/* * BIRD -- OSPF Topological Database * * (c) 1999 Martin Mares * (c) 1999--2004 Ondrej Filip * * Can be freely distributed and used under the terms of the GNU GPL. */ #include "nest/bird.h" #include "lib/string.h" #include "ospf.h" #define HASH_DEF_ORDER 6 #define HASH_HI_MARK *4 #define HASH_HI_STEP 2 #define HASH_HI_MAX 16 #define HASH_LO_MARK /5 #define HASH_LO_STEP 2 #define HASH_LO_MIN 8 void originate_prefix_rt_lsa(struct ospf_area *oa); void originate_prefix_net_lsa(struct ospf_iface *ifa); void flush_prefix_net_lsa(struct ospf_iface *ifa); #ifdef OSPFv2 #define ipa_to_rid(x) _I(x) #else /* OSPFv3 */ #define ipa_to_rid(x) _I3(x) #endif #ifdef OSPFv2 static inline u32 fibnode_to_lsaid(struct proto_ospf *po, struct fib_node *fn) { /* We have to map IP prefixes to u32 in such manner that resulting u32 interpreted as IP address is a member of given prefix. Therefore, /32 prefix have to be mapped on itself. All received prefixes have to be mapped on different u32s. We have an assumption that if there is nontrivial (non-/32) network prefix, then there is not /32 prefix for the first and the last IP address of the network (these are usually reserved, therefore it is not an important restriction). The network prefix is mapped to the first or the last IP address in the manner that disallow collisions - we use IP address that cannot be used by parent prefix. For example: 192.168.0.0/24 maps to 192.168.0.255 192.168.1.0/24 maps to 192.168.1.0 because 192.168.0.0 and 192.168.1.255 might be used by 192.168.0.0/23 . This is not compatible with older RFC 1583, so we have an option to the RFC 1583 compatible assignment (that always uses the first address) which disallows subnetting. Appendig E of RFC 2328 suggests different algorithm, that tries to maximize both compatibility and subnetting. But as it is not possible to have both reliably and the suggested algorithm was unnecessary complicated and it does crazy things like changing LSA ID for a network because different network appeared, we choose a different way. */ u32 id = _I(fn->prefix); if ((po->rfc1583) || (fn->pxlen == 0) || (fn->pxlen == 32)) return id; if (id & (1 << (32 - fn->pxlen))) return id; else return id | ~u32_mkmask(fn->pxlen); } #else /* OSPFv3 */ static inline u32 fibnode_to_lsaid(struct proto_ospf *po, struct fib_node *fn) { /* * In OSPFv3, it is simpler. There is not a requirement for * membership of the result in the input network, so we just use a * hash-based unique ID of a routing table entry for a route that * originated given LSA. For ext-LSA, it is an imported route in the * nest's routing table (p->table). For summary-LSA, it is a * 'source' route in the protocol internal routing table (po->rtf). */ return fn->uid; } #endif static void * lsab_alloc(struct proto_ospf *po, unsigned size) { unsigned offset = po->lsab_used; po->lsab_used += size; if (po->lsab_used > po->lsab_size) { po->lsab_size = MAX(po->lsab_used, 2 * po->lsab_size); po->lsab = mb_realloc(po->proto.pool, po->lsab, po->lsab_size); } return ((byte *) po->lsab) + offset; } static inline void * lsab_allocz(struct proto_ospf *po, unsigned size) { void *r = lsab_alloc(po, size); bzero(r, size); return r; } static inline void * lsab_flush(struct proto_ospf *po) { void *r = mb_alloc(po->proto.pool, po->lsab_used); memcpy(r, po->lsab, po->lsab_used); po->lsab_used = 0; return r; } static inline void * lsab_offset(struct proto_ospf *po, unsigned offset) { return ((byte *) po->lsab) + offset; } static inline void * lsab_end(struct proto_ospf *po) { return ((byte *) po->lsab) + po->lsab_used; } static s32 get_seqnum(struct top_hash_entry *en) { if (!en) return LSA_INITSEQNO; if (en->lsa.sn == LSA_MAXSEQNO) { log(L_WARN "OSPF: Premature origination of LSA (Type: %04x, Id: %R, Rt: %R)", en->lsa.type, en->lsa.id, en->lsa.rt); return LSA_INITSEQNO; } return en->lsa.sn + 1; } static int configured_stubnet(struct ospf_area *oa, struct ifa *a) { if (!oa->ac) return 0; /* Does not work for IA_PEER addresses, but it is not called on these */ struct ospf_stubnet_config *sn; WALK_LIST(sn, oa->ac->stubnet_list) { if (sn->summary) { if (ipa_in_net(a->prefix, sn->px.addr, sn->px.len) && (a->pxlen >= sn->px.len)) return 1; } else { if (ipa_equal(a->prefix, sn->px.addr) && (a->pxlen == sn->px.len)) return 1; } } return 0; } int bcast_net_active(struct ospf_iface *ifa) { struct ospf_neighbor *neigh; if (ifa->state == OSPF_IS_WAITING) return 0; WALK_LIST(neigh, ifa->neigh_list) { if (neigh->state == NEIGHBOR_FULL) { if (neigh->rid == ifa->drid) return 1; if (ifa->state == OSPF_IS_DR) return 1; } } return 0; } #ifdef OSPFv2 static void * originate_rt_lsa_body(struct ospf_area *oa, u16 *length) { struct proto_ospf *po = oa->po; struct ospf_iface *ifa; int i = 0, bitv = 0; struct ospf_lsa_rt *rt; struct ospf_lsa_rt_link *ln; struct ospf_neighbor *neigh; ASSERT(po->lsab_used == 0); rt = lsab_allocz(po, sizeof(struct ospf_lsa_rt)); rt->options = 0; if (po->areano > 1) rt->options |= OPT_RT_B; if ((po->areano > 1) && oa_is_nssa(oa) && oa->ac->translator) rt->options |= OPT_RT_NT; if (po->ebit && !oa_is_stub(oa)) rt->options |= OPT_RT_E; rt = NULL; /* buffer might be reallocated later */ WALK_LIST(ifa, po->iface_list) { int net_lsa = 0; if ((ifa->type == OSPF_IT_VLINK) && (ifa->voa == oa) && (!EMPTY_LIST(ifa->neigh_list))) { neigh = (struct ospf_neighbor *) HEAD(ifa->neigh_list); if ((neigh->state == NEIGHBOR_FULL) && (ifa->cost <= 0xffff)) bitv = 1; } if ((ifa->oa != oa) || (ifa->state == OSPF_IS_DOWN)) continue; ifa->rt_pos_beg = i; /* RFC2328 - 12.4.1.1-4 */ switch (ifa->type) { case OSPF_IT_PTP: case OSPF_IT_PTMP: WALK_LIST(neigh, ifa->neigh_list) if (neigh->state == NEIGHBOR_FULL) { ln = lsab_alloc(po, sizeof(struct ospf_lsa_rt_link)); ln->type = LSART_PTP; ln->id = neigh->rid; ln->data = (ifa->addr->flags & IA_PEER) ? ifa->iface_id : ipa_to_u32(ifa->addr->ip); ln->metric = ifa->cost; ln->padding = 0; i++; } break; case OSPF_IT_BCAST: case OSPF_IT_NBMA: if (bcast_net_active(ifa)) { ln = lsab_alloc(po, sizeof(struct ospf_lsa_rt_link)); ln->type = LSART_NET; ln->id = ipa_to_u32(ifa->drip); ln->data = ipa_to_u32(ifa->addr->ip); ln->metric = ifa->cost; ln->padding = 0; i++; net_lsa = 1; } break; case OSPF_IT_VLINK: neigh = (struct ospf_neighbor *) HEAD(ifa->neigh_list); if ((!EMPTY_LIST(ifa->neigh_list)) && (neigh->state == NEIGHBOR_FULL) && (ifa->cost <= 0xffff)) { ln = lsab_alloc(po, sizeof(struct ospf_lsa_rt_link)); ln->type = LSART_VLNK; ln->id = neigh->rid; ln->data = ipa_to_u32(ifa->addr->ip); ln->metric = ifa->cost; ln->padding = 0; i++; } break; default: log("Unknown interface type %s", ifa->iface->name); break; } ifa->rt_pos_end = i; /* Now we will originate stub area if there is no primary */ if (net_lsa || (ifa->type == OSPF_IT_VLINK) || ((ifa->addr->flags & IA_PEER) && ! ifa->cf->stub) || configured_stubnet(oa, ifa->addr)) continue; ln = lsab_alloc(po, sizeof(struct ospf_lsa_rt_link)); if ((ifa->addr->flags & IA_HOST) || (ifa->state == OSPF_IS_LOOP) || (ifa->type == OSPF_IT_PTMP)) { /* Host stub entry */ ln->type = LSART_STUB; ln->id = ipa_to_u32(ifa->addr->ip); ln->data = 0xffffffff; ln->metric = 0; ln->padding = 0; } else { /* Network stub entry */ ln->type = LSART_STUB; ln->id = ipa_to_u32(ifa->addr->prefix); ln->data = ipa_to_u32(ipa_mkmask(ifa->addr->pxlen)); ln->metric = ifa->cost; ln->padding = 0; } i++; ifa->rt_pos_end = i; } struct ospf_stubnet_config *sn; if (oa->ac) WALK_LIST(sn, oa->ac->stubnet_list) if (!sn->hidden) { ln = lsab_alloc(po, sizeof(struct ospf_lsa_rt_link)); ln->type = LSART_STUB; ln->id = ipa_to_u32(sn->px.addr); ln->data = ipa_to_u32(ipa_mkmask(sn->px.len)); ln->metric = sn->cost; ln->padding = 0; i++; } rt = po->lsab; rt->links = i; if (bitv) rt->options |= OPT_RT_V; *length = po->lsab_used + sizeof(struct ospf_lsa_header); return lsab_flush(po); } #else /* OSPFv3 */ static void add_lsa_rt_link(struct proto_ospf *po, struct ospf_iface *ifa, u8 type, u32 nif, u32 id) { struct ospf_lsa_rt_link *ln = lsab_alloc(po, sizeof(struct ospf_lsa_rt_link)); ln->type = type; ln->padding = 0; ln->metric = ifa->cost; ln->lif = ifa->iface_id; ln->nif = nif; ln->id = id; } static void * originate_rt_lsa_body(struct ospf_area *oa, u16 *length) { struct proto_ospf *po = oa->po; struct ospf_iface *ifa; int bitv = 0; int i = 0; struct ospf_lsa_rt *rt; struct ospf_neighbor *neigh; ASSERT(po->lsab_used == 0); rt = lsab_allocz(po, sizeof(struct ospf_lsa_rt)); rt->options = oa->options & OPTIONS_MASK; if (po->areano > 1) rt->options |= OPT_RT_B; if ((po->areano > 1) && oa_is_nssa(oa) && oa->ac->translator) rt->options |= OPT_RT_NT; if (po->ebit && !oa_is_stub(oa)) rt->options |= OPT_RT_E; rt = NULL; /* buffer might be reallocated later */ WALK_LIST(ifa, po->iface_list) { if ((ifa->type == OSPF_IT_VLINK) && (ifa->voa == oa) && (!EMPTY_LIST(ifa->neigh_list))) { neigh = (struct ospf_neighbor *) HEAD(ifa->neigh_list); if ((neigh->state == NEIGHBOR_FULL) && (ifa->cost <= 0xffff)) bitv = 1; } if ((ifa->oa != oa) || (ifa->state == OSPF_IS_DOWN)) continue; ifa->rt_pos_beg = i; /* RFC5340 - 4.4.3.2 */ switch (ifa->type) { case OSPF_IT_PTP: case OSPF_IT_PTMP: WALK_LIST(neigh, ifa->neigh_list) if (neigh->state == NEIGHBOR_FULL) add_lsa_rt_link(po, ifa, LSART_PTP, neigh->iface_id, neigh->rid), i++; break; case OSPF_IT_BCAST: case OSPF_IT_NBMA: if (bcast_net_active(ifa)) add_lsa_rt_link(po, ifa, LSART_NET, ifa->dr_iface_id, ifa->drid), i++; break; case OSPF_IT_VLINK: neigh = (struct ospf_neighbor *) HEAD(ifa->neigh_list); if ((!EMPTY_LIST(ifa->neigh_list)) && (neigh->state == NEIGHBOR_FULL) && (ifa->cost <= 0xffff)) add_lsa_rt_link(po, ifa, LSART_VLNK, neigh->iface_id, neigh->rid), i++; break; default: log("Unknown interface type %s", ifa->iface->name); break; } ifa->rt_pos_end = i; } if (bitv) { rt = po->lsab; rt->options |= OPT_RT_V; } *length = po->lsab_used + sizeof(struct ospf_lsa_header); return lsab_flush(po); } #endif /** * originate_rt_lsa - build new instance of router LSA * @oa: ospf_area which is LSA built to * * It builds router LSA walking through all OSPF interfaces in * specified OSPF area. This function is mostly called from * area_disp(). Builds new LSA, increases sequence number (if old * instance exists) and sets age of LSA to zero. */ void originate_rt_lsa(struct ospf_area *oa) { struct ospf_lsa_header lsa; struct proto_ospf *po = oa->po; struct proto *p = &po->proto; void *body; OSPF_TRACE(D_EVENTS, "Originating router-LSA for area %R", oa->areaid); lsa.age = 0; lsa.type = LSA_T_RT; #ifdef OSPFv2 lsa.options = oa->options; lsa.id = po->router_id; #else /* OSPFv3 */ lsa.id = 