/* * Copyright (c) 2016 Cisco and/or its affiliates. * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include <vnet/adj/adj_nbr.h> #include <vnet/adj/adj_internal.h> #include <vnet/ethernet/arp_packet.h> #include <vnet/fib/fib_walk.h> #include <vppinfra/bihash_24_8.h> /* * Vector Hash tables of neighbour (traditional) adjacencies * Key: interface(for the vector index), address (and its proto), * link-type/ether-type. */ static BVT(clib_bihash) **adj_nbr_tables[FIB_PROTOCOL_MAX]; // FIXME SIZE APPROPRIATELY. ASK DAVEB. #define ADJ_NBR_DEFAULT_HASH_NUM_BUCKETS (64 * 64) #define ADJ_NBR_DEFAULT_HASH_MEMORY_SIZE (32<<20) #define ADJ_NBR_SET_KEY(_key, _lt, _nh) \ { \ _key.key[0] = (_nh)->as_u64[0]; \ _key.key[1] = (_nh)->as_u64[1]; \ _key.key[2] = (_lt); \ } #define ADJ_NBR_ITF_OK(_proto, _itf) \ (((_itf) < vec_len(adj_nbr_tables[_proto])) && \ (NULL != adj_nbr_tables[_proto][sw_if_index])) static void adj_nbr_insert (fib_protocol_t nh_proto, vnet_link_t link_type, const ip46_address_t *nh_addr, u32 sw_if_index, adj_index_t adj_index) { BVT(clib_bihash_kv) kv; if (sw_if_index >= vec_len(adj_nbr_tables[nh_proto])) { vec_validate(adj_nbr_tables[nh_proto], sw_if_index); } if (NULL == adj_nbr_tables[nh_proto][sw_if_index]) { adj_nbr_tables[nh_proto][sw_if_index] = clib_mem_alloc_aligned(sizeof(BVT(clib_bihash)), CLIB_CACHE_LINE_BYTES); clib_memset(adj_nbr_tables[nh_proto][sw_if_index], 0, sizeof(BVT(clib_bihash))); BV(clib_bihash_init) (adj_nbr_tables[nh_proto][sw_if_index], "Adjacency Neighbour table", ADJ_NBR_DEFAULT_HASH_NUM_BUCKETS, ADJ_NBR_DEFAULT_HASH_MEMORY_SIZE); } ADJ_NBR_SET_KEY(kv, link_type, nh_addr); kv.value = adj_index; BV(clib_bihash_add_del) (adj_nbr_tables[nh_proto][sw_if_index], &kv, 1); } void adj_nbr_remove (adj_index_t ai, fib_protocol_t nh_proto, vnet_link_t link_type, const ip46_address_t *nh_addr, u32 sw_if_index) { BVT(clib_bihash_kv) kv; if (!ADJ_NBR_ITF_OK(nh_proto, sw_if_index)) return; ADJ_NBR_SET_KEY(kv, link_type, nh_addr); kv.value = ai; BV(clib_bihash_add_del) (adj_nbr_tables[nh_proto][sw_if_index], &kv, 0); } adj_index_t adj_nbr_find (fib_protocol_t nh_proto, vnet_link_t link_type, const ip46_address_t *nh_addr, u32 sw_if_index) { BVT(clib_bihash_kv) kv; ADJ_NBR_SET_KEY(kv, link_type, nh_addr); if (!ADJ_NBR_ITF_OK(nh_proto, sw_if_index)) return (ADJ_INDEX_INVALID); if (BV(clib_bihash_search)(adj_nbr_tables[nh_proto][sw_if_index], &kv, &kv) < 0) { return (ADJ_INDEX_INVALID); } else { return (kv.value); } } static inline u32 adj_get_nd_node (fib_protocol_t proto) { switch (proto) { case FIB_PROTOCOL_IP4: return (ip4_arp_node.index); case FIB_PROTOCOL_IP6: return (ip6_discover_neighbor_node.index); case FIB_PROTOCOL_MPLS: break; } ASSERT(0); return (ip4_arp_node.index); } /** * @brief Check and set feature flags if o/p interface has any o/p features. */ static void adj_nbr_evaluate_feature (adj_index_t ai) { ip_adjacency_t *adj; vnet_feature_main_t *fm = &feature_main; i16 feature_count; u8 arc_index; u32 sw_if_index; adj = adj_get(ai); switch (adj->ia_link) { case VNET_LINK_IP4: arc_index = ip4_main.lookup_main.output_feature_arc_index; break; case VNET_LINK_IP6: arc_index = ip6_main.lookup_main.output_feature_arc_index; break; case VNET_LINK_MPLS: arc_index = mpls_main.output_feature_arc_index; break; default: return; } sw_if_index = adj->rewrite_header.sw_if_index; if (vec_len(fm->feature_count_by_sw_if_index[arc_index]) > sw_if_index) { feature_count = fm->feature_count_by_sw_if_index[arc_index][sw_if_index]; if (feature_count > 0) adj->rewrite_header.flags |= VNET_REWRITE_HAS_FEATURES; } return; } static ip_adjacency_t* adj_nbr_alloc (fib_protocol_t nh_proto, vnet_link_t link_type, const ip46_address_t *nh_addr, u32 sw_if_index) { ip_adjacency_t *adj; adj = adj_alloc(nh_proto); adj_nbr_insert(nh_proto, link_type, nh_addr, sw_if_index, adj_get_index(adj)); /* * since we just added the ADJ we have no rewrite string for it, * so its for ARP */ adj->lookup_next_index = IP_LOOKUP_NEXT_ARP; adj->sub_type.nbr.next_hop = *nh_addr; adj->ia_link = link_type; adj->ia_nh_proto = nh_proto; adj->rewrite_header.sw_if_index = sw_if_index; vnet_rewrite_update_mtu(vnet_get_main(), adj->ia_link, &adj->rewrite_header); adj_nbr_evaluate_feature (adj_get_index(adj)); return (adj); } /* * adj_nbr_add_or_lock * * Add an adjacency for the neighbour requested. * * The key for an adj is: * - the Next-hops protocol (i.e. v4 or v6) * - the address of the next-hop * - the interface the next-hop is reachable through */ adj_index_t adj_nbr_add_or_lock (fib_protocol_t nh_proto, vnet_link_t link_type, const ip46_address_t *nh_addr, u32 sw_if_index) { adj_index_t adj_index; adj_index = adj_nbr_find(nh_proto, link_type, nh_addr, sw_if_index); if (ADJ_INDEX_INVALID == adj_index) { ip_adjacency_t *adj; vnet_main_t *vnm; vnm = vnet_get_main(); adj = adj_nbr_alloc(nh_proto, link_type, nh_addr, sw_if_index); adj_index = adj_get_index(adj); adj_lock(adj_index); if (ip46_address_is_equal(&ADJ_BCAST_ADDR, nh_addr)) { adj->lookup_next_index = IP_LOOKUP_NEXT_BCAST; } vnet_rewrite_init(vnm, sw_if_index, link_type, adj_get_nd_node(nh_proto), vnet_tx_node_index_for_sw_interface(vnm, sw_if_index), &adj->rewrite_header); /* * we need a rewrite where the destination IP address is converted * to the appropriate link-layer address. This is interface specific. * So ask the interface to do it. */ vnet_update_adjacency_for_sw_interface(vnm, sw_if_index, adj_index); } else { adj_lock(adj_index); } adj_delegate_adj_created(adj_get(adj_index)); return (adj_index); } adj_index_t adj_nbr_add_or_lock_w_rewrite (fib_protocol_t nh_proto, vnet_link_t link_type, const ip46_address_t *nh_addr, u32 sw_if_index, u8 *rewrite) { adj_index_t adj_index; adj_index = adj_nbr_find(nh_proto, link_type, nh_addr, sw_if_index); if (ADJ_INDEX_INVALID == adj_index) { ip_adjacency_t *adj; adj = adj_nbr_alloc(nh_proto, link_type, nh_addr, sw_if_index); adj->rewrite_header.sw_if_index = sw_if_index; adj_index = adj_get_index(adj); } adj_lock(adj_index); adj_nbr_update_rewrite(adj_index, ADJ_NBR_REWRITE_FLAG_COMPLETE, rewrite); adj_delegate_adj_created(adj_get(adj_index)); return (adj_index); } /** * adj_nbr_update_rewrite * * Update the adjacency's rewrite string. A NULL string implies the * rewrite is reset (i.e. when ARP/ND entry is