/* * 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/adj/adj_l2.h> #include <vnet/adj/adj_nsh.h> #include <vnet/adj/adj_midchain.h> #include <vnet/ethernet/arp_packet.h> #include <vnet/dpo/drop_dpo.h> #include <vnet/dpo/load_balance.h> #include <vnet/fib/fib_walk.h> #include <vnet/fib/fib_entry.h> /** * The two midchain tx feature node indices */ static u32 adj_midchain_tx_feature_node[VNET_LINK_NUM]; static u32 adj_midchain_tx_no_count_feature_node[VNET_LINK_NUM]; static u32 *adj_midchain_feat_count_per_sw_if_index[VNET_LINK_NUM]; /** * @brief Trace data for packets traversing the midchain tx node */ typedef struct adj_midchain_tx_trace_t_ { /** * @brief the midchain adj we are traversing */ adj_index_t ai; } adj_midchain_tx_trace_t; always_inline uword adj_midchain_tx_inline (vlib_main_t * vm, vlib_node_runtime_t * node, vlib_frame_t * frame, int interface_count) { u32 * from, * to_next, n_left_from, n_left_to_next; u32 next_index; vnet_main_t *vnm = vnet_get_main (); vnet_interface_main_t *im = &vnm->interface_main; u32 thread_index = vm->thread_index; /* Vector of buffer / pkt indices we're supposed to process */ from = vlib_frame_vector_args (frame); /* Number of buffers / pkts */ n_left_from = frame->n_vectors; /* Speculatively send the first buffer to the last disposition we used */ next_index = node->cached_next_index; while (n_left_from > 0) { /* set up to enqueue to our disposition with index = next_index */ vlib_get_next_frame (vm, node, next_index, to_next, n_left_to_next); while (n_left_from >= 8 && n_left_to_next > 4) { const ip_adjacency_t *adj0, *adj1, *adj2, *adj3; const dpo_id_t *dpo0, *dpo1, *dpo2, *dpo3; vlib_buffer_t * b0, *b1, *b2, *b3; u32 bi0, adj_index0, next0; u32 bi1, adj_index1, next1; u32 bi2, adj_index2, next2; u32 bi3, adj_index3, next3; /* Prefetch next iteration. */ { vlib_buffer_t * p4, * p5; vlib_buffer_t * p6, * p7; p4 = vlib_get_buffer (vm, from[4]); p5 = vlib_get_buffer (vm, from[5]); p6 = vlib_get_buffer (vm, from[6]); p7 = vlib_get_buffer (vm, from[7]); vlib_prefetch_buffer_header (p4, LOAD); vlib_prefetch_buffer_header (p5, LOAD); vlib_prefetch_buffer_header (p6, LOAD); vlib_prefetch_buffer_header (p7, LOAD); } bi0 = from[0]; to_next[0] = bi0; bi1 = from[1]; to_next[1] = bi1; bi2 = from[2]; to_next[2] = bi2; bi3 = from[3]; to_next[3] = bi3; from += 4; to_next += 4; n_left_from -= 4; n_left_to_next -= 4; b0 = vlib_get_buffer(vm, bi0); b1 = vlib_get_buffer(vm, bi1); b2 = vlib_get_buffer(vm, bi2); b3 = vlib_get_buffer(vm, bi3); /* Follow the DPO on which the midchain is stacked */ adj_index0 = vnet_buffer(b0)->ip.adj_index[VLIB_TX]; adj_index1 = vnet_buffer(b1)->ip.adj_index[VLIB_TX]; adj_index2 = vnet_buffer(b2)->ip.adj_index[VLIB_TX]; adj_index3 = vnet_buffer(b3)->ip.adj_index[VLIB_TX]; adj0 = adj_get(adj_index0); adj1 = adj_get(adj_index1); adj2 = adj_get(adj_index2); adj3 = adj_get(adj_index3); dpo0 = &adj0->sub_type.midchain.next_dpo; dpo1 = &adj1->sub_type.midchain.next_dpo; dpo2 = &adj2->sub_type.midchain.next_dpo; dpo3 = &adj3->sub_type.midchain.next_dpo; next0 = dpo0->dpoi_next_node; next1 = dpo1->dpoi_next_node; next2 = dpo2->dpoi_next_node; next3 = dpo3->dpoi_next_node; vnet_buffer(b1)->ip.adj_index[VLIB_TX] = dpo1->dpoi_index; vnet_buffer(b0)->ip.adj_index[VLIB_TX] = dpo0->dpoi_index; vnet_buffer(b2)->ip.adj_index[VLIB_TX] = dpo2->dpoi_index; vnet_buffer(b3)->ip.adj_index[VLIB_TX] = dpo3->dpoi_index; if (interface_count) { vlib_increment_combined_counter (im->combined_sw_if_counters + VNET_INTERFACE_COUNTER_TX, thread_index, adj0->rewrite_header.sw_if_index, 1, vlib_buffer_length_in_chain (vm, b0)); vlib_increment_combined_counter (im->combined_sw_if_counters + VNET_INTERFACE_COUNTER_TX, thread_index, adj1->rewrite_header.sw_if_index, 1, vlib_buffer_length_in_chain (vm, b1)); vlib_increment_combined_counter (im->combined_sw_if_counters + VNET_INTERFACE_COUNTER_TX, thread_index, adj2->rewrite_header.sw_if_index, 1, vlib_buffer_length_in_chain (vm, b2)); vlib_increment_combined_counter (im->combined_sw_if_counters + VNET_INTERFACE_COUNTER_TX, thread_index, adj3->rewrite_header.sw_if_index, 1, vlib_buffer_length_in_chain (vm, b3)); } if (PREDICT_FALSE(b0->flags & VLIB_BUFFER_IS_TRACED)) { adj_midchain_tx_trace_t *tr = vlib_add_trace (vm, node, b0, sizeof (*tr)); tr->ai = adj_index0; } if (PREDICT_FALSE(b1->flags & VLIB_BUFFER_IS_TRACED)) { adj_midchain_tx_trace_t *tr = vlib_add_trace (vm, node, b1, sizeof (*tr)); tr->ai = adj_index1; } if (PREDICT_FALSE(b2->flags & VLIB_BUFFER_IS_TRACED)) { adj_midchain_tx_trace_t *tr = vlib_add_trace (vm, node, b2, sizeof (*tr)); tr->ai = adj_index2; } if (PREDICT_FALSE(b3->flags & VLIB_BUFFER_IS_TRACED)) { adj_midchain_tx_trace_t *tr = vlib_add_trace (vm, node, b3, sizeof (*tr)); tr->ai = adj_index3; } vlib_validate_buffer_enqueue_x4 (vm, node, next_index, to_next, n_left_to_next, bi0, bi1, bi2, bi3, next0, next1, next2, next3); } while (n_left_from > 0 && n_left_to_next > 0) { u32 bi0, adj_index0, next0; const ip_adjacency_t * adj0; const dpo_id_t *dpo0; vlib_buffer_t * b0; bi0 = from[0]; to_next[0] = bi0; from += 1; to_next += 1; n_left_from -= 1; n_left_to_next -= 1; b0 = vlib_get_buffer(vm, bi0); /* Follow the DPO on which the midchain is stacked */ adj_index0 = vnet_buffer(b0)->ip.adj_index[VLIB_TX]; adj0 = adj_get(adj_index0); dpo0 = &adj0->sub_type.midchain.next_dpo; next0 = dpo0->dpoi_next_node; vnet_buffer(b0)->ip.adj_index[VLIB_TX] = dpo0->dpoi_index; if (interface_count) { vlib_increment_combined_counter (im->combined_sw_if_counters + VNET_INTERFACE_COUNTER_TX, thread_index, adj0->rewrite_header.sw_if_index, 1, vlib_buffer_length_in_chain (vm, b0)); } if (PREDICT_FALSE(b0->flags & VLIB_BUFFER_IS_TRACED)) { adj_midchain_tx_trace_t *tr = vlib_add_trace (vm, node, b0, sizeof (*tr)); tr->ai = adj_index0; } vlib_validate_buffer_enqueue_x1 (vm, node, next_index, to_next, n_left_to_next, bi0, next0); } vlib_put_next_frame (vm, node, next_index, n_left_to_next); } return frame->n_vectors; } static u8 * format_adj_midchain_tx_trace (u8 * s, va_list * args) { CLIB_UNUSED (vlib_main_t * vm) = va_arg (*args, vlib_main_t *); CLIB_UNUSED (vlib_node_t * node) = va_arg (*args, vlib_node_t *); adj_midchain_tx_trace_t *tr = va_arg (*args, adj_midchain_tx_trace_t*); s = format(s, "adj-midchain:[%d]:%U", tr->ai, format_ip_adjacency, tr->ai, FORMAT_IP_ADJACENCY_NONE); return (s); } static uword adj_midchain_tx (vlib_main_t * vm, vlib_node_runtime_t * node, vlib_frame_t * frame) { return (adj_midchain_tx_inline(vm, node, frame, 1)); } VLIB_REGISTER_NODE (adj_midchain_tx_node, static) = { .function = adj_midchain_tx, .name = "adj-midchain-tx", .vector_size = sizeof (u32), .format_trace = format_adj_midchain_tx_trace, .n_next_nodes = 1, .next_nodes = { [0] = "error-drop", }, }; static uword adj_midchain_tx_no_count (vlib_main_t * vm, vlib_node_runtime_t * node, vlib_frame_t * frame) { return (adj_midchain_tx_inline(vm, node, frame, 0)); } VLIB_REGISTER_NODE (adj_midchain_tx_no_count_node, static) = { .function = adj_midchain_tx_no_count, .name = "adj-midchain-tx-no-count", .vector_size = sizeof (u32), .format_trace = format_adj_midchain_tx_trace, .n_next_nodes = 1, .next_nodes = { [0] = "error-drop", }, }; VNET_FEATURE_INIT (adj_midchain_tx_ip4, static) = { .arc_name = "ip4-output", .node_name = "adj-midchain-tx", .runs_before = VNET_FEATURES ("interface-output"), .feature_index_ptr = &adj_midchain_tx_feature_node[VNET_LINK_IP4], }; VNET_FEATURE_INIT (adj_midchain_tx_no_count_ip4, static) = { .arc_name = "ip4-output", .node_name = "adj-midchain-tx-no-count", .runs_before = VNET_FEATURES ("interface-output"), .feature_index_ptr = &adj_midchain_tx_no_count_feature_node[VNET_LINK_IP4], }; VNET_FEATURE_INIT (adj_midchain_tx_ip6, static) = { .arc_name = "ip6-output", .node_name = "adj-midchain-tx", .runs_before = VNET_FEATURES ("interface-output"), .feature_index_ptr = &adj_midchain_tx_feature_node[VNET_LINK_IP6], }; VNET_FEATURE_INIT (adj_midchain_tx_no_count_ip6, static) = { .arc_name = "ip6-output", .node_name = "adj-midchain-tx-no-count", .runs_before = VNET_FEATURES ("interface-output"), .feature_index_ptr = &adj_midchain_tx_no_count_feature_node[VNET_LINK_IP6], }; VNET_FEATURE_INIT (adj_midchain_tx_mpls, static) = { .arc_name = "mpls-output", .node_name = "adj-midchain-tx", .runs_before = VNET_FEATURES ("interface-output"), .feature_index_ptr = &adj_midchain_tx_feature_node[VNET_LINK_MPLS], }; VNET_FEATURE_INIT (adj_midchain_tx_no_count_mpls, static) = { .arc_name = "mpls-output", .node_name = "adj-midchain-tx-no-count", .runs_before = VNET_FEATURES ("interface-output"), .feature_index_ptr = &adj_midchain_tx_no_count_feature_node[VNET_LINK_MPLS], }; VNET_FEATURE_INIT (adj_midchain_tx_ethernet, static) = { .arc_name = "ethernet-output", .node_name = "adj-midchain-tx", .runs_before = VNET_FEATURES ("error-drop"), .feature_index_ptr = &adj_midchain_tx_feature_node[VNET_LINK_ETHERNET], }; VNET_FEATURE_INIT (adj_midchain_tx_no_count_ethernet, static) = { .arc_name = "ethernet-output", .node_name = "adj-midchain-tx-no-count", .runs_before = VNET_FEATURES ("error-drop"), .feature_index_ptr = &adj_midchain_tx_no_count_feature_node[VNET_LINK_ETHERNET], }; VNET_FEATURE_INIT (adj_midchain_tx_nsh, static) = { .arc_name = "nsh-output", .node_name = "adj-midchain-tx", .runs_before = VNET_FEATURES ("error-drop"), .feature_index_ptr = &adj_midchain_tx_feature_node[VNET_LINK_NSH], }; VNET_FEATURE_INIT (adj_midchain_tx_no_count_nsh, static) = { .arc_name = "nsh-output", .node_name = "adj-midchain-tx-no-count", .runs_before = VNET_FEATURES ("error-drop"), .feature_index_ptr = &adj_midchain_tx_no_count_feature_node[VNET_LINK_NSH], }; static inline u32 adj_get_midchain_node (vnet_link_t link) { switch (link) { case VNET_LINK_IP4: return (ip4_midchain_node.index); case VNET_LINK_IP6: return (ip6_midchain_node.index); case VNET_LINK_MPLS: return (mpls_midchain_node.index); case VNET_LINK_ETHERNET: return (adj_l2_midchain_node.index); case VNET_LINK_NSH: return (adj_nsh_midchain_node.index); case VNET_LINK_ARP: break; } ASSERT(0); return (0); } static u8 adj_midchain_get_feature_arc_index_for_link_type (const ip_adjacency_t *adj) { u8 arc = (u8) ~0; switch (adj->ia_link) { case VNET_LINK_IP4: { arc = ip4_main.lookup_main.output_feature_arc_index; break; } case VNET_LINK_IP6: { arc = ip6_main.lookup_main.output_feature_arc_index; break; } case VNET_LINK_MPLS: { arc = mpls_main.output_feature_arc_index; break; } case VNET_LINK_ETHERNET: { arc = ethernet_main.output_feature_arc_index; break; } case VNET_LINK_NSH: { arc = nsh_main_dummy.output_feature_arc_index; break; } case VNET_LINK_ARP: ASSERT(0); break; } ASSERT (arc != (u8) ~0); return (arc); } static u32 adj_nbr_midchain_get_tx_node (ip_adjacency_t *adj) { return ((adj->ia_flags & ADJ_FLAG_MIDCHAIN_NO_COUNT) ? adj_midchain_tx_no_count_node.index : adj_midchain_tx_node.index); } static u32 adj_nbr_midchain_get_feature_node (ip_adjacency_t *adj) { if (adj->ia_flags & ADJ_FLAG_MIDCHAIN_NO_COUNT) { return (adj_midchain_tx_no_count_feature_node[adj->ia_link]); } return (adj_midchain_tx_feature_node[adj->ia_link]); } /** * adj_midchain_setup * * Setup the adj as a mid-chain */ void adj_midchain_teardown (ip_adjacency_t *adj) { u32 feature_index; u8 arc_index; dpo_reset(&adj->sub_type.midchain.next_dpo); arc_index = adj_midchain_get_feature_arc_index_for_link_type (adj); feature_index = adj_nbr_midchain_get_feature_node(adj); if (0 == --adj_midchain_feat_count_per_sw_if_index[adj->ia_link][adj->rewrite_header.sw_if_index]) { vnet_feature_enable_disable_with_index (arc_index, feature_index, adj->rewrite_header.sw_if_index, 0, 0, 0); } } /** * adj_midchain_setup * * Setup the adj as a mid-chain */ void adj_midchain_setup (adj_index_t adj_index, adj_midchain_fixup_t fixup, const void *data, adj_flags_t flags) { u32 feature_index, tx_node; ip_adjacency_t *adj; u8 arc_index; ASSERT(ADJ_INDEX_INVALID != adj_index); adj = adj_get(adj_index); adj->sub_type.midchain.fixup_func = fixup; adj->sub_type.midchain.fixup_data = data; adj->sub_type.midchain.fei = FIB_NODE_INDEX_INVALID; adj->ia_flags |= flags; arc_index = adj_midchain_get_feature_arc_index_for_link_type (adj); feature_index = adj_nbr_midchain_get_feature_node(adj); tx_node = adj_nbr_midchain_get_tx_node(adj); vec_validate (adj_midchain_feat_count_per_sw_if_index[adj->ia_link], adj->rewrite_header.sw_if_index); if (0 == adj_midchain_feat_count_per_sw_if_index[adj->ia_link][adj->rewrite_header.sw_if_index]++) { vnet_feature_enable_disable_with_index (arc_index, feature_index, adj->rewrite_header.sw_if_index, 