/* $OpenBSD: rde_rib.c,v 1.13 2003/12/30 13:03:27 henning Exp $ */ /* * Copyright (c) 2003 Claudio Jeker * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include "bgpd.h" #include "ensure.h" #include "rde.h" /* * BGP RIB -- Routing Information Base * * The RIB is build with one aspect in mind. Speed -- actually update speed. * Therefor one thing needs to be absolutely avoided, long table walks. * This is achieved by heavily linking the different parts together. */ struct rib_stats { u_int64_t attr_copy; u_int64_t aspath_create; u_int64_t aspath_destroy; u_int64_t path_update; u_int64_t path_get; u_int64_t path_add; u_int64_t path_remove; u_int64_t path_updateall; u_int64_t path_destroy; u_int64_t path_link; u_int64_t path_unlink; u_int64_t path_alloc; u_int64_t path_free; u_int64_t prefix_get; u_int64_t prefix_add; u_int64_t prefix_move; u_int64_t prefix_remove; u_int64_t prefix_updateall; u_int64_t prefix_link; u_int64_t prefix_unlink; u_int64_t prefix_alloc; u_int64_t prefix_free; u_int64_t nexthop_add; u_int64_t nexthop_remove; u_int64_t nexthop_update; u_int64_t nexthop_get; u_int64_t nexthop_alloc; u_int64_t nexthop_free; } ribstats; #define RIB_STAT(x) (ribstats.x++) /* * Maximum number of prefixes we allow per prefix. The number should * not be too big and ensure only that the prefix count is properly * increased and decreased. Only useful if ENSURE is active. */ #define MAX_PREFIX_PER_AS 1500 /* attribute specific functions */ int attr_equal(struct attr_flags *a, struct attr_flags *b) { /* astags not yet used */ if (a->origin != b->origin || aspath_equal(a->aspath, b->aspath) == 0 || a->nexthop.s_addr != b->nexthop.s_addr || a->med != b->med || a->lpref != b->lpref || a->aggr_atm != b->aggr_atm || a->aggr_as != b->aggr_as || a->aggr_ip.s_addr != b->aggr_ip.s_addr) return 0; return 1; } void attr_copy(struct attr_flags *t, struct attr_flags *s) { /* * first copy the full struct, then replace the path and tags with * a own copy. */ memcpy(t, s, sizeof(struct attr_flags)); /* XXX we could speed that a bit with a direct malloc, memcpy */ t->aspath = aspath_create(s->aspath->data, s->aspath->hdr.len); t->astags = NULL; /* XXX NOT YET */ } u_int16_t attr_length(struct attr_flags *attr) { u_int16_t alen, plen; alen = 4 /* origin */ + 7 /* nexthop */ + 7 /* lpref */; plen = aspath_length(attr->aspath); alen += 2 + plen + (plen > 255 ? 2 : 1); if (attr->med != 0) alen += 7; if (attr->aggr_atm == 1) alen += 3; if (attr->aggr_as != 0) alen += 9; return alen; } int attr_dump(void *p, u_int16_t len, struct attr_flags *a) { u_char *buf = p; u_int32_t tmp32; u_int16_t tmp16; u_int16_t aslen, wlen = 0; #define ATTR_WRITE(b, a, alen) \ do { \ if ((wlen + (alen)) > len) \ return (-1); \ memcpy((b) + wlen, (a), (alen)); \ wlen += (alen); \ } while (0) #define ATTR_WRITEB(b, c) \ do { \ if (wlen == len || (c) > 0xff) \ return (-1); \ (b)[wlen++] = (c); \ } while (0) /* origin */ ATTR_WRITEB(buf, ATTR_ORIGIN_FLAGS); ATTR_WRITEB(buf, ATTR_ORIGIN); ATTR_WRITEB(buf, 1); ATTR_WRITEB(buf, a->origin); /* aspath */ aslen = aspath_length(a->aspath); ATTR_WRITEB(buf, ATTR_TRANSITIVE | (aslen>255 ? ATTR_EXTLEN : 0)); ATTR_WRITEB(buf, ATTR_ASPATH); if (aslen > 255) { tmp16 = htonl(aslen); ATTR_WRITE(buf, &tmp16, 4); } else ATTR_WRITEB(buf, aslen); ATTR_WRITE(buf, aspath_dump(a->aspath), aslen); /* nexthop */ ATTR_WRITEB(buf, ATTR_NEXTHOP_FLAGS); ATTR_WRITEB(buf, ATTR_NEXTHOP); ATTR_WRITEB(buf, 4); ATTR_WRITE(buf, &a->nexthop, 4); /* network