/* $OpenBSD: kroute.c,v 1.303 2022/12/28 21:30:16 jmc Exp $ */ /* * Copyright (c) 2003, 2004 Henning Brauer * Copyright (c) 2022 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "bgpd.h" #include "log.h" #define RTP_MINE 0xff struct ktable **krt; u_int krt_size; struct { uint32_t rtseq; pid_t pid; int fd; uint8_t fib_prio; } kr_state; struct kroute { RB_ENTRY(kroute) entry; struct kroute *next; struct in_addr prefix; struct in_addr nexthop; uint32_t mplslabel; uint16_t flags; uint16_t labelid; u_short ifindex; uint8_t prefixlen; uint8_t priority; }; struct kroute6 { RB_ENTRY(kroute6) entry; struct kroute6 *next; struct in6_addr prefix; struct in6_addr nexthop; uint32_t prefix_scope_id; /* because ... */ uint32_t nexthop_scope_id; uint32_t mplslabel; uint16_t flags; uint16_t labelid; u_short ifindex; uint8_t prefixlen; uint8_t priority; }; struct knexthop { RB_ENTRY(knexthop) entry; struct bgpd_addr nexthop; void *kroute; u_short ifindex; }; struct kredist_node { RB_ENTRY(kredist_node) entry; struct bgpd_addr prefix; uint64_t rd; uint8_t prefixlen; uint8_t dynamic; }; struct kif { RB_ENTRY(kif) entry; char ifname[IFNAMSIZ]; uint64_t baudrate; u_int rdomain; int flags; u_short ifindex; uint8_t if_type; uint8_t link_state; uint8_t nh_reachable; /* for nexthop verification */ uint8_t depend_state; /* for session depend on */ }; int ktable_new(u_int, u_int, char *, int); void ktable_free(u_int); void ktable_destroy(struct ktable *); struct ktable *ktable_get(u_int); int kr4_change(struct ktable *, struct kroute_full *); int kr6_change(struct ktable *, struct kroute_full *); int krVPN4_change(struct ktable *, struct kroute_full *); int krVPN6_change(struct ktable *, struct kroute_full *); int kr_net_match(struct ktable *, struct network_config *, uint16_t, int); struct network *kr_net_find(struct ktable *, struct network *); void kr_net_clear(struct ktable *); void kr_redistribute(int, struct ktable *, struct kroute_full *); uint8_t kr_priority(struct kroute_full *); struct kroute_full *kr_tofull(struct kroute *); struct kroute_full *kr6_tofull(struct kroute6 *); int kroute_compare(struct kroute *, struct kroute *); int kroute6_compare(struct kroute6 *, struct kroute6 *); int knexthop_compare(struct knexthop *, struct knexthop *); int kredist_compare(struct kredist_node *, struct kredist_node *); int kif_compare(struct kif *, struct kif *); struct kroute *kroute_find(struct ktable *, const struct bgpd_addr *, uint8_t, uint8_t); struct kroute *kroute_matchgw(struct kroute *, struct kroute_full *); int kroute_insert(struct ktable *, struct kroute_full *); int kroute_remove(struct ktable *, struct kroute_full *, int); void kroute_clear(struct ktable *); struct kroute6 *kroute6_find(struct ktable *, const struct bgpd_addr *, uint8_t, uint8_t); struct kroute6 *kroute6_matchgw(struct kroute6 *, struct kroute_full *); void kroute6_clear(struct ktable *); struct knexthop *knexthop_find(struct ktable *, struct bgpd_addr *); int knexthop_insert(struct ktable *, struct knexthop *); void knexthop_remove(struct ktable *, struct knexthop *); void knexthop_clear(struct ktable *); struct kif *kif_find(int); int kif_insert(struct kif *); int kif_remove(struct kif *); void kif_clear(void); int kroute_validate(struct kroute *); int kroute6_validate(struct kroute6 *); int knexthop_true_nexthop(struct ktable *, struct kroute_full *); void knexthop_validate(struct ktable *, struct knexthop *); void knexthop_track(struct ktable *, u_short); void knexthop_update(struct ktable *, struct kroute_full *); void knexthop_send_update(struct knexthop *); struct kroute *kroute_match(struct ktable *, struct bgpd_addr *, int); struct kroute6 *kroute6_match(struct ktable *, struct bgpd_addr *, int); void kroute_detach_nexthop(struct ktable *, struct knexthop *); uint8_t prefixlen_classful(in_addr_t); uint8_t mask2prefixlen(in_addr_t); uint8_t mask2prefixlen6(struct sockaddr_in6 *); uint64_t ift2ifm(uint8_t); const char *get_media_descr(uint64_t); const char *get_linkstate(uint8_t, int); void get_rtaddrs(int, struct sockaddr *, struct sockaddr **); void if_change(u_short, int, struct if_data *); void if_announce(void *); int send_rtmsg(int, struct ktable *, struct kroute_full *); int dispatch_rtmsg(void); int fetchtable(struct ktable *); int fetchifs(int); int dispatch_rtmsg_addr(struct rt_msghdr *, struct kroute_full *); int kr_fib_delete(struct ktable *, struct kroute_full *, int); int kr_fib_change(struct ktable *, struct kroute_full *, int, int); RB_PROTOTYPE(kroute_tree, kroute, entry, kroute_compare) RB_GENERATE(kroute_tree, kroute, entry, kroute_compare) RB_PROTOTYPE(kroute6_tree, kroute6, entry, kroute6_compare) RB_GENERATE(kroute6_tree, kroute6, entry, kroute6_compare) RB_PROTOTYPE(knexthop_tree, knexthop, entry, knexthop_compare) RB_GENERATE(knexthop_tree, knexthop, entry, knexthop_compare) RB_PROTOTYPE(kredist_tree, kredist_node, entry, kredist_compare) RB_GENERATE(kredist_tree, kredist_node, entry, kredist_compare) RB_HEAD(kif_tree, kif) kit; RB_PROTOTYPE(kif_tree, kif, entry, kif_compare) RB_GENERATE(kif_tree, kif, entry, kif_compare) #define KT2KNT(x) (&(ktable_get((x)->nhtableid)->knt)) /* * exported functions */ int kr_init(int *fd, uint8_t fib_prio) { int opt = 0, rcvbuf, default_rcvbuf; unsigned int tid = RTABLE_ANY; socklen_t optlen; if ((kr_state.fd = socket(AF_ROUTE, SOCK_RAW | SOCK_CLOEXEC | SOCK_NONBLOCK, 0)) == -1) { log_warn("%s: socket", __func__); return (-1); } /* not interested in my own messages */ if (setsockopt(kr_state.fd, SOL_SOCKET, SO_USELOOPBACK, &opt, sizeof(opt)) == -1) log_warn("%s: setsockopt", __func__); /* not fatal */ /* grow receive buffer, don't wanna miss messages */ optlen = sizeof(default_rcvbuf); if (getsockopt(kr_state.fd, SOL_SOCKET, SO_RCVBUF, &default_rcvbuf, &optlen) == -1) log_warn("%s: getsockopt SOL_SOCKET SO_RCVBUF", __func__); else for (rcvbuf = MAX_RTSOCK_BUF; rcvbuf > default_rcvbuf && setsockopt(kr_state.fd, SOL_SOCKET, SO_RCVBUF, &rcvbuf, sizeof(rcvbuf)) == -1 && errno == ENOBUFS; rcvbuf /= 2) ; /* nothing */ if (setsockopt(kr_state.fd, AF_ROUTE, ROUTE_TABLEFILTER, &tid, sizeof(tid)) == -1) { log_warn("%s: setsockopt AF_ROUTE ROUTE_TABLEFILTER", __func__); return (-1); } kr_state.pid = getpid(); kr_state.rtseq = 1; kr_state.fib_prio = fib_prio; RB_INIT(&kit); if (fetchifs(0) == -1) return (-1); *fd = kr_state.fd; return (0); } int kr_default_prio(void) { return RTP_BGP; } int kr_check_prio(long long prio) { if (prio <= RTP_LOCAL || prio > RTP_MAX) return 0; return 1; } int ktable_new(u_int rtableid, u_int rdomid, char *name, int fs) { struct ktable **xkrt; struct ktable *kt; size_t oldsize; /* resize index table if needed */ if (rtableid >= krt_size) { oldsize = sizeof(struct ktable *) * krt_size; if ((xkrt = reallocarray(krt, rtableid + 1, sizeof(struct ktable *))) == NULL) { log_warn("%s", __func__); return (-1); } krt = xkrt; krt_size = rtableid + 1; memset((char *)krt + oldsize, 0, krt_size * sizeof(struct ktable *) - oldsize); } if (krt[rtableid]) fatalx("ktable_new: table already exists."); /* allocate new element */ kt = krt[rtableid] = calloc(1, sizeof(struct ktable)); if (kt == NULL) { log_warn("%s", __func__); return (-1); } /* initialize structure ... */ strlcpy(kt->descr, name, sizeof(kt->descr)); RB_INIT(&kt->krt); RB_INIT(&kt->krt6); RB_INIT(&kt->knt); TAILQ_INIT(&kt->krn); kt->fib_conf = kt->fib_sync = fs; kt->rtableid = rtableid; kt->nhtableid = rdomid; /* bump refcount of rdomain table for the nexthop lookups */ ktable_get(kt->nhtableid)->nhrefcnt++; /* ... and load it */ if (fetchtable(kt) == -1) return (-1); /* everything is up and running */ kt->state = RECONF_REINIT; log_debug("%s: %s with rtableid %d rdomain %d", __func__, name, rtableid, rdomid); return (0); } void ktable_free(u_int rtableid) { struct ktable *kt, *nkt; if ((kt = ktable_get(rtableid)) == NULL) return; /* decouple from kernel, no new routes will be entered from here */ kr_fib_decouple(kt->rtableid); /* first unhook from the nexthop table */ nkt = ktable_get(kt->nhtableid); nkt->nhrefcnt--; /* * Evil little details: * If kt->nhrefcnt > 0 then kt == nkt and nothing needs to be done. * If kt != nkt then kt->nhrefcnt must be 0 and kt must be killed. * If nkt is no longer referenced it must be killed (possible double * free so check that kt != nkt). */ if (kt != nkt && nkt->nhrefcnt <= 0) ktable_destroy(nkt); if (kt->nhrefcnt <= 0) ktable_destroy(kt); } void ktable_destroy(struct ktable *kt) { /* decouple just to be sure, does not hurt */ kr_fib_decouple(kt->rtableid); log_debug("%s: freeing ktable %s rtableid %u", __func__, kt->descr, kt->rtableid); /* only clear nexthop table if it is the main rdomain table */ if (kt->rtableid == kt->nhtableid) knexthop_clear(kt); kroute_clear(kt); kroute6_clear(kt); kr_net_clear(kt); krt[kt->rtableid] = NULL; free(kt); } struct ktable * ktable_get(u_int rtableid) { if (rtableid >= krt_size) return (NULL); return (krt[rtableid]); } int ktable_update(u_int rtableid, char *name, int flags) { struct ktable *kt, *rkt; u_int rdomid; if (!ktable_exists(rtableid, &rdomid)) fatalx("King Bula lost a table"); /* may not happen */ if (rdomid != rtableid || flags & F_RIB_NOFIB) { rkt = ktable_get(rdomid); if (rkt == NULL) { char buf[32]; snprintf(buf, sizeof(buf), "rdomain_%d", rdomid); if (ktable_new(rdomid, rdomid, buf, 0)) return (-1); } else { /* there is no need for full fib synchronisation if * the table is only used for nexthop lookups. */ if (rkt->state == RECONF_DELETE) { rkt->fib_conf = 0; rkt->state = RECONF_KEEP; } } } if (flags & (F_RIB_NOFIB | F_RIB_NOEVALUATE)) /* only rdomain table must exist */ return (0); kt = ktable_get(rtableid); if (kt == NULL) { if (ktable_new(rtableid, rdomid, name, !