0; #endif lsa.rt = po->router_id; lsa.sn = get_seqnum(oa->rt); u32 dom = oa->areaid; body = originate_rt_lsa_body(oa, &lsa.length); lsasum_calculate(&lsa, body); oa->rt = lsa_install_new(po, &lsa, dom, body); ospf_lsupd_flood(po, NULL, NULL, &lsa, dom, 1); } void update_rt_lsa(struct ospf_area *oa) { struct proto_ospf *po = oa->po; if ((oa->rt) && ((oa->rt->inst_t + MINLSINTERVAL)) > now) return; /* * Tick is probably set to very low value. We cannot * originate new LSA before MINLSINTERVAL. We will * try to do it next tick. */ originate_rt_lsa(oa); #ifdef OSPFv3 originate_prefix_rt_lsa(oa); #endif schedule_rtcalc(po); oa->origrt = 0; } static void * originate_net_lsa_body(struct ospf_iface *ifa, u16 *length, struct proto_ospf *po) { u16 i = 1; struct ospf_neighbor *n; struct ospf_lsa_net *net; int nodes = ifa->fadj + 1; net = mb_alloc(po->proto.pool, sizeof(struct ospf_lsa_net) + nodes * sizeof(u32)); #ifdef OSPFv2 net->netmask = ipa_mkmask(ifa->addr->pxlen); #endif #ifdef OSPFv3 /* In OSPFv3, we would like to merge options from Link LSAs of added neighbors */ struct top_hash_entry *en; u32 options = 0; #endif net->routers[0] = po->router_id; WALK_LIST(n, ifa->neigh_list) { if (n->state == NEIGHBOR_FULL) { #ifdef OSPFv3 en = ospf_hash_find(po->gr, ifa->iface_id, n->iface_id, n->rid, LSA_T_LINK); if (en) options |= ((struct ospf_lsa_link *) en->lsa_body)->options; #endif net->routers[i] = n->rid; i++; } } ASSERT(i == nodes); #ifdef OSPFv3 net->options = options & OPTIONS_MASK; #endif *length = sizeof(struct ospf_lsa_header) + sizeof(struct ospf_lsa_net) + nodes * sizeof(u32); return net; } /** * originate_net_lsa - originates of deletes network LSA * @ifa: interface which is LSA originated for * * Interface counts number of adjacent neighbors. If this number is * lower than one or interface is not in state %OSPF_IS_DR it deletes * and premature ages instance of network LSA for specified interface. * In other case, new instance of network LSA is originated. */ void originate_net_lsa(struct ospf_iface *ifa) { struct proto_ospf *po = ifa->oa->po; struct proto *p = &po->proto; struct ospf_lsa_header lsa; u32 dom = ifa->oa->areaid; void *body; OSPF_TRACE(D_EVENTS, "Originating network-LSA for iface %s", ifa->iface->name); lsa.age = 0; lsa.type = LSA_T_NET; #ifdef OSPFv2 lsa.options = ifa->oa->options; lsa.id = ipa_to_u32(ifa->addr->ip); #else /* OSPFv3 */ lsa.id = ifa->iface_id; #endif lsa.rt = po->router_id; lsa.sn = get_seqnum(ifa->net_lsa); body = originate_net_lsa_body(ifa, &lsa.length, po); lsasum_calculate(&lsa, body); ifa->net_lsa = lsa_install_new(po, &lsa, dom, body); ospf_lsupd_flood(po, NULL, NULL, &lsa, dom, 1); } void flush_net_lsa(struct ospf_iface *ifa) { struct proto_ospf *po = ifa->oa->po; struct proto *p = &po->proto; u32 dom = ifa->oa->areaid; if (ifa->net_lsa == NULL) return; OSPF_TRACE(D_EVENTS, "Flushing network-LSA for iface %s", ifa->iface->name); ifa->net_lsa->lsa.sn += 1; ifa->net_lsa->lsa.age = LSA_MAXAGE; lsasum_calculate(&ifa->net_lsa->lsa, ifa->net_lsa->lsa_body); ospf_lsupd_flood(po, NULL, NULL, &ifa->net_lsa->lsa, dom, 0); flush_lsa(ifa->net_lsa, po); ifa->net_lsa = NULL; } void update_net_lsa(struct ospf_iface *ifa) { struct proto_ospf *po = ifa->oa->po; if (ifa->net_lsa && ((ifa->net_lsa->inst_t + MINLSINTERVAL) > now)) return; /* * It's too early to originate new network LSA. We will * try to do it next tick */ if ((ifa->state != OSPF_IS_DR) || (ifa->fadj == 0)) { flush_net_lsa(ifa); #ifdef OSPFv3 flush_prefix_net_lsa(ifa); #endif } else { originate_net_lsa(ifa); #ifdef OSPFv3 originate_prefix_net_lsa(ifa); #endif } schedule_rtcalc(po); ifa->orignet = 0; } #ifdef OSPFv2 static inline void * originate_sum_lsa_body(struct proto_ospf *po, u16 *length, u32 mlen, u32 metric) { struct ospf_lsa_sum *sum = mb_alloc(po->proto.pool, sizeof(struct ospf_lsa_sum)); *length = sizeof(struct ospf_lsa_header) + sizeof(struct ospf_lsa_sum); sum->netmask = ipa_mkmask(mlen); sum->metric = metric; return sum; } #define originate_sum_net_lsa_body(po,length,fn,metric) \ originate_sum_lsa_body(po, length, (fn)->pxlen, metric) #define originate_sum_rt_lsa_body(po,length,drid,metric,options) \ originate_sum_lsa_body(po, length, 0, metric) static inline int check_sum_net_lsaid_collision(struct fib_node *fn, struct top_hash_entry *en) { struct ospf_lsa_sum *sum = en->lsa_body; return fn->pxlen != ipa_mklen(sum->netmask); } static inline int check_sum_lsa_same(struct top_hash_entry *en, u32 metric) { /* Netmask already checked in check_sum_net_lsaid_collision() */ struct ospf_lsa_sum *sum = en->lsa_body; return (en->lsa.sn != LSA_MAXSEQNO) && (sum->metric == metric); } #define check_sum_net_lsa_same(en,metric) \ check_sum_lsa_same(en, metric) #define check_sum_rt_lsa_same(en,drid,metric,options) \ check_sum_lsa_same(en, metric) #else /* OSPFv3 */ static inline void * originate_sum_net_lsa_body(struct proto_ospf *po, u16 *length, struct fib_node *fn, u32 metric) { int size = sizeof(struct ospf_lsa_sum_net) + IPV6_PREFIX_SPACE(fn->pxlen); struct ospf_lsa_sum_net *sum = mb_alloc(po->proto.pool, size); *length = sizeof(struct ospf_lsa_header) + size; sum->metric = metric; put_ipv6_prefix(sum->prefix, fn->prefix, fn->pxlen, 0, 0); return sum; } static inline int check_sum_net_lsaid_collision(struct fib_node *fn, struct top_hash_entry *en) { struct ospf_lsa_sum_net *sum = en->lsa_body; ip_addr prefix; int pxlen; u8 pxopts; u16 rest; lsa_get_ipv6_prefix(sum->prefix, &prefix, &pxlen, &pxopts, &rest); return (fn->pxlen != pxlen) || !ipa_equal(fn->prefix, prefix); } static inline int check_sum_net_lsa_same(struct top_hash_entry *en, u32 metric) { /* Prefix already checked in check_sum_net_lsaid_collision() */ struct ospf_lsa_sum_net *sum = en->lsa_body; return (en->lsa.sn != LSA_MAXSEQNO) && (sum->metric == metric); } static inline void * originate_sum_rt_lsa_body(struct proto_ospf *po, u16 *length, u32 drid, u32 metric, u32 options) { struct ospf_lsa_sum_rt *sum = mb_alloc(po->proto.pool, sizeof(struct ospf_lsa_sum_rt)); *length = sizeof(struct ospf_lsa_header) + sizeof(struct ospf_lsa_sum_rt); sum->options = options; sum->metric = metric; sum->drid = drid; return sum; } static inline int check_sum_rt_lsa_same(struct top_hash_entry *en, u32 drid, u32 metric, u32 options) { struct ospf_lsa_sum_rt *sum = en->lsa_body; return (en->lsa.sn != LSA_MAXSEQNO) && (sum->options == options) && (sum->metric == metric) && (sum->drid == drid); } #endif void originate_sum_net_lsa(struct ospf_area *oa, struct fib_node *fn, int metric) { struct proto_ospf *po = oa->po; struct proto *p = &po->proto; struct top_hash_entry *en; u32 dom = oa->areaid; struct ospf_lsa_header lsa; void *body; OSPF_TRACE(D_EVENTS, "Originating net-summary-LSA for %I/%d (metric %d)", fn->prefix, fn->pxlen, metric); /* options argument is used in ORT_NET and OSPFv3 only */ lsa.age = 0; #ifdef OSPFv2 lsa.options = oa->options; #endif lsa.type = LSA_T_SUM_NET; lsa.id = fibnode_to_lsaid(po, fn); lsa.rt = po->router_id; if ((en = ospf_hash_find_header(po->gr, dom, &lsa)) != NULL) { if (check_sum_net_lsaid_collision(fn, en)) { log(L_ERR "%s: LSAID collision for %I/%d", p->name, fn->prefix, fn->pxlen); return; } if (check_sum_net_lsa_same(en, metric)) return; } lsa.sn = get_seqnum(en); body = originate_sum_net_lsa_body(po, &lsa.length, fn, metric); lsasum_calculate(&lsa, body); lsa_install_new(po, &lsa, dom, body); ospf_lsupd_flood(po, NULL, NULL, &lsa, dom, 1); } void originate_sum_rt_lsa(struct ospf_area *oa, struct fib_node *fn, int metric, u32 options UNUSED) { struct proto_ospf *po = oa->po; struct proto *p = &po->proto; struct top_hash_entry *en; u32 dom = oa->areaid; u32 rid = ipa_to_rid(fn->prefix); struct ospf_lsa_header lsa; void *body; OSPF_TRACE(D_EVENTS, "Originating rt-summary-LSA for %R (metric %d)", rid, metric); lsa.age = 0; #ifdef OSPFv2 lsa.options = oa->options; #endif lsa.type = LSA_T_SUM_RT; /* In OSPFv3, LSA ID is meaningless, but we still use Router ID of ASBR */ lsa.id = rid; lsa.rt = po->router_id; options &= OPTIONS_MASK; if ((en = ospf_hash_find_header(po->gr, dom, &lsa)) != NULL) { if (check_sum_rt_lsa_same(en, lsa.id, metric, options)) return; } lsa.sn = get_seqnum(en); body = originate_sum_rt_lsa_body(po, &lsa.length, lsa.id, metric, options); lsasum_calculate(&lsa, body); lsa_install_new(po, &lsa, dom, body); ospf_lsupd_flood(po, NULL, NULL, &lsa, dom, 1); } void flush_sum_lsa(struct ospf_area *oa, struct fib_node *fn, int type) { struct proto_ospf *po = oa->po; struct proto *p = &po->proto; struct top_hash_entry *en; struct ospf_lsa_header lsa; lsa.rt = po->router_id; if (type == ORT_NET) { lsa.id = fibnode_to_lsaid(po, fn); lsa.type = LSA_T_SUM_NET; } else { /* In OSPFv3, LSA ID is meaningless, but we still use Router ID of ASBR */ lsa.id = ipa_to_rid(fn->prefix); lsa.type = LSA_T_SUM_RT; } if ((en = ospf_hash_find_header(po->gr, oa->areaid, &lsa)) != NULL) { OSPF_TRACE(D_EVENTS, "Flushing summary-LSA (id=%R, type=%d)", en->lsa.id, en->lsa.type); if ((type == ORT_NET) && check_sum_net_lsaid_collision(fn, en)) { log(L_ERR "%s: LSAID collision for %I/%d", p->name, fn->prefix, fn->pxlen); return; } struct ospf_lsa_sum *sum = en->lsa_body; en->lsa.age = LSA_MAXAGE; en->lsa.sn = LSA_MAXSEQNO; lsasum_calculate(&en->lsa, sum); ospf_lsupd_flood(po, NULL, NULL, &en->lsa, oa->areaid, 1); if (can_flush_lsa(po)) flush_lsa(en, po); } } #ifdef OSPFv2 static inline void * originate_ext_lsa_body(struct proto_ospf *po, u16 *length, struct fib_node *fn, u32 metric, ip_addr fwaddr, u32 tag, int pbit UNUSED) { struct ospf_lsa_ext *ext = mb_alloc(po->proto.pool, sizeof(struct ospf_lsa_ext)); *length = sizeof(struct ospf_lsa_header) + sizeof(struct ospf_lsa_ext); ext->metric = metric; ext->netmask = ipa_mkmask(fn->pxlen); ext->fwaddr = fwaddr; ext->tag = tag; return ext; } /* * check_ext_lsa() combines functions of check_*_lsaid_collision() and * check_*_lsa_same(). 'en' is existing ext LSA, and rest parameters * are parameters of new ext route. Function returns -1 if there is * LSAID collision, returns 1 if the existing LSA is the same and * returns 0 otherwise (in that case, we need to originate a new LSA). * * Really, checking for the same parameters is not as important as in * summary LSA origination, because in most cases the duplicate * external route propagation would be stopped by the nest. But there * are still some cases (route reload, the same route propagated through * different protocol) so it is also done here. */ static inline int check_ext_lsa(struct top_hash_entry *en, struct fib_node *fn, u32 metric, ip_addr fwaddr, u32 tag) { struct ospf_lsa_ext *ext = en->lsa_body; /* LSAID collision */ if (fn->pxlen != ipa_mklen(ext->netmask)) return -1; return (en->lsa.sn != LSA_MAXSEQNO) && (ext->metric == metric) && (ext->tag == tag) && ipa_equal(ext->fwaddr,fwaddr); } #else /* OSPFv3 */ static inline void * originate_ext_lsa_body(struct proto_ospf *po, u16 *length, struct fib_node *fn, u32 metric, ip_addr fwaddr, u32 tag, int pbit) { int size = sizeof(struct ospf_lsa_ext) + IPV6_PREFIX_SPACE(fn->pxlen) + (ipa_nonzero(fwaddr) ? 