byte order */ /* MED */ if (a->med != 0) { ATTR_WRITEB(buf, ATTR_MED_FLAGS); ATTR_WRITEB(buf, ATTR_MED); ATTR_WRITEB(buf, 4); tmp32 = htonl(a->med); ATTR_WRITE(buf, &tmp32, 4); } /* local preference */ ATTR_WRITEB(buf, ATTR_LOCALPREF_FLAGS); ATTR_WRITEB(buf, ATTR_LOCALPREF); ATTR_WRITEB(buf, 4); tmp32 = htonl(a->lpref); ATTR_WRITE(buf, &tmp32, 4); /* atomic aggregate */ if (a->aggr_atm == 1) { ATTR_WRITEB(buf, ATTR_ATOMIC_AGGREGATE_FLAGS); ATTR_WRITEB(buf, ATTR_ATOMIC_AGGREGATE); ATTR_WRITEB(buf, 0); } /* aggregator */ if (a->aggr_as != 0) { ATTR_WRITEB(buf, ATTR_AGGREGATOR_FLAGS); ATTR_WRITEB(buf, ATTR_AGGREGATOR); ATTR_WRITEB(buf, 6); tmp16 = htons(a->aggr_as); ATTR_WRITE(buf, &tmp16, 2); ATTR_WRITE(buf, &a->aggr_ip, 4); /* network byte order */ } return wlen; #undef ATTR_WRITEB #undef ATTR_WRITE } /* aspath specific functions */ /* TODO * aspath loop detection (partially done I think), * aspath regexp search, * aspath to string converter */ static u_int16_t aspath_extract(void *, int); /* * Extract the asnum out of the as segment at the specified position. * Direct access is not possible because of non-aligned reads. */ static u_int16_t aspath_extract(void *seg, int pos) { u_char *ptr = seg; u_int16_t as = 0; ENSURE(0 <= pos && pos < 0xff); ptr += 2 + 2 * pos; as = *ptr++; as <<= 8; as |= *ptr; return as; } int aspath_verify(void *data, u_int16_t len, u_int16_t myAS) { u_int8_t *seg = data; u_int16_t seg_size; u_int8_t i, seg_len, seg_type; for (; len > 0; len -= seg_size, seg += seg_size) { seg_type = seg[0]; seg_len = seg[1]; if (seg_type != AS_SET && seg_type != AS_SEQUENCE) { return AS_ERR_TYPE; } seg_size = 2 + 2 * seg_len; if (seg_size > len) return AS_ERR_LEN; for (i = 0; i < seg_len; i++) { if (myAS == aspath_extract(seg, i)) return AS_ERR_LOOP; } } return 0; /* all OK */ } struct aspath * aspath_create(void *data, u_int16_t len) { struct aspath *aspath; RIB_STAT(aspath_create); /* The aspath must already have been checked for correctness. */ aspath = malloc(ASPATH_HEADER_SIZE + len); if (aspath == NULL) fatal("aspath_create"); aspath->hdr.len = len; memcpy(aspath->data, data, len); aspath->hdr.as_cnt = aspath_count(aspath); return aspath; } void aspath_destroy(struct aspath *aspath) { RIB_STAT(aspath_destroy); /* currently there is only the aspath that needs to be freed */ free(aspath); } u_char * aspath_dump(struct aspath *aspath) { return aspath->data; } u_int16_t aspath_length(struct aspath *aspath) { return aspath->hdr.len; } u_int16_t aspath_count(struct aspath *aspath) { u_int8_t *seg; u_int16_t cnt, len, seg_size; u_int8_t seg_type, seg_len; cnt = 0; seg = aspath->data; for (len = aspath->hdr.len; len > 0; len -= seg_size, seg += seg_size) { seg_type = seg[0]; seg_len = seg[1]; ENSURE(seg_type == AS_SET || seg_type == AS_SEQUENCE); seg_size = 2 + 2 * seg_len; if (seg_type == AS_SET) cnt += 1; else cnt += seg_len; } return cnt; } u_int16_t aspath_neighbour(struct aspath *aspath) { /* * Empty aspath is OK -- internal as route. * But what is the neighbour? For now let's return 0 that * should not break anything. */ if (aspath->hdr.len < 2) fatalx("aspath_neighbour: aspath has no data"); if (aspath->data[1] > 0) return aspath_extract(aspath->data, 0); return 0; } #define AS_HASH_INITIAL 8271 u_long aspath_hash(struct aspath *aspath) { u_int8_t *seg; u_long hash; u_int16_t len, seg_size; u_int8_t i, seg_len, seg_type; hash = AS_HASH_INITIAL; seg = aspath->data; for (len = aspath->hdr.len; len > 0; len -= seg_size, seg += seg_size) { seg_type = seg[0]; seg_len = seg[1]; ENSURE(seg_type == AS_SET || seg_type == AS_SEQUENCE); seg_size = 2 + 2 * seg_len; ENSURE(seg_size <= len); for (i = 0; i < seg_len; i++) { hash += (hash << 5); hash ^= aspath_extract(seg, i); } } return hash; } int aspath_equal(struct aspath *a1, struct aspath *a2) { if (a1->hdr.len == a2->hdr.len && memcmp(a1->data, a2->data, a1->hdr.len) == 0) return 1; return 0; } /* path specific functions */ static void path_link(struct rde_aspath *, struct rde_peer *); static void path_unlink(struct rde_aspath *); static struct rde_aspath *path_alloc(void); static void path_free(struct rde_aspath *); struct path_table { struct aspath_head *path_hashtbl; u_long path_hashmask; } pathtable; #define PATH_HASH(x) \ &pathtable.path_hashtbl[aspath_hash((x)) & pathtable.path_hashmask] void path_init(u_long hashsize) { u_long hs, i; for (hs = 1; hs < hashsize; hs <<= 1) ; pathtable.path_hashtbl = calloc(hs, sizeof(struct aspath_head)); if (pathtable.path_hashtbl == NULL) fatal("path_init"); for (i = 0; i < hs; i++) LIST_INIT(&pathtable.path_hashtbl[i]); pathtable.path_hashmask = hs - 1; } void path_update(struct rde_peer *peer, struct attr_flags *attrs, struct in_addr prefix, int prefixlen) { struct rde_aspath *asp; struct prefix *p; struct pt_entry *pte; RIB_STAT(path_update); if ((asp = path_get(attrs->aspath, peer)) == NULL) { asp = path_add(peer, attrs); pte = prefix_add(asp, prefix, prefixlen); } else { if (attr_equal(&asp->flags, attrs) == 0) { if ((p = prefix_get(asp, prefix, prefixlen)) == NULL) { asp = path_add(peer, attrs); pte = prefix_add(asp, prefix, prefixlen); } else { asp = path_add(peer, attrs); pte = prefix_move(asp, p); } } else pte = prefix_add(asp, prefix, prefixlen); } } struct rde_aspath * path_get(struct aspath *aspath, struct rde_peer *peer) { struct aspath_head *head; struct rde_aspath *asp; RIB_STAT(path_get); head = PATH_HASH(aspath); ENSURE(head != NULL); LIST_FOREACH(asp, head, path_l) { if (aspath_equal(asp->flags.aspath, aspath) && peer == asp->peer) return asp; } return NULL; } struct rde_aspath * path_add(struct rde_peer *peer, struct attr_flags *attr) { struct rde_aspath *asp; RIB_STAT(path_add); ENSURE(peer != NULL); asp = path_alloc(); attr_copy(&asp->flags, attr); path_link(asp, peer); return asp; } void path_remove(struct rde_aspath *asp) { struct prefix *p, *np; RIB_STAT(path_remove); for (p = LIST_FIRST(&asp->prefix_h); p != LIST_END(&asp->prefix_h); p = np) { np = LIST_NEXT(p, path_l); prefix_destroy(p); } LIST_INIT(&asp->prefix_h); path_destroy(asp); } void path_updateall(struct rde_aspath *asp, enum nexthop_state state) { RIB_STAT(path_updateall); prefix_updateall(asp, state); } /* this function is only called by prefix_remove and path_remove */ void path_destroy(struct rde_aspath *asp) { RIB_STAT(path_destroy); /* path_destroy can only unlink and free empty rde_aspath */ ENSURE(path_empty(asp)); path_unlink(asp); path_free(asp); } int path_empty(struct rde_aspath *asp) { ENSURE(asp != NULL); return LIST_EMPTY(&asp->prefix_h); } /* * the path object is linked into multiple lists for fast access. * These are peer_l, path_l and nexthop_l. * peer_l: list of all aspaths that belong to that peer * path_l: hash list to find paths quickly * nexthop_l: list of all aspaths with an equal exit nexthop */ static void path_link(struct rde_aspath *asp, struct rde_peer *peer) { struct aspath_head *head; RIB_STAT(path_link); head = PATH_HASH(asp->flags.aspath); ENSURE(head != NULL); LIST_INSERT_HEAD(head, asp, path_l); LIST_INSERT_HEAD(&peer->path_h, asp, peer_l); asp->peer = peer; ENSURE(asp->nexthop == NULL); nexthop_add(asp); } static void path_unlink(struct rde_aspath *asp) { RIB_STAT(path_unlink); ENSURE(path_empty(asp)); ENSURE(asp->prefix_cnt == 0 && asp->active_cnt == 0); nexthop_remove(asp); LIST_REMOVE(asp, path_l); LIST_REMOVE(asp, peer_l); asp->peer = NULL; asp->nexthop = NULL; /* free the aspath and astags */ aspath_destroy(asp->flags.aspath); asp->flags.aspath = NULL; /* * astags_destroy(asp->flags.astags); * asp->flags.astags = NULL; */ } /* alloc and initialize new entry. May not fail. */ static struct rde_aspath * path_alloc(void) { struct rde_aspath *asp; RIB_STAT(path_alloc); asp = calloc(1, sizeof(*asp)); if (asp == NULL) fatal("path_alloc"); LIST_INIT(&asp->prefix_h); return asp; } /* free a unlinked element */ static void path_free(struct rde_aspath *asp) { RIB_STAT(path_free); ENSURE(asp->peer == NULL && asp->flags.aspath == NULL && asp->flags.astags == NULL); free(asp); } /* prefix specific functions */ static struct prefix *prefix_alloc(void); static void prefix_free(struct prefix *); static void prefix_link(struct prefix *, struct pt_entry *, struct rde_aspath *); static void prefix_unlink(struct prefix *); /* * search in the path list for specified prefix. Returns NULL if not found. */ struct prefix * prefix_get(struct rde_aspath *asp, struct in_addr prefix, int prefixlen) { struct prefix *p; RIB_STAT(prefix_get); ENSURE(asp != NULL); LIST_FOREACH(p, &asp->prefix_h, path_l) { ENSURE(p->prefix != NULL); if (p->prefix->prefixlen == prefixlen && p->prefix->prefix.s_addr == prefix.s_addr) { ENSURE(p->aspath == asp); return p; } } return NULL; } /* * Adds or updates a prefix. Returns 1 if a new routing decision needs * to be done -- which is actually always. */ struct pt_entry * prefix_add(struct rde_aspath *asp, struct in_addr prefix, int prefixlen) { struct prefix *p; struct pt_entry *pte; int needlink = 0; RIB_STAT(prefix_add); pte = pt_get(prefix, prefixlen); if (pte == NULL) { pte = pt_add(prefix, prefixlen); } p = prefix_bypeer(pte, asp->peer); if (p == NULL) { needlink = 1; p = prefix_alloc(); } if (needlink == 1) prefix_link(p, pte, asp); return pte; } /* * Move the prefix to the specified as path, removes the old asp if needed. */ struct pt_entry * prefix_move(struct rde_aspath *asp, struct prefix *p) { struct prefix *np; struct rde_aspath *oasp; RIB_STAT(prefix_move); ENSURE(asp->peer == p->peer); /* create new prefix node */ np = prefix_alloc(); np->aspath = asp; np->prefix = p->prefix; np->peer = p->peer; np->lastchange = time(NULL); /* add to new as path */ LIST_INSERT_HEAD(&asp->prefix_h, np, path_l); asp->prefix_cnt++; /* XXX for debugging */ if (asp->prefix_cnt == MAX_PREFIX_PER_AS) logit(LOG_INFO, "RDE: prefix hog, prefix %#x/%d", np->prefix->prefix.s_addr, np->prefix->prefixlen); ENSURE(asp->prefix_cnt < MAX_PREFIX_PER_AS); /* * First kick the old prefix node out of the prefix list, * afterwards run the route decision for new prefix node. * Because of this only one update is generated if the prefix * was active. */ LIST_REMOVE(p, prefix_l); prefix_evaluate(np, p->prefix); /* remove old prefix node */ oasp = p->aspath; LIST_REMOVE(p, path_l); ENSURE(oasp->prefix_cnt > 0); oasp->prefix_cnt--; /* destroy all references to other objects and free the old prefix */ p->aspath = NULL; p->prefix = NULL; p->peer = NULL; prefix_free(p); /* destroy