gone). * NB: the adj being updated may be handling traffic in the DP. */ void adj_nbr_update_rewrite (adj_index_t adj_index, adj_nbr_rewrite_flag_t flags, u8 *rewrite) { ip_adjacency_t *adj; ASSERT(ADJ_INDEX_INVALID != adj_index); adj = adj_get(adj_index); if (flags & ADJ_NBR_REWRITE_FLAG_COMPLETE) { /* * update the adj's rewrite string and build the arc * from the rewrite node to the interface's TX node */ adj_nbr_update_rewrite_internal(adj, IP_LOOKUP_NEXT_REWRITE, adj_get_rewrite_node(adj->ia_link), vnet_tx_node_index_for_sw_interface( vnet_get_main(), adj->rewrite_header.sw_if_index), rewrite); } else { adj_nbr_update_rewrite_internal(adj, IP_LOOKUP_NEXT_ARP, adj_get_nd_node(adj->ia_nh_proto), vnet_tx_node_index_for_sw_interface( vnet_get_main(), adj->rewrite_header.sw_if_index), rewrite); } } /** * adj_nbr_update_rewrite_internal * * Update the adjacency's rewrite string. A NULL string implies the * rewrite is reset (i.e. when ARP/ND entry is gone). * NB: the adj being updated may be handling traffic in the DP. */ void adj_nbr_update_rewrite_internal (ip_adjacency_t *adj, ip_lookup_next_t adj_next_index, u32 this_node, u32 next_node, u8 *rewrite) { ip_adjacency_t *walk_adj; adj_index_t walk_ai, ai; vlib_main_t * vm; u32 old_next; int do_walk; vm = vlib_get_main(); old_next = adj->lookup_next_index; ai = walk_ai = adj_get_index(adj); if (VNET_LINK_MPLS == adj->ia_link) { /* * The link type MPLS has no children in the control plane graph, it only * has children in the data-plane graph. The backwalk is up the former. * So we need to walk from its IP cousin. */ walk_ai = adj_nbr_find(adj->ia_nh_proto, fib_proto_to_link(adj->ia_nh_proto), &adj->sub_type.nbr.next_hop, adj->rewrite_header.sw_if_index); } /* * Don't call the walk re-entrantly */ if (ADJ_INDEX_INVALID != walk_ai) { walk_adj = adj_get(walk_ai); if (ADJ_FLAG_SYNC_WALK_ACTIVE & walk_adj->ia_flags) { do_walk = 0; } else { /* * Prevent re-entrant walk of the same adj */ walk_adj->ia_flags |= ADJ_FLAG_SYNC_WALK_ACTIVE; do_walk = 1; } } else { do_walk = 0; } /* * lock the adjacencies that are affected by updates this walk will provoke. * Since the aim of the walk is to update children to link to a different * DPO, this adj will no longer be in use and its lock count will drop to 0. * We don't want it to be deleted as part of this endeavour. */ adj_lock(ai); adj_lock(walk_ai); /* * Updating a rewrite string is not atomic; * - the rewrite string is too long to write in one instruction * - when swapping from incomplete to complete, we also need to update * the VLIB graph next-index of the adj. * ideally we would only want to suspend forwarding via this adj whilst we * do this, but we do not have that level of granularity - it's suspend all * worker threads or nothing. * The other choices are: * - to mark the adj down and back walk so child load-balances drop this adj * from the set. * - update the next_node index of this adj to point to error-drop * both of which will mean for MAC change we will drop for this adj * which is not acceptable. However, when the adj changes type (from * complete to incomplete and vice-versa) the child DPOs, which have