16 : 0) + (tag ? 4 : 0); struct ospf_lsa_ext *ext = mb_alloc(po->proto.pool, size); *length = sizeof(struct ospf_lsa_header) + size; ext->metric = metric; u32 *buf = ext->rest; buf = put_ipv6_prefix(buf, fn->prefix, fn->pxlen, pbit ? OPT_PX_P : 0, 0); if (ipa_nonzero(fwaddr)) { ext->metric |= LSA_EXT_FBIT; buf = put_ipv6_addr(buf, fwaddr); } if (tag) { ext->metric |= LSA_EXT_TBIT; *buf++ = tag; } return ext; } static inline int check_ext_lsa(struct top_hash_entry *en, struct fib_node *fn, u32 metric, ip_addr fwaddr, u32 tag) { struct ospf_lsa_ext *ext = en->lsa_body; ip_addr prefix; int pxlen; u8 pxopts; u16 rest; u32 *buf = lsa_get_ipv6_prefix(ext->rest, &prefix, &pxlen, &pxopts, &rest); /* LSAID collision */ if ((fn->pxlen != pxlen) || !ipa_equal(fn->prefix, prefix)) return -1; if (en->lsa.sn == LSA_MAXSEQNO) return 0; u32 rt_metric = ext->metric & METRIC_MASK; ip_addr rt_fwaddr = IPA_NONE; u32 rt_tag = 0; if (ext->metric & LSA_EXT_FBIT) buf = lsa_get_ipv6_addr(buf, &rt_fwaddr); if (ext->metric & LSA_EXT_TBIT) rt_tag = *buf++; return (rt_metric == metric) && ipa_equal(rt_fwaddr, fwaddr) && (rt_tag == tag); } #endif static inline ip_addr find_surrogate_fwaddr(struct ospf_area *oa) { struct proto_ospf *po = oa->po; struct ospf_iface *ifa; struct ifa *a, *cur_addr = NULL; int np, cur_np = 0; WALK_LIST(ifa, po->iface_list) { if ((ifa->oa != oa) || (ifa->type == OSPF_IT_VLINK)) continue; #ifdef OSPFv2 a = ifa->addr; if (a->flags & IA_PEER) continue; np = ((a->flags & IA_HOST) || ifa->stub) ? 2 : 1; if (np > cur_np) { cur_addr = a; cur_np = np; } #else /* OSPFv3 */ WALK_LIST(a, ifa->iface->addrs) { if ((a->flags & IA_SECONDARY) || (a->flags & IA_PEER) || (a->scope <= SCOPE_LINK)) continue; np = ((a->flags & IA_HOST) || ifa->stub) ? 2 : 1; if (np > cur_np) { cur_addr = a; cur_np = np; } } #endif } return cur_addr ? cur_addr->ip : IPA_NONE; } /** * originate_ext_lsa - new route received from nest and filters * @oa: ospf_area for which LSA is originated * @fn: network prefix and mask * @src: the source of origination of the LSA (EXT_EXPORT/EXT_NSSA) * @metric: the metric of a route * @fwaddr: the forwarding address * @tag: the route tag * @pbit: P-bit for NSSA LSAs, ignored for external LSAs * * If I receive a message that new route is installed, I try to originate an * external LSA. If @oa is an NSSA area, NSSA-LSA is originated instead. * @oa should not be a stub area. @src does not specify whether the LSA * is external or NSSA, but it specifies the source of origination - * the export from ospf_rt_notify(), or the NSSA-EXT translation. * * The function also sets flag ebit. If it's the first time, the new router lsa * origination is necessary. */ void originate_ext_lsa(struct ospf_area *oa, struct fib_node *fn, int src, u32 metric, ip_addr fwaddr, u32 tag, int pbit) { struct proto_ospf *po = oa->po; struct proto *p = &po->proto; struct ospf_lsa_header lsa; struct top_hash_entry *en = NULL; void *body; int nssa = oa_is_nssa(oa); u32 dom = nssa ? oa->areaid : 0; OSPF_TRACE(D_EVENTS, "Originating %s-LSA for %I/%d", nssa ? "NSSA" : "AS-external", fn->prefix, fn->pxlen); lsa.age = 0; #ifdef OSPFv2 lsa.options = nssa ? (pbit ? OPT_P : 0) : OPT_E; #endif lsa.type = nssa ? LSA_T_NSSA : LSA_T_EXT; lsa.id = fibnode_to_lsaid(po, fn); lsa.rt = po->router_id; if (nssa && pbit && ipa_zero(fwaddr)) { /* NSSA-LSA with P-bit set must have non-zero forwarding address */ fwaddr = find_surrogate_fwaddr(oa); if (ipa_zero(fwaddr)) { log(L_ERR "%s: Cannot find forwarding address for NSSA-LSA %I/%d", p->name, fn->prefix, fn->pxlen); return; } } if ((en = ospf_hash_find_header(po->gr, dom, &lsa)) != NULL) { int rv = check_ext_lsa(en, fn, metric, fwaddr, tag); if (rv < 0) { log(L_ERR "%s: LSAID collision for %I/%d", p->name, fn->prefix, fn->pxlen); return; } if (rv > 0) return; } lsa.sn = get_seqnum(en); body = originate_ext_lsa_body(po, &lsa.length, fn, metric, fwaddr, tag, pbit); lsasum_calculate(&lsa, body); if (src) fn->x1 = src; lsa_install_new(po, &lsa, dom, body); ospf_lsupd_flood(po, NULL, NULL, &lsa, dom, 1); if (po->ebit == 0) { po->ebit = 1; WALK_LIST(oa, po->area_list) { schedule_rt_lsa(oa); } } } void flush_ext_lsa(struct ospf_area *oa, struct fib_node *fn, int nssa) { struct proto_ospf *po = oa->po; struct proto *p = &po->proto; struct top_hash_entry *en; u32 dom = nssa ? oa->areaid : 0; u32 type = nssa ? LSA_T_NSSA : LSA_T_EXT; u32 lsaid = fibnode_to_lsaid(po, fn); if (en = ospf_hash_find(po->gr, dom, lsaid, po->router_id, type)) { OSPF_TRACE(D_EVENTS, "Flushing %s-LSA for %I/%d", nssa ? "NSSA" : "AS-external", fn->prefix, fn->pxlen); if (check_ext_lsa(en, fn, 0, IPA_NONE, 0) < 0) { log(L_ERR "%s: LSAID collision for %I/%d", p->name, fn->prefix, fn->pxlen); return; } fn->x1 = 0; ospf_lsupd_flush_nlsa(po, en); } } #ifdef OSPFv3 static void * originate_link_lsa_body(struct ospf_iface *ifa, u16 *length) { struct proto_ospf *po = ifa->oa->po; struct ospf_lsa_link *ll; int i = 0; u8 flags; ASSERT(po->lsab_used == 0); ll = lsab_allocz(po, sizeof(struct ospf_lsa_link)); ll->options = ifa->oa->options | (ifa->priority << 24); ll->lladdr = ifa->addr->ip; ll = NULL; /* buffer might be reallocated later */ struct ifa *a; WALK_LIST(a, ifa->iface->addrs) { if ((a->flags & IA_SECONDARY) || (a->scope < SCOPE_SITE)) continue; flags = (a->pxlen < MAX_PREFIX_LENGTH) ? 