(flags & F_RIB_NOFIBSYNC))) return (-1); } else { /* fib sync has higher preference then no sync */ if (kt->state == RECONF_DELETE) { kt->fib_conf = !(flags & F_RIB_NOFIBSYNC); kt->state = RECONF_KEEP; } else if (!kt->fib_conf) kt->fib_conf = !(flags & F_RIB_NOFIBSYNC); strlcpy(kt->descr, name, sizeof(kt->descr)); } return (0); } int ktable_exists(u_int rtableid, u_int *rdomid) { size_t len; struct rt_tableinfo info; int mib[6]; mib[0] = CTL_NET; mib[1] = PF_ROUTE; mib[2] = 0; mib[3] = 0; mib[4] = NET_RT_TABLE; mib[5] = rtableid; len = sizeof(info); if (sysctl(mib, 6, &info, &len, NULL, 0) == -1) { if (errno == ENOENT) /* table nonexistent */ return (0); log_warn("sysctl net.route.rtableid"); /* must return 0 so that the table is considered non-existent */ return (0); } if (rdomid) *rdomid = info.rti_domainid; return (1); } int kr_change(u_int rtableid, struct kroute_full *kf) { struct ktable *kt; if ((kt = ktable_get(rtableid)) == NULL) /* too noisy during reloads, just ignore */ return (0); kf->flags |= F_BGPD; kf->priority = RTP_MINE; if (!knexthop_true_nexthop(kt, kf)) return kroute_remove(kt, kf, 1); switch (kf->prefix.aid) { case AID_INET: return (kr4_change(kt, kf)); case AID_INET6: return (kr6_change(kt, kf)); case AID_VPN_IPv4: return (krVPN4_change(kt, kf)); case AID_VPN_IPv6: return (krVPN6_change(kt, kf)); } log_warnx("%s: not handled AID", __func__); return (-1); } int kr4_change(struct ktable *kt, struct kroute_full *kf) { struct kroute *kr; /* for blackhole and reject routes nexthop needs to be 127.0.0.1 */ if (kf->flags & (F_BLACKHOLE|F_REJECT)) kf->nexthop.v4.s_addr = htonl(INADDR_LOOPBACK); /* nexthop within 127/8 -> ignore silently */ else if ((kf->nexthop.v4.s_addr & htonl(IN_CLASSA_NET)) == htonl(INADDR_LOOPBACK & IN_CLASSA_NET)) return (0); if ((kr = kroute_find(kt, &kf->prefix, kf->prefixlen, kf->priority)) == NULL) { if (kroute_insert(kt, kf) == -1) return (-1); } else { kr->nexthop.s_addr = kf->nexthop.v4.s_addr; rtlabel_unref(kr->labelid); kr->labelid = rtlabel_name2id(kf->label); if (kf->flags & F_BLACKHOLE) kr->flags |= F_BLACKHOLE; else kr->flags &= ~F_BLACKHOLE; if (kf->flags & F_REJECT) kr->flags |= F_REJECT; else kr->flags &= ~F_REJECT; if (send_rtmsg(RTM_CHANGE, kt, kf)) kr->flags |= F_BGPD_INSERTED; } return (0); } int kr6_change(struct ktable *kt, struct kroute_full *kf) { struct kroute6 *kr6; struct in6_addr lo6 = IN6ADDR_LOOPBACK_INIT; /* for blackhole and reject routes nexthop needs to be ::1 */ if (kf->flags & (F_BLACKHOLE|F_REJECT)) memcpy(&kf->nexthop.v6, &lo6, sizeof(kf->nexthop.v6)); /* nexthop to loopback -> ignore silently */ else if (IN6_IS_ADDR_LOOPBACK(&kf->nexthop.v6)) return (0); if ((kr6 = kroute6_find(kt, &kf->prefix, kf->prefixlen, kf->priority)) == NULL) { if (kroute_insert(kt, kf) == -1) return (-1); } else { memcpy(&kr6->nexthop, &kf->nexthop.v6, sizeof(struct in6_addr)); kr6->nexthop_scope_id = kf->nexthop.scope_id; rtlabel_unref(kr6->labelid); kr6->labelid = rtlabel_name2id(kf->label); if (kf->flags & F_BLACKHOLE) kr6->flags |= F_BLACKHOLE; else kr6->flags &= ~F_BLACKHOLE; if (kf->flags & F_REJECT) kr6->flags |= F_REJECT; else kr6->flags &= ~F_REJECT; if (send_rtmsg(RTM_CHANGE, kt, kf)) kr6->flags |= F_BGPD_INSERTED; } return (0); } int krVPN4_change(struct ktable *kt, struct kroute_full *kf) { struct kroute *kr; uint32_t mplslabel = 0; /* nexthop within 127/8 -> ignore silently */ if ((kf->nexthop.v4.s_addr & htonl(IN_CLASSA_NET)) == htonl(INADDR_LOOPBACK & IN_CLASSA_NET)) return (0); /* only a single MPLS label is supported for now */ if (kf->prefix.labellen != 3) { log_warnx("%s: %s/%u has not a single label", __func__, log_addr(&kf->prefix), kf->prefixlen); return (0); } mplslabel = (kf->prefix.labelstack[0] << 24) | (kf->prefix.labelstack[1] << 16) | (kf->prefix.labelstack[2] << 8); mplslabel = htonl(mplslabel); kf->flags |= F_MPLS; kf->mplslabel = mplslabel; /* for blackhole and reject routes nexthop needs to be 127.0.0.1 */ if (kf->flags & (F_BLACKHOLE|F_REJECT)) kf->nexthop.v4.s_addr = htonl(INADDR_LOOPBACK); if ((kr = kroute_find(kt, &kf->prefix, kf->prefixlen, kf->priority)) == NULL) { if (kroute_insert(kt, kf) == -1) return (-1); } else { kr->mplslabel = mplslabel; kr->flags |= F_MPLS; kr->ifindex = kf->ifindex; kr->nexthop.s_addr = kf->nexthop.v4.s_addr; rtlabel_unref(kr->labelid); kr->labelid = rtlabel_name2id(kf->label); if (kf->flags & F_BLACKHOLE) kr->flags |= F_BLACKHOLE; else kr->flags &= ~F_BLACKHOLE; if (kf->flags & F_REJECT) kr->flags |= F_REJECT; else kr->flags &= ~F_REJECT; if (send_rtmsg(RTM_CHANGE, kt, kf)) kr->flags |= F_BGPD_INSERTED; } return (0); } int krVPN6_change(struct ktable *kt, struct kroute_full *kf) { struct kroute6 *kr6; struct in6_addr lo6 = IN6ADDR_LOOPBACK_INIT; uint32_t mplslabel = 0; /* nexthop to loopback -> ignore silently */ if (IN6_IS_ADDR_LOOPBACK(&kf->nexthop.v6)) return (0); /* only a single MPLS label is supported for now */ if (kf->prefix.labellen != 3) { log_warnx("%s: %s/%u has not a single label", __func__, log_addr(&kf->prefix), kf->prefixlen); return (0); } mplslabel = (kf->prefix.labelstack[0] << 24) | (kf->prefix.labelstack[1] << 16) | (kf->prefix.labelstack[2] << 8); mplslabel = htonl(mplslabel); kf->flags |= F_MPLS; kf->mplslabel = mplslabel; /* for blackhole and reject routes nexthop needs to be ::1 */ if (kf->flags & (F_BLACKHOLE|F_REJECT)) memcpy(&kf->nexthop.v6, &lo6, sizeof(kf->nexthop.v6)); if ((kr6 = kroute6_find(kt, &kf->prefix, kf->prefixlen, kf->priority)) == NULL) { if (kroute_insert(kt, kf) == -1) return (-1); } else { kr6->mplslabel = mplslabel; kr6->flags |= F_MPLS; kr6->ifindex = kf->ifindex; memcpy(&kr6->nexthop, &kf->nexthop.v6, sizeof(struct in6_addr)); kr6->nexthop_scope_id = kf->nexthop.scope_id; rtlabel_unref(kr6->labelid); kr6->labelid = rtlabel_name2id(kf->label); if (kf->flags & F_BLACKHOLE) kr6->flags |= F_BLACKHOLE; else kr6->flags &= ~F_BLACKHOLE; if (kf->flags & F_REJECT) kr6->flags |= F_REJECT; else kr6->flags &= ~F_REJECT; if (send_rtmsg(RTM_CHANGE, kt, kf)) kr6->flags |= F_BGPD_INSERTED; } return (0); } int kr_delete(u_int rtableid, struct kroute_full *kf) { struct ktable *kt; if ((kt = ktable_get(rtableid)) == NULL) /* too noisy during reloads, just ignore */ return (0); kf->flags |= F_BGPD; kf->priority = RTP_MINE; return kroute_remove(kt, kf, 1); } int kr_flush(u_int rtableid) { struct ktable *kt; struct kroute *kr, *next; struct kroute6 *kr6, *next6; if ((kt = ktable_get(rtableid)) == NULL) /* too noisy during reloads, just ignore */ return (0); RB_FOREACH_SAFE(kr, kroute_tree, &kt->krt, next) if ((kr->flags & F_BGPD_INSERTED)) { if (kroute_remove(kt, kr_tofull(kr), 1) == -1) return (-1); } RB_FOREACH_SAFE(kr6, kroute6_tree, &kt->krt6, next6) if ((kr6->flags & F_BGPD_INSERTED)) { if (kroute_remove(kt, kr6_tofull(kr6), 1) == -1) return (-1); } kt->fib_sync = 0; return (0); } void kr_shutdown(void) { u_int i; for (i = krt_size; i > 0; i--) ktable_free(i - 1); kif_clear(); free(krt); } void kr_fib_couple(u_int rtableid) { struct ktable *kt; struct kroute *kr; struct kroute6 *kr6; if ((kt = ktable_get(rtableid)) == NULL) /* table does not exist */ return; if (kt->fib_sync) /* already coupled */ return; kt->fib_sync = 1; RB_FOREACH(kr, kroute_tree, &kt->krt) if (kr->flags & F_BGPD) { if (send_rtmsg(RTM_ADD, kt, kr_tofull(kr))) kr->flags |= F_BGPD_INSERTED; } RB_FOREACH(kr6, kroute6_tree, &kt->krt6) if (kr6->flags & F_BGPD) { if (send_rtmsg(RTM_ADD, kt, kr6_tofull(kr6))) kr6->flags |= F_BGPD_INSERTED; } log_info("kernel routing table %u (%s) coupled", kt->rtableid, kt->descr); } void kr_fib_couple_all(void) { u_int i; for (i = krt_size; i > 0; i--) kr_fib_couple(i - 1); } void kr_fib_decouple(u_int rtableid) { struct ktable *kt; struct kroute *kr; struct kroute6 *kr6; if ((kt = ktable_get(rtableid)) == NULL) /* table does not exist */ return; if (!kt->fib_sync) /* already decoupled */ return; RB_FOREACH(kr, kroute_tree, &kt->krt) if ((kr->flags & F_BGPD_INSERTED)) { if (send_rtmsg(RTM_DELETE, kt, kr_tofull(kr))) kr->flags &= ~F_BGPD_INSERTED; } RB_FOREACH(kr6, kroute6_tree, &kt->krt6) if ((kr6->flags & F_BGPD_INSERTED)) { if (send_rtmsg(RTM_DELETE, kt, kr6_tofull(kr6))) kr6->flags &= ~F_BGPD_INSERTED; } kt->fib_sync = 0; log_info("kernel routing table %u (%s) decoupled", kt->rtableid, kt->descr); } void kr_fib_decouple_all(void) { u_int i; for (i = krt_size; i > 0; i--) kr_fib_decouple(i - 1); } void kr_fib_prio_set(uint8_t prio) { kr_state.fib_prio = prio; } int kr_dispatch_msg(void) { return (dispatch_rtmsg()); } int kr_nexthop_add(u_int rtableid, struct bgpd_addr *addr) { struct ktable *kt; struct knexthop *h; if ((kt = ktable_get(rtableid)) == NULL) { log_warnx("%s: non-existent rtableid %d", __func__, rtableid); return (0); } if ((h = knexthop_find(kt, addr)) != NULL) { /* should not happen... this is actually an error path */ knexthop_send_update(h); } else { if ((h = calloc(1, sizeof(*h))) == NULL) { log_warn("%s", __func__); return (-1); } memcpy(&h->nexthop, addr, sizeof(h->nexthop)); if (knexthop_insert(kt, h) == -1) return (-1); } return (0); } void kr_nexthop_delete(u_int rtableid, struct bgpd_addr *addr) { struct ktable *kt; struct knexthop *kn; if ((kt = ktable_get(rtableid)) == NULL) { log_warnx("%s: non-existent rtableid %d", __func__, rtableid); return; } if ((kn = knexthop_find(kt, addr)) == NULL) return; knexthop_remove(kt, kn); } static struct ctl_show_interface * kr_show_interface(struct kif *kif) { static struct ctl_show_interface iface; uint64_t ifms_type; memset(&iface, 0, sizeof(iface)); strlcpy(iface.ifname, kif->ifname, sizeof(iface.ifname)); snprintf(iface.linkstate, sizeof(iface.linkstate), "%s", get_linkstate(kif->if_type, kif->link_state)); if ((ifms_type = ift2ifm(kif->if_type)) != 0) snprintf(iface.media, sizeof(iface.media), "%s", get_media_descr(ifms_type)); iface.baudrate = kif->baudrate; iface.rdomain = kif->rdomain; iface.nh_reachable = kif->nh_reachable; iface.is_up = (kif->flags & IFF_UP) == IFF_UP; return &iface; } void kr_show_route(struct imsg *imsg) { struct ktable *kt; struct kroute *kr, *kn; struct kroute6 *kr6, *kn6; struct kroute_full *kf; struct bgpd_addr *addr; int flags; sa_family_t af; struct ctl_show_nexthop snh; struct knexthop *h; struct kif *kif; u_int i; u_short ifindex = 0; switch (imsg->hdr.type) { case IMSG_CTL_KROUTE: if (imsg->hdr.len != IMSG_HEADER_SIZE + sizeof(flags) + sizeof(af)) { log_warnx("%s: wrong imsg len", __func__); break; } kt = ktable_get(imsg->hdr.peerid); if (kt == NULL) { log_warnx("%s: table %u does not exist", __func__, imsg->hdr.peerid); break; } memcpy(&flags, imsg->data, sizeof(flags)); memcpy(&af, (char *)imsg->data + sizeof(flags), sizeof(af)); if (!af || af == AF_INET) RB_FOREACH(kr, kroute_tree, &kt->krt) { if (flags && (kr->flags & flags) == 0) continue; kn = kr; do { kf = kr_tofull(kn); kf->priority = kr_priority(kf); send_imsg_session(IMSG_CTL_KROUTE, imsg->hdr.pid, kf, sizeof(*kf)); } while ((kn = kn->next) != NULL); } if (!af || af == AF_INET6) RB_FOREACH(kr6, kroute6_tree, &kt->krt6) { if (flags && (kr6->flags & flags) == 0) continue; kn6 = kr6; do { kf = kr6_tofull(kn6); kf->priority = kr_priority(kf); send_imsg_session(IMSG_CTL_KROUTE, imsg->hdr.pid, kf, sizeof(*kf)); } while ((kn6 = kn6->next) != NULL); } break; case IMSG_CTL_KROUTE_ADDR: if (imsg->hdr.len != IMSG_HEADER_SIZE + sizeof(struct bgpd_addr)) { log_warnx("%s: wrong imsg len", __func__); break; } kt = ktable_get(imsg->hdr.peerid); if (kt == NULL) { log_warnx("%s: table %u does not exist", __func__, imsg->hdr.peerid); break; } addr = imsg->data; kr = NULL; switch (addr->aid) { case AID_INET: kr = kroute_match(kt, addr, 1); if (kr != NULL) { kf = kr_tofull(kr); kf->priority = kr_priority(kf); send_imsg_session(IMSG_CTL_KROUTE, imsg->hdr.pid, kf, sizeof(*kf)); } break; case AID_INET6: kr6 = kroute6_match(kt, addr, 1); if (kr6 != NULL) { kf = kr6_tofull(kr6); kf->priority = kr_priority(kf); send_imsg_session(IMSG_CTL_KROUTE, imsg->hdr.pid, kf, sizeof(*kf)); } break; } break; case IMSG_CTL_SHOW_NEXTHOP: kt = ktable_get(imsg->hdr.peerid); if (kt == NULL) { log_warnx("%s: table %u does not exist", __func__, imsg->hdr.peerid); break; } RB_FOREACH(h, knexthop_tree, KT2KNT(kt)) { memset(&snh, 0, sizeof(snh)); memcpy(&snh.addr, &h->nexthop, sizeof(snh.addr)); if (h->kroute != NULL) { switch (h->nexthop.aid) { case AID_INET: kr = h->kroute; snh.valid = kroute_validate(kr); snh.krvalid = 1; snh.kr = *kr_tofull(kr); ifindex = kr->ifindex; break; case AID_INET6: kr6 = h->kroute; snh.valid = kroute6_validate(kr6); snh.krvalid = 1; snh.kr = *kr6_tofull(kr6); ifindex = kr6->ifindex; break; } snh.kr.priority = kr_priority(&snh.kr); if ((kif = kif_find(ifindex)) != NULL) memcpy(&snh.iface, kr_show_interface(kif), sizeof(snh.iface)); } send_imsg_session(IMSG_CTL_SHOW_NEXTHOP, imsg->hdr.pid, &snh, sizeof(snh)); } break; case IMSG_CTL_SHOW_INTERFACE: RB_FOREACH(kif, kif_tree, &kit) send_imsg_session(IMSG_CTL_SHOW_INTERFACE, imsg->hdr.pid, kr_show_interface(kif), sizeof(struct ctl_show_interface)); break; case IMSG_CTL_SHOW_FIB_TABLES: for (i = 0; i < krt_size; i++) { struct ktable ktab; if ((kt = ktable_get(i)) == NULL) continue; ktab = *kt; /* do not leak internal information */ RB_INIT(&ktab.krt); RB_INIT(&ktab.krt6); RB_INIT(&ktab.knt); TAILQ_INIT(&ktab.krn); send_imsg_session(IMSG_CTL_SHOW_FIB_TABLES, imsg->hdr.pid, &ktab, sizeof(ktab)); } break; default: /* nada */ break; } send_imsg_session(IMSG_CTL_END, imsg->hdr.pid, NULL, 0); } static void kr_send_dependon(struct kif *kif) { struct session_dependon sdon = { {0} }; strlcpy(sdon.ifname, kif->ifname, sizeof(sdon.ifname)); sdon.depend_state = kif->depend_state; send_imsg_session(IMSG_SESSION_DEPENDON, 0, &sdon, sizeof(sdon)); } void kr_ifinfo(char *ifname) { struct kif *kif; RB_FOREACH(kif, kif_tree, &kit) if (!strcmp(ifname, kif->ifname)) { kr_send_dependon(kif); return; } } static int kr_net_redist_add(struct ktable *kt, struct network_config *net, struct filter_set_head *attr, int dynamic) { struct kredist_node *r, *xr; if ((r = calloc(1, sizeof(*r))) == NULL) fatal("%s", __func__); r->prefix = net->prefix; r->prefixlen = net->prefixlen; r->rd = net->rd; r->dynamic = dynamic; xr = RB_INSERT(kredist_tree, &kt->kredist, r); if (xr != NULL) { free(r); if (dynamic != xr->dynamic && dynamic) { /* * ignore update a non-dynamic announcement is * already present which has preference. */ return 0; } /* * only equal or non-dynamic announcement ends up here. * In both cases reset the dynamic flag (nop for equal) and * redistribute. */ xr->dynamic = dynamic; } if (send_network(IMSG_NETWORK_ADD, net, attr) == -1) log_warnx("%s: failed to send network update", __func__); return 1; } static void kr_net_redist_del(struct ktable *kt, struct network_config *net, int dynamic) { struct kredist_node *r, node; memset(&node, 0, sizeof(node)); node.prefix = net->prefix; node.prefixlen = net->prefixlen; node.rd = net->rd; r = RB_FIND(kredist_tree, &kt->kredist, &node); if (r == NULL || dynamic != r->dynamic) return; if (RB_REMOVE(kredist_tree, &kt->kredist, r) == NULL) { log_warnx("%s: failed to remove network %s/%u", __func__, log_addr(&node.prefix), node.prefixlen); return; } free(r); if (send_network(IMSG_NETWORK_REMOVE, net, NULL) == -1) log_warnx("%s: failed to send network removal", __func__); } int kr_net_match(struct ktable *kt, struct network_config *net, uint16_t flags, int loopback) { struct network *xn; TAILQ_FOREACH(xn, &kt->krn, entry) { if (xn->net.prefix.aid != net->prefix.aid) continue; switch (xn->net.type) { case NETWORK_DEFAULT: /* static match already redistributed */ continue; case NETWORK_STATIC: /* Skip networks with nexthop on loopback. */ if (loopback) continue; if (flags & F_STATIC) break; continue; case NETWORK_CONNECTED: /* Skip networks with nexthop on loopback. */ if (loopback) continue; if (flags & F_CONNECTED) break; continue; case NETWORK_RTLABEL: if (net->rtlabel == xn->net.rtlabel) break; continue; case NETWORK_PRIORITY: if (net->priority == xn->net.priority) break; continue; case NETWORK_MRTCLONE: case NETWORK_PREFIXSET: /* must not happen */ log_warnx("%s: found a NETWORK_PREFIXSET, " "please send a bug report", __func__); continue; } net->rd = xn->net.rd; if (kr_net_redist_add(kt, net, &xn->net.attrset, 1)) return (1); } return (0); } struct network * kr_net_find(struct ktable *kt, struct network *n) { struct network *xn; TAILQ_FOREACH(xn, &kt->krn, entry) { if (n->net.type != xn->net.type || n->net.prefixlen != xn->net.prefixlen || n->net.rd != xn->net.rd || n->net.rtlabel != xn->net.rtlabel || n->net.priority != xn->net.priority) continue; if (memcmp(&n->net.prefix, &xn->net.prefix, sizeof(n->net.prefix)) == 0) return (xn); } return (NULL); } void kr_net_reload(u_int rtableid, uint64_t rd, struct network_head *nh) { struct network *n, *xn; struct ktable *kt; if ((kt = ktable_get(rtableid)) == NULL) fatalx("%s: non-existent rtableid %d", __func__, rtableid); while ((n = TAILQ_FIRST(nh)) != NULL) { TAILQ_REMOVE(nh, n, entry); n->net.old = 0; n->net.rd = rd; xn = kr_net_find(kt, n); if (xn) { xn->net.old = 0; filterset_free(&xn->net.attrset); filterset_move(&n->net.attrset, &xn->net.attrset); network_free(n); } else TAILQ_INSERT_TAIL(&kt->krn, n, entry); } } void kr_net_clear(struct ktable *kt) { struct network *n, *xn; TAILQ_FOREACH_SAFE(n, &kt->krn, entry, xn) { TAILQ_REMOVE(&kt->krn, n, entry); if (n->net.type == NETWORK_DEFAULT) kr_net_redist_del(kt, &n->net, 0); network_free(n); } } void kr_redistribute(int type, struct ktable *kt, struct kroute_full *kf) { struct network_config net; uint32_t a; int loflag = 0; memset(&net, 0, sizeof(net)); net.prefix = kf->prefix; net.prefixlen = kf->prefixlen; net.rtlabel = rtlabel_name2id(kf->label); rtlabel_unref(net.rtlabel); /* drop reference now, which is ok here */ net.priority = kf->priority; /* shortcut for removals */ if (type == IMSG_NETWORK_REMOVE) { kr_net_redist_del(kt, &net, 1); return; } if (kf->flags & F_BGPD) return; switch (kf->prefix.aid) { case AID_INET: /* * We consider the loopback net and multicast addresses * as not redistributable. */ a = ntohl(kf->prefix.v4.s_addr); if (IN_MULTICAST(a) || (a >> IN_CLASSA_NSHIFT) == IN_LOOPBACKNET) return; /* Check if the nexthop is the loopback addr. */ if (kf->nexthop.v4.s_addr == htonl(INADDR_LOOPBACK)) loflag = 1; break; case AID_INET6: /* * We consider unspecified, loopback, multicast, * link- and site-local, IPv4 mapped and IPv4 compatible * addresses as not redistributable. */ if (IN6_IS_ADDR_UNSPECIFIED(&kf->prefix.v6) || IN6_IS_ADDR_LOOPBACK(&kf->prefix.v6) || IN6_IS_ADDR_MULTICAST(&kf->prefix.v6) || IN6_IS_ADDR_LINKLOCAL(&kf->prefix.v6) || IN6_IS_ADDR_SITELOCAL(&kf->prefix.v6) || IN6_IS_ADDR_V4MAPPED(&kf->prefix.v6) || IN6_IS_ADDR_V4COMPAT(&kf->prefix.v6)) return; /* Check if the nexthop is the loopback addr. */ if (IN6_IS_ADDR_LOOPBACK(&kf->nexthop.v6)) loflag = 1; break; default: /* unhandled AID cannot be redistributed */ return; } /* * never allow 0/0 or ::/0 the default route can only be redistributed * with announce default. */ if (kf->prefixlen == 0) return; if (kr_net_match(kt, &net, kf->flags, loflag) == 0) /* no longer matches, if still present remove it */ kr_net_redist_del(kt, &net, 1); } void ktable_preload(void) { struct ktable *kt; struct network *n; u_int i; for (i = 0; i < krt_size; i++) { if ((kt = ktable_get(i)) == NULL) continue; kt->state = RECONF_DELETE; /* mark all networks as old */ TAILQ_FOREACH(n, &kt->krn, entry) n->net.old = 1; } } void ktable_postload(void) { struct ktable *kt; struct network *n, *xn; u_int i; for (i = krt_size; i > 0; i--) { if ((kt = ktable_get(i - 1)) == NULL) continue; if (kt->state == RECONF_DELETE) { ktable_free(i - 1); continue; } else if (kt->state == RECONF_REINIT) kt->fib_sync = kt->fib_conf; /* cleanup old networks */ TAILQ_FOREACH_SAFE(n, &kt->krn, entry, xn) { if (n->net.old) { TAILQ_REMOVE(&kt->krn, n, entry); if (n->net.type == NETWORK_DEFAULT) kr_net_redist_del(kt, &n->net, 0); network_free(n); } } } } int kr_reload(void) { struct ktable *kt; struct kroute *kr; struct kroute6 *kr6; struct knexthop *nh; struct network *n; u_int rid; int hasdyn = 0; for (rid = 0; rid < krt_size; rid++) { if ((kt = ktable_get(rid)) == NULL) continue; /* if this is the main nexthop table revalidate nexthops */ if (kt->rtableid == kt->nhtableid) RB_FOREACH(nh, knexthop_tree, KT2KNT(kt)) knexthop_validate(kt, nh); TAILQ_FOREACH(n, &kt->krn, entry) if (n->net.type == NETWORK_DEFAULT) { kr_net_redist_add(kt, &n->net, &n->net.attrset, 0); } else hasdyn = 1; if (hasdyn) { /* only evaluate the full tree if we need */ RB_FOREACH(kr, kroute_tree, &kt->krt) kr_redistribute(IMSG_NETWORK_ADD, kt, kr_tofull(kr)); RB_FOREACH(kr6, kroute6_tree, &kt->krt6) kr_redistribute(IMSG_NETWORK_ADD, kt, kr6_tofull(kr6)); } } return (0); } uint8_t kr_priority(struct kroute_full *kf) { if (kf->priority == RTP_MINE) return kr_state.fib_prio; return kf->priority; } struct kroute_full * kr_tofull(struct kroute *kr) { static struct kroute_full kf; memset(&kf, 0, sizeof(kf)); kf.prefix.aid = AID_INET; kf.prefix.v4.s_addr = kr->prefix.s_addr; kf.nexthop.aid = AID_INET; kf.nexthop.v4.s_addr = kr->nexthop.s_addr; strlcpy(kf.label, rtlabel_id2name(kr->labelid), sizeof(kf.label)); kf.flags = kr->flags; kf.ifindex = kr->ifindex; kf.prefixlen = kr->prefixlen; kf.priority = kr->priority; kf.mplslabel = kr->mplslabel; return (&kf); } struct kroute_full * kr6_tofull(struct kroute6 *kr6) { static struct kroute_full kf; memset(&kf, 0, sizeof(kf)); kf.prefix.aid = AID_INET6; kf.prefix.v6 = kr6->prefix; kf.prefix.scope_id = kr6->prefix_scope_id; kf.nexthop.aid = AID_INET6; kf.nexthop.v6 = kr6->nexthop; kf.nexthop.scope_id = kr6->nexthop_scope_id; strlcpy(kf.label, rtlabel_id2name(kr6->labelid), sizeof(kf.label)); kf.flags = kr6->flags; kf.ifindex = kr6->ifindex; kf.prefixlen = kr6->prefixlen; kf.priority = kr6->priority; kf.mplslabel = kr6->mplslabel; return (&kf); } /* * RB-tree compare functions */ int kroute_compare(struct kroute *a, struct kroute *b) { if (ntohl(a->prefix.s_addr) < ntohl(b->prefix.s_addr)) return (-1); if (ntohl(a->prefix.s_addr) > ntohl(b->prefix.s_addr)) return (1); if (a->prefixlen < b->prefixlen) return (-1); if (a->prefixlen > b->prefixlen) return (1); /* if the priority is RTP_ANY finish on the first address hit */ if (a->priority == RTP_ANY || b->priority == RTP_ANY) return (0); if (a->priority < b->priority) return (-1); if (a->priority > b->priority) return (1); return (0); } int kroute6_compare(struct kroute6 *a, struct kroute6 *b) { int i; for (i = 0; i < 16; i++) { if (a->prefix.s6_addr[i] < b->prefix.s6_addr[i]) return (-1); if (a->prefix.s6_addr[i] > b->prefix.s6_addr[i]) return (1); } if (a->prefix_scope_id < b->prefix_scope_id) return (-1); if (a->prefix_scope_id > b->prefix_scope_id) return (1); if (a->prefixlen < b->prefixlen) return (-1); if (a->prefixlen > b->prefixlen) return (1); /* if the priority is RTP_ANY finish on the first address hit */ if (a->priority == RTP_ANY || b->priority == RTP_ANY) return (0); if (a->priority < b->priority) return (-1); if (a->priority > b->priority) return (1); return (0); } int knexthop_compare(struct knexthop *a, struct knexthop *b) { int i; if (a->nexthop.aid != b->nexthop.aid) return (b->nexthop.aid - a->nexthop.aid); switch (a->nexthop.aid) { case AID_INET: if (ntohl(a->nexthop.v4.s_addr) < ntohl(b->nexthop.v4.s_addr)) return (-1); if (ntohl(a->nexthop.v4.s_addr) > ntohl(b->nexthop.v4.s_addr)) return (1); break; case AID_INET6: for (i = 0; i < 16; i++) { if (a->nexthop.v6.s6_addr[i] < b->nexthop.v6.s6_addr[i]) return (-1); if (a->nexthop.v6.s6_addr[i] > b->nexthop.v6.s6_addr[i]) return (1); } break; default: fatalx("%s: unknown AF", __func__); } return (0); } int kredist_compare(struct kredist_node *a, struct kredist_node *b) { int i; if (a->prefix.aid != b->prefix.aid) return (b->prefix.aid - a->prefix.aid); if (a->prefixlen < b->prefixlen) return (-1); if (a->prefixlen > b->prefixlen) return (1); switch (a->prefix.aid) { case AID_INET: if (ntohl(a->prefix.v4.s_addr) < ntohl(b->prefix.v4.s_addr)) return (-1); if (ntohl(a->prefix.v4.s_addr) > ntohl(b->prefix.v4.s_addr)) return (1); break; case AID_INET6: for (i = 0; i < 16; i++) { if (a->prefix.v6.s6_addr[i] < b->prefix.v6.s6_addr[i]) return (-1); if (a->prefix.v6.s6_addr[i] > b->prefix.v6.s6_addr[i]) return (1); } break; default: fatalx("%s: unknown AF", __func__); } if (a->rd < b->rd) return (-1); if (a->rd > b->rd) return (1); return (0); } int kif_compare(struct kif *a, struct kif *b) { return (b->ifindex - a->ifindex); } /* * tree management functions */ struct kroute * kroute_find(struct ktable *kt, const struct bgpd_addr *prefix, uint8_t prefixlen, uint8_t prio) { struct kroute s; struct kroute *kn, *tmp; s.prefix = prefix->v4; s.prefixlen = prefixlen; s.priority = prio; kn = RB_FIND(kroute_tree, &kt->krt, &s); if (kn && prio == RTP_ANY) { tmp = RB_PREV(kroute_tree, &kt->krt, kn); while (tmp) { if (kroute_compare(&s, tmp) == 0) kn = tmp; else break; tmp = RB_PREV(kroute_tree, &kt->krt, kn); } } return (kn); } struct kroute * kroute_matchgw(struct kroute *kr, struct kroute_full *kf) { in_addr_t nexthop; if (kf->flags & F_CONNECTED) { do { if (kr->ifindex == kf->ifindex) return (kr); kr = kr->next; } while (kr); return (NULL); } nexthop = kf->nexthop.v4.s_addr; do { if (kr->nexthop.s_addr == nexthop) return (kr); kr = kr->next; } while (kr); return (NULL); } int kroute_insert(struct ktable *kt, struct kroute_full *kf) { struct kroute *kr, *krm; struct kroute6 *kr6, *kr6m; struct knexthop *n; uint32_t mplslabel = 0; int multipath = 0; if (kf->prefix.aid == AID_VPN_IPv4 || kf->prefix.aid == AID_VPN_IPv6) { /* only a single MPLS label is supported for now */ if (kf->prefix.labellen != 3) { log_warnx("%s/%u does not have a single label", log_addr(&kf->prefix), kf->prefixlen); return -1; } mplslabel = (kf->prefix.labelstack[0] << 24) | (kf->prefix.labelstack[1] << 16) | (kf->prefix.labelstack[2] << 8); } switch (kf->prefix.aid) { case AID_INET: case AID_VPN_IPv4: if ((kr = calloc(1, sizeof(*kr))) == NULL) { log_warn("%s", __func__); return (-1); } kr->flags = kf->flags; kr->prefix = kf->prefix.v4; kr->prefixlen = kf->prefixlen; if (kf->nexthop.aid == AID_INET) kr->nexthop = kf->nexthop.v4; if (kf->prefix.aid == AID_VPN_IPv4) { kr->flags |= F_MPLS; kr->mplslabel = htonl(mplslabel); } kr->ifindex = kf->ifindex; kr->priority = kf->priority; kr->labelid = rtlabel_name2id(kf->label); if ((krm = RB_INSERT(kroute_tree, &kt->krt, kr)) != NULL) { /* multipath route, add at end of list */ while (krm->next != NULL) krm = krm->next; krm->next = kr; multipath = 1; } if (kf->flags & F_BGPD) if (send_rtmsg(RTM_ADD, kt, kf)) kr->flags |= F_BGPD_INSERTED; break; case AID_INET6: case AID_VPN_IPv6: if ((kr6 = calloc(1, sizeof(*kr6))) == NULL) { log_warn("%s", __func__); return (-1); } kr6->flags = kf->flags; kr6->prefix = kf->prefix.v6; kr6->prefix_scope_id = kf->prefix.scope_id; kr6->prefixlen = kf->prefixlen; if (kf->nexthop.aid == AID_INET6) { kr6->nexthop = kf->nexthop.v6; kr6->nexthop_scope_id = kf->nexthop.scope_id; } else kr6->nexthop = in6addr_any; if (kf->prefix.aid == AID_VPN_IPv6) { kr6->flags |= F_MPLS; kr6->mplslabel = htonl(mplslabel); } kr6->ifindex = kf->ifindex; kr6->priority = kf->priority; kr6->labelid = rtlabel_name2id(kf->label); if ((kr6m = RB_INSERT(kroute6_tree, &kt->krt6, kr6)) != NULL) { /* multipath route, add at end of list */ while (kr6m->next != NULL) kr6m = kr6m->next; kr6m->next = kr6; multipath = 1; } if (kf->flags & F_BGPD) if (send_rtmsg(RTM_ADD, kt, kf)) kr6->flags |= F_BGPD_INSERTED; break; } /* XXX this is wrong for nexthop validated via BGP */ if (!(kf->flags & F_BGPD)) { RB_FOREACH(n, knexthop_tree, KT2KNT(kt)) if (prefix_compare(&kf->prefix, &n->nexthop, kf->prefixlen) == 0) knexthop_validate(kt, n); /* redistribute multipath routes only once */ if (!multipath) kr_redistribute(IMSG_NETWORK_ADD, kt, kf); } return (0); } static int kroute4_remove(struct ktable *kt, struct kroute_full *kf, int any) { struct kroute *kr, *krm; struct knexthop *n; int multipath = 1; if ((kr = kroute_find(kt, &kf->prefix, kf->prefixlen, kf->priority)) == NULL) return (-1); if ((kr->flags & F_BGPD) != (kf->flags & F_BGPD)) { log_warnx("%s: wrong type for %s/%u", __func__, log_addr(&kf->prefix), kf->prefixlen); if (!(kf->flags & F_BGPD)) kr->flags &= ~F_BGPD_INSERTED; return (-1); } /* get the correct route to remove */ krm = kr; if (!any) { if ((krm = kroute_matchgw(kr, kf)) == NULL) { log_warnx("delete %s/%u: route not found", log_addr(&kf->prefix), kf->prefixlen); return (-2); } } if (krm == kr) { /* head element */ RB_REMOVE(kroute_tree, &kt->krt, krm); if (krm->next != NULL) { kr = krm->next; if (RB_INSERT(kroute_tree, &kt->krt, kr) != NULL) { log_warnx("%s: failed to add %s/%u", __func__, inet_ntoa(kr->prefix), kr->prefixlen); return (-2); } } else { multipath = 0; } } else { /* somewhere in the list */ while (kr->next != krm && kr->next != NULL) kr = kr->next; if (kr->next == NULL) { log_warnx("%s: multipath list corrupted for %s/%u", __func__, inet_ntoa(kr->prefix), kr->prefixlen); return (-2); } kr->next = krm->next; } /* check whether a nexthop depends on this kroute */ if (krm->flags & F_NEXTHOP) { RB_FOREACH(n, knexthop_tree, KT2KNT(kt)) { if (n->kroute == krm) knexthop_validate(kt, n); } } *kf = *kr_tofull(krm); rtlabel_unref(krm->labelid); free(krm); return (multipath); } static int kroute6_remove(struct ktable *kt, struct kroute_full *kf, int any) { struct kroute6 *kr, *krm; struct knexthop *n; int multipath = 1; if ((kr = kroute6_find(kt, &kf->prefix, kf->prefixlen, kf->priority)) == NULL) return (-1); if ((kr->flags & F_BGPD) != (kf->flags & F_BGPD)) { log_warnx("%s: wrong type for %s/%u", __func__, log_addr(&kf->prefix), kf->prefixlen); if (!(kf->flags & F_BGPD)) kr->flags &= ~F_BGPD_INSERTED; return (-1); } /* get the correct route to remove */ krm = kr; if (!any) { if ((krm = kroute6_matchgw(kr, kf)) == NULL) { log_warnx("delete %s/%u: route not found", log_addr(&kf->prefix), kf->prefixlen); return (-2); } } if (krm == kr) { /* head element */ RB_REMOVE(kroute6_tree, &kt->krt6, krm); if (krm->next != NULL) { kr = krm->next; if (RB_INSERT(kroute6_tree, &kt->krt6, kr) != NULL) { log_warnx("%s: failed to add %s/%u", __func__, log_in6addr(&kr->prefix), kr->prefixlen); return (-2); } } else { multipath = 0; } } else { /* somewhere in the list */ while (kr->next != krm && kr->next != NULL) kr = kr->next; if (kr->next == NULL) { log_warnx("%s: multipath list corrupted for %s/%u", __func__, log_in6addr(&kr->prefix), kr->prefixlen); return (-2); } kr->next = krm->next; } /* check whether a nexthop depends on this kroute */ if (kr->flags & F_NEXTHOP) { RB_FOREACH(n, knexthop_tree, KT2KNT(kt)) { if (n->kroute == krm) knexthop_validate(kt, n); } } *kf = *kr6_tofull(krm); rtlabel_unref(krm->labelid); free(krm); return (multipath); } int kroute_remove(struct ktable *kt, struct kroute_full *kf, int any) { int multipath; switch (kf->prefix.aid) { case AID_INET: case AID_VPN_IPv4: multipath = kroute4_remove(kt, kf, any); break; case AID_INET6: case AID_VPN_IPv6: multipath = kroute6_remove(kt, kf, any); break; default: log_warnx("%s: not handled AID", __func__); return (-1); } if (multipath < 0) return (multipath + 1); if (kf->flags & F_BGPD_INSERTED) send_rtmsg(RTM_DELETE, kt, kf); /* remove only once all multipath routes are gone */ if (!(kf->flags & F_BGPD) && !multipath) kr_redistribute(IMSG_NETWORK_REMOVE, kt, kf); return (0); } void kroute_clear(struct ktable *kt) { struct kroute *kr; while ((kr = RB_MIN(kroute_tree, &kt->krt)) != NULL) kroute_remove(kt, kr_tofull(kr), 1); } struct kroute6 * kroute6_find(struct ktable *kt, const struct bgpd_addr *prefix, uint8_t prefixlen, uint8_t prio) { struct kroute6 s; struct kroute6 *kn6, *tmp; s.prefix = prefix->v6; s.prefix_scope_id = prefix->scope_id; s.prefixlen = prefixlen; s.priority = prio; kn6 = RB_FIND(kroute6_tree, &kt->krt6, &s); if (kn6 && prio == RTP_ANY) { tmp = RB_PREV(kroute6_tree, &kt->krt6, kn6); while (tmp) { if (kroute6_compare(&s, tmp) == 0) kn6 = tmp; else break; tmp = RB_PREV(kroute6_tree, &kt->krt6, kn6); } } return (kn6); } struct kroute6 * kroute6_matchgw(struct kroute6 *kr, struct kroute_full *kf) { struct in6_addr nexthop; if (kf->flags & F_CONNECTED) { do { if (kr->ifindex == kf->ifindex) return (kr); kr = kr->next; } while (kr); return (NULL); } nexthop = kf->nexthop.v6; do { if (memcmp(&kr->nexthop, &nexthop, sizeof(nexthop)) == 0 && kr->nexthop_scope_id == kf->nexthop.scope_id) return (kr); kr = kr->next; } while (kr); return (NULL); } void kroute6_clear(struct ktable *kt) { struct kroute6 *kr; while ((kr = RB_MIN(kroute6_tree, &kt->krt6)) != NULL) kroute_remove(kt, kr6_tofull(kr), 1); } struct knexthop * knexthop_find(struct ktable *kt, struct bgpd_addr *addr) { struct knexthop s; memset(&s, 0, sizeof(s)); memcpy(&s.nexthop, addr, sizeof(s.nexthop)); return (RB_FIND(knexthop_tree, KT2KNT(kt), &s)); } int knexthop_insert(struct ktable *kt, struct knexthop *kn) { if (RB_INSERT(knexthop_tree, KT2KNT(kt), kn) != NULL) { log_warnx("%s: failed for %s", __func__, log_addr(&kn->nexthop)); free(kn); return (-1); } knexthop_validate(kt, kn); return (0); } void knexthop_remove(struct ktable *kt, struct knexthop *kn) { kroute_detach_nexthop(kt, kn); RB_REMOVE(knexthop_tree, KT2KNT(kt), kn); free(kn); } void knexthop_clear(struct ktable *kt) { struct knexthop *kn; while ((kn = RB_MIN(knexthop_tree, KT2KNT(kt))) != NULL) knexthop_remove(kt, kn); } struct kif * kif_find(int ifindex) { struct kif s; memset(&s, 0, sizeof(s)); s.ifindex = ifindex; return (RB_FIND(kif_tree, &kit, &s)); } int kif_insert(struct kif *kif) { if (RB_INSERT(kif_tree, &kit, kif) != NULL) { log_warnx("RB_INSERT(kif_tree, &kit, kif)"); free(kif); return (-1); } return (0); } int kif_remove(struct kif *kif) { struct ktable *kt; kif->flags &= ~IFF_UP; /* * TODO, remove all kroutes using this interface, * the kernel does this for us but better to do it * here as well. */ if ((kt = ktable_get(kif->rdomain)) != NULL) knexthop_track(kt, kif->ifindex); RB_REMOVE(kif_tree, &kit, kif); free(kif); return (0); } void kif_clear(void) { struct kif *kif; while ((kif = RB_MIN(kif_tree, &kit)) != NULL) kif_remove(kif); } /* * nexthop validation */ static int kif_validate(struct kif *kif) { if (!