the * VLIB graph next node index, will be sending packets to the wrong graph * node. So from the options above, updating the next_node of the adj to * be drop will work, but it relies on each graph node v4/v6/mpls, rewrite/ * arp/midchain always be valid w.r.t. a mis-match of adj type and node type * (i.e. a rewrite adj in the arp node). This is not enforceable. Getting it * wrong will lead to hard to find bugs since its a race condition. So we * choose the more reliable method of updating the children to use the drop, * then switching adj's type, then updating the children again. Did I mention * that this doesn't happen often... * So we need to distinguish between the two cases: * 1 - mac change * 2 - adj type change */ if (do_walk && old_next != adj_next_index && ADJ_INDEX_INVALID != walk_ai) { /* * the adj is changing type. we need to fix all children so that they * stack momentarily on a drop, while the adj changes. If we don't do * this the children will send packets to a VLIB graph node that does * not correspond to the adj's type - and it goes downhill from there. */ fib_node_back_walk_ctx_t bw_ctx = { .fnbw_reason = FIB_NODE_BW_REASON_FLAG_ADJ_DOWN, /* * force this walk to be synchronous. if we don't and a node in the graph * (a heavily shared path-list) chooses to back-ground the walk (make it * async) then it will pause and we will do the adj update below, before * all the children are updated. not good. */ .fnbw_flags = FIB_NODE_BW_FLAG_FORCE_SYNC, }; fib_walk_sync(FIB_NODE_TYPE_ADJ, walk_ai, &bw_ctx); /* * fib_walk_sync may allocate a new adjacency and potentially cuase a * realloc for adj_pool. When that happens, adj pointer is no longer * valid here. We refresh the adj pointer accordingly. */ adj = adj_get (ai); } /* * If we are just updating the MAC string of the adj (which we also can't * do atomically), then we need to stop packets switching through the adj. * We can't do that on a per-adj basis, so it's all the packets. * If we are updating the type, and we walked back to the children above, * then this barrier serves to flush the queues/frames. */ vlib_worker_thread_barrier_sync(vm); adj->lookup_next_index = adj_next_index; adj->ia_node_index = this_node; if (NULL != rewrite) { /* * new rewrite provided. * fill in the adj's rewrite string, and build the VLIB graph arc. */ vnet_rewrite_set_data_internal(&adj->rewrite_header, sizeof(adj->rewrite_data), rewrite, vec_len(rewrite)); vec_free(rewrite); } else { vnet_rewrite_clear_data_internal(&adj->rewrite_header, sizeof(adj->rewrite_data)); } adj->rewrite_header.next_index = vlib_node_add_next(vlib_get_main(), this_node, next_node); /* * done with the rewrite update - let the workers loose. */ vlib_worker_thread_barrier_release(vm); if (do_walk && (old_next != adj->lookup_next_index) && (ADJ_INDEX_INVALID != walk_ai)) { /* * backwalk to the children so they can stack on the now updated * adjacency */ fib_node_back_walk_ctx_t bw_ctx = { .fnbw_reason = FIB_NODE_BW_REASON_FLAG_ADJ_UPDATE, }; fib_walk_sync(FIB_NODE_TYPE_ADJ, walk_ai, &bw_ctx); } /* * Prevent re-entrant walk of the same adj */ if (do_walk) { walk_adj = adj_get(walk_ai); walk_adj->ia_flags &= ~ADJ_FLAG_SYNC_WALK_ACTIVE; } adj_unlock(ai); adj_unlock(walk_ai); } typedef struct adj_db_count_ctx_t_ { u64 count; } adj_db_count_ctx_t; static int adj_db_count (BVT(clib_bihash_kv) * kvp, void *arg) { adj_db_count_ctx_t * ctx = arg; ctx->count++; return (BIHASH_WALK_CONTINUE); } u32 adj_nbr_db_size (void) { adj_db_count_ctx_t ctx = { .count = 0, }; fib_protocol_t proto; u32 sw_if_index = 0; for (proto = FIB_PROTOCOL_IP4; proto <= FIB_PROTOCOL_IP6; proto++) { vec_foreach_index(sw_if_index, adj_nbr_tables[proto]) { if (NULL != adj_nbr_tables[proto][sw_if_index]) { BV(clib_bihash_foreach_key_value_pair) ( adj_nbr_tables[proto][sw_if_index], adj_db_count, &ctx); } } } return (ctx.count); } /** * @brief Context for a walk of the adjacency neighbour DB */ typedef struct adj_walk_ctx_t_ { adj_walk_cb_t awc_cb; void *awc_ctx; } adj_walk_ctx_t; static int adj_nbr_walk_cb (BVT(clib_bihash_kv) * kvp, void *arg) { adj_walk_ctx_t *ctx = arg; // FIXME: can't stop early... if (ADJ_WALK_RC_STOP == ctx->awc_cb(kvp->value, ctx->awc_ctx)) return (BIHASH_WALK_STOP); return (BIHASH_WALK_CONTINUE); } void adj_nbr_walk (u32 sw_if_index, fib_protocol_t adj_nh_proto, adj_walk_cb_t cb, void *ctx) { if (!ADJ_NBR_ITF_OK(adj_nh_proto, sw_if_index)) return; adj_walk_ctx_t awc = { .awc_ctx = ctx, .awc_cb = cb, }; BV(clib_bihash_foreach_key_value_pair) ( adj_nbr_tables[adj_nh_proto][sw_if_index], adj_nbr_walk_cb, &awc); } /** * @brief Walk adjacencies on a link with a given v4 next-hop. * that is visit the adjacencies with different link types. */ void adj_nbr_walk_nh4 (u32 sw_if_index, const ip4_address_t *addr, adj_walk_cb_t cb, void *ctx) { if (!ADJ_NBR_ITF_OK(FIB_PROTOCOL_IP4, sw_if_index)) return; ip46_address_t nh = { .ip4 = *addr, }; vnet_link_t linkt; adj_index_t ai; FOR_EACH_VNET_LINK(linkt) { ai = adj_nbr_find (FIB_PROTOCOL_IP4, linkt, &nh, sw_if_index); if (INDEX_INVALID != ai) cb(ai, ctx); } } /** * @brief Walk adjacencies on a link with a given v6 next-hop. * that is visit the adjacencies with different link types. */ void adj_nbr_walk_nh6 (u32 sw_if_index, const ip6_address_t *addr, adj_walk_cb_t cb, void *ctx) { if (!ADJ_NBR_ITF_OK(FIB_PROTOCOL_IP6, sw_if_index)) return; ip46_address_t nh = { .ip6 = *addr, }; vnet_link_t linkt; adj_index_t ai; FOR_EACH_VNET_LINK(linkt) { ai = adj_nbr_find (FIB_PROTOCOL_IP6, linkt, &nh, sw_if_index); if (INDEX_INVALID != ai) cb(ai, ctx); } } /** * @brief Walk adjacencies on a link with a given next-hop. * that is visit the adjacencies with different link types. */ void adj_nbr_walk_nh (u32 sw_if_index, fib_protocol_t adj_nh_proto, const ip46_address_t *nh, adj_walk_cb_t cb, void *ctx) { if (!ADJ_NBR_ITF_OK(adj_nh_proto, sw_if_index)) return; switch (adj_nh_proto) { case FIB_PROTOCOL_IP4: adj_nbr_walk_nh4(sw_if_index, &nh->ip4, cb, ctx); break; case FIB_PROTOCOL_IP6: adj_nbr_walk_nh6(sw_if_index, &nh->ip6, cb, ctx); break; case FIB_PROTOCOL_MPLS: ASSERT(0); break; } } /** * Flags associated with the interface state walks */ typedef enum adj_nbr_interface_flags_t_ { ADJ_NBR_INTERFACE_UP = (1 << 0), } adj_nbr_interface_flags_t; /** * Context for the state