0 : OPT_PX_LA; put_ipv6_prefix(lsab_alloc(po, IPV6_PREFIX_SPACE(a->pxlen)), a->ip, a->pxlen, flags, 0); i++; } ll = po->lsab; ll->pxcount = i; *length = po->lsab_used + sizeof(struct ospf_lsa_header); return lsab_flush(po); } void originate_link_lsa(struct ospf_iface *ifa) { struct ospf_lsa_header lsa; struct proto_ospf *po = ifa->oa->po; struct proto *p = &po->proto; void *body; /* FIXME check for vlink and skip that? */ OSPF_TRACE(D_EVENTS, "Originating link-LSA for iface %s", ifa->iface->name); lsa.age = 0; lsa.type = LSA_T_LINK; lsa.id = ifa->iface_id; lsa.rt = po->router_id; lsa.sn = get_seqnum(ifa->link_lsa); u32 dom = ifa->iface_id; body = originate_link_lsa_body(ifa, &lsa.length); lsasum_calculate(&lsa, body); ifa->link_lsa = lsa_install_new(po, &lsa, dom, body); ospf_lsupd_flood(po, NULL, NULL, &lsa, dom, 1); /* Just to be sure to not forget on our link LSA */ if (ifa->state == OSPF_IS_DR) schedule_net_lsa(ifa); } void update_link_lsa(struct ospf_iface *ifa) { if (ifa->link_lsa && ((ifa->link_lsa->inst_t + MINLSINTERVAL) > now)) return; /* * It's too early to originate new link LSA. We will * try to do it next tick */ originate_link_lsa(ifa); ifa->origlink = 0; } static inline void lsa_put_prefix(struct proto_ospf *po, ip_addr prefix, u32 pxlen, u32 cost) { put_ipv6_prefix(lsab_alloc(po, IPV6_PREFIX_SPACE(pxlen)), prefix, pxlen, (pxlen < MAX_PREFIX_LENGTH) ? 0 : OPT_PX_LA, cost); } static void * originate_prefix_rt_lsa_body(struct ospf_area *oa, u16 *length) { struct proto_ospf *po = oa->po; struct ospf_config *cf = (struct ospf_config *) (po->proto.cf); struct ospf_iface *ifa; struct ospf_lsa_prefix *lp; int host_addr = 0; int net_lsa; int i = 0; ASSERT(po->lsab_used == 0); lp = lsab_allocz(po, sizeof(struct ospf_lsa_prefix)); lp->ref_type = LSA_T_RT; lp->ref_id = 0; lp->ref_rt = po->router_id; lp = NULL; /* buffer might be reallocated later */ WALK_LIST(ifa, po->iface_list) { if ((ifa->oa != oa) || (ifa->type == OSPF_IT_VLINK) || (ifa->state == OSPF_IS_DOWN)) continue; ifa->px_pos_beg = i; if ((ifa->type == OSPF_IT_BCAST) || (ifa->type == OSPF_IT_NBMA)) net_lsa = bcast_net_active(ifa); else net_lsa = 0; struct ifa *a; WALK_LIST(a, ifa->iface->addrs) { if ((a->flags & IA_SECONDARY) || (a->flags & IA_PEER) || (a->scope <= SCOPE_LINK)) continue; if (((a->pxlen < MAX_PREFIX_LENGTH) && net_lsa) || configured_stubnet(oa, a)) continue; if ((a->flags & IA_HOST) || (ifa->state == OSPF_IS_LOOP) || (ifa->type == OSPF_IT_PTMP)) { lsa_put_prefix(po, a->ip, MAX_PREFIX_LENGTH, 0); host_addr = 1; } else lsa_put_prefix(po, a->prefix, a->pxlen, ifa->cost); i++; } ifa->px_pos_end = i; } struct ospf_stubnet_config *sn; if (oa->ac) WALK_LIST(sn, oa->ac->stubnet_list) if (!sn->hidden) { lsa_put_prefix(po, sn->px.addr, sn->px.len, sn->cost); if (sn->px.len == MAX_PREFIX_LENGTH) host_addr = 1; i++; } /* If there are some configured vlinks, find some global address (even from another area), which will be used as a vlink endpoint. */ if (!EMPTY_LIST(cf->vlink_list) && !host_addr) { WALK_LIST(ifa, po->iface_list) { if ((ifa->type == OSPF_IT_VLINK) || (ifa->state == OSPF_IS_DOWN)) continue; struct ifa *a; WALK_LIST(a, ifa->iface->addrs) { if ((a->flags & IA_SECONDARY) || (a->scope <= SCOPE_LINK)) continue; /* Found some IP */ lsa_put_prefix(po, a->ip, MAX_PREFIX_LENGTH, 0); i++; goto done; } } } done: lp = po->lsab; lp->pxcount = i; *length = po->lsab_used + sizeof(struct ospf_lsa_header); return lsab_flush(po); } void originate_prefix_rt_lsa(struct ospf_area *oa) { struct proto_ospf *po = oa->po; struct proto *p = &po->proto; struct ospf_lsa_header lsa; void *body; OSPF_TRACE(D_EVENTS, "Originating router prefix-LSA for area %R", oa->areaid); lsa.age = 0; lsa.type = LSA_T_PREFIX; lsa.id = 0; lsa.rt = po->router_id; lsa.sn = get_seqnum(oa->pxr_lsa); u32 dom = oa->areaid; body = originate_prefix_rt_lsa_body(oa, &lsa.length); lsasum_calculate(&lsa, body); oa->pxr_lsa = lsa_install_new(po, &lsa, dom, body); ospf_lsupd_flood(po, NULL, NULL, &lsa, dom, 1); } static inline int prefix_space(u32 *buf) { int pxl = *buf >> 24; return IPV6_PREFIX_SPACE(pxl); } static inline int prefix_same(u32 *b1, u32 *b2) { int pxl1 = *b1 >> 24; int pxl2 = *b2 >> 24; int pxs, i; if (pxl1 != pxl2) return 0; pxs = IPV6_PREFIX_WORDS(pxl1); for (i = 1; i < pxs; i++) if (b1[i] != b2[i]) return 0; return 1; } static inline u32 * prefix_advance(u32 *buf) { int pxl = *buf >> 24; return buf + IPV6_PREFIX_WORDS(pxl); } /* FIXME eliminate items with LA bit set? see 4.4.3.9 */ static void add_prefix(struct proto_ospf *po, u32 *px, int offset, int *pxc) { u32 *pxl = lsab_offset(po, offset); int i; for (i = 0; i < *pxc; pxl = prefix_advance(pxl), i++) if (prefix_same(px, pxl)) { /* Options should be logically OR'ed together */ *pxl |= (*px & 