// SPDX-License-Identifier: GPL-2.0-or-later /* * This is an implementation of Segment Routing * as per RFC 8665 - OSPF Extensions for Segment Routing * and RFC 8476 - Signaling Maximum SID Depth (MSD) Using OSPF * * Module name: Segment Routing * * Author: Olivier Dugeon * Author: Anselme Sawadogo * * Copyright (C) 2016 - 2020 Orange Labs http://www.orange.com */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include #include "printfrr.h" #include "command.h" #include "hash.h" #include "if.h" #include "if.h" #include "jhash.h" #include "libospf.h" /* for ospf interface types */ #include "linklist.h" #include "log.h" #include "memory.h" #include "monotime.h" #include "network.h" #include "prefix.h" #include "sockunion.h" /* for inet_aton() */ #include "stream.h" #include "table.h" #include "frrevent.h" #include "vty.h" #include "zclient.h" #include "sbuf.h" #include #include "ospf_errors.h" #include "ospfd/ospfd.h" #include "ospfd/ospf_interface.h" #include "ospfd/ospf_ism.h" #include "ospfd/ospf_asbr.h" #include "ospfd/ospf_lsa.h" #include "ospfd/ospf_lsdb.h" #include "ospfd/ospf_neighbor.h" #include "ospfd/ospf_nsm.h" #include "ospfd/ospf_flood.h" #include "ospfd/ospf_packet.h" #include "ospfd/ospf_spf.h" #include "ospfd/ospf_dump.h" #include "ospfd/ospf_route.h" #include "ospfd/ospf_ase.h" #include "ospfd/ospf_sr.h" #include "ospfd/ospf_ri.h" #include "ospfd/ospf_ext.h" #include "ospfd/ospf_zebra.h" /* * Global variable to manage Segment Routing on this node. * Note that all parameter values are stored in network byte order. */ static struct ospf_sr_db OspfSR; static void ospf_sr_register_vty(void); static inline void del_adj_sid(struct sr_nhlfe nhlfe); static int ospf_sr_start(struct ospf *ospf); /* * Segment Routing Data Base functions */ /* Hash function for Segment Routing entry */ static unsigned int sr_hash(const void *p) { const struct in_addr *rid = p; return jhash_1word(rid->s_addr, 0); } /* Compare 2 Router ID hash entries based on SR Node */ static bool sr_cmp(const void *p1, const void *p2) { const struct sr_node *srn = p1; const struct in_addr *rid = p2; return IPV4_ADDR_SAME(&srn->adv_router, rid); } /* Functions to remove an SR Link */ static void del_sr_link(void *val) { struct sr_link *srl = (struct sr_link *)val; del_adj_sid(srl->nhlfe[0]); del_adj_sid(srl->nhlfe[1]); XFREE(MTYPE_OSPF_SR_PARAMS, val); } /* Functions to remove an SR Prefix */ static void del_sr_pref(void *val) { struct sr_prefix *srp = (struct sr_prefix *)val; ospf_zebra_delete_prefix_sid(srp); XFREE(MTYPE_OSPF_SR_PARAMS, val); } /* Allocate new Segment Routine node */ static struct sr_node *sr_node_new(struct in_addr *rid) { if (rid == NULL) return NULL; struct sr_node *new; /* Allocate Segment Routing node memory */ new = XCALLOC(MTYPE_OSPF_SR_PARAMS, sizeof(struct sr_node)); /* Default Algorithm, SRGB and MSD */ for (int i = 0; i < ALGORITHM_COUNT; i++) new->algo[i] = SR_ALGORITHM_UNSET; new->srgb.range_size = 0; new->srgb.lower_bound = 0; new->msd = 0; /* Create Link, Prefix and Range TLVs list */ new->ext_link = list_new(); new->ext_prefix = list_new(); new->ext_link->del = del_sr_link; new->ext_prefix->del = del_sr_pref; IPV4_ADDR_COPY(&new->adv_router, rid); new->neighbor = NULL; new->instance = 0; osr_debug(" |- Created new SR node for %pI4", &new->adv_router); return new; } /* Supposed to be used for testing */ struct sr_node *ospf_sr_node_create(struct in_addr *rid) { struct sr_node *srn; srn = hash_get(OspfSR.neighbors, (void *)rid, (void *)sr_node_new); return srn; } /* Delete Segment Routing node */ static void sr_node_del(struct sr_node *srn) { /* Sanity Check */ if (srn == NULL) return; osr_debug(" |- Delete SR node for %pI4", &srn->adv_router); /* Clean Extended Link */ list_delete(&srn->ext_link); /* Clean Prefix List */ list_delete(&srn->ext_prefix); XFREE(MTYPE_OSPF_SR_PARAMS, srn); } /* Get SR Node for a given nexthop */ static struct sr_node *get_sr_node_by_nexthop(struct ospf *ospf, struct in_addr nexthop) { struct ospf_interface *oi = NULL; struct ospf_neighbor *nbr = NULL; struct listnode *node; struct route_node *rn; struct sr_node *srn; bool found; /* Sanity check */ if (OspfSR.neighbors == NULL) return NULL; osr_debug(" |- Search SR-Node for nexthop %pI4", &nexthop); /* First, search neighbor Router ID for this nexthop */ found = false; for (ALL_LIST_ELEMENTS_RO(ospf->oiflist, node, oi)) { for (rn = route_top(oi->nbrs); rn; rn = route_next(rn)) { nbr = rn->info; if ((nbr) && (IPV4_ADDR_SAME(&nexthop, &nbr->src))) { found = true; break; } } if (found) break; } if (!found) return NULL; osr_debug(" |- Found nexthop Router ID %pI4", &nbr->router_id); /* Then, search SR Node */ srn = (struct sr_node *)hash_lookup(OspfSR.neighbors, &nbr->router_id); return srn; } /* * Segment Routing Local Block management functions */ /** * It is necessary to known which label is already allocated to manage the range * of SRLB. This is particular useful when an interface flap (goes up / down * frequently). Here, SR will release and then allocate label for the Adjacency * for each concerned interface. If we don't care, there is a risk to run out of * label. * * For that purpose, a similar principle as already provided to manage chunk of * label is proposed. But, here, the label chunk has not a fix range of 64 * labels that could be easily manage with a single variable of 64 bits size. * So, used_mark is used as a bit wise to mark label reserved (bit set) or not * (bit unset). Its size is equal to the number of label of the SRLB range round * up to 64 bits. * * - sr__local_block_init() computes the number of 64 bits variables that are * needed to manage the SRLB range and allocates this number. * - ospf_sr_local_block_request_label() pick up the first available label and * set corresponding bit * - ospf_sr_local_block_release_label() release label by reseting the * corresponding bit and set the next label to the first free position */ /** * Initialize Segment Routing Local Block from SRDB configuration and reserve * block of bits to manage label allocation. * * @param lower_bound The lower bound of the SRLB range * @param upper_bound The upper bound of the SRLB range * * @return 0 on success, -1 otherwise */ static int sr_local_block_init(uint32_t lower_bound, uint32_t upper_bound) { struct sr_local_block *srlb = &OspfSR.srlb; uint32_t size; /* Check if SRLB is not already configured */ if (srlb->reserved) return 0; /* * Request SRLB to the label manager. If the allocation fails, return * an error to disable SR until a new SRLB is successfully allocated. */ size = upper_bound - lower_bound + 1; if (ospf_zebra_request_label_range(lower_bound, size)) { zlog_err("SR: Error reserving SRLB [%u/%u] %u labels", lower_bound, upper_bound, size); return -1; } osr_debug("SR: Got new SRLB [%u/%u], %u labels", lower_bound, upper_bound, size); /* Initialize the SRLB */ srlb->start = lower_bound; srlb->end = upper_bound; srlb->current = 0; /* Compute the needed Used Mark number and allocate them */ srlb->max_block = size / SRLB_BLOCK_SIZE; if ((size % SRLB_BLOCK_SIZE) != 0) srlb->max_block++; srlb->used_mark = XCALLOC(MTYPE_OSPF_SR_PARAMS, srlb->max_block * SRLB_BLOCK_SIZE); srlb->reserved = true; return 0; } static int sr_global_block_init(uint32_t start, uint32_t size) { struct sr_global_block *srgb = &OspfSR.srgb; /* Check if already configured */ if (srgb->reserved) return 0; /* request chunk */ uint32_t end = start + size - 1; if (ospf_zebra_request_label_range(start, size) < 0) { zlog_err("SR: Error reserving SRGB [%u/%u], %u labels", start, end, size); return -1; } osr_debug("SR: Got new SRGB [%u/%u], %u labels", start, end, size); /* success */ srgb->start = start; srgb->size = size; srgb->reserved = true; return 0; } /** * Remove Segment Routing Local Block. * */ static void sr_local_block_delete(void) { struct sr_local_block *srlb = &OspfSR.srlb; /* Check if SRLB is not already delete */ if (!srlb->reserved) return; osr_debug("SR (%s): Remove SRLB [%u/%u]", __func__, srlb->start, srlb->end); /* First release the label block */ ospf_zebra_release_label_range(srlb->start, srlb->end); /* Then reset SRLB structure */ if (srlb->used_mark != NULL) XFREE(MTYPE_OSPF_SR_PARAMS, srlb->used_mark); srlb->reserved = false; } /** * Remove Segment Routing Global block */ static void sr_global_block_delete(void) { struct sr_global_block *srgb = &OspfSR.srgb; if (!srgb->reserved) return; osr_debug("SR (%s): Remove SRGB [%u/%u]", __func__, srgb->start, srgb->start + srgb->size - 1); ospf_zebra_release_label_range(srgb->start, srgb->start + srgb->size - 1); srgb->reserved = false; } /** * Request a label from the Segment Routing Local Block. * * @return First available label on success or MPLS_INVALID_LABEL if the * block of labels is full */ mpls_label_t ospf_sr_local_block_request_label(void) { struct sr_local_block *srlb = &OspfSR.srlb; mpls_label_t label; uint32_t index; uint32_t pos; uint32_t size = srlb->end - srlb->start + 1; /* Check if we ran out of available labels */ if (srlb->current >= size) return MPLS_INVALID_LABEL; /* Get first available label and mark it used */ label = srlb->current + srlb->start; index = srlb->current / SRLB_BLOCK_SIZE; pos = 1ULL << (srlb->current % SRLB_BLOCK_SIZE); srlb->used_mark[index] |= pos; /* Jump to the next free position */ srlb->current++; pos = srlb->current % SRLB_BLOCK_SIZE; while (srlb->current < size) { if (pos == 0) index++; if (!