr *addr; struct listnode *node; char *name; tmp.p = *p; if (tmp.p.family == AF_INET) tmp.p.prefixlen = IPV4_MAX_BITLEN; else if (tmp.p.family == AF_INET6) tmp.p.prefixlen = IPV6_MAX_BITLEN; addr = hash_get(bgp->address_hash, &tmp, bgp_address_hash_alloc); for (ALL_LIST_ELEMENTS_RO(addr->ifp_name_list, node, name)) { if (strcmp(ifc->ifp->name, name) == 0) break; } if (!node) { name = XSTRDUP(MTYPE_MARTIAN_STRING, ifc->ifp->name); listnode_add(addr->ifp_name_list, name); } } static void bgp_address_del(struct bgp *bgp, struct connected *ifc, struct prefix *p) { struct bgp_addr tmp; struct bgp_addr *addr; struct listnode *node; char *name; tmp.p = *p; if (tmp.p.family == AF_INET) tmp.p.prefixlen = IPV4_MAX_BITLEN; else if (tmp.p.family == AF_INET6) tmp.p.prefixlen = IPV6_MAX_BITLEN; addr = hash_lookup(bgp->address_hash, &tmp); /* may have been deleted earlier by bgp_interface_down() */ if (addr == NULL) return; for (ALL_LIST_ELEMENTS_RO(addr->ifp_name_list, node, name)) { if (strcmp(ifc->ifp->name, name) == 0) break; } if (node) { list_delete_node(addr->ifp_name_list, node); XFREE(MTYPE_MARTIAN_STRING, name); } if (addr->ifp_name_list->count == 0) { hash_release(bgp->address_hash, addr); list_delete(&addr->ifp_name_list); XFREE(MTYPE_BGP_ADDR, addr); } } struct bgp_connected_ref { unsigned int refcnt; }; void bgp_connected_add(struct bgp *bgp, struct connected *ifc) { struct prefix p; struct prefix *addr; struct bgp_node *rn; struct bgp_connected_ref *bc; struct listnode *node, *nnode; struct peer *peer; addr = ifc->address; p = *(CONNECTED_PREFIX(ifc)); if (addr->family == AF_INET) { apply_mask_ipv4((struct prefix_ipv4 *)&p); if (prefix_ipv4_any((struct prefix_ipv4 *)&p)) return; bgp_address_add(bgp, ifc, addr); rn = bgp_node_get(bgp->connected_table[AFI_IP], (struct prefix *)&p); bc = bgp_node_get_bgp_connected_ref_info(rn); if (bc) bc->refcnt++; else { bc = XCALLOC(MTYPE_BGP_CONN, sizeof(struct bgp_connected_ref)); bc->refcnt = 1; bgp_node_set_bgp_connected_ref_info(rn, bc); } for (ALL_LIST_ELEMENTS(bgp->peer, node, nnode, peer)) { if (peer->conf_if && (strcmp(peer->conf_if, ifc->ifp->name) == 0) && peer->status != Established && !CHECK_FLAG(peer->flags, PEER_FLAG_IFPEER_V6ONLY)) { if (peer_active(peer)) BGP_EVENT_ADD(peer, BGP_Stop); BGP_EVENT_ADD(peer, BGP_Start); } } } else if (addr->family == AF_INET6) { apply_mask_ipv6((struct prefix_ipv6 *)&p); if (IN6_IS_ADDR_UNSPECIFIED(&p.u.prefix6)) return; if (IN6_IS_ADDR_LINKLOCAL(&p.u.prefix6)) return; bgp_address_add(bgp, ifc, addr); rn = bgp_node_get(bgp->connected_table[AFI_IP6], (struct prefix *)&p); bc = bgp_node_get_bgp_connected_ref_info(rn); if (bc) bc->refcnt++; else { bc = XCALLOC(MTYPE_BGP_CONN, sizeof(struct bgp_connected_ref)); bc->refcnt = 1; bgp_node_set_bgp_connected_ref_info(rn, bc); } } } void