(kif->flags & IFF_UP)) return (0); /* * we treat link_state == LINK_STATE_UNKNOWN as valid, * not all interfaces have a concept of "link state" and/or * do not report up */ if (kif->link_state == LINK_STATE_DOWN) return (0); return (1); } /* * return 1 when the interface is up and the link state is up or unknown * except when this is a carp interface, then return 1 only when link state * is up */ static int kif_depend_state(struct kif *kif) { if (!(kif->flags & IFF_UP)) return (0); if (kif->if_type == IFT_CARP && kif->link_state == LINK_STATE_UNKNOWN) return (0); return LINK_STATE_IS_UP(kif->link_state); } int kroute_validate(struct kroute *kr) { struct kif *kif; if (kr->flags & (F_REJECT | F_BLACKHOLE)) return (0); if ((kif = kif_find(kr->ifindex)) == NULL) { if (kr->ifindex) log_warnx("%s: interface with index %d not found, " "referenced from route for %s/%u", __func__, kr->ifindex, inet_ntoa(kr->prefix), kr->prefixlen); return (1); } return (kif->nh_reachable); } int kroute6_validate(struct kroute6 *kr) { struct kif *kif; if (kr->flags & (F_REJECT | F_BLACKHOLE)) return (0); if ((kif = kif_find(kr->ifindex)) == NULL) { if (kr->ifindex) log_warnx("%s: interface with index %d not found, " "referenced from route for %s/%u", __func__, kr->ifindex, log_in6addr(&kr->prefix), kr->prefixlen); return (1); } return (kif->nh_reachable); } int knexthop_true_nexthop(struct ktable *kt, struct kroute_full *kf) { struct bgpd_addr gateway = { 0 }; struct knexthop *kn; struct kroute *kr; struct kroute6 *kr6; /* * Ignore the nexthop for VPN routes. The gateway is forced * to an mpe(4) interface route using an MPLS label. */ switch (kf->prefix.aid) { case AID_VPN_IPv4: case AID_VPN_IPv6: return 1; } kn = knexthop_find(kt, &kf->nexthop); if (kn == NULL) { log_warnx("%s: nexthop %s not found", __func__, log_addr(&kf->nexthop)); return 0; } if (kn->kroute == NULL) return 0; switch (kn->nexthop.aid) { case AID_INET: kr = kn->kroute; if (kr->flags & F_CONNECTED) return 1; gateway.aid = AID_INET; gateway.v4.s_addr = kr->nexthop.s_addr; break; case AID_INET6: kr6 = kn->kroute; if (kr6->flags & F_CONNECTED) return 1; gateway.aid = AID_INET6; gateway.v6 = kr6->nexthop; gateway.scope_id = kr6->nexthop_scope_id; break; } kf->nexthop = gateway; return 1; } void knexthop_validate(struct ktable *kt, struct knexthop *kn) { void *oldk; struct kroute *kr; struct kroute6 *kr6; oldk = kn->kroute; kroute_detach_nexthop(kt, kn); if ((kt = ktable_get(kt->nhtableid)) == NULL) fatalx("%s: lost nexthop routing table", __func__); switch (kn->nexthop.aid) { case AID_INET: kr = kroute_match(kt, &kn->nexthop, 0); if (kr != NULL) { kn->kroute = kr; kn->ifindex = kr->ifindex; kr->flags |= F_NEXTHOP; } /* * Send update if nexthop route changed under us if * the route remains the same then the NH state has not * changed. */ if (kr != oldk) knexthop_send_update(kn); break; case AID_INET6: kr6 = kroute6_match(kt, &kn->nexthop, 0); if (kr6 != NULL) { kn->kroute = kr6; kn->ifindex = kr6->ifindex; kr6->flags |= F_NEXTHOP; } if (kr6 != oldk) knexthop_send_update(kn); break; } } /* * Called on interface state change. */ void knexthop_track(struct ktable *kt, u_short ifindex) { struct knexthop *kn; RB_FOREACH(kn, knexthop_tree, KT2KNT(kt)) if (kn->ifindex == ifindex) knexthop_validate(kt, kn); } /* * Called on route change. */ void knexthop_update(struct ktable *kt, struct kroute_full *kf) { struct knexthop *kn; RB_FOREACH(kn, knexthop_tree, KT2KNT(kt)) if (prefix_compare(&kf->prefix, &kn->nexthop, kf->prefixlen) == 0) knexthop_send_update(kn); } void knexthop_send_update(struct knexthop *kn) { struct kroute_nexthop n; struct kroute *kr; struct kroute6 *kr6; memset(&n, 0, sizeof(n)); n.nexthop = kn->nexthop; if (kn->kroute == NULL) { n.valid = 0; /* NH is not valid */ send_nexthop_update(&n); return; } switch (kn->nexthop.aid) { case AID_INET: kr = kn->kroute; n.valid = kroute_validate(kr); n.connected = kr->flags & F_CONNECTED; if (!n.connected) { n.gateway.aid = AID_INET; n.gateway.v4.s_addr = kr->nexthop.s_addr; } else { n.gateway = n.nexthop; n.net.aid = AID_INET; n.net.v4.s_addr = kr->prefix.s_addr; n.netlen = kr->prefixlen; } break; case AID_INET6: kr6 = kn->kroute; n.valid = kroute6_validate(kr6); n.connected = kr6->flags & F_CONNECTED; if (!n.connected) { n.gateway.aid = AID_INET6; n.gateway.v6 = kr6->nexthop; n.gateway.scope_id = kr6->nexthop_scope_id; } else { n.gateway = n.nexthop; n.net.aid = AID_INET6; n.net.v6 = kr6->prefix; n.net.scope_id = kr6->prefix_scope_id; n.netlen = kr6->prefixlen; } break; } send_nexthop_update(&n); } struct kroute * kroute_match(struct ktable *kt, struct bgpd_addr *key, int matchany) { int i; struct kroute *kr; struct bgpd_addr masked; for (i = 32; i >= 0; i--) { applymask(&masked, key, i); if ((kr = kroute_find(kt, &masked, i, RTP_ANY)) != NULL) if (matchany || bgpd_oknexthop(kr_tofull(kr))) return (kr); } return (NULL); } struct kroute6 * kroute6_match(struct ktable *kt, struct bgpd_addr *key, int matchany) { int i; struct kroute6 *kr6; struct bgpd_addr masked; for (i = 128; i >= 0; i--) { applymask(&masked, key, i); if ((kr6 = kroute6_find(kt, &masked, i, RTP_ANY)) != NULL) if (matchany || bgpd_oknexthop(kr6_tofull(kr6))) return (kr6); } return (NULL); } void kroute_detach_nexthop(struct ktable *kt, struct knexthop *kn) { struct knexthop *s; struct kroute *k; struct kroute6 *k6; if (kn->kroute == NULL) return; /* * check whether there's another nexthop depending on this kroute * if not remove the flag */ RB_FOREACH(s, knexthop_tree, KT2KNT(kt)) if (s->kroute == kn->kroute && s != kn) break; if (s == NULL) { switch (kn->nexthop.aid) { case AID_INET: k = kn->kroute; k->flags &= ~F_NEXTHOP; break; case AID_INET6: k6 = kn->kroute; k6->flags &= ~F_NEXTHOP; break; } } kn->kroute = NULL; kn->ifindex = 0; } /* * misc helpers */ uint8_t prefixlen_classful(in_addr_t ina) { /* it hurt to write this. */ if (ina >= 0xf0000000U) /* class E */ return (32); else if (ina >= 0xe0000000U) /* class D */ return (4); else if (ina >= 0xc0000000U) /* class C */ return (24); else if (ina >= 0x80000000U) /* class B */ return (16); else /* class A */ return (8); } uint8_t mask2prefixlen(in_addr_t ina) { if (ina == 0) return (0); else return (33 - ffs(ntohl(ina))); } uint8_t mask2prefixlen6(struct sockaddr_in6 *sa_in6) { uint8_t *ap, *ep; u_int l = 0; /* * sin6_len is the size of the sockaddr so subtract the offset of * the possibly truncated sin6_addr struct. */ ap = (uint8_t *)&sa_in6->sin6_addr; ep = (uint8_t *)sa_in6 + sa_in6->sin6_len; for (; ap < ep; ap++) { /* this "beauty" is adopted from sbin/route/show.c ... */ switch (*ap) { case 0xff: l += 8; break; case 0xfe: l += 7; goto done; case 0xfc: l += 6; goto done; case 0xf8: l += 5; goto done; case 0xf0: l += 4; goto done; case 0xe0: l += 3; goto done; case 0xc0: l += 2; goto done; case 0x80: l += 1; goto done; case 0x00: goto done; default: fatalx("non contiguous inet6 netmask"); } } done: if (l > sizeof(struct in6_addr) * 8) fatalx("%s: prefixlen %d out of bound", __func__, l); return (l); } const struct if_status_description if_status_descriptions[] = LINK_STATE_DESCRIPTIONS; const struct ifmedia_description ifm_type_descriptions[] = IFM_TYPE_DESCRIPTIONS; uint64_t ift2ifm(uint8_t if_type) { switch (if_type) { case IFT_ETHER: return (IFM_ETHER); case IFT_FDDI: return (IFM_FDDI); case