((1ULL << pos) & srlb->used_mark[index])) break; else { srlb->current++; pos = srlb->current % SRLB_BLOCK_SIZE; } } if (srlb->current == size) zlog_warn( "SR: Warning, SRLB is depleted and next label request will fail"); return label; } /** * Release label in the Segment Routing Local Block. * * @param label Label to be release * * @return 0 on success or -1 if label falls outside SRLB */ int ospf_sr_local_block_release_label(mpls_label_t label) { struct sr_local_block *srlb = &OspfSR.srlb; uint32_t index; uint32_t pos; /* Check that label falls inside the SRLB */ if ((label < srlb->start) || (label > srlb->end)) { flog_warn(EC_OSPF_SR_SID_OVERFLOW, "%s: Returning label %u is outside SRLB [%u/%u]", __func__, label, srlb->start, srlb->end); return -1; } index = (label - srlb->start) / SRLB_BLOCK_SIZE; pos = 1ULL << ((label - srlb->start) % SRLB_BLOCK_SIZE); srlb->used_mark[index] &= ~pos; /* Reset current to the first available position */ for (index = 0; index < srlb->max_block; index++) { if (srlb->used_mark[index] != 0xFFFFFFFFFFFFFFFF) { for (pos = 0; pos < SRLB_BLOCK_SIZE; pos++) if (!((1ULL << pos) & srlb->used_mark[index])) { srlb->current = index * SRLB_BLOCK_SIZE + pos; break; } break; } } return 0; } /* * Segment Routing Initialization functions */ /** * Thread function to re-attempt connection to the Label Manager and thus be * able to start Segment Routing. * * @param start Thread structure that contains area as argument * * @return 1 on success */ static void sr_start_label_manager(struct event *start) { struct ospf *ospf; ospf = EVENT_ARG(start); /* re-attempt to start SR & Label Manager connection */ ospf_sr_start(ospf); } /* Segment Routing starter function */ static int ospf_sr_start(struct ospf *ospf) { struct route_node *rn; struct ospf_lsa *lsa; struct sr_node *srn; int rc = 0; osr_debug("SR (%s): Start Segment Routing", __func__); /* Initialize self SR Node if not already done */ if (OspfSR.self == NULL) { srn = hash_get(OspfSR.neighbors, (void *)&(ospf->router_id), (void *)sr_node_new); /* Complete & Store self SR Node */ srn->srgb.range_size = OspfSR.srgb.size; srn->srgb.lower_bound = OspfSR.srgb.start; srn->srlb.lower_bound = OspfSR.srlb.start; srn->srlb.range_size = OspfSR.srlb.end - OspfSR.srlb.start + 1; srn->algo[0] = OspfSR.algo[0]; srn->msd = OspfSR.msd; OspfSR.self = srn; } /* Then, start Label Manager if not ready */ if (!ospf_zebra_label_manager_ready()) if (ospf_zebra_label_manager_connect() < 0) { /* Re-attempt to connect to Label Manager in 1 sec. */ event_add_timer(master, sr_start_label_manager, ospf, 1, &OspfSR.t_start_lm); osr_debug(" |- Failed to start the Label Manager"); return -1; } /* * Request SRLB & SGRB to the label manager if not already reserved. * If the allocation fails, return an error to disable SR until a new * SRLB and/or SRGB are successfully allocated. */ if (sr_local_block_init(OspfSR.srlb.start, OspfSR.srlb.end) < 0) return -1; if (sr_global_block_init(OspfSR.srgb.start, OspfSR.srgb.size) < 0) return -1; /* SR is UP and ready to flood LSA */ OspfSR.status = SR_UP; /* Set Router Information SR parameters */ osr_debug("SR: Activate SR for Router Information LSA"); ospf_router_info_update_sr(true, OspfSR.self); /* Update Ext LSA */ osr_debug("SR: Activate SR for Extended Link/Prefix LSA"); ospf_ext_update_sr(true); osr_debug("SR (%s): Update SR-DB from LSDB", __func__); /* Start by looking to Router Info & Extended LSA in lsdb */ if ((ospf != NULL) && (ospf->backbone != NULL)) { LSDB_LOOP (OPAQUE_AREA_LSDB(ospf->backbone), rn, lsa) { if (IS_LSA_MAXAGE(lsa) || IS_LSA_SELF(lsa)) continue; int lsa_id = GET_OPAQUE_TYPE(ntohl(lsa->data->id.s_addr)); switch (lsa_id) { case OPAQUE_TYPE_ROUTER_INFORMATION_LSA: ospf_sr_ri_lsa_update(lsa); break; case OPAQUE_TYPE_EXTENDED_PREFIX_LSA: ospf_sr_ext_prefix_lsa_update(lsa); break; case OPAQUE_TYPE_EXTENDED_LINK_LSA: ospf_sr_ext_link_lsa_update(lsa); break; default: break; } } } rc = 1; return rc; } /* Stop Segment Routing */ static void ospf_sr_stop(void) { if (OspfSR.status == SR_OFF) return; osr_debug("SR (%s): Stop Segment Routing", __func__); /* Disable any re-attempt to connect to Label Manager */ EVENT_OFF(OspfSR.t_start_lm); /* Release SRGB if active */ sr_global_block_delete(); /* Release SRLB if active */ sr_local_block_delete(); /* * Remove all SR Nodes from the Hash table. Prefix and Link SID will * be remove though list_delete() call. See sr_node_del() */ hash_clean(OspfSR.neighbors, (void *)sr_node_del); OspfSR.self = NULL; OspfSR.status = SR_OFF; OspfSR.msd = 0; } /* * Segment Routing initialize function * * @param - nothing * * @return 0 if OK, -1 otherwise */ int ospf_sr_init(void) { int rc = -1; osr_debug("SR (%s): Initialize SR Data Base", __func__); memset(&OspfSR, 0, sizeof(OspfSR)); OspfSR.status = SR_OFF; /* Only AREA flooding is supported in this release */ OspfSR.scope = OSPF_OPAQUE_AREA_LSA; /* Initialize Algorithms, SRGB, SRLB and MSD TLVs */ /* Only Algorithm SPF is supported */ OspfSR.algo[0] = SR_ALGORITHM_SPF; for (int i = 1; i < ALGORITHM_COUNT; i++) OspfSR.algo[i] = SR_ALGORITHM_UNSET; OspfSR.srgb.size = DEFAULT_SRGB_SIZE; OspfSR.srgb.start = DEFAULT_SRGB_LABEL; OspfSR.srgb.reserved = false; OspfSR.srlb.start = DEFAULT_SRLB_LABEL; OspfSR.srlb.end = DEFAULT_SRLB_END; OspfSR.srlb.reserved = false; OspfSR.msd = 0; /* Initialize Hash table for neighbor SR nodes */ OspfSR.neighbors = hash_create(sr_hash, sr_cmp, "OSPF_SR"); if (OspfSR.neighbors == NULL) return rc; /* Register Segment Routing VTY command */ ospf_sr_register_vty(); rc = 0; return rc; } /* * Segment Routing termination function * * @param - nothing * @return - nothing */ void ospf_sr_term(void) { /* Stop Segment Routing */ ospf_sr_stop(); hash_clean_and_free(&OspfSR.neighbors, (void *)sr_node_del); } /* * Segment Routing finish function * * @param - nothing * @return - nothing */ void ospf_sr_finish(void) { /* Stop Segment Routing */ ospf_sr_stop(); } /* * Following functions are used to manipulate the * Next Hop Label Forwarding entry (NHLFE) */ /* Compute label from index */ static mpls_label_t index2label(uint32_t index, struct sr_block srgb) { mpls_label_t label; label = srgb.lower_bound + index; if (label > (srgb.lower_bound + srgb.range_size)) { flog_warn(EC_OSPF_SR_SID_OVERFLOW, "%s: SID index %u falls outside SRGB range", __func__, index); return MPLS_INVALID_LABEL; } else return label; } /* Get the prefix sid for a specific router id */ mpls_label_t ospf_sr_get_prefix_sid_by_id(struct in_addr *id) { struct sr_node *srn; struct sr_prefix *srp; mpls_label_t label; srn = (struct sr_node *)hash_lookup(OspfSR.neighbors, id); if (srn) { /* * TODO: Here we assume that the SRGBs are the same, * and that the node's prefix SID is at the head of * the list, probably needs tweaking. */ srp = listnode_head(srn->ext_prefix); label = index2label(srp->sid, srn->srgb); } else { label = MPLS_INVALID_LABEL; } return label; } /* Get the adjacency sid for a specific 'root' id and 'neighbor' id */ mpls_label_t ospf_sr_get_adj_sid_by_id(struct in_addr *root_id, struct in_addr *neighbor_id) { struct sr_node *srn; struct sr_link *srl; mpls_label_t label; struct listnode *node; srn = (struct sr_node *)hash_lookup(OspfSR.neighbors, root_id); label = MPLS_INVALID_LABEL; if (srn) { for (ALL_LIST_ELEMENTS_RO(srn->ext_link, node, srl)) { if (srl->type == ADJ_SID && srl->remote_id.s_addr == neighbor_id->s_addr) { label = srl->sid[0]; break; } } } return label; } /* Get neighbor full structure from address */ static struct ospf_neighbor *get_neighbor_by_addr(struct ospf *top, struct in_addr addr) { struct ospf_neighbor *nbr; struct ospf_interface *oi; struct listnode *node; struct route_node *rn; /* Sanity Check */ if (top == NULL) return NULL; for (ALL_LIST_ELEMENTS_RO(top->oiflist, node, oi)) for (rn = route_top(oi->nbrs); rn; rn = route_next(rn)) { nbr = rn->info; if (!nbr) continue; if (IPV4_ADDR_SAME(&nbr->address.u.prefix4, &addr) || IPV4_ADDR_SAME(&nbr->router_id, &addr)) { route_unlock_node(rn); return nbr; } } return NULL; } /* Get OSPF Path from address */ static struct ospf_route *get_nexthop_by_addr(struct ospf *top, struct prefix_ipv4 p) { struct route_node *rn; /* Sanity Check */ if (top == NULL) return NULL; osr_debug(" |- Search Nexthop for prefix %pFX", (struct prefix *)&p); rn = route_node_lookup(top->new_table, (struct prefix *)&p); /* * Check if we found an OSPF route. May be NULL if SPF has not * yet populate routing table for this prefix. */ if (rn == NULL) return NULL; route_unlock_node(rn); return rn->info; } /* Compute NHLFE entry for Extended Link */ static int compute_link_nhlfe(struct sr_link *srl) { struct ospf *top = ospf_lookup_by_vrf_id(VRF_DEFAULT); struct ospf_neighbor *nh; int rc = 0; osr_debug(" |- Compute NHLFE for link %pI4", &srl->itf_addr); /* First determine the OSPF Neighbor */ nh = get_neighbor_by_addr(top, srl->nhlfe[0].nexthop); /* Neighbor could be not found when OSPF Adjacency just fire up * because SPF don't yet populate routing table. This NHLFE will * be fixed later when SR SPF schedule will be called. */ if (nh == NULL) return rc; osr_debug(" |- Found nexthop %pI4", &nh->router_id); /* Set ifindex for this neighbor */ srl->nhlfe[0].ifindex = nh->oi->ifp->ifindex; srl->nhlfe[1].ifindex = nh->oi->ifp->ifindex; /* Update neighbor address for LAN_ADJ_SID */ if (srl->type == LAN_ADJ_SID) { IPV4_ADDR_COPY(&srl->nhlfe[0].nexthop, &nh->src); IPV4_ADDR_COPY(&srl->nhlfe[1].nexthop, &nh->src); } /* Set Input & Output Label */ if (CHECK_FLAG(srl->flags[0], EXT_SUBTLV_LINK_ADJ_SID_VFLG)) srl->nhlfe[0].label_in = srl->sid[0]; else srl->nhlfe[0].label_in = index2label(srl->sid[0], srl->srn->srgb); if (CHECK_FLAG(srl->flags[1], EXT_SUBTLV_LINK_ADJ_SID_VFLG)) srl->nhlfe[1].label_in = srl->sid[1]; else srl->nhlfe[1].label_in = index2label(srl->sid[1], srl->srn->srgb); srl->nhlfe[0].label_out = MPLS_LABEL_IMPLICIT_NULL; srl->nhlfe[1].label_out = MPLS_LABEL_IMPLICIT_NULL; rc = 1; return rc; } /** * Compute output label for the given Prefix-SID. * * @param srp Segment Routing Prefix * @param srnext Segment Routing nexthop node * * @return MPLS label or MPLS_INVALID_LABEL in case of error */ static mpls_label_t sr_prefix_out_label(const struct sr_prefix *srp, const struct sr_node *srnext) { /* Check if the nexthop SR Node is the last hop? */ if (srnext == srp->srn) { /* SR-Node doesn't request NO-PHP. Return Implicit NULL label */ if (!CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_NPFLG)) return MPLS_LABEL_IMPLICIT_NULL; /* SR-Node requests Explicit NULL Label */ if (CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_EFLG)) return MPLS_LABEL_IPV4_EXPLICIT_NULL; /* Fallthrough */ } /* Return SID value as MPLS label if it is an Absolute SID */ if (CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_VFLG | EXT_SUBTLV_PREFIX_SID_LFLG)) { /* * V/L SIDs have local significance, so only adjacent routers * can use them (RFC8665 section #5) */ if (srp->srn != srnext) return MPLS_INVALID_LABEL; return srp->sid; } /* Return MPLS label as SRGB lower bound + SID index as per RFC 8665 */ return (index2label(srp->sid, srnext->srgb)); } /* * Compute NHLFE entry for Extended Prefix * * @param srp - Segment Routing Prefix * * @return -1 if no route is found, 0 if there is no SR route ready * and 1 if success or update */ static int compute_prefix_nhlfe(struct sr_prefix *srp) { struct ospf *top = ospf_lookup_by_vrf_id(VRF_DEFAULT); struct ospf_path *path; struct listnode *node; struct sr_node *srnext; int rc = -1; osr_debug(" |- Compute NHLFE for prefix %pFX", (struct prefix *)&srp->prefv4); /* First determine the nexthop */ srp->route = get_nexthop_by_addr(top, srp->prefv4); /* Nexthop could be not found when OSPF Adjacency just fire up * because SPF don't yet populate routing table. This NHLFE will * be fixed later when SR SPF schedule will be called. */ if (srp->route == NULL) return rc; /* Compute Input Label with self SRGB */ srp->label_in = index2label(srp->sid, OspfSR.self->srgb); rc = 0; for (ALL_LIST_ELEMENTS_RO(srp->route->paths, node, path)) { osr_debug(" |- Process new route via %pI4 for this prefix", &path->nexthop); /* * Get SR-Node for this nexthop. Could be not yet available * as Extended Link / Prefix and Router Information are flooded * after LSA Type 1 & 2 which populate the OSPF Route Table */ srnext = get_sr_node_by_nexthop(top, path->nexthop); if (srnext == NULL) continue; /* And store this information for later update */ srnext->neighbor = OspfSR.self; path->srni.nexthop = srnext; /* * SR Node could be known, but SRGB could be not initialize * This is due to the fact that Extended Link / Prefix could * be received before corresponding Router Information LSA */ if (srnext == NULL || srnext->srgb.lower_bound == 0 || srnext->srgb.range_size == 0) { osr_debug( " |- SR-Node %pI4 not ready. Stop process", &srnext->adv_router); path->srni.label_out = MPLS_INVALID_LABEL; continue; } osr_debug(" |- Found SRGB %u/%u for next hop SR-Node %pI4", srnext->srgb.range_size, srnext->srgb.lower_bound, &srnext->adv_router); /* Compute Output Label with Nexthop SR Node SRGB */ path->srni.label_out = sr_prefix_out_label(srp, srnext); osr_debug(" |- Computed new labels in: %u out: %u", srp->label_in, path->srni.label_out); rc = 1; } return rc; } /* Add new NHLFE entry for Adjacency SID */ static inline void add_adj_sid(struct sr_nhlfe nhlfe) { if (nhlfe.label_in != 0) ospf_zebra_send_adjacency_sid(ZEBRA_MPLS_LABELS_ADD, nhlfe); } /* Remove NHLFE entry for Adjacency SID */ static inline void del_adj_sid(struct sr_nhlfe nhlfe) { if (nhlfe.label_in != 0) ospf_zebra_send_adjacency_sid(ZEBRA_MPLS_LABELS_DELETE, nhlfe); } /* Update NHLFE entry for Adjacency SID */ static inline void update_adj_sid(struct sr_nhlfe n1, struct sr_nhlfe n2) { del_adj_sid(n1); add_adj_sid(n2); } /* * Functions to parse and get Extended Link / Prefix * TLVs and SubTLVs */ /* Extended Link SubTLVs Getter */ static struct sr_link *get_ext_link_sid(struct tlv_header *tlvh, size_t size) { struct sr_link *srl; struct ext_tlv_link *link = (struct ext_tlv_link *)tlvh; struct ext_subtlv_adj_sid *adj_sid; struct ext_subtlv_lan_adj_sid *lan_sid; struct ext_subtlv_rmt_itf_addr *rmt_itf; struct tlv_header *sub_tlvh; uint16_t length = 0, sum = 0, i = 0; /* Check TLV size */ if ((ntohs(tlvh->length) > size) || ntohs(tlvh->length) < EXT_TLV_LINK_SIZE) { zlog_warn("Wrong Extended Link TLV size. Abort!"); return NULL; } srl = XCALLOC(MTYPE_OSPF_SR_PARAMS, sizeof(struct sr_link)); /* Initialize TLV browsing */ length = ntohs(tlvh->length) - EXT_TLV_LINK_SIZE; sub_tlvh = (struct tlv_header *)((char *)(tlvh) + TLV_HDR_SIZE + EXT_TLV_LINK_SIZE); for (; sum < length && sub_tlvh; sub_tlvh = TLV_HDR_NEXT(sub_tlvh)) { switch (ntohs(sub_tlvh->type)) { case EXT_SUBTLV_ADJ_SID: adj_sid = (struct ext_subtlv_adj_sid *)sub_tlvh; srl->type = ADJ_SID; i = CHECK_FLAG(adj_sid->flags, EXT_SUBTLV_LINK_ADJ_SID_BFLG) ? 1 : 0; srl->flags[i] = adj_sid->flags; if (CHECK_FLAG(adj_sid->flags, EXT_SUBTLV_LINK_ADJ_SID_VFLG)) srl->sid[i] = GET_LABEL(ntohl(adj_sid->value)); else srl->sid[i] = ntohl(adj_sid->value); IPV4_ADDR_COPY(&srl->nhlfe[i].nexthop, &link->link_id); break; case EXT_SUBTLV_LAN_ADJ_SID: lan_sid = (struct ext_subtlv_lan_adj_sid *)sub_tlvh; srl->type = LAN_ADJ_SID; i = CHECK_FLAG(lan_sid->flags, EXT_SUBTLV_LINK_ADJ_SID_BFLG) ? 1 : 0; srl->flags[i] = lan_sid->flags; if (CHECK_FLAG(lan_sid->flags, EXT_SUBTLV_LINK_ADJ_SID_VFLG)) srl->sid[i] = GET_LABEL(ntohl(lan_sid->value)); else srl->sid[i] = ntohl(lan_sid->value); IPV4_ADDR_COPY(&srl->nhlfe[i].nexthop, &lan_sid->neighbor_id); break; case EXT_SUBTLV_RMT_ITF_ADDR: rmt_itf = (struct ext_subtlv_rmt_itf_addr *)sub_tlvh; IPV4_ADDR_COPY(&srl->nhlfe[0].nexthop, &rmt_itf->value); IPV4_ADDR_COPY(&srl->nhlfe[1].nexthop, &rmt_itf->value); break; default: break; } sum += TLV_SIZE(sub_tlvh); } IPV4_ADDR_COPY(&srl->itf_addr, &link->link_data); osr_debug(" |- Found primary %u and backup %u Adj/Lan Sid for %pI4", srl->sid[0], srl->sid[1], &srl->itf_addr); return srl; } /* Extended Prefix SubTLVs Getter */ static struct sr_prefix *get_ext_prefix_sid(struct tlv_header *tlvh, size_t size) { struct sr_prefix *srp; struct ext_tlv_prefix *pref = (struct ext_tlv_prefix *)tlvh; struct ext_subtlv_prefix_sid *psid; struct tlv_header *sub_tlvh; uint16_t length = 0, sum = 0; /* Check TLV size */ if ((ntohs(tlvh->length) > size) || ntohs(tlvh->length) < EXT_TLV_PREFIX_SIZE) { zlog_warn("Wrong Extended Link TLV size. Abort!"); return NULL; } srp = XCALLOC(MTYPE_OSPF_SR_PARAMS, sizeof(struct sr_prefix)); /* Initialize TLV browsing */ length = ntohs(tlvh->length) - EXT_TLV_PREFIX_SIZE; sub_tlvh = (struct tlv_header *)((char *)(tlvh) + TLV_HDR_SIZE + EXT_TLV_PREFIX_SIZE); for (; sum < length && sub_tlvh; sub_tlvh = TLV_HDR_NEXT(sub_tlvh)) { switch (ntohs(sub_tlvh->type)) { case EXT_SUBTLV_PREFIX_SID: psid = (struct ext_subtlv_prefix_sid *)sub_tlvh; if (psid->algorithm != SR_ALGORITHM_SPF) { flog_err(EC_OSPF_INVALID_ALGORITHM, "SR (%s): Unsupported Algorithm", __func__); XFREE(MTYPE_OSPF_SR_PARAMS, srp); return NULL; } srp->type = PREF_SID; srp->flags = psid->flags; if (CHECK_FLAG(psid->flags, EXT_SUBTLV_PREFIX_SID_VFLG)) srp->sid = GET_LABEL(ntohl(psid->value)); else srp->sid = ntohl(psid->value); IPV4_ADDR_COPY(&srp->prefv4.prefix, &pref->address); srp->prefv4.prefixlen = pref->pref_length; srp->prefv4.family = AF_INET; apply_mask_ipv4(&srp->prefv4); break; default: break; } sum += TLV_SIZE(sub_tlvh); } osr_debug(" |- Found SID %u for prefix %pFX", srp->sid, (struct prefix *)&srp->prefv4); return srp; } /* * Functions to manipulate Segment Routing Link & Prefix structures */ /* Compare two Segment Link: return 0 if equal, 1 otherwise */ static inline int sr_link_cmp(struct sr_link *srl1, struct sr_link *srl2) { if ((srl1->sid[0] == srl2->sid[0]) && (srl1->sid[1] == srl2->sid[1]) && (srl1->type == srl2->type) && (srl1->flags[0] == srl2->flags[0]) && (srl1->flags[1] == srl2->flags[1])) return 0; else return 1; } /* Compare two Segment Prefix: return 0 if equal, 1 otherwise */ static inline int sr_prefix_cmp(struct sr_prefix *srp1, struct sr_prefix *srp2) { if ((srp1->sid == srp2->sid) && (srp1->flags == srp2->flags)) return 0; else return 1; } /* Update Segment Link of given Segment Routing Node */ static void update_ext_link_sid(struct sr_node *srn, struct sr_link *srl, uint8_t lsa_flags) { struct listnode *node; struct sr_link *lk; bool found = false; bool config = true; /* Sanity check */ if ((srn == NULL) || (srl == NULL)) return; osr_debug(" |- Process Extended Link Adj/Lan-SID"); /* Detect if Adj/Lan_Adj SID must be configured */ if (!CHECK_FLAG(lsa_flags, OSPF_LSA_SELF) && (CHECK_FLAG(srl->flags[0], EXT_SUBTLV_LINK_ADJ_SID_LFLG) || CHECK_FLAG(srl->flags[1], EXT_SUBTLV_LINK_ADJ_SID_LFLG))) config = false; /* Search for existing Segment Link */ for (ALL_LIST_ELEMENTS_RO(srn->ext_link, node, lk)) if (lk->instance == srl->instance) { found = true; break; } osr_debug(" |- %s SR Link 8.0.0.