change walk of the DB */ typedef struct adj_nbr_interface_state_change_ctx_t_ { /** * Flags on the interface */ adj_nbr_interface_flags_t flags; } adj_nbr_interface_state_change_ctx_t; static adj_walk_rc_t adj_nbr_interface_state_change_one (adj_index_t ai, void *arg) { /* * Back walk the graph to inform the forwarding entries * that this interface state has changed. Do this synchronously * since this is the walk that provides convergence */ adj_nbr_interface_state_change_ctx_t *ctx = arg; fib_node_back_walk_ctx_t bw_ctx = { .fnbw_reason = ((ctx->flags & ADJ_NBR_INTERFACE_UP) ? FIB_NODE_BW_REASON_FLAG_INTERFACE_UP : FIB_NODE_BW_REASON_FLAG_INTERFACE_DOWN), /* * the force sync applies only as far as the first fib_entry. * And it's the fib_entry's we need to converge away from * the adjacencies on the now down link */ .fnbw_flags = (!(ctx->flags & ADJ_NBR_INTERFACE_UP) ? FIB_NODE_BW_FLAG_FORCE_SYNC : FIB_NODE_BW_FLAG_NONE), }; ip_adjacency_t *adj; adj = adj_get(ai); adj->ia_flags |= ADJ_FLAG_SYNC_WALK_ACTIVE; fib_walk_sync(FIB_NODE_TYPE_ADJ, ai, &bw_ctx); adj->ia_flags &= ~ADJ_FLAG_SYNC_WALK_ACTIVE; return (ADJ_WALK_RC_CONTINUE); } /** * @brief Registered function for SW interface state changes */ static clib_error_t * adj_nbr_sw_interface_state_change (vnet_main_t * vnm, u32 sw_if_index, u32 flags) { fib_protocol_t proto; /* * walk each adj on the interface and trigger a walk from that adj */ for (proto = FIB_PROTOCOL_IP4; proto <= FIB_PROTOCOL_IP6; proto++) { adj_nbr_interface_state_change_ctx_t ctx = { .flags = ((flags & VNET_SW_INTERFACE_FLAG_ADMIN_UP) ? ADJ_NBR_INTERFACE_UP : 0), }; adj_nbr_walk(sw_if_index, proto, adj_nbr_interface_state_change_one, &ctx); } return (NULL); } VNET_SW_INTERFACE_ADMIN_UP_DOWN_FUNCTION_PRIO( adj_nbr_sw_interface_state_change, VNET_ITF_FUNC_PRIORITY_HIGH); /** * @brief Invoked on each SW interface of a HW interface when the * HW interface state changes */ static walk_rc_t adj_nbr_hw_sw_interface_state_change (vnet_main_t * vnm, u32 sw_if_index, void *arg) { adj_nbr_interface_state_change_ctx_t *ctx = arg; fib_protocol_t proto; /* * walk each adj on the interface and trigger a walk from that adj */ for (proto = FIB_PROTOCOL_IP4; proto <= FIB_PROTOCOL_IP6; proto++) { adj_nbr_walk(sw_if_index, proto, adj_nbr_interface_state_change_one, ctx); } return (WALK_CONTINUE); } /** * @brief Registered callback for HW interface state changes */ static clib_error_t * adj_nbr_hw_interface_state_change (vnet_main_t * vnm, u32 hw_if_index, u32 flags) { /* * walk SW interface on the HW */ adj_nbr_interface_state_change_ctx_t ctx = { .flags = ((flags & VNET_HW_INTERFACE_FLAG_LINK_UP) ? ADJ_NBR_INTERFACE_UP : 0), }; vnet_hw_interface_walk_sw(vnm, hw_if_index, adj_nbr_hw_sw_interface_state_change, &ctx); return (NULL); } VNET_HW_INTERFACE_LINK_UP_DOWN_FUNCTION_PRIO( adj_nbr_hw_interface_state_change, VNET_ITF_FUNC_PRIORITY_HIGH); static adj_walk_rc_t adj_nbr_interface_delete_one (adj_index_t ai, void *arg) { /* * Back walk the graph to inform the forwarding entries * that this interface has been deleted. */ fib_node_back_walk_ctx_t bw_ctx = { .fnbw_reason = FIB_NODE_BW_REASON_FLAG_INTERFACE_DELETE, }; ip_adjacency_t *adj; adj_lock(ai); adj = adj_get(ai); adj->ia_flags |= ADJ_FLAG_SYNC_WALK_ACTIVE; fib_walk_sync(FIB_NODE_TYPE_ADJ, ai, &bw_ctx); adj->ia_flags &= ~ADJ_FLAG_SYNC_WALK_ACTIVE; adj_unlock(ai); return (ADJ_WALK_RC_CONTINUE); } /** * adj_nbr_interface_add_del * * Registered to receive interface Add and delete notifications */ static clib_error_t * adj_nbr_interface_add_del (vnet_main_t * vnm, u32 sw_if_index, u32 is_add) { fib_protocol_t proto; if (is_add) { /* * not interested in interface additions. we will not back walk * to resolve paths through newly added interfaces. Why? The control * plane should have the brains to add interfaces first, then routes. * So the case where there are paths with a interface that matches * one just created is the case where the path resolved through an * interface that was deleted, and still has not been removed. The * new interface added, is NO GUARANTEE that the interface being * added now, even though it may have the same sw_if_index, is the * same interface that the path needs. So tough! * If the control plane wants these routes to resolve it needs to * remove and add them again. */ return (NULL); } for (proto = FIB_PROTOCOL_IP4; proto <= FIB_PROTOCOL_IP6; proto++) { adj_nbr_walk(sw_if_index, proto, adj_nbr_interface_delete_one, NULL); } return (NULL); } VNET_SW_INTERFACE_ADD_DEL_FUNCTION(adj_nbr_interface_add_del); static adj_walk_rc_t adj_nbr_show_one (adj_index_t ai, void *arg) { vlib_cli_output (arg, "[@%d] %U", ai, format_ip_adjacency, ai, FORMAT_IP_ADJACENCY_NONE); return (ADJ_WALK_RC_CONTINUE); } static clib_error_t * adj_nbr_show (vlib_main_t * vm, unformat_input_t * input, vlib_cli_command_t * cmd) { adj_index_t ai = ADJ_INDEX_INVALID; ip46_address_t nh = ip46_address_initializer; u32 sw_if_index = ~0; while (unformat_check_input (input) != UNFORMAT_END_OF_INPUT) { if (unformat (input, "%U", unformat_vnet_sw_interface, vnet_get_main(), &sw_if_index)) ; else if (unformat (input, "%U", unformat_ip46_address, &nh, IP46_TYPE_ANY)) ; else if (unformat (input, "%d", &ai)) ; else break; } if (ADJ_INDEX_INVALID != ai) { vlib_cli_output (vm, "[@%d] %U", ai, format_ip_adjacency, ai, FORMAT_IP_ADJACENCY_DETAIL); } else if (~0 != sw_if_index) { fib_protocol_t proto; if (ip46_address_is_zero(&nh)) { for (proto = FIB_PROTOCOL_IP4; proto <= FIB_PROTOCOL_IP6; proto++) { adj_nbr_walk(sw_if_index, proto, adj_nbr_show_one, vm); } } else { proto = (ip46_address_is_ip4(&nh) ? FIB_PROTOCOL_IP4 : FIB_PROTOCOL_IP6); adj_nbr_walk_nh(sw_if_index, proto, &nh, adj_nbr_show_one, vm); } } else { fib_protocol_t proto; for (proto = FIB_PROTOCOL_IP4; proto <= FIB_PROTOCOL_IP6; proto++) { vec_foreach_index(sw_if_index, adj_nbr_tables[proto]) { adj_nbr_walk(sw_if_index, proto, adj_nbr_show_one, vm); } } } return 0; } /*? * Show all neighbour adjacencies. * @cliexpar * @cliexstart{sh adj nbr} * [@2] ipv4 via 1.0.0.2 loop0: IP4: 00:00:22:aa:bb:cc -> 00:00:11:aa:bb:cc * [@3] mpls via 1.0.0.2 loop0: MPLS_UNICAST: 00:00:22:aa:bb:cc -> 00:00:11:aa:bb:cc * [@4] ipv4 via 1.0.0.3 loop0: IP4: 00:00:22:aa:bb:cc -> 00:00:11:aa:bb:cc * [@5] mpls via 1.0.0.3 loop0: MPLS_UNICAST: 00:00:22:aa:bb:cc -> 00:00:11:aa:bb:cc * @cliexend ?