0x00FF0000); return; } ASSERT(pxl == lsab_end(po)); int pxspace = prefix_space(px); pxl = lsab_alloc(po, pxspace); memcpy(pxl, px, pxspace); *pxl &= 0xFFFF0000; /* Set metric to zero */ (*pxc)++; } static void add_link_lsa(struct proto_ospf *po, struct top_hash_entry *en, int offset, int *pxc) { struct ospf_lsa_link *ll = en->lsa_body; u32 *pxb = ll->rest; int j; for (j = 0; j < ll->pxcount; pxb = prefix_advance(pxb), j++) { u8 pxlen = (pxb[0] >> 24); u8 pxopts = (pxb[0] >> 16); /* Skip NU or LA prefixes */ if (pxopts & (OPT_PX_NU | OPT_PX_LA)) continue; /* Skip link-local prefixes */ if ((pxlen >= 10) && ((pxb[1] & 0xffc00000) == 0xfe800000)) continue; add_prefix(po, pxb, offset, pxc); } } static void * originate_prefix_net_lsa_body(struct ospf_iface *ifa, u16 *length) { struct proto_ospf *po = ifa->oa->po; struct ospf_lsa_prefix *lp; struct ospf_neighbor *n; struct top_hash_entry *en; int pxc, offset; ASSERT(po->lsab_used == 0); lp = lsab_allocz(po, sizeof(struct ospf_lsa_prefix)); lp->ref_type = LSA_T_NET; lp->ref_id = ifa->net_lsa->lsa.id; lp->ref_rt = po->router_id; lp = NULL; /* buffer might be reallocated later */ pxc = 0; offset = po->lsab_used; /* Find all Link LSAs associated with the link and merge their prefixes */ if (ifa->link_lsa) add_link_lsa(po, ifa->link_lsa, offset, &pxc); WALK_LIST(n, ifa->neigh_list) if ((n->state == NEIGHBOR_FULL) && (en = ospf_hash_find(po->gr, ifa->iface_id, n->iface_id, n->rid, LSA_T_LINK))) add_link_lsa(po, en, offset, &pxc); lp = po->lsab; lp->pxcount = pxc; *length = po->lsab_used + sizeof(struct ospf_lsa_header); return lsab_flush(po); } void originate_prefix_net_lsa(struct ospf_iface *ifa) { struct proto_ospf *po = ifa->oa->po; struct proto *p = &po->proto; struct ospf_lsa_header lsa; void *body; OSPF_TRACE(D_EVENTS, "Originating network prefix-LSA for iface %s", ifa->iface->name); lsa.age = 0; lsa.type = LSA_T_PREFIX; lsa.id = ifa->iface_id; lsa.rt = po->router_id; lsa.sn = get_seqnum(ifa->pxn_lsa); u32 dom = ifa->oa->areaid; body = originate_prefix_net_lsa_body(ifa, &lsa.length); lsasum_calculate(&lsa, body); ifa->pxn_lsa = lsa_install_new(po, &lsa, dom, body); ospf_lsupd_flood(po, NULL, NULL, &lsa, dom, 1); } void flush_prefix_net_lsa(struct ospf_iface *ifa) { struct proto_ospf *po = ifa->oa->po; struct proto *p = &po->proto; struct top_hash_entry *en = ifa->pxn_lsa; u32 dom = ifa->oa->areaid; if (en == NULL) return; OSPF_TRACE(D_EVENTS, "Flushing network prefix-LSA for iface %s", ifa->iface->name); en->lsa.sn += 1; en->lsa.age = LSA_MAXAGE; lsasum_calculate(&en->lsa, en->lsa_body); ospf_lsupd_flood(po, NULL, NULL, &en->lsa, dom, 0); flush_lsa(en, po); ifa->pxn_lsa = NULL; } #endif static void ospf_top_ht_alloc(struct top_graph *f) { f->hash_size = 1 << f->hash_order; f->hash_mask = f->hash_size - 1; if (f->hash_order > HASH_HI_MAX - HASH_HI_STEP) f->hash_entries_max = ~0; else f->hash_entries_max = f->hash_size HASH_HI_MARK; if (f->hash_order < HASH_LO_MIN + HASH_LO_STEP) f->hash_entries_min = 0; else f->hash_entries_min = f->hash_size HASH_LO_MARK; DBG("Allocating OSPF hash of order %d: %d hash_entries, %d low, %d high\n", f->hash_order, f->hash_size, f->hash_entries_min, f->hash_entries_max); f->hash_table = mb_alloc(f->pool, f->hash_size * sizeof(struct top_hash_entry *)); bzero(f->hash_table, f->hash_size * sizeof(struct top_hash_entry *)); } static inline void ospf_top_ht_free(struct top_hash_entry **h) { mb_free(h); } static inline u32 ospf_top_hash_u32(u32 a) { /* Shamelessly stolen from IP address hashing in ipv4.h */ a ^= a >> 16; a ^= a << 10; return a; } static inline unsigned ospf_top_hash(struct top_graph *f, u32 domain, u32 lsaid, u32 rtrid, u32 type) { /* In OSPFv2, we don't know Router ID when looking for network LSAs. In OSPFv3, we don't know LSA ID when looking for router LSAs. In both cases, there is (usually) just one (or small number) appropriate LSA, so we just clear unknown part of key. */ return ( #ifdef OSPFv2 ((type == LSA_T_NET) ? 0 : ospf_top_hash_u32(rtrid)) + ospf_top_hash_u32(lsaid) + #else /* OSPFv3 */ ospf_top_hash_u32(rtrid) + ((type == LSA_T_RT) ? 0 : ospf_top_hash_u32(lsaid)) + #endif type + domain) & f->hash_mask; /* return (ospf_top_hash_u32(lsaid) + ospf_top_hash_u32(rtrid) + type + areaid) & f->hash_mask; */ } /** * ospf_top_new - allocated new topology database * @p: current instance of ospf * * this dynamically hashed structure is often used for keeping lsas. mainly * its used in @ospf_area structure. */ struct top_graph * ospf_top_new(pool *pool) { struct top_graph *f; f = mb_allocz(pool, sizeof(struct top_graph)); f->pool = pool; f->hash_slab = sl_new(f->pool, sizeof(struct top_hash_entry)); f->hash_order = HASH_DEF_ORDER; ospf_top_ht_alloc(f); f->hash_entries = 0; f->hash_entries_min = 0; return f; } void ospf_top_free(struct top_graph *f) { rfree(f->hash_slab); ospf_top_ht_free(f->hash_table); mb_free(f); } static void ospf_top_rehash(struct top_graph *f, int step) { unsigned int oldn, oldh; struct top_hash_entry **n, **oldt, **newt, *e, *x; oldn = f->hash_size; oldt = f->hash_table; DBG("re-hashing topology hash from order %d to %d\n", f->hash_order, f->hash_order + step); f->hash_order += step; ospf_top_ht_alloc(f); newt = f->hash_table; for (oldh = 0; oldh < oldn; oldh++) { e = oldt[oldh]; while (e) { x = e->next; n = newt + ospf_top_hash(f, e->domain, e->lsa.id, e->lsa.rt, e->lsa.type); e->next = *n; *n = e; e = x; } } ospf_top_ht_free(oldt); } #ifdef OSPFv2 u32 ospf_lsa_domain(u32 type, struct ospf_iface *ifa) { return (type == LSA_T_EXT) ? 