%u for SR node %pI4", found ? "Update" : "Add", GET_OPAQUE_ID(srl->instance), &srn->adv_router); /* if not found, add new Segment Link and install NHLFE */ if (!found) { /* Complete SR-Link and add it to SR-Node list */ srl->srn = srn; IPV4_ADDR_COPY(&srl->adv_router, &srn->adv_router); listnode_add(srn->ext_link, srl); /* Try to set MPLS table */ if (config && compute_link_nhlfe(srl)) { add_adj_sid(srl->nhlfe[0]); add_adj_sid(srl->nhlfe[1]); } } else { /* Update SR-Link if they are different */ if (sr_link_cmp(lk, srl)) { /* Try to set MPLS table */ if (config) { if (compute_link_nhlfe(srl)) { update_adj_sid(lk->nhlfe[0], srl->nhlfe[0]); update_adj_sid(lk->nhlfe[1], srl->nhlfe[1]); } else { del_adj_sid(lk->nhlfe[0]); del_adj_sid(lk->nhlfe[1]); } } /* Replace SR-Link in SR-Node Adjacency List */ listnode_delete(srn->ext_link, lk); XFREE(MTYPE_OSPF_SR_PARAMS, lk); srl->srn = srn; IPV4_ADDR_COPY(&srl->adv_router, &srn->adv_router); listnode_add(srn->ext_link, srl); } else { /* * This is just an LSA refresh. * Stop processing and free SR Link */ XFREE(MTYPE_OSPF_SR_PARAMS, srl); } } } /* Update Segment Prefix of given Segment Routing Node */ static void update_ext_prefix_sid(struct sr_node *srn, struct sr_prefix *srp) { struct listnode *node; struct sr_prefix *pref; bool found = false; /* Sanity check */ if (srn == NULL || srp == NULL) return; osr_debug(" |- Process Extended Prefix SID %u", srp->sid); /* Process only Global Prefix SID */ if (CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_LFLG)) return; /* Search for existing Segment Prefix */ for (ALL_LIST_ELEMENTS_RO(srn->ext_prefix, node, pref)) if (pref->instance == srp->instance && prefix_same((struct prefix *)&srp->prefv4, &pref->prefv4)) { found = true; break; } osr_debug(" |- %s SR LSA ID 7.0.0.%u for SR node %pI4", found ? "Update" : "Add", GET_OPAQUE_ID(srp->instance), &srn->adv_router); /* Complete SR-Prefix */ srp->srn = srn; IPV4_ADDR_COPY(&srp->adv_router, &srn->adv_router); /* if not found, add new Segment Prefix and install NHLFE */ if (!found) { /* Add it to SR-Node list ... */ listnode_add(srn->ext_prefix, srp); /* ... and try to set MPLS table */ if (compute_prefix_nhlfe(srp) == 1) ospf_zebra_update_prefix_sid(srp); } else { /* * An old SR prefix exist. Check if something changes or if it * is just a refresh. */ if (sr_prefix_cmp(pref, srp)) { if (compute_prefix_nhlfe(srp) == 1) { ospf_zebra_delete_prefix_sid(pref); /* Replace Segment Prefix */ listnode_delete(srn->ext_prefix, pref); XFREE(MTYPE_OSPF_SR_PARAMS, pref); listnode_add(srn->ext_prefix, srp); ospf_zebra_update_prefix_sid(srp); } else { /* New NHLFE was not found. * Just free the SR Prefix */ XFREE(MTYPE_OSPF_SR_PARAMS, srp); } } else { /* This is just an LSA refresh. * Stop processing and free SR Prefix */ XFREE(MTYPE_OSPF_SR_PARAMS, srp); } } } /* * When change the FRR Self SRGB, update the NHLFE Input Label * for all Extended Prefix with SID index through hash_iterate() */ static void update_in_nhlfe(struct hash_bucket *bucket, void *args) { struct listnode *node; struct sr_node *srn = (struct sr_node *)bucket->data; struct sr_prefix *srp; /* Process Every Extended Prefix for this SR-Node */ for (ALL_LIST_ELEMENTS_RO(srn->ext_prefix, node, srp)) { /* Process Self SRN only if NO-PHP is requested */ if ((srn == OspfSR.self) && !CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_NPFLG)) continue; /* Process only SID Index */ if (CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_VFLG)) continue; /* First, remove old MPLS table entries ... */ ospf_zebra_delete_prefix_sid(srp); /* ... then compute new input label ... */ srp->label_in = index2label(srp->sid, OspfSR.self->srgb); /* ... and install new MPLS LFIB */ ospf_zebra_update_prefix_sid(srp); } } /* * When SRGB has changed, update NHLFE Output Label for all Extended Prefix * with SID index which use the given SR-Node as nexthop through hash_iterate() */ static void update_out_nhlfe(struct hash_bucket *bucket, void *args) { struct listnode *node, *pnode; struct sr_node *srn = (struct sr_node *)bucket->data; struct sr_node *srnext = (struct sr_node *)args; struct sr_prefix *srp; struct ospf_path *path; /* Skip Self SR-Node */ if (srn == OspfSR.self) return; osr_debug("SR (%s): Update Out NHLFE for neighbor SR-Node %pI4", __func__, &srn->adv_router); for (ALL_LIST_ELEMENTS_RO(srn->ext_prefix, node, srp)) { /* Skip Prefix that has not yet a valid route */ if (srp->route == NULL) continue; for (ALL_LIST_ELEMENTS_RO(srp->route->paths, pnode, path)) { /* Skip path that has not next SR-Node as nexthop */ if (path->srni.nexthop != srnext) continue; /* Compute new Output Label */ path->srni.label_out = sr_prefix_out_label(srp, srnext); } /* Finally update MPLS table */ ospf_zebra_update_prefix_sid(srp); } } /* * Following functions are call when new Segment Routing LSA are received * - Router Information: ospf_sr_ri_lsa_update() & ospf_sr_ri_lsa_delete() * - Extended Link: ospf_sr_ext_link_update() & ospf_sr_ext_link_delete() * - Extended Prefix: ospf_ext_prefix_update() & ospf_sr_ext_prefix_delete() */ /* Update Segment Routing from Router Information LSA */ void ospf_sr_ri_lsa_update(struct ospf_lsa *lsa) { struct sr_node *srn; struct tlv_header *tlvh; struct lsa_header *lsah = lsa->data; struct ri_sr_tlv_sid_label_range *ri_srgb = NULL; struct ri_sr_tlv_sid_label_range *ri_srlb = NULL; struct ri_sr_tlv_sr_algorithm *algo = NULL; struct sr_block srgb; uint16_t length = 0, sum = 0; uint8_t msd = 0; osr_debug("SR (%s): Process Router Information LSA 4.0.0.%u from %pI4", __func__, GET_OPAQUE_ID(ntohl(lsah->id.s_addr)), &lsah->adv_router); /* Sanity check */ if (IS_LSA_SELF(lsa)) return; if (OspfSR.neighbors == NULL) { flog_err(EC_OSPF_SR_INVALID_DB, "SR (%s): Abort! no valid SR DataBase", __func__); return; } /* Search SR Node in hash table from Router ID */ srn = (struct sr_node *)hash_lookup(OspfSR.neighbors, &lsah->adv_router); /* Collect Router Information Sub TLVs */ /* Initialize TLV browsing */ length = lsa->size - OSPF_LSA_HEADER_SIZE; srgb.range_size = 0; srgb.lower_bound = 0; for (tlvh = TLV_HDR_TOP(lsah); (sum < length) && (tlvh != NULL); tlvh = TLV_HDR_NEXT(tlvh)) { switch (ntohs(tlvh->type)) { case RI_SR_TLV_SR_ALGORITHM: algo = (struct ri_sr_tlv_sr_algorithm *)tlvh; break; case RI_SR_TLV_SRGB_LABEL_RANGE: ri_srgb = (struct ri_sr_tlv_sid_label_range *)tlvh; break; case RI_SR_TLV_SRLB_LABEL_RANGE: ri_srlb = (struct ri_sr_tlv_sid_label_range *)tlvh; break; case RI_SR_TLV_NODE_MSD: msd = ((struct ri_sr_tlv_node_msd *)(tlvh))->value; break; default: break; } sum += TLV_SIZE(tlvh); } /* Check if Segment Routing Capabilities has been found */ if (ri_srgb == NULL) { /* Skip Router Information without SR capabilities * advertise by a non SR Node */ if (srn == NULL) { return; } else { /* Remove SR Node that advertise Router Information * without SR capabilities. This could correspond to a * Node stopping Segment Routing */ hash_release(OspfSR.neighbors, &(srn->adv_router)); sr_node_del(srn); return; } } /* Check that RI LSA belongs to the correct SR Node */ if ((srn != NULL) && (srn->instance != 0) && (srn->instance != ntohl(lsah->id.s_addr))) { flog_err(EC_OSPF_SR_INVALID_LSA_ID, "SR (%s): Abort! Wrong LSA ID 4.0.0.%u for SR node %pI4/%u", __func__, GET_OPAQUE_ID(ntohl(lsah->id.s_addr)), &lsah->adv_router, srn->instance); return; } /* OK. All things look good. Get SRGB */ srgb.range_size = GET_RANGE_SIZE(ntohl(ri_srgb->size)); srgb.lower_bound = GET_LABEL(ntohl(ri_srgb->lower.value)); /* Check if it is a new SR Node or not */ if (srn == NULL) { /* Get a new SR Node in hash table from Router ID */ srn = (struct sr_node *)hash_get(OspfSR.neighbors, &lsah->adv_router, (void *)sr_node_new); /* update LSA ID */ srn->instance = ntohl(lsah->id.s_addr); /* Copy SRGB */ srn->srgb.range_size = srgb.range_size; srn->srgb.lower_bound = srgb.lower_bound; } /* Update Algorithm, SRLB and MSD if present */ if (algo != NULL) { int i; for (i = 0; i < ntohs(algo->header.length) && i < ALGORITHM_COUNT; i++) srn->algo[i] = algo->value[0]; for (; i < ALGORITHM_COUNT; i++) srn->algo[i] = SR_ALGORITHM_UNSET; } else { srn->algo[0] = SR_ALGORITHM_SPF; } srn->msd = msd; if (ri_srlb != NULL) { srn->srlb.range_size = GET_RANGE_SIZE(ntohl(ri_srlb->size)); srn->srlb.lower_bound = GET_LABEL(ntohl(ri_srlb->lower.value)); } /* Check if SRGB has changed */ if ((srn->srgb.range_size == srgb.range_size) && (srn->srgb.lower_bound == srgb.lower_bound)) return; /* Copy SRGB */ srn->srgb.range_size = srgb.range_size; srn->srgb.lower_bound = srgb.lower_bound; osr_debug(" |- Update SR-Node[%pI4], SRGB[%u/%u], SRLB[%u/%u], Algo[%u], MSD[%u]", &srn->adv_router, srn->srgb.lower_bound, srn->srgb.range_size, srn->srlb.lower_bound, srn->srlb.range_size, srn->algo[0], srn->msd); /* ... and NHLFE if it is a neighbor SR node */ if (srn->neighbor == OspfSR.self) hash_iterate(OspfSR.neighbors, update_out_nhlfe, srn); } /* * Delete SR Node entry in hash table information corresponding to an expired * Router Information LSA */ void ospf_sr_ri_lsa_delete(struct ospf_lsa *lsa) { struct sr_node *srn; struct lsa_header *lsah = lsa->data; osr_debug("SR (%s): Remove SR node %pI4 from lsa_id 4.0.0.%u", __func__, &lsah->adv_router, GET_OPAQUE_ID(ntohl(lsah->id.s_addr))); /* Sanity check */ if (OspfSR.neighbors == NULL) { flog_err(EC_OSPF_SR_INVALID_DB, "SR (%s): Abort! no valid SR Data Base", __func__); return; } /* Release Router ID entry in SRDB hash table */ srn = hash_release(OspfSR.neighbors, &(lsah->adv_router)); /* Sanity check */ if (srn == NULL) { flog_err(EC_OSPF_SR_NODE_CREATE, "SR (%s): Abort! no entry in SRDB for SR Node %pI4", __func__, &lsah->adv_router); return; } if ((srn->instance != 0) && (srn->instance != ntohl(lsah->id.s_addr))) { flog_err( EC_OSPF_SR_INVALID_LSA_ID, "SR (%s): Abort! Wrong LSA ID 4.0.0.