IFT_CARP: return (IFM_CARP); case IFT_IEEE80211: return (IFM_IEEE80211); default: return (0); } } const char * get_media_descr(uint64_t media_type) { const struct ifmedia_description *p; for (p = ifm_type_descriptions; p->ifmt_string != NULL; p++) if (media_type == p->ifmt_word) return (p->ifmt_string); return ("unknown media"); } const char * get_linkstate(uint8_t if_type, int link_state) { const struct if_status_description *p; static char buf[8]; for (p = if_status_descriptions; p->ifs_string != NULL; p++) { if (LINK_STATE_DESC_MATCH(p, if_type, link_state)) return (p->ifs_string); } snprintf(buf, sizeof(buf), "[#%d]", link_state); return (buf); } #define ROUNDUP(a) \ ((a) > 0 ? (1 + (((a) - 1) | (sizeof(long) - 1))) : sizeof(long)) void get_rtaddrs(int addrs, struct sockaddr *sa, struct sockaddr **rti_info) { int i; for (i = 0; i < RTAX_MAX; i++) { if (addrs & (1 << i)) { rti_info[i] = sa; sa = (struct sockaddr *)((char *)(sa) + ROUNDUP(sa->sa_len)); } else rti_info[i] = NULL; } } void if_change(u_short ifindex, int flags, struct if_data *ifd) { struct ktable *kt; struct kif *kif; uint8_t reachable; if ((kif = kif_find(ifindex)) == NULL) { log_warnx("%s: interface with index %u not found", __func__, ifindex); return; } log_info("%s: %s: rdomain %u %s, %s, %s, %s", __func__, kif->ifname, ifd->ifi_rdomain, flags & IFF_UP ? "UP" : "DOWN", get_media_descr(ift2ifm(ifd->ifi_type)), get_linkstate(ifd->ifi_type, ifd->ifi_link_state), get_baudrate(ifd->ifi_baudrate, "bps")); kif->flags = flags; kif->link_state = ifd->ifi_link_state; kif->if_type = ifd->ifi_type; kif->rdomain = ifd->ifi_rdomain; kif->baudrate = ifd->ifi_baudrate; kif->depend_state = kif_depend_state(kif); kr_send_dependon(kif); if ((reachable = kif_validate(kif)) == kif->nh_reachable) return; /* nothing changed wrt nexthop validity */ kif->nh_reachable = reachable; kt = ktable_get(kif->rdomain); if (kt == NULL) return; knexthop_track(kt, ifindex); } void if_announce(void *msg) { struct if_announcemsghdr *ifan; struct kif *kif; ifan = msg; switch (ifan->ifan_what) { case IFAN_ARRIVAL: if ((kif = calloc(1, sizeof(*kif))) == NULL) { log_warn("%s", __func__); return; } kif->ifindex = ifan->ifan_index; strlcpy(kif->ifname, ifan->ifan_name, sizeof(kif->ifname)); kif_insert(kif); break; case IFAN_DEPARTURE: kif = kif_find(ifan->ifan_index); if (kif != NULL) kif_remove(kif); break; } } int get_mpe_config(const char *name, u_int *rdomain, u_int *label) { struct ifreq ifr; struct shim_hdr shim; int s; *label = 0; *rdomain = 0; s = socket(AF_INET, SOCK_DGRAM | SOCK_CLOEXEC, 0); if (s == -1) return (-1); memset(&shim, 0, sizeof(shim)); memset(&ifr, 0, sizeof(ifr)); strlcpy(ifr.ifr_name, name, sizeof(ifr.ifr_name)); ifr.ifr_data = (caddr_t)&shim; if (ioctl(s, SIOCGETLABEL, (caddr_t)&ifr) == -1) { close(s); return (-1); } ifr.ifr_data = NULL; if (ioctl(s, SIOCGIFRDOMAIN, (caddr_t)&ifr) == -1) { close(s); return (-1); } close(s); *rdomain = ifr.ifr_rdomainid; *label = shim.shim_label; return (0); } /* * rtsock related functions */ #define satosin6(sa) ((struct sockaddr_in6 *)(sa)) int send_rtmsg(int action, struct ktable *kt, struct kroute_full *kf) { struct iovec iov[7]; struct rt_msghdr hdr; struct sockaddr_storage prefix, nexthop, mask, ifp, label, mpls; struct bgpd_addr netmask; struct sockaddr *sa; struct sockaddr_dl *dl; struct sockaddr_mpls *mp; struct sockaddr_rtlabel *la; socklen_t salen; int iovcnt = 0; if (!kt->fib_sync) return (0); /* initialize header */ memset(&hdr, 0, sizeof(hdr)); hdr.rtm_version = RTM_VERSION; hdr.rtm_type = action; hdr.rtm_tableid = kt->rtableid; hdr.rtm_priority = kr_state.fib_prio; if (kf->flags & F_BLACKHOLE) hdr.rtm_flags |= RTF_BLACKHOLE; if (kf->flags & F_REJECT) hdr.rtm_flags |= RTF_REJECT; if (action == RTM_CHANGE) /* reset these flags on change */ hdr.rtm_fmask = RTF_REJECT|RTF_BLACKHOLE; hdr.rtm_seq = kr_state.rtseq++; /* overflow doesn't matter */ hdr.rtm_msglen = sizeof(hdr); /* adjust iovec */ iov[iovcnt].iov_base = &hdr; iov[iovcnt++].iov_len = sizeof(hdr); memset(&prefix, 0, sizeof(prefix)); sa = addr2sa(&kf->prefix, 0, &salen); sa->sa_len = salen; #ifdef __KAME__ /* XXX need to embed the stupid scope for now */ if (sa->sa_family == AF_INET6 && (IN6_IS_ADDR_LINKLOCAL(&satosin6(sa)->sin6_addr) || IN6_IS_ADDR_MC_LINKLOCAL(&satosin6(sa)->sin6_addr) || IN6_IS_ADDR_MC_NODELOCAL(&satosin6(sa)->sin6_addr))) { *(u_int16_t *)&satosin6(sa)->sin6_addr.s6_addr[2] = htons(satosin6(sa)->sin6_scope_id); satosin6(sa)->sin6_scope_id = 0; } #endif memcpy(&prefix, sa, salen); /* adjust header */ hdr.rtm_addrs |= RTA_DST; hdr.rtm_msglen += ROUNDUP(salen); /* adjust iovec */ iov[iovcnt].iov_base = &prefix; iov[iovcnt++].iov_len = ROUNDUP(salen); /* XXX can we even have no nexthop ??? */ if (kf->nexthop.aid != AID_UNSPEC) { memset(&nexthop, 0, sizeof(nexthop)); sa = addr2sa(&kf->nexthop, 0, &salen); sa->sa_len = salen; #ifdef __KAME__ /* XXX need to embed the stupid scope for now */ if (sa->sa_family == AF_INET6 && (IN6_IS_ADDR_LINKLOCAL(&satosin6(sa)->sin6_addr) || IN6_IS_ADDR_MC_LINKLOCAL(&satosin6(sa)->sin6_addr) || IN6_IS_ADDR_MC_NODELOCAL(&satosin6(sa)->sin6_addr))) { *(u_int16_t *)&satosin6(sa)->sin6_addr.s6_addr[2] = htons(satosin6(sa)->sin6_scope_id); satosin6(sa)->sin6_scope_id = 0; } #endif memcpy(&nexthop, sa, salen); /* adjust header */ hdr.rtm_flags |= RTF_GATEWAY; hdr.rtm_addrs |= RTA_GATEWAY; hdr.rtm_msglen += ROUNDUP(salen); /* adjust iovec */ iov[iovcnt].iov_base = &nexthop; iov[iovcnt++].iov_len = ROUNDUP(salen); } memset(&netmask, 0, sizeof(netmask)); memset(&netmask.v6, 0xff, sizeof(netmask.v6)); netmask.aid = kf->prefix.aid; applymask(&netmask, &netmask, kf->prefixlen); memset(&mask, 0, sizeof(mask)); sa = addr2sa(&netmask, 0, &salen); sa->sa_len = salen; memcpy(&mask, sa, salen); /* adjust header */ hdr.rtm_addrs |= RTA_NETMASK; hdr.rtm_msglen += ROUNDUP(salen); /* adjust iovec */ iov[iovcnt].iov_base = &mask; iov[iovcnt++].iov_len = ROUNDUP(salen); if (kf->flags & F_MPLS) { /* need to force interface for mpe(4) routes */ memset(&ifp, 0, sizeof(ifp)); dl = (struct sockaddr_dl *)&ifp; salen = sizeof(*dl); dl->sdl_len = salen; dl->sdl_family = AF_LINK; dl->sdl_index = kf->ifindex; /* adjust header */ hdr.rtm_addrs |= RTA_IFP; hdr.rtm_msglen += ROUNDUP(salen); /* adjust iovec */ iov[iovcnt].iov_base = &ifp; iov[iovcnt++].iov_len = ROUNDUP(salen); memset(&mpls, 0, sizeof(mpls)); mp = (struct sockaddr_mpls *)&mpls; salen = sizeof(*mp); mp->smpls_len = salen; mp->smpls_family = AF_MPLS; mp->smpls_label = kf->mplslabel; /* adjust header */ hdr.rtm_flags |= RTF_MPLS; hdr.rtm_mpls = MPLS_OP_PUSH; hdr.rtm_addrs |= RTA_SRC; hdr.rtm_msglen += ROUNDUP(salen); /* clear gateway flag since this is for mpe(4) */ hdr.rtm_flags &= ~RTF_GATEWAY; /* adjust iovec */ iov[iovcnt].iov_base = &mpls; iov[iovcnt++].iov_len = ROUNDUP(salen); } if (kf->label[0] != '\0') { memset(&label, 0, sizeof(label)); la = (struct sockaddr_rtlabel *)&label; salen = sizeof(struct sockaddr_rtlabel); label.ss_len = salen; strlcpy(la->sr_label, kf->label, sizeof(la->sr_label)); /* adjust header */ hdr.rtm_addrs |= RTA_LABEL; hdr.rtm_msglen += ROUNDUP(salen); /* adjust iovec */ iov[iovcnt].iov_base = &label; iov[iovcnt++].iov_len = ROUNDUP(salen); } retry: if (writev(kr_state.fd, iov, iovcnt) == -1) { if (errno == ESRCH) { if (hdr.rtm_type == RTM_CHANGE) { hdr.rtm_type = RTM_ADD; goto retry; } else if (hdr.rtm_type == RTM_DELETE) { log_info("route %s/%u vanished before delete", log_addr(&kf->prefix), kf->prefixlen); return (1); } } log_warn("%s: action %u, prefix %s/%u", __func__, hdr.rtm_type, log_addr(&kf->prefix), kf->prefixlen); return (0); } return (1); } int fetchtable(struct ktable *kt) { size_t len; int mib[7]; char *buf = NULL, *next, *lim; struct rt_msghdr *rtm; struct kroute_full kf; mib[0] = CTL_NET; mib[1] = PF_ROUTE; mib[2] = 0; mib[3] = 0; mib[4] = NET_RT_DUMP; mib[5] = 0; mib[6] = kt->rtableid; if (sysctl(mib, 7, NULL, &len, NULL, 0) == -1) { if (kt->rtableid != 0 && errno == EINVAL) /* table nonexistent */ return (0); log_warn("%s: sysctl", __func__); return (-1); } if (len > 0) { if ((buf = malloc(len)) == NULL) { log_warn("%s", __func__); return (-1); } if (sysctl(mib, 7, buf, &len, NULL, 0) == -1) { log_warn("%s: sysctl2", __func__); free(buf); return (-1); } } lim = buf + len; for (next = buf; next < lim; next += rtm->rtm_msglen) { rtm = (struct rt_msghdr *)next; if (rtm->rtm_version != RTM_VERSION) continue; if (dispatch_rtmsg_addr(rtm, &kf) == -1) continue; if (kf.priority == RTP_MINE) send_rtmsg(RTM_DELETE, kt, &kf); else