old path if empty */ if (path_empty(oasp)) path_destroy(oasp); /* XXX probably use path_remove */ return np->prefix; } /* * Removes a prefix from all lists. If the parent objects -- path or * pt_entry -- become empty remove them too. */ void prefix_remove(struct rde_peer *peer, struct in_addr prefix, int prefixlen) { struct prefix *p; struct pt_entry *pte; struct rde_aspath *asp; RIB_STAT(prefix_remove); pte = pt_get(prefix, prefixlen); if (pte == NULL) /* Got a dummy withdrawn request */ return; p = prefix_bypeer(pte, peer); if (p == NULL) /* Got a dummy withdrawn request. */ return; asp = p->aspath; prefix_unlink(p); prefix_free(p); if (pt_empty(pte)) pt_remove(pte); if (path_empty(asp)) path_destroy(asp); /* XXX probably use path_remove */ } /* * Searches in the prefix list of specified pt_entry for a prefix entry * belonging to the peer peer. Returns NULL if no match found. */ struct prefix * prefix_bypeer(struct pt_entry *pte, struct rde_peer *peer) { struct prefix *p; ENSURE(pte != NULL); LIST_FOREACH(p, &pte->prefix_h, prefix_l) { if (p->peer == peer) return p; } return NULL; } void prefix_updateall(struct rde_aspath *asp, enum nexthop_state state) { struct prefix *p; RIB_STAT(prefix_updateall); ENSURE(asp != NULL); LIST_FOREACH(p, &asp->prefix_h, path_l) { /* redo the route decision */ LIST_REMOVE(p, prefix_l); prefix_evaluate(p, p->prefix); } } /* kill a prefix. Only called by path_remove. */ void prefix_destroy(struct prefix *p) { struct pt_entry *pte; struct rde_aspath *asp; asp = p->aspath; pte = p->prefix; prefix_unlink(p); prefix_free(p); if (pt_empty(pte)) pt_remove(pte); } /* * Link a prefix into the different parent objects. */ static void prefix_link(struct prefix *pref, struct pt_entry *pte, struct rde_aspath *asp) { RIB_STAT(prefix_link); ENSURE(pref->aspath == NULL && pref->prefix == NULL && pref->peer == NULL); ENSURE(pref != NULL && pte != NULL && asp != NULL); ENSURE(prefix_bypeer(pte, asp->peer) == NULL); LIST_INSERT_HEAD(&asp->prefix_h, pref, path_l); asp->prefix_cnt++; /* XXX for debugging */ if (asp->prefix_cnt == MAX_PREFIX_PER_AS) logit(LOG_INFO, "RDE: prefix hog, prefix %#x/%d", pte->prefix.s_addr, pte->prefixlen); ENSURE(asp->prefix_cnt < MAX_PREFIX_PER_AS); pref->aspath = asp; pref->prefix = pte; pref->peer = asp->peer; pref->lastchange = time(NULL); /* make route decision */ prefix_evaluate(pref, pte); } /* * Unlink a prefix from the different parent objects. */ static void prefix_unlink(struct prefix *pref) { RIB_STAT(prefix_unlink); ENSURE(pref != NULL); ENSURE(pref->prefix != NULL && pref->aspath != NULL); /* make route decision */ LIST_REMOVE(pref, prefix_l); prefix_evaluate(NULL, pref->prefix); LIST_REMOVE(pref, path_l); ENSURE(pref->aspath->prefix_cnt > 0); pref->aspath->prefix_cnt--; /* destroy all references to other objects */ pref->aspath = NULL; pref->prefix = NULL; pref->peer = NULL; /* * It's the caller's duty to remove empty aspath respectively pt_entry * structures. Also freeing the unlinked prefix is the caller's duty. */ } /* alloc and bzero new entry. May not fail. */ static struct prefix * prefix_alloc(void) { struct prefix *p; RIB_STAT(prefix_alloc); p = calloc(1, sizeof(*p)); if (p == NULL) fatal("prefix_alloc"); return p; } /* free a unlinked entry */ static void prefix_free(struct prefix *pref) { RIB_STAT(prefix_free); ENSURE(pref->aspath == NULL && pref->prefix == NULL && pref->peer == NULL); free(pref); } /* nexthop functions */ /* * XXX * Storing the nexthop