%u for SR node %pI4", __func__, GET_OPAQUE_ID(ntohl(lsah->id.s_addr)), &lsah->adv_router); return; } /* Remove SR node */ sr_node_del(srn); } /* Update Segment Routing from Extended Link LSA */ void ospf_sr_ext_link_lsa_update(struct ospf_lsa *lsa) { struct sr_node *srn; struct tlv_header *tlvh; struct lsa_header *lsah = lsa->data; struct sr_link *srl; int length; osr_debug("SR (%s): Process Extended Link LSA 8.0.0.%u from %pI4", __func__, GET_OPAQUE_ID(ntohl(lsah->id.s_addr)), &lsah->adv_router); /* Sanity check */ if (OspfSR.neighbors == NULL) { flog_err(EC_OSPF_SR_INVALID_DB, "SR (%s): Abort! no valid SR DataBase", __func__); return; } /* Get SR Node in hash table from Router ID */ srn = (struct sr_node *)hash_get(OspfSR.neighbors, (void *)&(lsah->adv_router), (void *)sr_node_new); /* Initialize TLV browsing */ length = lsa->size - OSPF_LSA_HEADER_SIZE; for (tlvh = TLV_HDR_TOP(lsah); length > 0 && tlvh; tlvh = TLV_HDR_NEXT(tlvh)) { if (ntohs(tlvh->type) == EXT_TLV_LINK) { /* Got Extended Link information */ srl = get_ext_link_sid(tlvh, length); /* Update SID if not null */ if (srl != NULL) { srl->instance = ntohl(lsah->id.s_addr); update_ext_link_sid(srn, srl, lsa->flags); } } length -= TLV_SIZE(tlvh); } } /* Delete Segment Routing from Extended Link LSA */ void ospf_sr_ext_link_lsa_delete(struct ospf_lsa *lsa) { struct listnode *node; struct sr_link *srl; struct sr_node *srn; struct lsa_header *lsah = lsa->data; uint32_t instance = ntohl(lsah->id.s_addr); osr_debug("SR (%s): Remove Extended Link LSA 8.0.0.%u from %pI4", __func__, GET_OPAQUE_ID(ntohl(lsah->id.s_addr)), &lsah->adv_router); /* Sanity check */ if (OspfSR.neighbors == NULL) { flog_err(EC_OSPF_SR_INVALID_DB, "SR (%s): Abort! no valid SR DataBase", __func__); return; } /* Search SR Node in hash table from Router ID */ srn = (struct sr_node *)hash_lookup(OspfSR.neighbors, (void *)&(lsah->adv_router)); /* * SR-Node may be NULL if it has been remove previously when * processing Router Information LSA deletion */ if (srn == NULL) { flog_err(EC_OSPF_SR_INVALID_DB, "SR (%s): Stop! no entry in SRDB for SR Node %pI4", __func__, &lsah->adv_router); return; } /* Search for corresponding Segment Link */ for (ALL_LIST_ELEMENTS_RO(srn->ext_link, node, srl)) if (srl->instance == instance) break; /* Remove Segment Link if found. Note that for Neighbors, only Global * Adj/Lan-Adj SID are stored in the SR-DB */ if ((srl != NULL) && (srl->instance == instance)) { del_adj_sid(srl->nhlfe[0]); del_adj_sid(srl->nhlfe[1]); listnode_delete(srn->ext_link, srl); XFREE(MTYPE_OSPF_SR_PARAMS, srl); } } /* Add (LAN)Adjacency-SID from Extended Link Information */ void ospf_sr_ext_itf_add(struct ext_itf *exti) { struct sr_node *srn = OspfSR.self; struct sr_link *srl; osr_debug("SR (%s): Add Extended Link LSA 8.0.0.%u from self", __func__, exti->instance); /* Sanity check */ if (srn == NULL) return; /* Initialize new Segment Routing Link */ srl = XCALLOC(MTYPE_OSPF_SR_PARAMS, sizeof(struct sr_link)); srl->srn = srn; srl->adv_router = srn->adv_router; srl->itf_addr = exti->link.link_data; srl->instance = SET_OPAQUE_LSID(OPAQUE_TYPE_EXTENDED_LINK_LSA, exti->instance); srl->remote_id = exti->link.link_id; switch (exti->stype) { case ADJ_SID: srl->type = ADJ_SID; /* Primary information */ srl->flags[0] = exti->adj_sid[0].flags; if (CHECK_FLAG(exti->adj_sid[0].flags, EXT_SUBTLV_LINK_ADJ_SID_VFLG)) srl->sid[0] = GET_LABEL(ntohl(exti->adj_sid[0].value)); else srl->sid[0] = ntohl(exti->adj_sid[0].value); if (exti->rmt_itf_addr.header.type == 0) srl->nhlfe[0].nexthop = exti->link.link_id; else srl->nhlfe[0].nexthop = exti->rmt_itf_addr.value; /* Backup Information if set */ if (exti->adj_sid[1].header.type == 0) break; srl->flags[1] = exti->adj_sid[1].flags; if (CHECK_FLAG(exti->adj_sid[1].flags, EXT_SUBTLV_LINK_ADJ_SID_VFLG)) srl->sid[1] = GET_LABEL(ntohl(exti->adj_sid[1].value)); else srl->sid[1] = ntohl(exti->adj_sid[1].value); if (exti->rmt_itf_addr.header.type == 0) srl->nhlfe[1].nexthop = exti->link.link_id; else srl->nhlfe[1].nexthop = exti->rmt_itf_addr.value; break; case LAN_ADJ_SID: srl->type = LAN_ADJ_SID; /* Primary information */ srl->flags[0] = exti->lan_sid[0].flags; if (CHECK_FLAG(exti->lan_sid[0].flags, EXT_SUBTLV_LINK_ADJ_SID_VFLG)) srl->sid[0] = GET_LABEL(ntohl(exti->lan_sid[0].value)); else srl->sid[0] = ntohl(exti->lan_sid[0].value); if (exti->rmt_itf_addr.header.type == 0) srl->nhlfe[0].nexthop = exti->lan_sid[0].neighbor_id; else srl->nhlfe[0].nexthop = exti->rmt_itf_addr.value; /* Backup Information if set */ if (exti->lan_sid[1].header.type == 0) break; srl->flags[1] = exti->lan_sid[1].flags; if (CHECK_FLAG(exti->lan_sid[1].flags, EXT_SUBTLV_LINK_ADJ_SID_VFLG)) srl->sid[1] = GET_LABEL(ntohl(exti->lan_sid[1].value)); else srl->sid[1] = ntohl(exti->lan_sid[1].value); if (exti->rmt_itf_addr.header.type == 0) srl->nhlfe[1].nexthop = exti->lan_sid[1].neighbor_id; else srl->nhlfe[1].nexthop = exti->rmt_itf_addr.value; break; case PREF_SID: case LOCAL_SID: /* Wrong SID Type. Abort! */ XFREE(MTYPE_OSPF_SR_PARAMS, srl); return; } /* Segment Routing Link is ready, update it */ update_ext_link_sid(srn, srl, OSPF_LSA_SELF); } /* Delete Prefix or (LAN)Adjacency-SID from Extended Link Information */ void ospf_sr_ext_itf_delete(struct ext_itf *exti) { struct listnode *node; struct sr_node *srn = OspfSR.self; struct sr_prefix *srp = NULL; struct sr_link *srl = NULL; uint32_t instance; osr_debug("SR (%s): Remove Extended LSA %u.0.0.%u from self", __func__, exti->stype == PREF_SID ? 7 : 8, exti->instance); /* Sanity check: SR-Node and Extended Prefix/Link list may have been * removed earlier when stopping OSPF or OSPF-SR */ if (srn == NULL || srn->ext_prefix == NULL || srn->ext_link == NULL) return; if (exti->stype == PREF_SID) { instance = SET_OPAQUE_LSID(OPAQUE_TYPE_EXTENDED_PREFIX_LSA, exti->instance); for (ALL_LIST_ELEMENTS_RO(srn->ext_prefix, node, srp)) if (srp->instance == instance) break; /* Uninstall Segment Prefix SID if found */ if ((srp != NULL) && (srp->instance == instance)) ospf_zebra_delete_prefix_sid(srp); } else { /* Search for corresponding Segment Link for self SR-Node */ instance = SET_OPAQUE_LSID(OPAQUE_TYPE_EXTENDED_LINK_LSA, exti->instance); for (ALL_LIST_ELEMENTS_RO(srn->ext_link, node, srl)) if (srl->instance == instance) break; /* Remove Segment Link if found */ if ((srl != NULL) && (srl->instance == instance)) { del_adj_sid(srl->nhlfe[0]); del_adj_sid(srl->nhlfe[1]); listnode_delete(srn->ext_link, srl); XFREE(MTYPE_OSPF_SR_PARAMS, srl); } } } /* Update Segment Routing from Extended Prefix LSA */ void ospf_sr_ext_prefix_lsa_update(struct ospf_lsa *lsa) { struct sr_node *srn; struct tlv_header *tlvh; struct lsa_header *lsah = (struct lsa_header *)lsa->data; struct sr_prefix *srp; int length; osr_debug("SR (%s): Process Extended Prefix LSA 7.0.0.%u from %pI4", __func__, GET_OPAQUE_ID(ntohl(lsah->id.s_addr)), &lsah->adv_router); /* Sanity check */ if (OspfSR.neighbors == NULL) { flog_err(EC_OSPF_SR_INVALID_DB, "SR (%s): Abort! no valid SR DataBase", __func__); return; } /* Get SR Node in hash table from Router ID */ srn = (struct sr_node *)hash_get(OspfSR.neighbors, (void *)&(lsah->adv_router), (void *)sr_node_new); /* Initialize TLV browsing */ length = lsa->size - OSPF_LSA_HEADER_SIZE; for (tlvh = TLV_HDR_TOP(lsah); length > 0 && tlvh; tlvh = TLV_HDR_NEXT(tlvh)) { if (ntohs(tlvh->type) == EXT_TLV_LINK) { /* Got Extended Link information */ srp = get_ext_prefix_sid(tlvh, length); /* Update SID if not null */ if (srp != NULL) { srp->instance = ntohl(lsah->id.s_addr); update_ext_prefix_sid(srn, srp); } } length -= TLV_SIZE(tlvh); } } /* Delete Segment Routing from Extended Prefix LSA */ void ospf_sr_ext_prefix_lsa_delete(struct ospf_lsa *lsa) { struct listnode *node; struct sr_prefix *srp; struct sr_node *srn; struct lsa_header *lsah = (struct lsa_header *)lsa->data; uint32_t instance = ntohl(lsah->id.s_addr); osr_debug("SR (%s): Remove Extended Prefix LSA 7.0.0.%u from %pI4", __func__, GET_OPAQUE_ID(ntohl(lsah->id.s_addr)), &lsah->adv_router); /* Sanity check */ if (OspfSR.neighbors == NULL) { flog_err(EC_OSPF_SR_INVALID_DB, "SR (%s): Abort! no valid SR DataBase", __func__); return; } /* Search SR Node in hash table from Router ID */ srn = (struct sr_node *)hash_lookup(OspfSR.neighbors, (void *)&(lsah->adv_router)); /* * SR-Node may be NULL if it has been remove previously when * processing Router Information LSA deletion */ if (srn == NULL) { flog_err(EC_OSPF_SR_INVALID_DB, "SR (%s): Stop! no entry in SRDB for SR Node %pI4", __func__, &lsah->adv_router); return; } /* Search for corresponding Segment Prefix */ for (ALL_LIST_ELEMENTS_RO(srn->ext_prefix, node, srp)) if (srp->instance == instance) break; /* Remove Prefix if found */ if ((srp != NULL) && (srp->instance == instance)) { ospf_zebra_delete_prefix_sid(srp); listnode_delete(srn->ext_prefix, srp); XFREE(MTYPE_OSPF_SR_PARAMS, srp); } else { flog_err( EC_OSPF_SR_INVALID_DB, "SR (%s): Didn't found corresponding SR Prefix 7.0.0.