1 /* enable */, 0, 0); } /* * stack the midchain on the drop so it's ready to forward in the adj-midchain-tx. * The graph arc used/created here is from the midchain-tx node to the * child's registered node. This is because post adj processing the next * node are any output features, then the midchain-tx. from there we * need to get to the stacked child's node. */ dpo_stack_from_node(tx_node, &adj->sub_type.midchain.next_dpo, drop_dpo_get(vnet_link_to_dpo_proto(adj->ia_link))); } /** * adj_nbr_midchain_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_midchain_update_rewrite (adj_index_t adj_index, adj_midchain_fixup_t fixup, const void *fixup_data, adj_flags_t flags, u8 *rewrite) { ip_adjacency_t *adj; ASSERT(ADJ_INDEX_INVALID != adj_index); adj = adj_get(adj_index); /* * one time only update. since we don't support changing the tunnel * src,dst, this is all we need. */ if (adj->lookup_next_index != IP_LOOKUP_NEXT_MIDCHAIN && adj->lookup_next_index != IP_LOOKUP_NEXT_MCAST_MIDCHAIN) { adj_midchain_setup(adj_index, fixup, fixup_data, flags); } /* * update the rewrite with the workers paused. */ adj_nbr_update_rewrite_internal(adj, IP_LOOKUP_NEXT_MIDCHAIN, adj_get_midchain_node(adj->ia_link), adj_nbr_midchain_get_tx_node(adj), rewrite); } /** * adj_nbr_midchain_unstack * * Unstack the adj. stack it on drop */ void adj_nbr_midchain_unstack (adj_index_t adj_index) { fib_node_index_t *entry_indicies, tmp; ip_adjacency_t *adj; ASSERT(ADJ_INDEX_INVALID != adj_index); adj = adj_get (adj_index); /* * check to see if this unstacking breaks a recursion loop */ entry_indicies = NULL; tmp = adj->sub_type.midchain.fei; adj->sub_type.midchain.fei = FIB_NODE_INDEX_INVALID; if (FIB_NODE_INDEX_INVALID != tmp) { fib_entry_recursive_loop_detect(tmp, &entry_indicies); vec_free(entry_indicies); } /* * stack on the drop */ dpo_stack(DPO_ADJACENCY_MIDCHAIN, vnet_link_to_dpo_proto(adj->ia_link), &adj->sub_type.midchain.next_dpo, drop_dpo_get(vnet_link_to_dpo_proto(adj->ia_link))); CLIB_MEMORY_BARRIER(); } void adj_nbr_midchain_stack_on_fib_entry (adj_index_t ai, fib_node_index_t fei, fib_forward_chain_type_t fct) { fib_node_index_t *entry_indicies; dpo_id_t tmp = DPO_INVALID; ip_adjacency_t *adj; adj = adj_get (ai); /* * check to see if this stacking will form a recursion loop */ entry_indicies = NULL; adj->sub_type.midchain.fei = fei; if (fib_entry_recursive_loop_detect(adj->sub_type.midchain.fei, &entry_indicies)) { /* * loop formed, stack on the drop. */ dpo_copy(&tmp, drop_dpo_get(fib_forw_chain_type_to_dpo_proto(fct))); } else { fib_entry_contribute_forwarding (fei, fct, &tmp); if ((adj->ia_flags & ADJ_FLAG_MIDCHAIN_IP_STACK) && (DPO_LOAD_BALANCE == tmp.dpoi_type)) { /* * do that hash now and stack on the choice. * If the choice is an incomplete adj then we will need a poke when * it becomes complete. This happens since the adj update walk propagates * as far a recursive paths. */ const dpo_id_t *choice; load_balance_t *lb; int hash; lb = load_balance_get (tmp.dpoi_index); if (FIB_FORW_CHAIN_TYPE_UNICAST_IP4 == fct) { hash = ip4_compute_flow_hash ((ip4_header_t *) adj_get_rewrite (ai), lb->lb_hash_config); } else