*/ VLIB_CLI_COMMAND (ip4_show_fib_command, static) = { .path = "show adj nbr", .short_help = "show adj nbr [<adj_index>] [interface]", .function = adj_nbr_show, }; u8* format_adj_nbr_incomplete (u8* s, va_list *ap) { index_t index = va_arg(*ap, index_t); CLIB_UNUSED(u32 indent) = va_arg(*ap, u32); vnet_main_t * vnm = vnet_get_main(); ip_adjacency_t * adj = adj_get(index); s = format (s, "arp-%U", format_vnet_link, adj->ia_link); s = format (s, ": via %U", format_ip46_address, &adj->sub_type.nbr.next_hop, adj_proto_to_46(adj->ia_nh_proto)); s = format (s, " %U", format_vnet_sw_if_index_name, vnm, adj->rewrite_header.sw_if_index); return (s); } u8* format_adj_nbr (u8* s, va_list *ap) { index_t index = va_arg(*ap, index_t); CLIB_UNUSED(u32 indent) = va_arg(*ap, u32); ip_adjacency_t * adj = adj_get(index); s = format (s, "%U", format_vnet_link, adj->ia_link); s = format (s, " via %U ", format_ip46_address, &adj->sub_type.nbr.next_hop, adj_proto_to_46(adj->ia_nh_proto)); s = format (s, "%U", format_vnet_rewrite, &adj->rewrite_header, sizeof (adj->rewrite_data), 0); return (s); } static void adj_dpo_lock (dpo_id_t *dpo) { adj_lock(dpo->dpoi_index); } static void adj_dpo_unlock (dpo_id_t *dpo) { adj_unlock(dpo->dpoi_index); } static void adj_mem_show (void) { fib_show_memory_usage("Adjacency", pool_elts(adj_pool), pool_len(adj_pool), sizeof(ip_adjacency_t)); } const static dpo_vft_t adj_nbr_dpo_vft = { .dv_lock = adj_dpo_lock, .dv_unlock = adj_dpo_unlock, .dv_format = format_adj_nbr, .dv_mem_show = adj_mem_show, .dv_get_urpf = adj_dpo_get_urpf, }; const static dpo_vft_t adj_nbr_incompl_dpo_vft = { .dv_lock = adj_dpo_lock, .dv_unlock = adj_dpo_unlock, .dv_format = format_adj_nbr_incomplete, .dv_get_urpf = adj_dpo_get_urpf, }; /** * @brief The per-protocol VLIB graph nodes that are assigned to an adjacency * object. * * this means that these graph nodes are ones from which a nbr is the * parent object in the DPO-graph. */ const static char* const nbr_ip4_nodes[] = { "ip4-rewrite", NULL, }; const static char* const nbr_ip6_nodes[] = { "ip6-rewrite", NULL, }; const static char* const nbr_mpls_nodes[] = { "mpls-output", NULL, }; const static char* const nbr_ethernet_nodes[] = { "adj-l2-rewrite", NULL, }; const static char* const * const nbr_nodes[DPO_PROTO_NUM] = { [DPO_PROTO_IP4] = nbr_ip4_nodes, [DPO_PROTO_IP6] = nbr_ip6_nodes, [DPO_PROTO_MPLS] = nbr_mpls_nodes, [DPO_PROTO_ETHERNET] = nbr_ethernet_nodes, }; const static char* const nbr_incomplete_ip4_nodes[] = { "ip4-arp", NULL, }; const static char* const nbr_incomplete_ip6_nodes[] = { "ip6-discover-neighbor", NULL, }; const static char* const nbr_incomplete_mpls_nodes[] = { "mpls-adj-incomplete", NULL, }; const static char* const * const nbr_incomplete_nodes[DPO_PROTO_NUM] = { [DPO_PROTO_IP4] = nbr_incomplete_ip4_nodes, [DPO_PROTO_IP6] = nbr_incomplete_ip6_nodes, [DPO_PROTO_MPLS] = nbr_incomplete_mpls_nodes, }; void adj_nbr_module_init (void) { dpo_register(DPO_ADJACENCY, &adj_nbr_dpo_vft, nbr_nodes); dpo_register(DPO_ADJACENCY_INCOMPLETE, &adj_nbr_incompl_dpo_vft, nbr_incomplete_nodes); }