%u for SR Node %pI4", __func__, GET_OPAQUE_ID(ntohl(lsah->id.s_addr)), &lsah->adv_router); } } /* * Update Prefix SID. Call by ospf_ext_pref_ism_change to * complete initial CLI command at startup. * * @param ifp - Loopback interface * @param pref - Prefix address of this interface * * @return - void */ void ospf_sr_update_local_prefix(struct interface *ifp, struct prefix *p) { struct listnode *node; struct sr_prefix *srp; /* Sanity Check */ if ((ifp == NULL) || (p == NULL)) return; /* * Search if there is a Segment Prefix that correspond to this * interface or prefix, and update it if found */ for (ALL_LIST_ELEMENTS_RO(OspfSR.self->ext_prefix, node, srp)) { if ((srp->nhlfe.ifindex == ifp->ifindex) || ((IPV4_ADDR_SAME(&srp->prefv4.prefix, &p->u.prefix4)) && (srp->prefv4.prefixlen == p->prefixlen))) { /* Update Interface & Prefix info */ srp->nhlfe.ifindex = ifp->ifindex; IPV4_ADDR_COPY(&srp->prefv4.prefix, &p->u.prefix4); srp->prefv4.prefixlen = p->prefixlen; srp->prefv4.family = p->family; IPV4_ADDR_COPY(&srp->nhlfe.nexthop, &p->u.prefix4); /* OK. Let's Schedule Extended Prefix LSA */ srp->instance = ospf_ext_schedule_prefix_index( ifp, srp->sid, &srp->prefv4, srp->flags); osr_debug( " |- Update Node SID %pFX - %u for self SR Node", (struct prefix *)&srp->prefv4, srp->sid); /* Install SID if NO-PHP is set and not EXPLICIT-NULL */ if (CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_NPFLG) && !CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_EFLG)) { srp->label_in = index2label(srp->sid, OspfSR.self->srgb); srp->nhlfe.label_out = MPLS_LABEL_IMPLICIT_NULL; ospf_zebra_update_prefix_sid(srp); } } } } /* * Following functions are used to update MPLS LFIB after a SPF run */ static void ospf_sr_nhlfe_update(struct hash_bucket *bucket, void *args) { struct sr_node *srn = (struct sr_node *)bucket->data; struct listnode *node; struct sr_prefix *srp; bool old; int rc; osr_debug(" |- Update Prefix for SR Node %pI4", &srn->adv_router); /* Skip Self SR Node */ if (srn == OspfSR.self) return; /* Update Extended Prefix */ for (ALL_LIST_ELEMENTS_RO(srn->ext_prefix, node, srp)) { /* Keep track of valid route */ old = srp->route != NULL; /* Compute the new NHLFE */ rc = compute_prefix_nhlfe(srp); /* Check computation result */ switch (rc) { /* Routes are not know, remove old NHLFE if any to avoid loop */ case -1: if (old) ospf_zebra_delete_prefix_sid(srp); break; /* Routes exist but are not ready, skip it */ case 0: break; /* There is at least one route, update NHLFE */ case 1: ospf_zebra_update_prefix_sid(srp); break; default: break; } } } void ospf_sr_update_task(struct ospf *ospf) { struct timeval start_time, stop_time; /* Check ospf and SR status */ if ((ospf == NULL) || (OspfSR.status != SR_UP)) return; monotime(&start_time); osr_debug("SR (%s): Start SPF update", __func__); hash_iterate(OspfSR.neighbors, (void (*)(struct hash_bucket *, void *))ospf_sr_nhlfe_update, NULL); monotime(&stop_time); osr_debug("SR (%s): SPF Processing Time(usecs): %lld", __func__, (stop_time.tv_sec - start_time.tv_sec) * 1000000LL + (stop_time.tv_usec - start_time.tv_usec)); } /* * -------------------------------------- * Following are vty command functions. * -------------------------------------- */ /* * Segment Routing Router configuration * * Must be centralize as it concerns both Extended Link/Prefix LSA * and Router Information LSA. Choose to call it from Extended Prefix * write_config() call back. * * @param vty VTY output * * @return none */ void ospf_sr_config_write_router(struct vty *vty) { struct listnode *node; struct sr_prefix *srp; uint32_t upper; if (OspfSR.status == SR_UP) vty_out(vty, " segment-routing on\n"); upper = OspfSR.srgb.start + OspfSR.srgb.size - 1; if ((OspfSR.srgb.start != DEFAULT_SRGB_LABEL) || (OspfSR.srgb.size != DEFAULT_SRGB_SIZE)) vty_out(vty, " segment-routing global-block %u %u", OspfSR.srgb.start, upper); if ((OspfSR.srlb.start != DEFAULT_SRLB_LABEL) || (OspfSR.srlb.end != DEFAULT_SRLB_END)) { if ((OspfSR.srgb.start == DEFAULT_SRGB_LABEL) && (OspfSR.srgb.size == DEFAULT_SRGB_SIZE)) vty_out(vty, " segment-routing global-block %u %u", OspfSR.srgb.start, upper); vty_out(vty, " local-block %u %u\n", OspfSR.srlb.start, OspfSR.srlb.end); } else vty_out(vty, "\n"); if (OspfSR.msd != 0) vty_out(vty, " segment-routing node-msd %u\n", OspfSR.msd); if (OspfSR.self != NULL) { for (ALL_LIST_ELEMENTS_RO(OspfSR.self->ext_prefix, node, srp)) { vty_out(vty, " segment-routing prefix %pFX index %u", &srp->prefv4, srp->sid); if (CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_EFLG)) vty_out(vty, " explicit-null\n"); else if (CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_NPFLG)) vty_out(vty, " no-php-flag\n"); else vty_out(vty, "\n"); } } } DEFUN(ospf_sr_enable, ospf_sr_enable_cmd, "segment-routing on", SR_STR "Enable Segment Routing\n") { VTY_DECLVAR_INSTANCE_CONTEXT(ospf, ospf); if (OspfSR.status != SR_OFF) return CMD_SUCCESS; if (ospf->vrf_id != VRF_DEFAULT) { vty_out(vty, "Segment Routing is only supported in default VRF\n"); return CMD_WARNING_CONFIG_FAILED; } osr_debug("SR: Segment Routing: OFF -> ON"); /* Start Segment Routing */ OspfSR.status = SR_ON; ospf_sr_start(ospf); return CMD_SUCCESS; } DEFUN (no_ospf_sr_enable, no_ospf_sr_enable_cmd, "no segment-routing [on]", NO_STR SR_STR "Disable Segment Routing\n") { if (OspfSR.status == SR_OFF) return CMD_SUCCESS; osr_debug("SR: Segment Routing: ON -> OFF"); /* Start by Disabling Extended Link & Prefix LSA */ ospf_ext_update_sr(false); /* then, disable Router Information SR parameters */ ospf_router_info_update_sr(false, OspfSR.self); /* Finally, stop Segment Routing */ ospf_sr_stop(); return CMD_SUCCESS; } static int ospf_sr_enabled(struct vty *vty) { if (OspfSR.status != SR_OFF) return 1; if (vty) vty_out(vty, "%% OSPF SR is not turned on\n"); return 0; } /* tell if two ranges [r1_lower, r1_upper] and [r2_lower,r2_upper] overlap */ static bool ranges_overlap(uint32_t r1_lower, uint32_t r1_upper, uint32_t r2_lower, uint32_t r2_upper) { return !((r1_upper < r2_lower) || (r1_lower > r2_upper)); } /* tell if a range is valid */ static bool sr_range_is_valid(uint32_t lower, uint32_t upper, uint32_t min_size) { return (upper >= lower + min_size); } /** * Update SRGB and/or SRLB using new CLI values. * * @param gb_lower Lower bound of the SRGB * @param gb_upper Upper bound of the SRGB * @param lb_lower Lower bound of the SRLB * @param lb_upper Upper bound of the SRLB * * @return 0 on success, -1 otherwise */ static int update_sr_blocks(uint32_t gb_lower, uint32_t gb_upper, uint32_t lb_lower, uint32_t lb_upper) { /* Check if values have changed */ bool gb_changed, lb_changed; uint32_t gb_size = gb_upper - gb_lower + 1; uint32_t lb_size = lb_upper - lb_lower + 1; gb_changed = (OspfSR.srgb.size != gb_size || OspfSR.srgb.start != gb_lower); lb_changed = (OspfSR.srlb.end != lb_upper || OspfSR.srlb.start != lb_lower); if (!gb_changed && !lb_changed) return 0; /* Check if SR is correctly started i.e. Label Manager connected */ if (OspfSR.status != SR_UP) { OspfSR.srgb.size = gb_size; OspfSR.srgb.start = gb_lower; OspfSR.srlb.end = lb_upper; OspfSR.srlb.start = lb_lower; return 0; } /* Release old SRGB if it has changed and is active. */ if (gb_changed) { sr_global_block_delete(); /* Set new SRGB values - but do not reserve yet (we need to * release the SRLB too) */ OspfSR.srgb.size = gb_size; OspfSR.srgb.start = gb_lower; if (OspfSR.self != NULL) { OspfSR.self->srgb.range_size = gb_size; OspfSR.self->srgb.lower_bound = gb_lower; } } /* Release old SRLB if it has changed and reserve new block as needed. */ if (lb_changed) { sr_local_block_delete(); /* Set new SRLB values */ if (sr_local_block_init(lb_lower, lb_upper) < 0) { ospf_sr_stop(); return -1; } if (OspfSR.self != NULL) { OspfSR.self->srlb.lower_bound = lb_lower; OspfSR.self->srlb.range_size = lb_size; } } /* * Try to reserve the new SRGB from the Label Manger. If the * allocation fails, disable SR until new blocks are successfully * allocated. */ if (gb_changed) { if (sr_global_block_init(OspfSR.srgb.start, OspfSR.srgb.size) < 0) { ospf_sr_stop(); return -1; } } /* Update Self SR-Node */ if (OspfSR.self != NULL) { /* SRGB is reserved, set Router Information parameters */ ospf_router_info_update_sr(true, OspfSR.self); /* and update NHLFE entries */ if (gb_changed) hash_iterate(OspfSR.neighbors, (void (*)(struct hash_bucket *, void *))update_in_nhlfe, NULL); /* and update (LAN)-Adjacency SID */ if (lb_changed) ospf_ext_link_srlb_update(); } return 0; } DEFUN(sr_global_label_range, sr_global_label_range_cmd, "segment-routing global-block (16-1048575) (16-1048575) [local-block (16-1048575) (16-1048575)]", SR_STR "Segment Routing Global Block label range\n" "Lower-bound range in decimal (16-1048575)\n" "Upper-bound range in decimal (16-1048575)\n" "Segment Routing Local Block label range\n" "Lower-bound range in decimal (16-1048575)\n" "Upper-bound range in decimal (16-1048575)\n") { uint32_t lb_upper, lb_lower; uint32_t gb_upper, gb_lower; int idx_gb_low = 2, idx_gb_up = 3; int idx_lb_low = 5, idx_lb_up = 6; /* Get lower and upper bound for mandatory global-block */ gb_lower = strtoul(argv[idx_gb_low]->arg, NULL, 10); gb_upper = strtoul(argv[idx_gb_up]->arg, NULL, 10); /* SRLB values are taken from vtysh if there, else use the known ones */ lb_upper = argc > idx_lb_up ? strtoul(argv[idx_lb_up]->arg, NULL, 10) : OspfSR.srlb.end; lb_lower = argc > idx_lb_low ? strtoul(argv[idx_lb_low]->arg, NULL, 10) : OspfSR.srlb.start; /* check correctness of input SRGB */ if (!sr_range_is_valid(gb_lower, gb_upper, MIN_SRGB_SIZE)) { vty_out(vty, "Invalid SRGB range\n"); return CMD_WARNING_CONFIG_FAILED; } /* check correctness of SRLB */ if (!sr_range_is_valid(lb_lower, lb_upper, MIN_SRLB_SIZE)) { vty_out(vty, "Invalid