0 : ifa->oa->areaid; } #else /* OSPFv3 */ u32 ospf_lsa_domain(u32 type, struct ospf_iface *ifa) { switch (type & LSA_SCOPE_MASK) { case LSA_SCOPE_LINK: return ifa->iface_id; case LSA_SCOPE_AREA: return ifa->oa->areaid; case LSA_SCOPE_AS: default: return 0; } } #endif struct top_hash_entry * ospf_hash_find_header(struct top_graph *f, u32 domain, struct ospf_lsa_header *h) { return ospf_hash_find(f, domain, h->id, h->rt, h->type); } struct top_hash_entry * ospf_hash_get_header(struct top_graph *f, u32 domain, struct ospf_lsa_header *h) { return ospf_hash_get(f, domain, h->id, h->rt, h->type); } struct top_hash_entry * ospf_hash_find(struct top_graph *f, u32 domain, u32 lsa, u32 rtr, u32 type) { struct top_hash_entry *e; e = f->hash_table[ospf_top_hash(f, domain, lsa, rtr, type)]; while (e && (e->lsa.id != lsa || e->lsa.type != type || e->lsa.rt != rtr || e->domain != domain)) e = e->next; return e; } #ifdef OSPFv2 /* In OSPFv2, sometimes we don't know Router ID when looking for network LSAs. There should be just one, so we find any match. */ struct top_hash_entry * ospf_hash_find_net(struct top_graph *f, u32 domain, u32 lsa) { struct top_hash_entry *e; e = f->hash_table[ospf_top_hash(f, domain, lsa, 0, LSA_T_NET)]; while (e && (e->lsa.id != lsa || e->lsa.type != LSA_T_NET || e->domain != domain)) e = e->next; return e; } #endif #ifdef OSPFv3 /* In OSPFv3, usually we don't know LSA ID when looking for router LSAs. We return matching LSA with smallest LSA ID. */ struct top_hash_entry * ospf_hash_find_rt(struct top_graph *f, u32 domain, u32 rtr) { struct top_hash_entry *rv = NULL; struct top_hash_entry *e; e = f->hash_table[ospf_top_hash(f, domain, 0, rtr, LSA_T_RT)]; while (e) { if (e->lsa.rt == rtr && e->lsa.type == LSA_T_RT && e->domain == domain) if (!rv || e->lsa.id < rv->lsa.id) rv = e; e = e->next; } return rv; } static inline struct top_hash_entry * find_matching_rt(struct top_hash_entry *e, u32 domain, u32 rtr) { while (e && (e->lsa.rt != rtr || e->lsa.type != LSA_T_RT || e->domain != domain)) e = e->next; return e; } struct top_hash_entry * ospf_hash_find_rt_first(struct top_graph *f, u32 domain, u32 rtr) { struct top_hash_entry *e; e = f->hash_table[ospf_top_hash(f, domain, 0, rtr, LSA_T_RT)]; return find_matching_rt(e, domain, rtr); } struct top_hash_entry * ospf_hash_find_rt_next(struct top_hash_entry *e) { return find_matching_rt(e->next, e->domain, e->lsa.rt); } #endif struct top_hash_entry * ospf_hash_get(struct top_graph *f, u32 domain, u32 lsa, u32 rtr, u32 type) { struct top_hash_entry **ee; struct top_hash_entry *e; ee = f->hash_table + ospf_top_hash(f, domain, lsa, rtr, type); e = *ee; while (e && (e->lsa.id != lsa || e->lsa.rt != rtr || e->lsa.type != type || e->domain != domain)) e = e->next; if (e) return e; e = sl_alloc(f->hash_slab); e->color = OUTSPF; e->dist = LSINFINITY; e->nhs = NULL; e->lb = IPA_NONE; e->lsa.id = lsa; e->lsa.rt = rtr; e->lsa.type = type; e->lsa_body = NULL; e->domain = domain; e->next = *ee; *ee = e; if (f->hash_entries++ > f->hash_entries_max) ospf_top_rehash(f, HASH_HI_STEP); return e; } void ospf_hash_delete(struct top_graph *f, struct top_hash_entry *e) { struct top_hash_entry **ee = f->hash_table + ospf_top_hash(f, e->domain, e->lsa.id, e->lsa.rt, e->lsa.type); while (*ee) { if (*ee == e) { *ee = e->next; sl_free(f->hash_slab, e); if (f->hash_entries-- < f->hash_entries_min) ospf_top_rehash(f, -HASH_LO_STEP); return; } ee = &((*ee)->next); } bug("ospf_hash_delete() called for invalid node"); } /* static void ospf_dump_lsa(struct top_hash_entry *he, struct proto *p) { struct ospf_lsa_rt *rt = NULL; struct ospf_lsa_rt_link *rr = NULL; struct ospf_lsa_net *ln = NULL; u32 *rts = NULL; u32 i, max; OSPF_TRACE(D_EVENTS, "- %1x %-1R %-1R %4u 0x%08x 0x%04x %-1R", he->lsa.type, he->lsa.id, he->lsa.rt, he->lsa.age, he->lsa.sn, he->lsa.checksum, he->domain); switch (he->lsa.type) { case LSA_T_RT: rt = he->lsa_body; rr = (struct ospf_lsa_rt_link *) (rt + 1); for (i = 0; i < lsa_rt_items(&he->lsa); i++) OSPF_TRACE(D_EVENTS, " - %1x %-1R %-1R %5u", rr[i].type, rr[i].id, rr[i].data, rr[i].metric); break; case LSA_T_NET: ln = he->lsa_body; rts = (u32 *) (ln + 1); for (i = 0; i < lsa_net_items(&he->lsa); i++) OSPF_TRACE(D_EVENTS, " - %-1R", rts[i]); break; default: break; } } void ospf_top_dump(struct top_graph *f, struct proto *p) { unsigned int i; OSPF_TRACE(D_EVENTS, "Hash entries: %d", f->hash_entries); for (i = 0; i < f->hash_size; i++) { struct top_hash_entry *e; for (e = f->hash_table[i]; e != NULL; e = e->next) ospf_dump_lsa(e, p); } } */ /* This is very inefficient, please don't call it often */ /* I should also test for every LSA if it's in some link state * retransmission list for every neighbor. I will not test it. * It could happen that I'll receive some strange ls ack's. */ int can_flush_lsa(struct proto_ospf *po) { struct ospf_iface *ifa; struct ospf_neighbor *n; WALK_LIST(ifa, po->iface_list) { WALK_LIST(n, ifa->neigh_list) { if ((n->state == NEIGHBOR_EXCHANGE) || (n->state == NEIGHBOR_LOADING)) return 0; break; } } return 1; }