// SPDX-License-Identifier: GPL-2.0-or-later /* * This is an implementation of RFC 5187 Graceful Restart. * * Copyright 2021 NetDEF (c), All rights reserved. */ #include #include "memory.h" #include "command.h" #include "table.h" #include "vty.h" #include "log.h" #include "hook.h" #include "printfrr.h" #include "lib_errors.h" #include "ospf6d/ospf6_lsa.h" #include "ospf6d/ospf6_lsdb.h" #include "ospf6d/ospf6_route.h" #include "ospf6d/ospf6_area.h" #include "ospf6d/ospf6_interface.h" #include "ospf6d/ospf6d.h" #include "ospf6d/ospf6_asbr.h" #include "ospf6d/ospf6_zebra.h" #include "ospf6d/ospf6_message.h" #include "ospf6d/ospf6_neighbor.h" #include "ospf6d/ospf6_network.h" #include "ospf6d/ospf6_flood.h" #include "ospf6d/ospf6_intra.h" #include "ospf6d/ospf6_spf.h" #include "ospf6d/ospf6_gr.h" #include "ospf6d/ospf6_gr_clippy.c" static void ospf6_gr_grace_period_expired(struct event *thread); /* Originate and install Grace-LSA for a given interface. */ static int ospf6_gr_lsa_originate(struct ospf6_interface *oi, enum ospf6_gr_restart_reason reason) { struct ospf6 *ospf6 = oi->area->ospf6; struct ospf6_gr_info *gr_info = &ospf6->gr_info; struct ospf6_lsa_header *lsa_header; struct ospf6_grace_lsa *grace_lsa; struct ospf6_lsa *lsa; uint16_t lsa_length; char buffer[OSPF6_MAX_LSASIZE]; if (IS_OSPF6_DEBUG_ORIGINATE(LINK)) zlog_debug("Originate Grace-LSA for Interface %s", oi->interface->name); /* prepare buffer */ memset(buffer, 0, sizeof(buffer)); lsa_header = (struct ospf6_lsa_header *)buffer; grace_lsa = (struct ospf6_grace_lsa *)((caddr_t)lsa_header + sizeof(struct ospf6_lsa_header)); /* Put grace period. */ grace_lsa->tlv_period.header.type = htons(GRACE_PERIOD_TYPE); grace_lsa->tlv_period.header.length = htons(GRACE_PERIOD_LENGTH); grace_lsa->tlv_period.interval = htonl(gr_info->grace_period); /* Put restart reason. */ grace_lsa->tlv_reason.header.type = htons(RESTART_REASON_TYPE); grace_lsa->tlv_reason.header.length = htons(RESTART_REASON_LENGTH); grace_lsa->tlv_reason.reason = reason; /* Fill LSA Header */ lsa_length = sizeof(*lsa_header) + sizeof(*grace_lsa); lsa_header->age = 0; lsa_header->type = htons(OSPF6_LSTYPE_GRACE_LSA); lsa_header->id = htonl(oi->interface->ifindex); lsa_header->adv_router = ospf6->router_id; lsa_header->seqnum = ospf6_new_ls_seqnum(lsa_header->type, lsa_header->id, lsa_header->adv_router, oi->lsdb); lsa_header->length = htons(lsa_length); /* LSA checksum */ ospf6_lsa_checksum(lsa_header); if (reason == OSPF6_GR_UNKNOWN_RESTART) { struct ospf6_header *oh; uint32_t *uv32; int n; uint16_t length = OSPF6_HEADER_SIZE + 4 + lsa_length; struct iovec iovector[2] = {}; /* Reserve space for OSPFv3 header. */ memmove(&buffer[OSPF6_HEADER_SIZE + 4], buffer, lsa_length); /* Fill in the OSPFv3 header. */ oh = (struct ospf6_header *)buffer; oh->version = OSPFV3_VERSION; oh->type = OSPF6_MESSAGE_TYPE_LSUPDATE; oh->router_id = oi->area->ospf6->router_id; oh->area_id = oi->area->area_id; oh->instance_id = oi->instance_id; oh->reserved = 0; oh->length = htons(length); /* Fill LSA header. */ uv32 = (uint32_t *)&buffer[sizeof(*oh)]; *uv32 = htonl(1); /* Send packet. */ iovector[0].iov_base = lsa_header; iovector[0].iov_len = length; n = ospf6_sendmsg(oi->linklocal_addr, &allspfrouters6, oi->interface->ifindex, iovector, ospf6->fd); if (n != length) flog_err(EC_LIB_DEVELOPMENT, "%s: could not send entire message", __func__); } else { /* Create and install LSA. */ lsa = ospf6_lsa_create(lsa_header); ospf6_lsa_originate_interface(lsa, oi); } return 0; } /* Flush all self-originated Grace-LSAs. */ static void ospf6_gr_flush_grace_lsas(struct ospf6 *ospf6) { struct ospf6_area *area; struct listnode *anode; for (ALL_LIST_ELEMENTS_RO(ospf6->area_list, anode, area)) { struct ospf6_lsa *lsa; struct ospf6_interface *oi; struct listnode *inode; if (IS_DEBUG_OSPF6_GR) zlog_debug( "GR: flushing self-originated Grace-LSAs [area %pI4]", &area->area_id); for (ALL_LIST_ELEMENTS_RO(area->if_list, inode, oi)) { lsa = ospf6_lsdb_lookup(htons(OSPF6_LSTYPE_GRACE_LSA), htonl(oi->interface->ifindex), oi->area->ospf6->router_id, oi->lsdb); if (!lsa) { zlog_warn( "%s: Grace-LSA not found [interface %s] [area %pI4]", __func__, oi->interface->name, &area->area_id); continue; } ospf6_lsa_purge(lsa); } } } /* Exit from the Graceful Restart mode. */ static void ospf6_gr_restart_exit(struct ospf6 *ospf6, const char *reason) { struct ospf6_area *area; struct listnode *onode, *anode; struct ospf6_route *route; if (IS_DEBUG_OSPF6_GR) zlog_debug("GR: exiting graceful restart: %s", reason); ospf6->gr_info.restart_in_progress = false; ospf6->gr_info.finishing_restart = true; XFREE(MTYPE_TMP, ospf6->gr_info.exit_reason); ospf6->gr_info.exit_reason = XSTRDUP(MTYPE_TMP, reason); EVENT_OFF(ospf6->gr_info.t_grace_period); for (ALL_LIST_ELEMENTS_RO(ospf6->area_list, onode, area)) { struct ospf6_interface *oi; /* * 1) The router should reoriginate its router-LSAs for all * attached areas in order to make sure they have the correct * contents. */ OSPF6_ROUTER_LSA_EXECUTE(area); /* * Force reorigination of intra-area-prefix-LSAs to handle * areas without any full adjacency. */ OSPF6_INTRA_PREFIX_LSA_SCHEDULE_STUB(area); for (ALL_LIST_ELEMENTS_RO(area->if_list, anode, oi)) { /* Disable hello delay. */ if (oi->gr.hello_delay.t_grace_send) { oi->gr.hello_delay.elapsed_seconds = 0; EVENT_OFF(oi->gr.hello_delay.t_grace_send); event_add_event(master, ospf6_hello_send, oi, 0, &oi->thread_send_hello); } /* Reoriginate Link-LSA. */ if (oi->type != OSPF_IFTYPE_VIRTUALLINK) OSPF6_LINK_LSA_EXECUTE(oi); /* * 2) The router should reoriginate network-LSAs on all * segments where it is the Designated Router. */ if (oi->state == OSPF6_INTERFACE_DR) OSPF6_NETWORK_LSA_EXECUTE(oi); } } /* * While all self-originated NSSA and AS-external LSAs were already * learned from the helping neighbors, we need to reoriginate them in * order to ensure they will be refreshed periodically. */ for (route = ospf6_route_head(ospf6->external_table); route; route = ospf6_route_next(route)) ospf6_handle_external_lsa_origination(ospf6, route, &route->prefix); /* * 3) The router reruns its OSPF routing calculations, this time * installing the results into the system forwarding table, and * originating summary-LSAs, Type-7 LSAs and AS-external-LSAs as * necessary. * * 4) Any remnant entries in the system forwarding table that were * installed before the