SRLB range\n"); return CMD_WARNING_CONFIG_FAILED; } /* Validate SRGB against SRLB */ if (ranges_overlap(gb_lower, gb_upper, lb_lower, lb_upper)) { vty_out(vty, "New SR Global Block (%u/%u) conflicts with Local Block (%u/%u)\n", gb_lower, gb_upper, lb_lower, lb_upper); return CMD_WARNING_CONFIG_FAILED; } if (update_sr_blocks(gb_lower, gb_upper, lb_lower, lb_upper) < 0) return CMD_WARNING_CONFIG_FAILED; else return CMD_SUCCESS; } DEFUN(no_sr_global_label_range, no_sr_global_label_range_cmd, "no segment-routing global-block [(16-1048575) (16-1048575) local-block (16-1048575) (16-1048575)]", NO_STR SR_STR "Segment Routing Global Block label range\n" "Lower-bound range in decimal (16-1048575)\n" "Upper-bound range in decimal (16-1048575)\n" "Segment Routing Local Block label range\n" "Lower-bound range in decimal (16-1048575)\n" "Upper-bound range in decimal (16-1048575)\n") { if (update_sr_blocks(DEFAULT_SRGB_LABEL, DEFAULT_SRGB_END, DEFAULT_SRLB_LABEL, DEFAULT_SRLB_END) < 0) return CMD_WARNING_CONFIG_FAILED; else return CMD_SUCCESS; } DEFUN (sr_node_msd, sr_node_msd_cmd, "segment-routing node-msd (1-16)", SR_STR "Maximum Stack Depth for this router\n" "Maximum number of label that could be stack (1-16)\n") { uint32_t msd; int idx = 1; if (!ospf_sr_enabled(vty)) return CMD_WARNING_CONFIG_FAILED; /* Get MSD */ argv_find(argv, argc, "(1-16)", &idx); msd = strtoul(argv[idx]->arg, NULL, 10); if (msd < 1 || msd > MPLS_MAX_LABELS) { vty_out(vty, "MSD must be comprise between 1 and %u\n", MPLS_MAX_LABELS); return CMD_WARNING_CONFIG_FAILED; } /* Check if value has changed */ if (OspfSR.msd == msd) return CMD_SUCCESS; /* Set this router MSD */ OspfSR.msd = msd; if (OspfSR.self != NULL) { OspfSR.self->msd = msd; /* Set Router Information parameters if SR is UP */ if (OspfSR.status == SR_UP) ospf_router_info_update_sr(true, OspfSR.self); } return CMD_SUCCESS; } DEFUN (no_sr_node_msd, no_sr_node_msd_cmd, "no segment-routing node-msd [(1-16)]", NO_STR SR_STR "Maximum Stack Depth for this router\n" "Maximum number of label that could be stack (1-16)\n") { if (!ospf_sr_enabled(vty)) return CMD_WARNING_CONFIG_FAILED; /* unset this router MSD */ OspfSR.msd = 0; if (OspfSR.self != NULL) { OspfSR.self->msd = 0; /* Set Router Information parameters if SR is UP */ if (OspfSR.status == SR_UP) ospf_router_info_update_sr(true, OspfSR.self); } return CMD_SUCCESS; } DEFUN (sr_prefix_sid, sr_prefix_sid_cmd, "segment-routing prefix A.B.C.D/M index (0-65535) [no-php-flag|explicit-null]", SR_STR "Prefix SID\n" "IPv4 Prefix as A.B.C.D/M\n" "SID index for this prefix in decimal (0-65535)\n" "Index value inside SRGB (lower_bound < index < upper_bound)\n" "Don't request Penultimate Hop Popping (PHP)\n" "Upstream neighbor must replace prefix-sid with explicit null label\n") { int idx = 0; struct prefix p, pexist; uint32_t index; struct listnode *node; struct sr_prefix *srp, *exist = NULL; struct interface *ifp; bool no_php_flag = false; bool exp_null = false; bool index_in_use = false; uint8_t desired_flags = 0; if (!ospf_sr_enabled(vty)) return CMD_WARNING_CONFIG_FAILED; /* Get network prefix */ argv_find(argv, argc, "A.B.C.D/M", &idx); if (!str2prefix(argv[idx]->arg, &p)) { vty_out(vty, "Invalid prefix format %s\n", argv[idx]->arg); return CMD_WARNING_CONFIG_FAILED; } /* Get & verify index value */ argv_find(argv, argc, "(0-65535)", &idx); index = strtoul(argv[idx]->arg, NULL, 10); if (index > OspfSR.srgb.size - 1) { vty_out(vty, "Index %u must be lower than range size %u\n", index, OspfSR.srgb.size); return CMD_WARNING_CONFIG_FAILED; } /* Get options */ no_php_flag = argv_find(argv, argc, "no-php-flag", &idx); exp_null = argv_find(argv, argc, "explicit-null", &idx); desired_flags |= no_php_flag ? EXT_SUBTLV_PREFIX_SID_NPFLG : 0; desired_flags |= exp_null ? EXT_SUBTLV_PREFIX_SID_NPFLG : 0; desired_flags |= exp_null ? EXT_SUBTLV_PREFIX_SID_EFLG : 0; /* Search for an existing Prefix-SID */ for (ALL_LIST_ELEMENTS_RO(OspfSR.self->ext_prefix, node, srp)) { if (prefix_same((struct prefix *)&srp->prefv4, &p)) exist = srp; if (srp->sid == index) { index_in_use = true; pexist = p; } } /* done if prefix segment already there with same index and flags */ if (exist && exist->sid == index && exist->flags == desired_flags) return CMD_SUCCESS; /* deny if index is already in use by a distinct prefix */ if (!exist && index_in_use) { vty_out(vty, "Index %u is already used by %pFX\n", index, &pexist); return CMD_WARNING_CONFIG_FAILED; } /* First, remove old NHLFE if installed */ if (exist && CHECK_FLAG(exist->flags, EXT_SUBTLV_PREFIX_SID_NPFLG) && !CHECK_FLAG(exist->flags, EXT_SUBTLV_PREFIX_SID_EFLG)) ospf_zebra_delete_prefix_sid(exist); /* Create new Extended Prefix to SRDB if not found */ if (exist == NULL) { srp = XCALLOC(MTYPE_OSPF_SR_PARAMS, sizeof(struct sr_prefix)); IPV4_ADDR_COPY(&srp->prefv4.prefix, &p.u.prefix4); srp->prefv4.prefixlen = p.prefixlen; srp->prefv4.family = p.family; srp->sid = index; srp->type = LOCAL_SID; } else { /* we work on the existing SR prefix */ srp = exist; } /* Reset labels to handle flag update */ srp->label_in = 0; srp->nhlfe.label_out = 0; srp->sid = index; srp->flags = desired_flags; /* If NO PHP flag is present, compute NHLFE and set label */ if (no_php_flag) { srp->label_in = index2label(srp->sid, OspfSR.self->srgb); srp->nhlfe.label_out = MPLS_LABEL_IMPLICIT_NULL; } osr_debug("SR (%s): Add new index %u to Prefix %pFX", __func__, index, (struct prefix *)&srp->prefv4); /* Get Interface and check if it is a Loopback */ ifp = if_lookup_prefix(&p, VRF_DEFAULT); if (ifp == NULL) { /* * Interface could be not yet available i.e. when this * command is in the configuration file, OSPF is not yet * ready. In this case, store the prefix SID for latter * update of this Extended Prefix */ if (exist == NULL) listnode_add(OspfSR.self->ext_prefix, srp); zlog_info( "Interface for prefix %pFX not found. Deferred LSA flooding", &p); return CMD_SUCCESS; } if (!if_is_loopback(ifp)) { vty_out(vty, "interface %s is not a Loopback\n", ifp->name); XFREE(MTYPE_OSPF_SR_PARAMS, srp); return CMD_WARNING_CONFIG_FAILED; } srp->nhlfe.ifindex = ifp->ifindex; /* Add SR Prefix if new */ if (!exist) listnode_add(OspfSR.self->ext_prefix, srp); /* Update Prefix SID if SR is UP */ if (OspfSR.status == SR_UP) { if (no_php_flag && !exp_null) ospf_zebra_update_prefix_sid(srp); } else return CMD_SUCCESS; /* Finally, update Extended Prefix LSA id SR is UP */ srp->instance = ospf_ext_schedule_prefix_index( ifp, srp->sid, &srp->prefv4, srp->flags); if (srp->instance == 0) { vty_out(vty, "Unable to set index %u for prefix %pFX\n", index, &p); return CMD_WARNING; } return CMD_SUCCESS; } DEFUN (no_sr_prefix_sid, no_sr_prefix_sid_cmd, "no segment-routing prefix A.B.C.D/M [index (0-65535)|no-php-flag|explicit-null]", NO_STR SR_STR "Prefix SID\n" "IPv4 Prefix as A.B.C.D/M\n" "SID index for this prefix in decimal (0-65535)\n" "Index value inside SRGB (lower_bound < index < upper_bound)\n" "Don't request Penultimate Hop Popping (PHP)\n" "Upstream neighbor must replace prefix-sid with explicit null label\n") { int idx = 0; struct prefix p; struct listnode *node; struct sr_prefix *srp; struct interface *ifp; bool found = false; int rc; if (!ospf_sr_enabled(vty)) return CMD_WARNING_CONFIG_FAILED; if (OspfSR.status != SR_UP) return CMD_SUCCESS; /* Get network prefix */ argv_find(argv, argc, "A.B.C.D/M", &idx); rc = str2prefix(argv[idx]->arg, &p); if (!rc) { vty_out(vty, "Invalid prefix format %s\n", argv[idx]->arg); return CMD_WARNING_CONFIG_FAILED; } /* check that the prefix is already set */ for (ALL_LIST_ELEMENTS_RO(OspfSR.self->ext_prefix, node, srp)) if (IPV4_ADDR_SAME(&srp->prefv4.prefix, &p.u.prefix4) && (srp->prefv4.prefixlen == p.prefixlen)) { found = true; break; } if (!found) { vty_out(vty, "Prefix %s is not found. Abort!\n", argv[idx]->arg); return CMD_WARNING_CONFIG_FAILED; } osr_debug("SR (%s): Remove Prefix %pFX with index %u", __func__, (struct prefix *)&srp->prefv4, srp->sid); /* Get Interface */ ifp = if_lookup_by_index(srp->nhlfe.ifindex, VRF_DEFAULT); if (ifp == NULL) { vty_out(vty, "interface for prefix %s not found.\n", argv[idx]->arg); /* silently remove from list */ listnode_delete(OspfSR.self->ext_prefix, srp); XFREE(MTYPE_OSPF_SR_PARAMS, srp); return CMD_SUCCESS; } /* Update Extended Prefix LSA */ if (!ospf_ext_schedule_prefix_index(ifp, 0, NULL, 0)) { vty_out(vty, "No corresponding loopback interface. Abort!