if (FIB_FORW_CHAIN_TYPE_UNICAST_IP6 == fct) { hash = ip6_compute_flow_hash ((ip6_header_t *) adj_get_rewrite (ai), lb->lb_hash_config); } else { hash = 0; ASSERT(0); } choice = load_balance_get_bucket_i (lb, hash & lb->lb_n_buckets_minus_1); dpo_copy (&tmp, choice); } } adj_nbr_midchain_stack (ai, &tmp); dpo_reset(&tmp); vec_free(entry_indicies); } /** * adj_nbr_midchain_stack */ void adj_nbr_midchain_stack (adj_index_t adj_index, const dpo_id_t *next) { ip_adjacency_t *adj; ASSERT(ADJ_INDEX_INVALID != adj_index); adj = adj_get(adj_index); ASSERT((IP_LOOKUP_NEXT_MIDCHAIN == adj->lookup_next_index) || (IP_LOOKUP_NEXT_MCAST_MIDCHAIN == adj->lookup_next_index)); dpo_stack_from_node(adj_nbr_midchain_get_tx_node(adj), &adj->sub_type.midchain.next_dpo, next); } int adj_ndr_midchain_recursive_loop_detect (adj_index_t ai, fib_node_index_t **entry_indicies) { fib_node_index_t *entry_index, *entries; ip_adjacency_t * adj; adj = adj_get(ai); entries = *entry_indicies; vec_foreach(entry_index, entries) { if (*entry_index == adj->sub_type.midchain.fei) { /* * The entry this midchain links to is already in the set * of visited entries, this is a loop */ adj->ia_flags |= ADJ_FLAG_MIDCHAIN_LOOPED; return (1); } } adj->ia_flags &= ~ADJ_FLAG_MIDCHAIN_LOOPED; return (0); } u8* format_adj_midchain (u8* s, va_list *ap) { index_t index = va_arg(*ap, index_t); u32 indent = va_arg(*ap, u32); ip_adjacency_t * adj = adj_get(index); s = format (s, "%U", format_vnet_link, adj->ia_link); if (adj->rewrite_header.flags & VNET_REWRITE_HAS_FEATURES) s = format(s, " [features]"); 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), indent); s = format (s, "\n%Ustacked-on", format_white_space, indent); if (FIB_NODE_INDEX_INVALID != adj->sub_type.midchain.fei) { s = format (s, " entry:%d", adj->sub_type.midchain.fei); } s = format (s, ":\n%U%U", format_white_space, indent+2, format_dpo_id, &adj->sub_type.midchain.next_dpo, indent+2); 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); } const static dpo_vft_t adj_midchain_dpo_vft = { .dv_lock = adj_dpo_lock, .dv_unlock = adj_dpo_unlock, .dv_format = format_adj_midchain, .dv_get_urpf = adj_dpo_get_urpf, }; /** * @brief The per-protocol VLIB graph nodes that are assigned to a midchain * object. * * this means that these graph nodes are ones from which a midchain is the * parent object in the DPO-graph. */ const static char* const midchain_ip4_nodes[] = { "ip4-midchain", NULL, }; const static char* const midchain_ip6_nodes[] = { "ip6-midchain", NULL, }; const static char* const midchain_mpls_nodes[] = { "mpls-midchain", NULL, }; const static char* const midchain_ethernet_nodes[] = { "adj-l2-midchain", NULL, }; const static char* const midchain_nsh_nodes[] = { "adj-nsh-midchain", NULL, }; const static char* const * const midchain_nodes[DPO_PROTO_NUM] = { [DPO_PROTO_IP4] = midchain_ip4_nodes, [DPO_PROTO_IP6] = midchain_ip6_nodes, [DPO_PROTO_MPLS] = midchain_mpls_nodes, [DPO_PROTO_ETHERNET] = midchain_ethernet_nodes, [DPO_PROTO_NSH] = midchain_nsh_nodes, }; void adj_midchain_module_init (void) { dpo_register(DPO_ADJACENCY_MIDCHAIN, &adj_midchain_dpo_vft, midchain_nodes); }