restart, but that are no longer valid, * should be removed. */ ospf6_spf_schedule(ospf6, OSPF6_SPF_FLAGS_GR_FINISH); /* 6) Any grace-LSAs that the router originated should be flushed. */ ospf6_gr_flush_grace_lsas(ospf6); } /* Enter the Graceful Restart mode. */ void ospf6_gr_restart_enter(struct ospf6 *ospf6, enum ospf6_gr_restart_reason reason, time_t timestamp) { unsigned long remaining_time; ospf6->gr_info.restart_in_progress = true; ospf6->gr_info.reason = reason; /* Schedule grace period timeout. */ remaining_time = timestamp - time(NULL); if (IS_DEBUG_OSPF6_GR) zlog_debug( "GR: remaining time until grace period expires: %lu(s)", remaining_time); event_add_timer(master, ospf6_gr_grace_period_expired, ospf6, remaining_time, &ospf6->gr_info.t_grace_period); } #define RTR_LSA_MISSING 0 #define RTR_LSA_ADJ_FOUND 1 #define RTR_LSA_ADJ_NOT_FOUND 2 /* Check if a Router-LSA exists and if it contains a given link. */ static int ospf6_router_lsa_contains_adj(struct ospf6_area *area, in_addr_t adv_router, in_addr_t neighbor_router_id) { uint16_t type; struct ospf6_lsa *lsa; bool empty = true; type = ntohs(OSPF6_LSTYPE_ROUTER); for (ALL_LSDB_TYPED_ADVRTR(area->lsdb, type, adv_router, lsa)) { struct ospf6_router_lsa *router_lsa; char *start, *end, *current; empty = false; router_lsa = (struct ospf6_router_lsa *)((char *)lsa->header + sizeof(struct ospf6_lsa_header)); /* Iterate over all interfaces in the Router-LSA. */ start = (char *)router_lsa + sizeof(struct ospf6_router_lsa); end = (char *)lsa->header + ntohs(lsa->header->length); for (current = start; current + sizeof(struct ospf6_router_lsdesc) <= end; current += sizeof(struct ospf6_router_lsdesc)) { struct ospf6_router_lsdesc *lsdesc; lsdesc = (struct ospf6_router_lsdesc *)current; if (lsdesc->type != OSPF6_ROUTER_LSDESC_POINTTOPOINT) continue; if (lsdesc->neighbor_router_id == neighbor_router_id) { ospf6_lsa_unlock(&lsa); return RTR_LSA_ADJ_FOUND; } } } if (empty) return RTR_LSA_MISSING; return RTR_LSA_ADJ_NOT_FOUND; } static bool ospf6_gr_check_router_lsa_consistency(struct ospf6 *ospf6, struct ospf6_area *area, struct ospf6_lsa *lsa) { if (lsa->header->adv_router == ospf6->router_id) { struct ospf6_router_lsa *router_lsa; char *start, *end, *current; router_lsa = (struct ospf6_router_lsa *)((char *)lsa->header + sizeof(struct ospf6_lsa_header)); /* Iterate over all interfaces in the Router-LSA. */ start = (char *)router_lsa + sizeof(struct ospf6_router_lsa); end = (char *)lsa->header + ntohs(lsa->header->length); for (current = start; current + sizeof(struct ospf6_router_lsdesc) <= end; current += sizeof(struct ospf6_router_lsdesc)) { struct ospf6_router_lsdesc *lsdesc; lsdesc = (struct ospf6_router_lsdesc *)current; if (lsdesc->type != OSPF6_ROUTER_LSDESC_POINTTOPOINT) continue; if (ospf6_router_lsa_contains_adj( area, lsdesc->neighbor_router_id, ospf6->router_id) == RTR_LSA_ADJ_NOT_FOUND) return false; } } else { int adj1, adj2; adj1 = ospf6_router_lsa_contains_adj(area, ospf6->router_id, lsa->header->adv_router); adj2 = ospf6_router_lsa_contains_adj( area, lsa->header->adv_router, ospf6->router_id); if ((adj1 == RTR_LSA_ADJ_FOUND && adj2 == RTR_LSA_ADJ_NOT_FOUND) || (adj1 == RTR_LSA_ADJ_NOT_FOUND && adj2 == RTR_LSA_ADJ_FOUND)) return false; } return true; } /* * Check for LSAs that are inconsistent with the pre-restart LSAs, and abort the * ongoing graceful restart when that's the case. */ void ospf6_gr_check_lsdb_consistency(struct ospf6 *ospf6, struct ospf6_area *area) { uint16_t type; struct ospf6_lsa *lsa; type = ntohs(OSPF6_LSTYPE_ROUTER); for (ALL_LSDB_TYPED(area->lsdb, type, lsa)) { if (!ospf6_gr_check_router_lsa_consistency(ospf6, area, lsa)) { char reason[256]; snprintfrr(reason, sizeof(reason), "detected inconsistent LSA %s [area %pI4]", lsa->name, &area->area_id); ospf6_gr_restart_exit(ospf6, reason); return; } } } /* Check if there's a fully formed adjacency with the given neighbor ID. */ static bool ospf6_gr_check_adj_id(struct ospf6_area *area, in_addr_t neighbor_router_id) { struct ospf6_neighbor *nbr; nbr = ospf6_area_neighbor_lookup(area, neighbor_router_id); if (!nbr || nbr->state < OSPF6_NEIGHBOR_FULL) { if (IS_DEBUG_OSPF6_GR) zlog_debug("GR: missing adjacency to router %pI4", &neighbor_router_id); return false; } return true; } static bool ospf6_gr_check_adjs_lsa_transit(struct ospf6_area *area, in_addr_t neighbor_router_id, uint32_t neighbor_interface_id) { struct ospf6 *ospf6 = area->ospf6; /* Check if we are the DR. */ if (neighbor_router_id == ospf6->router_id) { struct ospf6_lsa *lsa; char *start, *end, *current; struct ospf6_network_lsa *network_lsa; struct ospf6_network_lsdesc *lsdesc; /* Lookup Network LSA corresponding to this interface. */ lsa = ospf6_lsdb_lookup(htons(OSPF6_LSTYPE_NETWORK), neighbor_interface_id, neighbor_router_id, area->lsdb); if (!lsa) return false; /* Iterate over all routers present in the network. */ network_lsa = (struct ospf6_network_lsa *)((char *)lsa->header + sizeof(struct ospf6_lsa_header)); start = (char *)network_lsa + sizeof(struct ospf6_network_lsa); end = (char *)lsa->header + ntohs(lsa->header->length); for (current = start; current + sizeof(struct ospf6_network_lsdesc) <= end; current += sizeof(struct ospf6_network_lsdesc)) { lsdesc = (struct ospf6_network_lsdesc *)current; /* Skip self in the pseudonode. */ if (lsdesc->router_id == ospf6->router_id) continue; /* * Check if there's a fully formed adjacency with this * router. */ if (!ospf6_gr_check_adj_id(area, lsdesc->router_id)) return false; } } else { struct ospf6_neighbor *nbr; /* Check if there's a fully formed adjacency with the DR. */ nbr = ospf6_area_neighbor_lookup(area, neighbor_router_id); if (!nbr || nbr->state < OSPF6_NEIGHBOR_FULL) { if (IS_DEBUG_OSPF6_GR) zlog_debug( "GR: missing adjacency to DR router %pI4", &neighbor_router_id); return false; } } return true; } static bool ospf6_gr_check_adjs_lsa(struct ospf6_area *area, struct ospf6_lsa *lsa) { struct ospf6_router_lsa *router_lsa; char *start, *end, *current; router_lsa = (struct ospf6_router_lsa *)((char *)lsa->header + sizeof(struct ospf6_lsa_header)); /* Iterate over all interfaces in the Router-LSA. */ start = (char *)router_lsa + sizeof(struct ospf6_router_lsa); end = (char *)lsa->header + ntohs(lsa->header->length); for (current = start; current + sizeof(struct ospf6_router_lsdesc) <= end; current += sizeof(struct ospf6_router_lsdesc)) { struct