bgp_connected_delete(struct bgp *bgp, struct connected *ifc) { struct prefix p; struct prefix *addr; struct bgp_node *rn = NULL; struct bgp_connected_ref *bc; addr = ifc->address; p = *(CONNECTED_PREFIX(ifc)); apply_mask(&p); if (addr->family == AF_INET) { if (prefix_ipv4_any((struct prefix_ipv4 *)&p)) return; bgp_address_del(bgp, ifc, addr); rn = bgp_node_lookup(bgp->connected_table[AFI_IP], &p); } else if (addr->family == AF_INET6) { if (IN6_IS_ADDR_UNSPECIFIED(&p.u.prefix6)) return; if (IN6_IS_ADDR_LINKLOCAL(&p.u.prefix6)) return; bgp_address_del(bgp, ifc, addr); rn = bgp_node_lookup(bgp->connected_table[AFI_IP6], (struct prefix *)&p); } if (!rn) return; bc = bgp_node_get_bgp_connected_ref_info(rn); bc->refcnt--; if (bc->refcnt == 0) { XFREE(MTYPE_BGP_CONN, bc); bgp_node_set_bgp_connected_ref_info(rn, NULL); } bgp_unlock_node(rn); bgp_unlock_node(rn); } static void bgp_connected_cleanup(struct route_table *table, struct route_node *rn) { struct bgp_connected_ref *bc; struct bgp_node *bn = bgp_node_from_rnode(rn); bc = bgp_node_get_bgp_connected_ref_info(bn); if (!bc) return; bc->refcnt--; if (bc->refcnt == 0) { XFREE(MTYPE_BGP_CONN, bc); bgp_node_set_bgp_connected_ref_info(bn, NULL); } } int bgp_nexthop_self(struct bgp *bgp, afi_t afi, uint8_t type, uint8_t sub_type, struct attr *attr, struct bgp_node *rn) { uint8_t new_afi = afi == AFI_IP ? AF_INET : AF_INET6; struct bgp_addr tmp_addr = {{0}}, *addr = NULL; struct tip_addr tmp_tip, *tip = NULL; bool is_bgp_static_route = ((type == ZEBRA_ROUTE_BGP) && (sub_type == BGP_ROUTE_STATIC)) ? true : false; if (!is_bgp_static_route) new_afi = BGP_ATTR_NEXTHOP_AFI_IP6(attr) ? AF_INET6 : AF_INET; tmp_addr.p.family = new_afi; switch (new_afi) { case AF_INET: if (is_bgp_static_route) { tmp_addr.p.u.prefix4 = rn->p.u.prefix4; tmp_addr.p.prefixlen = rn->p.prefixlen; } else { /* Here we need to find out which nexthop to be used*/ if (attr->flag & ATTR_FLAG_BIT(BGP_ATTR_NEXT_HOP)) { tmp_addr.p.u.prefix4 = attr->nexthop; tmp_addr.p.prefixlen = IPV4_MAX_BITLEN; } else if ((attr->mp_nexthop_len) && ((attr->mp_nexthop_len == BGP_ATTR_NHLEN_IPV4) || (attr->mp_nexthop_len == BGP_ATTR_NHLEN_VPNV4))) { tmp_addr.p.u.prefix4 = attr->mp_nexthop_global_in; tmp_addr.p.prefixlen = IPV4_MAX_BITLEN; } else return 0; } break; case AF_INET6: if (is_bgp_static_route) { tmp_addr.p.u.prefix6 = rn->p.u.prefix6; tmp_addr.p.prefixlen = rn->p.prefixlen; } else { tmp_addr.p.u.prefix6 = attr->mp_nexthop_global; tmp_addr.p.prefixlen = IPV6_MAX_BITLEN; } break; default: break; } addr = hash_lookup(bgp->address_hash, &tmp_addr); if (addr) return 1; if (new_afi == AF_INET) { memset(&tmp_tip, 0, sizeof(struct tip_addr)); tmp_tip.addr = attr->nexthop; if (attr->flag & ATTR_FLAG_BIT(BGP_ATTR_NEXT_HOP)) { tmp_tip.addr = attr->nexthop; } else if ((attr->mp_nexthop_len) && ((attr->mp_nexthop_len == BGP_ATTR_NHLEN_IPV4) || (attr->mp_nexthop_len == BGP_ATTR_NHLEN_VPNV4))) { tmp_tip.addr = attr->mp_nexthop_global_in; } tip = hash_lookup(bgp->tip_hash, &tmp_tip); if (tip) return 1; } return 0; } int bgp_multiaccess_check_v4(struct in_addr nexthop, struct peer *peer) { struct bgp_node *rn1; struct bgp_node *rn2; struct prefix p; int ret; p.family = AF_INET; p.prefixlen = IPV4_MAX_BITLEN; p.u.prefix4 = nexthop; rn1 = bgp_node_match(peer->bgp->connected_table[AFI_IP], &p); if (!rn1) return 0; p.family = AF_INET; p.prefixlen = IPV4_MAX_BITLEN; p.u.prefix4 = peer->su.sin.sin_addr; rn2 = bgp_node_match(peer->bgp->connected_table[AFI_IP], &p); if (!rn2) { bgp_unlock_node(rn1); return 0; } ret = (rn1 == rn2) ? 1 : 0; bgp_unlock_node(rn1); bgp_unlock_node(rn2); return (ret); } int bgp_multiaccess_check_v6(struct in6_addr nexthop, struct peer *peer) { struct bgp_node *rn1; struct bgp_node *rn2; struct prefix p; int ret; p.family = AF_INET6; p.prefixlen = IPV6_MAX_BITLEN; p.u.prefix6 = nexthop; rn1 = bgp_node_match(peer->bgp->connected_table[AFI_IP6], &p); if (!rn1) return 0; p.family = AF_INET6; p.prefixlen = IPV6_MAX_BITLEN; p.u.prefix6 = peer->su.sin6.sin6_addr; rn2 = bgp_node_match(peer->bgp->connected_table[AFI_IP6], &p); if (!rn2) { bgp_unlock_node(rn1); return 0; } ret = (rn1 == rn2) ? 1 : 0; bgp_unlock_node(rn1); bgp_unlock_node(rn2); return ret; } int bgp_subgrp_multiaccess_check_v6(struct in6_addr nexthop, struct update_subgroup *subgrp) { struct bgp_node *rn1 = NULL, *rn2 = NULL; struct peer_af *paf = NULL; struct prefix p = {0}, np = {0}; struct bgp *bgp = NULL; np.family = AF_INET6; np.prefixlen = IPV6_MAX_BITLEN; np.u.prefix6 = nexthop; p.family = AF_INET; p.prefixlen = IPV6_MAX_BITLEN; bgp = SUBGRP_INST(subgrp); rn1 = bgp_node_match(bgp->connected_table[AFI_IP6], &np); if (!rn1) return 0; SUBGRP_FOREACH_PEER (subgrp, paf) { p.u.prefix6 = paf->peer->su.sin6.sin6_addr; rn2 = bgp_node_match(bgp->connected_table[AFI_IP6], &p); if (rn1 == rn2) { bgp_unlock_node(rn1); bgp_unlock_node(rn2); return 1; } if (rn2) bgp_unlock_node(rn2); } bgp_unlock_node(rn1); return 0; } int bgp_subgrp_multiaccess_check_v4(struct in_addr nexthop, struct update_subgroup *subgrp) { struct bgp_node *rn1, *rn2; struct peer_af *paf; struct prefix p, np; struct bgp *bgp; np.family = AF_INET; np.prefixlen = IPV4_MAX_BITLEN; np.u.prefix4 = nexthop; p.family = AF_INET; p.prefixlen = IPV4_MAX_BITLEN; bgp = SUBGRP_INST(subgrp); rn1 = bgp_node_match(bgp->connected_table[AFI_IP], &np); if (!rn1) return 0; SUBGRP_FOREACH_PEER (subgrp, paf) { p.u.prefix4 = paf->peer->su.sin.sin_addr; rn2 = bgp_node_match(bgp->connected_table[AFI_IP], &p); if (rn1 == rn2) { bgp_unlock_node(rn1); bgp_unlock_node(rn2); return 