kroute_insert(kt, &kf); } free(buf); return (0); } int fetchifs(int ifindex) { size_t len; int mib[6]; char *buf, *next, *lim; struct if_msghdr ifm; struct kif *kif; struct sockaddr *sa, *rti_info[RTAX_MAX]; struct sockaddr_dl *sdl; mib[0] = CTL_NET; mib[1] = PF_ROUTE; mib[2] = 0; mib[3] = AF_INET; /* AF does not matter but AF_INET is shorter */ mib[4] = NET_RT_IFLIST; mib[5] = ifindex; if (sysctl(mib, 6, NULL, &len, NULL, 0) == -1) { log_warn("%s: sysctl", __func__); return (-1); } if ((buf = malloc(len)) == NULL) { log_warn("%s", __func__); return (-1); } if (sysctl(mib, 6, buf, &len, NULL, 0) == -1) { log_warn("%s: sysctl2", __func__); free(buf); return (-1); } lim = buf + len; for (next = buf; next < lim; next += ifm.ifm_msglen) { memcpy(&ifm, next, sizeof(ifm)); if (ifm.ifm_version != RTM_VERSION) continue; if (ifm.ifm_type != RTM_IFINFO) continue; sa = (struct sockaddr *)(next + sizeof(ifm)); get_rtaddrs(ifm.ifm_addrs, sa, rti_info); if ((kif = calloc(1, sizeof(*kif))) == NULL) { log_warn("%s", __func__); free(buf); return (-1); } kif->ifindex = ifm.ifm_index; kif->flags = ifm.ifm_flags; kif->link_state = ifm.ifm_data.ifi_link_state; kif->if_type = ifm.ifm_data.ifi_type; kif->rdomain = ifm.ifm_data.ifi_rdomain; kif->baudrate = ifm.ifm_data.ifi_baudrate; kif->nh_reachable = kif_validate(kif); kif->depend_state = kif_depend_state(kif); if ((sa = rti_info[RTAX_IFP]) != NULL) if (sa->sa_family == AF_LINK) { sdl = (struct sockaddr_dl *)sa; if (sdl->sdl_nlen >= sizeof(kif->ifname)) memcpy(kif->ifname, sdl->sdl_data, sizeof(kif->ifname) - 1); else if (sdl->sdl_nlen > 0) memcpy(kif->ifname, sdl->sdl_data, sdl->sdl_nlen); /* string already terminated via calloc() */ } kif_insert(kif); } free(buf); return (0); } int dispatch_rtmsg(void) { char buf[RT_BUF_SIZE]; ssize_t n; char *next, *lim; struct rt_msghdr *rtm; struct if_msghdr ifm; struct kroute_full kf; struct ktable *kt; int mpath = 0; if ((n = read(kr_state.fd, &buf, sizeof(buf))) == -1) { if (errno == EAGAIN || errno == EINTR) return (0); log_warn("%s: read error", __func__); return (-1); } if (n == 0) { log_warnx("routing socket closed"); return (-1); } lim = buf + n; for (next = buf; next < lim; next += rtm->rtm_msglen) { rtm = (struct rt_msghdr *)next; if (lim < next + sizeof(u_short) || lim < next + rtm->rtm_msglen) fatalx("%s: partial rtm in buffer", __func__); if (rtm->rtm_version != RTM_VERSION) continue; switch (rtm->rtm_type) { case RTM_ADD: case RTM_CHANGE: case RTM_DELETE: if (rtm->rtm_pid == kr_state.pid) /* cause by us */ continue; /* failed attempts */ if (rtm->rtm_errno || !(rtm->rtm_flags & RTF_DONE)) continue; if ((kt = ktable_get(rtm->rtm_tableid)) == NULL) continue; if (dispatch_rtmsg_addr(rtm, &kf) == -1) continue; if (rtm->rtm_flags & RTF_MPATH) mpath = 1; switch (rtm->rtm_type) { case RTM_ADD: case RTM_CHANGE: if (kr_fib_change(kt, &kf, rtm->rtm_type, mpath) == -1) return -1; break; case RTM_DELETE: if (kr_fib_delete(kt, &kf, mpath) == -1) return -1; break; } break; case RTM_IFINFO: memcpy(&ifm, next, sizeof(ifm)); if_change(ifm.ifm_index, ifm.ifm_flags, &ifm.ifm_data); break; case RTM_IFANNOUNCE: if_announce(next); break; default: /* ignore for now */ break; } } return (0); } int dispatch_rtmsg_addr(struct rt_msghdr *rtm, struct kroute_full *kf) { struct sockaddr *sa, *rti_info[RTAX_MAX]; struct sockaddr_in *sa_in; struct sockaddr_in6 *sa_in6; struct sockaddr_rtlabel *label; sa = (struct sockaddr *)((char *)rtm + rtm->rtm_hdrlen); get_rtaddrs(rtm->rtm_addrs, sa, rti_info); /* Skip ARP/ND cache, broadcast and dynamic routes. */ if (rtm->rtm_flags & (RTF_LLINFO|RTF_BROADCAST|RTF_DYNAMIC)) return (-1); if ((sa = rti_info[RTAX_DST]) == NULL) { log_warnx("route message without destination"); return (-1); } memset(kf, 0, sizeof(*kf)); if (rtm->rtm_flags & RTF_STATIC) kf->flags |= F_STATIC; if (rtm->rtm_flags & RTF_BLACKHOLE) kf->flags |= F_BLACKHOLE; if (rtm->rtm_flags & RTF_REJECT) kf->flags |= F_REJECT; /* adjust priority here */ if (rtm->rtm_priority == kr_state.fib_prio) kf->priority = RTP_MINE; else kf->priority = rtm->rtm_priority; label = (struct sockaddr_rtlabel *)rti_info[RTAX_LABEL]; if (label != NULL) if (strlcpy(kf->label, label->sr_label, sizeof(kf->label)) >= sizeof(kf->label)) fatalx("rtm label overflow"); sa2addr(sa, &kf->prefix, NULL); switch (sa->sa_family) { case AF_INET: sa_in = (struct sockaddr_in *)rti_info[RTAX_NETMASK]; if (sa_in != NULL) { if (sa_in->sin_len != 0) kf->prefixlen = mask2prefixlen(sa_in->sin_addr.s_addr); } else if (rtm->rtm_flags & RTF_HOST) kf->prefixlen = 32; else kf->prefixlen = prefixlen_classful(kf->prefix.v4.s_addr); break; case AF_INET6: sa_in6 = (struct sockaddr_in6 *)rti_info[RTAX_NETMASK]; if (sa_in6 != NULL) { if (sa_in6->sin6_len != 0) kf->prefixlen = mask2prefixlen6(sa_in6); } else if (rtm->rtm_flags & RTF_HOST) kf->prefixlen = 128; else fatalx("in6 net addr without netmask"); break; default: return (-1); } if ((sa = rti_info[RTAX_GATEWAY]) == NULL) { log_warnx("route %s/%u without gateway", log_addr(&kf->prefix), kf->prefixlen); return (-1); } kf->ifindex = rtm->rtm_index; if (rtm->rtm_flags & RTF_GATEWAY) { switch (sa->sa_family) { case AF_LINK: kf->flags |= F_CONNECTED; break; case AF_INET: case AF_INET6: sa2addr(rti_info[RTAX_GATEWAY], &kf->nexthop, NULL); break; } } else { kf->flags |= F_CONNECTED; } return (0); } int kr_fib_delete(struct ktable *kt, struct kroute_full *kf, int mpath) { return kroute_remove(kt, kf, !mpath); } int kr_fib_change(struct ktable *kt, struct kroute_full *kf, int type, int mpath) { struct kroute *kr; struct kroute6 *kr6; int flags, oflags; int changed = 0, rtlabel_changed = 0; uint16_t new_labelid; flags = kf->flags; switch (kf->prefix.aid) { case AID_INET: if ((kr = kroute_find(kt, &kf->prefix, kf->prefixlen, kf->priority)) != NULL) { if (!(kf->flags & F_BGPD)) { /* get the correct route */ if (mpath && type == RTM_CHANGE && (kr = kroute_matchgw(kr, kf)) == NULL) { log_warnx("%s[change]: " "mpath route not found", __func__); goto add4; } else if (mpath && type == RTM_ADD) goto add4; if (kf->nexthop.aid == AID_INET) { if (kr->nexthop.s_addr != kf->nexthop.v4.s_addr) changed = 1; kr->nexthop.s_addr = kf->nexthop.v4.s_addr; kr->ifindex = kf->ifindex; } else { if (kr->nexthop.s_addr != 0) changed = 1; kr->nexthop.s_addr = 0; kr->ifindex = kf->ifindex; } if (kr->flags & F_NEXTHOP) flags |= F_NEXTHOP; new_labelid = rtlabel_name2id(kf->label); if (kr->labelid != new_labelid) { rtlabel_unref(kr->labelid); kr->labelid = new_labelid; rtlabel_changed = 1; } oflags = kr->flags; if (flags != oflags) changed = 1; kr->flags = flags; if (rtlabel_changed) kr_redistribute(IMSG_NETWORK_ADD, kt, kr_tofull(kr)); if ((oflags & F_CONNECTED) && !(flags & F_CONNECTED)) kr_redistribute(IMSG_NETWORK_ADD, kt, kr_tofull(kr)); if ((flags & F_CONNECTED) && !(oflags & F_CONNECTED)) kr_redistribute(IMSG_NETWORK_ADD, kt, kr_tofull(kr)); if (kr->flags & F_NEXTHOP && changed) knexthop_update(kt, kf); } else { kr->flags &= ~F_BGPD_INSERTED; } } else { add4: kroute_insert(kt, kf); } break; case AID_INET6: if ((kr6 = kroute6_find(kt, &kf->prefix, kf->prefixlen, kf->priority)) != NULL) { if (!(kf->flags & F_BGPD)) { /* get the correct route */ if (mpath && type == RTM_CHANGE && (kr6 = kroute6_matchgw(kr6, kf)) == NULL) { log_warnx("%s[change]: IPv6 mpath " "route not found", __func__); goto add6; } else if (mpath && type == RTM_ADD) goto add6; if (kf->nexthop.aid == AID_INET6) { if (memcmp(&kr6->nexthop, &kf->nexthop.v6, sizeof(struct in6_addr)) || kr6->nexthop_scope_id != kf->nexthop.scope_id) changed = 1; kr6->nexthop = kf->nexthop.v6; kr6->nexthop_scope_id = kf->nexthop.scope_id; kr6->ifindex = kf->ifindex; } else { if (memcmp(&kr6->nexthop, &in6addr_any, sizeof(struct in6_addr))) changed = 1; kr6->nexthop = in6addr_any; kr6->nexthop_scope_id = 0; kr6->ifindex = kf->ifindex; } if (kr6->flags & F_NEXTHOP) flags |= F_NEXTHOP; new_labelid = rtlabel_name2id(kf->label); if (kr6->labelid != new_labelid) { rtlabel_unref(kr6->labelid); kr6->labelid = new_labelid; rtlabel_changed = 1; } oflags = kr6->flags; if (flags != oflags) changed = 1; kr6->flags = flags; if (rtlabel_changed) kr_redistribute(IMSG_NETWORK_ADD, kt, kr6_tofull(kr6)); if ((oflags & F_CONNECTED) && !(flags & F_CONNECTED)) kr_redistribute(IMSG_NETWORK_ADD, kt, kr6_tofull(kr6)); if ((flags & F_CONNECTED) && !(oflags & F_CONNECTED)) kr_redistribute(IMSG_NETWORK_ADD, kt, kr6_tofull(kr6)); if (kr6->flags & F_NEXTHOP && changed) knexthop_update(kt, kf); } else { kr6->flags &= ~F_BGPD_INSERTED; } } else { add6: kroute_insert(kt, kf); } break; } return (0); }