ospf6_router_lsdesc *lsdesc; lsdesc = (struct ospf6_router_lsdesc *)current; switch (lsdesc->type) { case OSPF6_ROUTER_LSDESC_POINTTOPOINT: if (!ospf6_gr_check_adj_id(area, lsdesc->neighbor_router_id)) return false; break; case OSPF6_ROUTER_LSDESC_TRANSIT_NETWORK: if (!ospf6_gr_check_adjs_lsa_transit( area, lsdesc->neighbor_router_id, lsdesc->neighbor_interface_id)) return false; break; default: break; } } return true; } /* * Check if all adjacencies prior to the restart were reestablished. * * This is done using pre-restart Router LSAs and pre-restart Network LSAs * received from the helping neighbors. */ static bool ospf6_gr_check_adjs(struct ospf6 *ospf6) { struct ospf6_area *area; struct listnode *node; for (ALL_LIST_ELEMENTS_RO(ospf6->area_list, node, area)) { uint16_t type; uint32_t router; struct ospf6_lsa *lsa_self; bool found = false; type = ntohs(OSPF6_LSTYPE_ROUTER); router = ospf6->router_id; for (ALL_LSDB_TYPED_ADVRTR(area->lsdb, type, router, lsa_self)) { found = true; if (!ospf6_gr_check_adjs_lsa(area, lsa_self)) { ospf6_lsa_unlock(&lsa_self); return false; } } if (!found) return false; } return true; } /* Handling of grace period expiry. */ static void ospf6_gr_grace_period_expired(struct event *thread) { struct ospf6 *ospf6 = EVENT_ARG(thread); ospf6_gr_restart_exit(ospf6, "grace period has expired"); } /* Send extra Grace-LSA out the interface (unplanned outages only). */ void ospf6_gr_iface_send_grace_lsa(struct event *thread) { struct ospf6_interface *oi = EVENT_ARG(thread); ospf6_gr_lsa_originate(oi, oi->area->ospf6->gr_info.reason); if (++oi->gr.hello_delay.elapsed_seconds < oi->gr.hello_delay.interval) event_add_timer(master, ospf6_gr_iface_send_grace_lsa, oi, 1, &oi->gr.hello_delay.t_grace_send); else event_add_event(master, ospf6_hello_send, oi, 0, &oi->thread_send_hello); } /* * Record in non-volatile memory that the given OSPF instance is attempting to * perform a graceful restart. */ static void ospf6_gr_nvm_update(struct ospf6 *ospf6, bool prepare) { const char *inst_name; json_object *json; json_object *json_instances; json_object *json_instance; inst_name = ospf6->name ? ospf6->name : VRF_DEFAULT_NAME; json = frr_daemon_state_load(); json_object_object_get_ex(json, "instances", &json_instances); if (!json_instances) { json_instances = json_object_new_object(); json_object_object_add(json, "instances", json_instances); } json_object_object_get_ex(json_instances, inst_name, &json_instance); if (!json_instance) { json_instance = json_object_new_object(); json_object_object_add(json_instances, inst_name, json_instance); } json_object_int_add(json_instance, "gracePeriod", ospf6->gr_info.grace_period); /* * Record not only the grace period, but also a UNIX timestamp * corresponding to the end of that period. That way, once ospf6d is * restarted, it will be possible to take into account the time that * passed while ospf6d wasn't running. */ if (prepare) json_object_int_add(json_instance, "timestamp", time(NULL) + ospf6->gr_info.grace_period); frr_daemon_state_save(&json); } /* * Delete GR status information about the given OSPF instance from non-volatile * memory. */ void ospf6_gr_nvm_delete(struct ospf6 *ospf6) { const char *inst_name; json_object *json; json_object *json_instances; inst_name = ospf6->name ? ospf6->name : VRF_DEFAULT_NAME; json = frr_daemon_state_load(); json_object_object_get_ex(json, "instances", &json_instances); if (!json_instances) { json_instances = json_object_new_object(); json_object_object_add(json, "instances", json_instances); } json_object_object_del(json_instances, inst_name); frr_daemon_state_save(&json); } /* * Fetch from non-volatile memory whether the given OSPF instance is performing * a graceful shutdown or not. */ void ospf6_gr_nvm_read(struct ospf6 *ospf6) { const char *inst_name; json_object *json; json_object *json_instances; json_object *json_instance; json_object *json_timestamp; json_object *json_grace_period; time_t timestamp = 0; inst_name = ospf6->name ? ospf6->name : VRF_DEFAULT_NAME; json = frr_daemon_state_load(); json_object_object_get_ex(json, "instances", &json_instances); if (!json_instances) { json_instances = json_object_new_object(); json_object_object_add(json, "instances", json_instances); } json_object_object_get_ex(json_instances, inst_name, &json_instance); if (!json_instance) { json_instance = json_object_new_object(); json_object_object_add(json_instances, inst_name, json_instance); } json_object_object_get_ex(json_instance, "gracePeriod", &json_grace_period); json_object_object_get_ex(json_instance, "timestamp", &json_timestamp); if (json_timestamp) { time_t now; /* Planned GR: check if the grace period has already expired. */ now = time(NULL); timestamp = json_object_get_int(json_timestamp); if (now > timestamp) { ospf6_gr_restart_exit( ospf6, "grace period has expired already"); } else ospf6_gr_restart_enter(ospf6, OSPF6_GR_SW_RESTART, timestamp); } else if (json_grace_period) { uint32_t grace_period; /* * Unplanned GR: the Grace-LSAs will be sent later as soon as * the interfaces are operational. */ grace_period = json_object_get_int(json_grace_period); ospf6->gr_info.grace_period = grace_period; ospf6_gr_restart_enter(ospf6, OSPF6_GR_UNKNOWN_RESTART, time(NULL) + ospf6->gr_info.grace_period); } json_object_object_del(json_instance, "gracePeriod"); json_object_object_del(json_instance, "timestamp"); frr_daemon_state_save(&json); } void ospf6_gr_unplanned_start_interface(struct ospf6_interface *oi) { /* * Can't check OSPF interface state as the OSPF instance might not be * enabled yet. */ if (!if_is_operative(oi->interface) || if_is_loopback(oi->interface)) return; /* Send Grace-LSA. */ ospf6_gr_lsa_originate(oi, oi->area->ospf6->gr_info.reason); /* Start GR hello-delay interval. */ oi->gr.hello_delay.elapsed_seconds = 0; event_add_timer(master, ospf6_gr_iface_send_grace_lsa, oi, 1, &oi->gr.hello_delay.t_grace_send); } /* Prepare to start a Graceful Restart. */ static void ospf6_gr_prepare(void) { struct ospf6 *ospf6; struct ospf6_interface *oi; struct listnode *onode, *anode, *inode; for (ALL_LIST_ELEMENTS_RO(om6->ospf6, onode, ospf6)) { struct ospf6_area *area; if (!ospf6->gr_info.restart_support || ospf6->gr_info.prepare_in_progress) continue; if (IS_DEBUG_OSPF6_GR) zlog_debug( "GR: preparing to perform a graceful restart [period %u second(s)] [vrf %s]", ospf6->gr_info.grace_period, ospf6_vrf_id_to_name(ospf6->vrf_id)); /* Send a Grace-LSA to all neighbors. */ for (ALL_LIST_ELEMENTS_RO(ospf6->area_list, anode, area)) { for (ALL_LIST_ELEMENTS_RO(area->if_list, inode, oi)) { if (oi->state < OSPF6_INTERFACE_POINTTOPOINT) continue; ospf6_gr_lsa_originate(oi, OSPF6_GR_SW_RESTART); } } /* Record end of the grace period in non-volatile memory. */ ospf6_gr_nvm_update(ospf6, true); /* * Mark that a Graceful Restart preparation is in progress, to * prevent ospf6d from flushing its self-originated LSAs on * exit. */ ospf6->gr_info.prepare_in_progress = true; } } static int ospf6_gr_neighbor_change(struct ospf6_neighbor *on, int next_state, int prev_state) { struct ospf6 *ospf6 = on->ospf6_if->area->ospf6; if (next_state == OSPF6_NEIGHBOR_FULL && ospf6->gr_info.restart_in_progress) { if (ospf6_gr_check_adjs(ospf6)) { ospf6_gr_restart_exit( ospf6, "all adjacencies were reestablished"); } else { if (IS_DEBUG_OSPF6_GR) zlog_debug( "GR: not all adjacencies were reestablished yet"); } } return 0; } int config_write_ospf6_gr(struct vty *vty, struct ospf6 *ospf6) { if (!ospf6->gr_info.restart_support) return 0; if (ospf6->gr_info.grace_period == OSPF6_DFLT_GRACE_INTERVAL) vty_out(vty, " graceful-restart\n"); else vty_out(vty, " graceful-restart grace-period %u\n", ospf6->gr_info.grace_period); return 0; } DEFPY(ospf6_graceful_restart_prepare, ospf6_graceful_restart_prepare_cmd, "graceful-restart prepare ipv6 ospf", "Graceful Restart commands\n" "Prepare upcoming graceful restart\n" IPV6_STR "Prepare to restart the OSPFv3 process\n") { ospf6_gr_prepare(); return CMD_SUCCESS; } DEFPY(ospf6_graceful_restart, ospf6_graceful_restart_cmd, "graceful-restart [grace-period (1-1800)$grace_period]", OSPF_GR_STR "Maximum length of the 'grace period'\n" "Maximum length of the 'grace period' in seconds\n") { VTY_DECLVAR_INSTANCE_CONTEXT(ospf6, ospf6); /* Check and get restart period if present. */ if (!grace_period_str) grace_period = OSPF6_DFLT_GRACE_INTERVAL; ospf6->gr_info.restart_support = true; ospf6->gr_info.grace_period = grace_period; /* Freeze OSPF routes in the RIB. */ (void)ospf6_zebra_gr_enable(ospf6, ospf6->gr_info.grace_period); /* Record that GR is enabled in non-volatile memory. */ ospf6_gr_nvm_update(ospf6, false); return CMD_SUCCESS; } DEFPY(ospf6_no_graceful_restart, ospf6_no_graceful_restart_cmd, "no graceful-restart [period (1-1800)]", NO_STR OSPF_GR_STR "Maximum length of the 'grace period'\n" "Maximum length of the 'grace period' in seconds\n") { VTY_DECLVAR_INSTANCE_CONTEXT(ospf6, ospf6); if (!ospf6->gr_info.restart_support) return CMD_SUCCESS; if (ospf6->gr_info.prepare_in_progress) { vty_out(vty, "%% Error: Graceful Restart preparation in progress\n"); return CMD_WARNING; } ospf6->gr_info.restart_support = false; ospf6->gr_info.grace_period = OSPF6_DFLT_GRACE_INTERVAL; ospf6_gr_nvm_delete(ospf6); ospf6_zebra_gr_disable(ospf6); return CMD_SUCCESS; } void ospf6_gr_init(void) { hook_register(ospf6_neighbor_change, ospf6_gr_neighbor_change); install_element(ENABLE_NODE, &ospf6_graceful_restart_prepare_cmd); install_element(OSPF6_NODE, &ospf6_graceful_restart_cmd); install_element(OSPF6_NODE, &ospf6_no_graceful_restart_cmd); }