\n"); return CMD_WARNING; } /* Delete NHLFE if NO-PHP is set and EXPLICIT NULL not set */ if (CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_NPFLG) && !CHECK_FLAG(srp->flags, EXT_SUBTLV_PREFIX_SID_EFLG)) ospf_zebra_delete_prefix_sid(srp); /* OK, all is clean, remove SRP from SRDB */ listnode_delete(OspfSR.self->ext_prefix, srp); XFREE(MTYPE_OSPF_SR_PARAMS, srp); return CMD_SUCCESS; } static char *sr_op2str(char *buf, size_t size, mpls_label_t label_in, mpls_label_t label_out) { if (size < 24) return NULL; switch (label_out) { case MPLS_LABEL_IMPLICIT_NULL: snprintf(buf, size, "Pop(%u)", label_in); break; case MPLS_LABEL_IPV4_EXPLICIT_NULL: if (label_in == MPLS_LABEL_IPV4_EXPLICIT_NULL) snprintf(buf, size, "no-op."); else snprintf(buf, size, "Swap(%u, null)", label_in); break; case MPLS_INVALID_LABEL: snprintf(buf, size, "no-op."); break; default: snprintf(buf, size, "Swap(%u, %u)", label_in, label_out); break; } return buf; } static void show_sr_prefix(struct sbuf *sbuf, struct json_object *json, struct sr_prefix *srp) { struct listnode *node; struct ospf_path *path; struct interface *itf; json_object *json_route = NULL, *json_obj; char pref[19]; char sid[22]; char op[32]; char buf[PREFIX_STRLEN]; int indent = 0; snprintfrr(pref, 19, "%pFX", (struct prefix *)&srp->prefv4); snprintf(sid, 22, "SR Pfx (idx %u)", srp->sid); if (json) { json_object_string_add(json, "prefix", pref); json_object_int_add(json, "sid", srp->sid); json_object_int_add(json, "inputLabel", srp->label_in); } else { sbuf_push(sbuf, 0, "%18s %21s ", pref, sid); } /* Check if it is a Local Node SID */ if (srp->type == LOCAL_SID) { itf = if_lookup_by_index(srp->nhlfe.ifindex, VRF_DEFAULT); if (json) { if (!json_route) { json_route = json_object_new_array(); json_object_object_add(json, "prefixRoute", json_route); } json_obj = json_object_new_object(); json_object_int_add(json_obj, "outputLabel", srp->nhlfe.label_out); json_object_string_add(json_obj, "interface", itf ? itf->name : "-"); json_object_string_addf(json_obj, "nexthop", "%pI4", &srp->nhlfe.nexthop); json_object_array_add(json_route, json_obj); } else { sbuf_push(sbuf, 0, "%20s %9s %15s\n", sr_op2str(op, 32, srp->label_in, srp->nhlfe.label_out), itf ? itf->name : "-", inet_ntop(AF_INET, &srp->nhlfe.nexthop, buf, sizeof(buf))); } return; } /* Check if we have a valid path for this prefix */ if (srp->route == NULL) { if (!json) { sbuf_push(sbuf, 0, "\n"); } return; } /* Process list of OSPF paths */ for (ALL_LIST_ELEMENTS_RO(srp->route->paths, node, path)) { itf = if_lookup_by_index(path->ifindex, VRF_DEFAULT); if (json) { if (!json_route) { json_route = json_object_new_array(); json_object_object_add(json, "prefixRoute", json_route); } json_obj = json_object_new_object(); json_object_int_add(json_obj, "outputLabel", path->srni.label_out); json_object_string_add(json_obj, "interface", itf ? itf->name : "-"); json_object_string_addf(json_obj, "nexthop", "%pI4", &path->nexthop); json_object_array_add(json_route, json_obj); } else { sbuf_push(sbuf, indent, "%20s %9s %15s\n", sr_op2str(op, 32, srp->label_in, path->srni.label_out), itf ? itf->name : "-", inet_ntop(AF_INET, &path->nexthop, buf, sizeof(buf))); /* Offset to align information for ECMP */ indent = 43; } } } static void show_sr_node(struct vty *vty, struct json_object *json, struct sr_node *srn) { struct listnode *node; struct sr_link *srl; struct sr_prefix *srp; struct interface *itf; struct sbuf sbuf; char pref[19]; char sid[22]; char op[32]; char buf[PREFIX_STRLEN]; uint32_t upper; json_object *json_node = NULL, *json_algo, *json_obj; json_object *json_prefix = NULL, *json_link = NULL; /* Sanity Check */ if (srn == NULL) return; sbuf_init(&sbuf, NULL, 0); if (json) { json_node = json_object_new_object(); json_object_string_addf(json_node, "routerID", "%pI4", &srn->adv_router); json_object_int_add(json_node, "srgbSize", srn->srgb.range_size); json_object_int_add(json_node, "srgbLabel", srn->srgb.lower_bound); json_object_int_add(json_node, "srlbSize", srn->srlb.range_size); json_object_int_add(json_node, "srlbLabel", srn->srlb.lower_bound); json_algo = json_object_new_array(); json_object_object_add(json_node, "algorithms", json_algo); for (int i = 0; i < ALGORITHM_COUNT; i++) { if (srn->algo[i] == SR_ALGORITHM_UNSET) continue; json_obj = json_object_new_object(); char tmp[12]; snprintf(tmp, sizeof(tmp), "%d", i); json_object_string_add(json_obj, tmp, srn->algo[i] == SR_ALGORITHM_SPF ? "SPF" : "S-SPF"); json_object_array_add(json_algo, json_obj); } if (srn->msd != 0) json_object_int_add(json_node, "nodeMsd", srn->msd); } else { sbuf_push(&sbuf, 0, "SR-Node: %pI4", &srn->adv_router); upper = srn->srgb.lower_bound + srn->srgb.range_size - 1; sbuf_push(&sbuf, 0, "\tSRGB: [%u/%u]", srn->srgb.lower_bound, upper); upper = srn->srlb.lower_bound + srn->srlb.range_size - 1; sbuf_push(&sbuf, 0, "\tSRLB: [%u/%u]", srn->srlb.lower_bound, upper); sbuf_push(&sbuf, 0, "\tAlgo.(s): %s", srn->algo[0] == SR_ALGORITHM_SPF ? "SPF" : "S-SPF"); for (int i = 1; i < ALGORITHM_COUNT; i++) { if (srn->algo[i] == SR_ALGORITHM_UNSET) continue; sbuf_push(&sbuf, 0, "/%s", srn->algo[i] == SR_ALGORITHM_SPF ? "SPF" : "S-SPF"); } if (srn->msd != 0) sbuf_push(&sbuf, 0, "\tMSD: %u", srn->msd); } if (!json) { sbuf_push(&sbuf, 0, "\n\n Prefix or Link Node or Adj. SID Label Operation Interface Nexthop\n"); sbuf_push(&sbuf, 0, "------------------ --------------------- -------------------- --------- ---------------\n"); } for (ALL_LIST_ELEMENTS_RO(srn->ext_prefix, node, srp)) { if (json) { if (!json_prefix) { json_prefix = json_object_new_array(); json_object_object_add(json_node, "extendedPrefix", json_prefix); } json_obj = json_object_new_object(); show_sr_prefix(NULL, json_obj, srp); json_object_array_add(json_prefix, json_obj); } else { show_sr_prefix(&sbuf, NULL, srp); } } for (ALL_LIST_ELEMENTS_RO(srn->ext_link, node, srl)) { snprintfrr(pref, 19, "%pI4/32", &srl->itf_addr); snprintf(sid, 22, "SR Adj. (lbl %u)", srl->sid[0]); itf = if_lookup_by_index(srl->nhlfe[0].ifindex, VRF_DEFAULT); if (json) { if (!json_link) { json_link = json_object_new_array(); json_object_object_add( json_node, "extendedLink", json_link); } /* Primary Link */ json_obj = json_object_new_object(); json_object_string_add(json_obj, "prefix", pref); json_object_int_add(json_obj, "sid", srl->sid[0]); json_object_int_add(json_obj, "inputLabel", srl->nhlfe[0].label_in); json_object_int_add(json_obj, "outputLabel", srl->nhlfe[0].label_out); json_object_string_add(json_obj, "interface", itf ? itf->name : "-"); json_object_string_addf(json_obj, "nexthop", "%pI4", &srl->nhlfe[0].nexthop); json_object_array_add(json_link, json_obj); /* Backup Link */ json_obj = json_object_new_object(); snprintf(sid, 22, "SR Adj. (lbl %u)", srl->sid[1]); json_object_string_add(json_obj, "prefix", pref); json_object_int_add(json_obj, "sid", srl->sid[1]); json_object_int_add(json_obj, "inputLabel", srl->nhlfe[1].label_in); json_object_int_add(json_obj, "outputLabel", srl->nhlfe[1].label_out); json_object_string_add(json_obj, "interface", itf ? itf->name : "-"); json_object_string_addf(json_obj, "nexthop", "%pI4", &srl->nhlfe[1].nexthop); json_object_array_add(json_link, json_obj); } else { sbuf_push(&sbuf, 0, "%18s %21s %20s %9s %15s\n", pref, sid, sr_op2str(op, 32, srl->nhlfe[0].label_in, srl->nhlfe[0].label_out), itf ? itf->name : "-", inet_ntop(AF_INET, &srl->nhlfe[0].nexthop, buf, sizeof(buf))); snprintf(sid, 22, "SR Adj. (lbl %u)", srl->sid[1]); sbuf_push(&sbuf, 0, "%18s %21s %20s %9s %15s\n", pref, sid, sr_op2str(op, 32, srl->nhlfe[1].label_in, srl->nhlfe[1].label_out), itf ? itf->name : "-", inet_ntop(AF_INET, &srl->nhlfe[1].nexthop, buf, sizeof(buf))); } } if (json) json_object_array_add(json, json_node); else vty_out(vty, "%s\n", sbuf_buf(&sbuf)); sbuf_free(&sbuf); } static void show_vty_srdb(struct hash_bucket *bucket, void *args) { struct vty *vty = (struct vty *)args; struct sr_node *srn = (struct sr_node *)bucket->data; show_sr_node(vty, NULL, srn); } static void show_json_srdb(struct hash_bucket *bucket, void *args) { struct json_object *json = (struct json_object *)args; struct sr_node *srn = (struct sr_node *)bucket->data; show_sr_node(NULL, json, srn); } DEFUN (show_ip_opsf_srdb, show_ip_ospf_srdb_cmd, "show ip ospf database segment-routing [adv-router A.B.C.D|self-originate] [json]", SHOW_STR IP_STR OSPF_STR "Database summary\n" "Show Segment Routing Data Base\n" "Advertising SR node\n" "Advertising SR node ID (as an IP address)\n" "Self-originated SR node\n" JSON_STR) { int idx = 0; struct in_addr rid; struct sr_node *srn; bool uj = use_json(argc, argv); json_object *json = NULL, *json_node_array = NULL; if (OspfSR.status == SR_OFF) { vty_out(vty, "Segment Routing is disabled on this router\n"); return CMD_WARNING; } if (uj) { json = json_object_new_object(); json_node_array = json_object_new_array(); json_object_string_addf(json, "srdbID", "%pI4", &OspfSR.self->adv_router); json_object_object_add(json, "srNodes", json_node_array); } else { vty_out(vty, "\n\t\tOSPF Segment Routing database for ID %pI4\n\n", &OspfSR.self->adv_router); } if (argv_find(argv, argc, "self-originate", &idx)) { srn = OspfSR.self; show_sr_node(vty, json_node_array, srn); if (uj) vty_json(vty, json); return CMD_SUCCESS; } if (argv_find(argv, argc, "A.B.C.D", &idx)) { if (!inet_aton(argv[idx]->arg, &rid)) { vty_out(vty, "Specified Router ID %s is invalid\n", argv[idx]->arg); return CMD_WARNING_CONFIG_FAILED; } /* Get the SR Node from the SRDB */ srn = (struct sr_node *)hash_lookup(OspfSR.neighbors, (void *)&rid); show_sr_node(vty, json_node_array, srn); if (uj) vty_json(vty, json); return CMD_SUCCESS; } /* No parameters have been provided, Iterate through all the SRDB */ if (uj) { hash_iterate(OspfSR.neighbors, (void (*)(struct hash_bucket *, void *))show_json_srdb, (void *)json_node_array); vty_json(vty, json); } else { hash_iterate(OspfSR.neighbors, (void (*)(struct hash_bucket *, void *))show_vty_srdb, (void *)vty); } return CMD_SUCCESS; } /* Install new CLI commands */ void ospf_sr_register_vty(void) { install_element(VIEW_NODE, &show_ip_ospf_srdb_cmd); install_element(OSPF_NODE, &ospf_sr_enable_cmd); install_element(OSPF_NODE, &no_ospf_sr_enable_cmd); install_element(OSPF_NODE, &sr_global_label_range_cmd); install_element(OSPF_NODE, &no_sr_global_label_range_cmd); install_element(OSPF_NODE, &sr_node_msd_cmd); install_element(OSPF_NODE, &no_sr_node_msd_cmd); install_element(OSPF_NODE, &sr_prefix_sid_cmd); install_element(OSPF_NODE, &no_sr_prefix_sid_cmd); }