info in a hash table is not optimal. The problem is * that updates (invalidate and validate) come in as prefixes and so storing * the nexthops in a hash is not optimal. An (in)validate needs to do a table * walk to find all candidates. * Currently I think that there are many more adds and removes so that a * hash table has more benefits and the table walk should not happen too often. */ static struct nexthop *nexthop_get(in_addr_t); static struct nexthop *nexthop_alloc(void); static void nexthop_free(struct nexthop *); /* * In BGP there exist two nexthops: the exit nexthop which was announced via * BGP and the true nexthop which is used in the FIB -- forward information * base a.k.a kernel routing table. When sending updates it is even more * confusing. In IBGP we pass the unmodified exit nexthop to the neighbors * while in EBGP normaly the address of the router is sent. The exit nexthop * may be passed to the external neighbor if the neighbor and the exit nexthop * reside in the same subnet -- directly connected. */ struct nexthop_table { LIST_HEAD(, nexthop) *nexthop_hashtbl; u_long nexthop_hashmask; } nexthoptable; #define NEXTHOP_HASH(x) \ &nexthoptable.nexthop_hashtbl[(x) & nexthoptable.nexthop_hashmask] void nexthop_init(u_long hashsize) { u_long hs, i; for (hs = 1; hs < hashsize; hs <<= 1) ; nexthoptable.nexthop_hashtbl = calloc(hs, sizeof(struct aspath_head)); if (nexthoptable.nexthop_hashtbl == NULL) fatal("nextop_init"); for (i = 0; i < hs; i++) LIST_INIT(&nexthoptable.nexthop_hashtbl[i]); nexthoptable.nexthop_hashmask = hs - 1; } void nexthop_add(struct rde_aspath *asp) { struct nexthop *nh; RIB_STAT(nexthop_add); ENSURE(asp != NULL); if ((nh = asp->nexthop) == NULL) nh = nexthop_get(asp->flags.nexthop.s_addr); if (nh == NULL) { nh = nexthop_alloc(); nh->state = NEXTHOP_LOOKUP; nh->exit_nexthop = asp->flags.nexthop; LIST_INSERT_HEAD(NEXTHOP_HASH(asp->flags.nexthop.s_addr), nh, nexthop_l); rde_send_nexthop(nh->exit_nexthop.s_addr, 1); } asp->nexthop = nh; LIST_INSERT_HEAD(&nh->path_h, asp, nexthop_l); } void nexthop_remove(struct rde_aspath *asp) { struct nexthop *nh; RIB_STAT(nexthop_remove); ENSURE(asp != NULL); LIST_REMOVE(asp, nexthop_l); /* see if list is empty */ nh = asp->nexthop; if (LIST_EMPTY(&nh->path_h)) { LIST_REMOVE(nh, nexthop_l); rde_send_nexthop(nh->exit_nexthop.s_addr, 0); nexthop_free(nh); } } static struct nexthop * nexthop_get(in_addr_t nexthop) { struct nexthop *nh; RIB_STAT(nexthop_get); LIST_FOREACH(nh, NEXTHOP_HASH(nexthop), nexthop_l) { if (nh->exit_nexthop.s_addr == nexthop) return nh; } return NULL; } void nexthop_update(struct kroute_nexthop *msg) { struct nexthop *nh; struct rde_aspath *asp; RIB_STAT(nexthop_update); nh = nexthop_get(msg->nexthop); if (nh == NULL) { logit(LOG_INFO, "nexthop_update: non-existent nexthop"); return; } ENSURE(nh->exit_nexthop.s_addr == msg->nexthop); if (msg->valid) nh->state = NEXTHOP_REACH; else nh->state = NEXTHOP_UNREACH; if (msg->connected) nh->true_nexthop.s_addr = nh->exit_nexthop.s_addr; else nh->true_nexthop.s_addr = msg->gateway; nh->connected = msg->connected; LIST_FOREACH(asp, &nh->path_h, nexthop_l) { path_updateall(asp, nh->state); } } static struct nexthop * nexthop_alloc(void) { struct nexthop *nh; RIB_STAT(nexthop_alloc); nh = calloc(1, sizeof(*nh)); if (nh == NULL) fatal("nexthop_alloc"); LIST_INIT(&nh->path_h); return nh; } static void nexthop_free(struct nexthop *nh) { RIB_STAT(nexthop_free); ENSURE(LIST_EMPTY(&nh->path_h)); free(nh); }