1; } if (rn2) bgp_unlock_node(rn2); } bgp_unlock_node(rn1); return 0; } static void bgp_show_nexthops_detail(struct vty *vty, struct bgp *bgp, struct bgp_nexthop_cache *bnc) { char buf[PREFIX2STR_BUFFER]; struct nexthop *nexthop; for (nexthop = bnc->nexthop; nexthop; nexthop = nexthop->next) switch (nexthop->type) { case NEXTHOP_TYPE_IPV6: vty_out(vty, " gate %s\n", inet_ntop(AF_INET6, &nexthop->gate.ipv6, buf, sizeof(buf))); break; case NEXTHOP_TYPE_IPV6_IFINDEX: vty_out(vty, " gate %s, if %s\n", inet_ntop(AF_INET6, &nexthop->gate.ipv6, buf, sizeof(buf)), ifindex2ifname(nexthop->ifindex, bgp->vrf_id)); break; case NEXTHOP_TYPE_IPV4: vty_out(vty, " gate %s\n", inet_ntop(AF_INET, &nexthop->gate.ipv4, buf, sizeof(buf))); break; case NEXTHOP_TYPE_IFINDEX: vty_out(vty, " if %s\n", ifindex2ifname(nexthop->ifindex, bgp->vrf_id)); break; case NEXTHOP_TYPE_IPV4_IFINDEX: vty_out(vty, " gate %s, if %s\n", inet_ntop(AF_INET, &nexthop->gate.ipv4, buf, sizeof(buf)), ifindex2ifname(nexthop->ifindex, bgp->vrf_id)); break; case NEXTHOP_TYPE_BLACKHOLE: vty_out(vty, " blackhole\n"); break; default: vty_out(vty, " invalid nexthop type %u\n", nexthop->type); } } static void bgp_show_nexthops(struct vty *vty, struct bgp *bgp, int detail, bool import_table) { struct bgp_node *rn; struct bgp_nexthop_cache *bnc; char buf[PREFIX2STR_BUFFER]; time_t tbuf; afi_t afi; struct bgp_table **table; if (import_table) vty_out(vty, "Current BGP import check cache:\n"); else vty_out(vty, "Current BGP nexthop cache:\n"); if (import_table) table = bgp->import_check_table; else table = bgp->nexthop_cache_table; for (afi = AFI_IP; afi < AFI_MAX; afi++) { if (!table || !table[afi]) continue; for (rn = bgp_table_top(table[afi]); rn; rn = bgp_route_next(rn)) { struct peer *peer; bnc = bgp_node_get_bgp_nexthop_info(rn); if (!bnc) continue; peer = (struct peer *)bnc->nht_info; if (CHECK_FLAG(bnc->flags, BGP_NEXTHOP_VALID)) { vty_out(vty, " %s valid [IGP metric %d], #paths %d", inet_ntop(rn->p.family, &rn->p.u.prefix, buf, sizeof(buf)), bnc->metric, bnc->path_count); if (peer) vty_out(vty, ", peer %s", peer->host); vty_out(vty, "\n"); if (!detail) continue; bgp_show_nexthops_detail(vty, bgp, bnc); } else { vty_out(vty, " %s invalid", inet_ntop(rn->p.family, &rn->p.u.prefix, buf, sizeof(buf))); if (peer) vty_out(vty, ", peer %s", peer->host); vty_out(vty, "\n"); if (CHECK_FLAG(bnc->flags, BGP_NEXTHOP_CONNECTED)) vty_out(vty, " Must be Connected\n"); if (!CHECK_FLAG(bnc->flags, BGP_NEXTHOP_REGISTERED)) vty_out(vty, " Is not Registered\n"); } tbuf = time(NULL) - (bgp_clock() - bnc->last_update); vty_out(vty, " Last update: %s", ctime(&tbuf)); vty_out(vty, "\n"); } } } static int show_ip_bgp_nexthop_table(struct vty *vty, const char *name, int detail, bool import_table) { struct bgp *bgp; if (name) bgp = bgp_lookup_by_name(name); else bgp = bgp_get_default(); if (!bgp) { vty_out(vty, "%% No such BGP instance exist\n"); return CMD_WARNING; } bgp_show_nexthops(vty, bgp, detail, import_table); return CMD_SUCCESS; } static void bgp_show_all_instances_nexthops_vty(struct vty *vty) { struct listnode *node, *nnode; struct bgp *bgp; for (ALL_LIST_ELEMENTS(bm->bgp, node, nnode, bgp)) { vty_out(vty, "\nInstance %s:\n", (bgp->inst_type == BGP_INSTANCE_TYPE_DEFAULT) ? VRF_DEFAULT_NAME : bgp->name); bgp_show_nexthops(vty, bgp, 0, false); } } DEFUN (show_ip_bgp_nexthop, show_ip_bgp_nexthop_cmd, "show [ip] bgp [ VIEWVRFNAME] nexthop [detail]", SHOW_STR IP_STR BGP_STR BGP_INSTANCE_HELP_STR "BGP nexthop table\n" "Show detailed information\n") { int idx = 0; char *vrf = NULL; if (argv_find(argv, argc, "view", &idx) || argv_find(argv, argc, "vrf", &idx)) vrf = argv[++idx]->arg; int detail = argv_find(argv, argc, "detail", &idx) ? 1 : 0; return show_ip_bgp_nexthop_table(vty, vrf, detail, false); } DEFUN (show_ip_bgp_import_check, show_ip_bgp_import_check_cmd, "show [ip] bgp [ VIEWVRFNAME] import-check-table [detail]", SHOW_STR IP_STR BGP_STR BGP_INSTANCE_HELP_STR "BGP import check table\n" "Show detailed information\n") { int idx = 0; char *vrf = NULL; if (argv_find(argv, argc, "view", &idx) || argv_find(argv, argc, "vrf", &idx)) vrf = argv[++idx]->arg; int detail = argv_find(argv, argc, "detail", &idx) ? 1 : 0; return show_ip_bgp_nexthop_table(vty, vrf, detail, true); } DEFUN (show_ip_bgp_instance_all_nexthop, show_ip_bgp_instance_all_nexthop_cmd, "show [ip] bgp all nexthop", SHOW_STR IP_STR BGP_STR BGP_INSTANCE_ALL_HELP_STR "BGP nexthop table\n") { bgp_show_all_instances_nexthops_vty(vty); return CMD_SUCCESS; } void bgp_scan_init(struct bgp *bgp) { afi_t afi; for (afi = AFI_IP; afi < AFI_MAX; afi++) { bgp->nexthop_cache_table[afi] = bgp_table_init(bgp, afi, SAFI_UNICAST); bgp->connected_table[afi] = bgp_table_init(bgp, afi, SAFI_UNICAST); bgp->import_check_table[afi] = bgp_table_init(bgp, afi, SAFI_UNICAST); } } void bgp_scan_vty_init(void) { install_element(VIEW_NODE, &show_ip_bgp_nexthop_cmd); install_element(VIEW_NODE, &show_ip_bgp_import_check_cmd); install_element(VIEW_NODE, &show_ip_bgp_instance_all_nexthop_cmd); } void bgp_scan_finish(struct bgp *bgp) { afi_t afi; for (afi = AFI_IP; afi < AFI_MAX; afi++) { /* Only the current one needs to be reset. */ bgp_nexthop_cache_reset(bgp->nexthop_cache_table[afi]); bgp_table_unlock(bgp->nexthop_cache_table[afi]); bgp->nexthop_cache_table[afi] = NULL; bgp->connected_table[afi]->route_table->cleanup = bgp_connected_cleanup; bgp_table_unlock(bgp->connected_table[afi]); bgp->connected_table[afi] = NULL; bgp_table_unlock(bgp->import_check_table[afi]); bgp->import_check_table[afi] = NULL; } }