/* $OpenBSD: session.c,v 1.370 2018/10/22 07:46:55 claudio Exp $ */ /* * Copyright (c) 2003, 2004, 2005 Henning Brauer * Copyright (c) 2017 Peter van Dijk * * 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 #include "bgpd.h" #include "mrt.h" #include "session.h" #include "log.h" #define PFD_PIPE_MAIN 0 #define PFD_PIPE_ROUTE 1 #define PFD_PIPE_ROUTE_CTL 2 #define PFD_SOCK_CTL 3 #define PFD_SOCK_RCTL 4 #define PFD_SOCK_PFKEY 5 #define PFD_LISTENERS_START 6 void session_sighdlr(int); int setup_listeners(u_int *); void init_conf(struct bgpd_config *); void init_peer(struct peer *); void start_timer_holdtime(struct peer *); void start_timer_keepalive(struct peer *); void session_close_connection(struct peer *); void change_state(struct peer *, enum session_state, enum session_events); int session_setup_socket(struct peer *); void session_accept(int); int session_connect(struct peer *); void session_tcp_established(struct peer *); void session_capa_ann_none(struct peer *); int session_capa_add(struct ibuf *, u_int8_t, u_int8_t); int session_capa_add_mp(struct ibuf *, u_int8_t); int session_capa_add_gr(struct peer *, struct ibuf *, u_int8_t); struct bgp_msg *session_newmsg(enum msg_type, u_int16_t); int session_sendmsg(struct bgp_msg *, struct peer *); void session_open(struct peer *); void session_keepalive(struct peer *); void session_update(u_int32_t, void *, size_t); void session_notification(struct peer *, u_int8_t, u_int8_t, void *, ssize_t); void session_rrefresh(struct peer *, u_int8_t); int session_graceful_restart(struct peer *); int session_graceful_stop(struct peer *); int session_dispatch_msg(struct pollfd *, struct peer *); int session_process_msg(struct peer *); int parse_header(struct peer *, u_char *, u_int16_t *, u_int8_t *); int parse_open(struct peer *); int parse_update(struct peer *); int parse_refresh(struct peer *); int parse_notification(struct peer *); int parse_capabilities(struct peer *, u_char *, u_int16_t, u_int32_t *); int capa_neg_calc(struct peer *); void session_dispatch_imsg(struct imsgbuf *, int, u_int *); void session_up(struct peer *); void session_down(struct peer *); int imsg_rde(int, u_int32_t, void *, u_int16_t); void session_demote(struct peer *, int); int session_link_state_is_up(int, int, int); int la_cmp(struct listen_addr *, struct listen_addr *); struct peer *getpeerbyip(struct sockaddr *); void session_template_clone(struct peer *, struct sockaddr *, u_int32_t, u_int32_t); int session_match_mask(struct peer *, struct bgpd_addr *); struct peer *getpeerbyid(u_int32_t); struct bgpd_config *conf, *nconf; struct bgpd_sysdep sysdep; struct peer *peers, *npeers; volatile sig_atomic_t session_quit; int pending_reconf; int csock = -1, rcsock = -1; u_int peer_cnt; struct imsgbuf *ibuf_rde; struct imsgbuf *ibuf_rde_ctl; struct imsgbuf *ibuf_main; struct mrt_head mrthead; time_t pauseaccept; void session_sighdlr(int sig) { switch (sig) { case SIGINT: case SIGTERM: session_quit = 1; break; } } int setup_listeners(u_int *la_cnt) { int ttl = 255; int opt; struct listen_addr *la; u_int cnt = 0; TAILQ_FOREACH(la, conf->listen_addrs, entry) { la->reconf = RECONF_NONE; cnt++; if (la->flags & LISTENER_LISTENING) continue; if (la->fd == -1) { log_warn("cannot establish listener on %s: invalid fd", log_sockaddr((struct sockaddr *)&la->sa)); continue; } opt = 1; if (setsockopt(la->fd, IPPROTO_TCP, TCP_MD5SIG, &opt, sizeof(opt)) == -1) { if (errno == ENOPROTOOPT) { /* system w/o md5sig */ log_warnx("md5sig not available, disabling"); sysdep.no_md5sig = 1; } else fatal("setsockopt TCP_MD5SIG"); } /* set ttl to 255 so that ttl-security works */ if (la->sa.ss_family == AF_INET && setsockopt(la->fd, IPPROTO_IP, IP_TTL, &ttl, sizeof(ttl)) == -1) { log_warn("setup_listeners setsockopt TTL"); continue; } if (la->sa.ss_family == AF_INET6 && setsockopt(la->fd, IPPROTO_IPV6, IPV6_UNICAST_HOPS, &ttl, sizeof(ttl)) == -1) { log_warn("setup_listeners setsockopt hoplimit"); continue; } if (listen(la->fd, MAX_BACKLOG)) { close(la->fd); fatal("listen"); } la->flags |= LISTENER_LISTENING; log_info("listening on %s", log_sockaddr((struct sockaddr *)&la->sa)); } *la_cnt = cnt; return (0); } void session_main(int debug, int verbose) { int timeout, pfkeysock; unsigned int i, j, idx_peers, idx_listeners, idx_mrts; u_int pfd_elms = 0, peer_l_elms = 0, mrt_l_elms = 0; u_int listener_cnt, ctl_cnt, mrt_cnt; u_int new_cnt; struct passwd *pw; struct peer *p, **peer_l = NULL, *last, *next; struct mrt *m, *xm, **mrt_l = NULL; struct pollfd *pfd = NULL; struct ctl_conn *ctl_conn; struct listen_addr *la; void *newp; short events; log_init(debug, LOG_DAEMON); log_setverbose(verbose); bgpd_process = PROC_SE; log_procinit(log_procnames[bgpd_process]); if ((pw = getpwnam(BGPD_USER)) == NULL) fatal(NULL); if (chroot(pw->pw_dir) == -1) fatal("chroot"); if (chdir("/") == -1) fatal("chdir(\"/\")"); setproctitle("session engine"); pfkeysock = pfkey_init(&sysdep); if (setgroups(1, &pw->pw_gid) || setresgid(pw->pw_gid, pw->pw_gid, pw->pw_gid) || setresuid(pw->pw_uid, pw->pw_uid, pw->pw_uid)) fatal("can't drop privileges"); if (pledge("stdio inet recvfd", NULL) == -1) fatal("pledge"); signal(SIGTERM, session_sighdlr); signal(SIGINT, session_sighdlr); signal(SIGPIPE, SIG_IGN); signal(SIGHUP, SIG_IGN); signal(SIGALRM, SIG_IGN); signal(SIGUSR1, SIG_IGN); if ((ibuf_main = malloc(sizeof(struct imsgbuf))) == NULL) fatal(NULL); imsg_init(ibuf_main, 3); TAILQ_INIT(&ctl_conns); LIST_INIT(&mrthead); listener_cnt = 0; peer_cnt = 0; ctl_cnt = 0; if ((conf = calloc(1, sizeof(struct bgpd_config))) == NULL) fatal(NULL); if ((conf->listen_addrs = calloc(1, sizeof(struct listen_addrs))) == NULL) fatal(NULL); TAILQ_INIT(conf->listen_addrs); log_info("session engine ready"); while (session_quit == 0) { /* check for peers to be initialized or deleted */ last = NULL; if (!pending_reconf) { for (p = peers; p != NULL; p = next) { next = p->next; /* cloned peer that idled out? */ if (p->template && (p->state == STATE_IDLE || p->state == STATE_ACTIVE) && time(NULL) - p->stats.last_updown >= INTERVAL_HOLD_CLONED) p->conf.reconf_action = RECONF_DELETE; /* new peer that needs init? */ if (p->state == STATE_NONE) init_peer(p); /* reinit due? */ if (p->conf.reconf_action == RECONF_REINIT) { session_stop(p, ERR_CEASE_ADMIN_RESET); if (!p->conf.down) timer_set(p, Timer_IdleHold, 0); } /* deletion due? */ if (p->conf.reconf_action == RECONF_DELETE) { if (p->demoted) session_demote(p, -1); p->conf.demote_group[0] = 0; session_stop(p, ERR_CEASE_PEER_UNCONF); log_peer_warnx(&p->conf, "removed"); if (last != NULL) last->next = next; else peers = next; timer_remove_all(p); free(p); peer_cnt--; continue; } p->conf.reconf_action = RECONF_NONE; last = p; } } if (peer_cnt > peer_l_elms) { if ((newp = reallocarray(peer_l, peer_cnt, sizeof(struct peer *))) == NULL) { /* panic for now */ log_warn("could not resize peer_l from %u -> %u" " entries", peer_l_elms, peer_cnt); fatalx("exiting"); } peer_l = newp; peer_l_elms = peer_cnt; } mrt_cnt = 0; for (m = LIST_FIRST(&mrthead); m != NULL; m = xm) { xm = LIST_NEXT(m, entry); if (m->state == MRT_STATE_REMOVE) { mrt_clean(m); LIST_REMOVE(m, entry); free(m); continue; } if (m->wbuf.queued) mrt_cnt++; } if (mrt_cnt > mrt_l_elms) { if ((newp = reallocarray(mrt_l, mrt_cnt, sizeof(struct mrt *))) == NULL) { /* panic for now */ log_warn("could not resize mrt_l from %u -> %u" " entries", mrt_l_elms, mrt_cnt); fatalx("exiting"); } mrt_l = newp; mrt_l_elms = mrt_cnt; } new_cnt = PFD_LISTENERS_START + listener_cnt + peer_cnt + ctl_cnt + mrt_cnt; if (new_cnt > pfd_elms) { if ((newp = reallocarray(pfd, new_cnt, sizeof(struct pollfd))) == NULL) { /* panic for now */ log_warn("could not resize pfd from %u -> %u" " entries", pfd_elms, new_cnt); fatalx("exiting"); } pfd = newp; pfd_elms = new_cnt; } bzero(pfd, sizeof(struct pollfd) * pfd_elms); set_pollfd(&pfd[PFD_PIPE_MAIN], ibuf_main); set_pollfd(&pfd[PFD_PIPE_ROUTE], ibuf_rde); set_pollfd(&pfd[PFD_PIPE_ROUTE_CTL], ibuf_rde_ctl); if (pauseaccept == 0) { pfd[PFD_SOCK_CTL].fd = csock; pfd[PFD_SOCK_CTL].events = POLLIN; pfd[PFD_SOCK_RCTL].fd = rcsock; pfd[PFD_SOCK_RCTL].events = POLLIN; } else { pfd[PFD_SOCK_CTL].fd = -1; pfd[PFD_SOCK_RCTL].fd = -1; } pfd[PFD_SOCK_PFKEY].fd = pfkeysock; pfd[PFD_SOCK_PFKEY].events = POLLIN; i = PFD_LISTENERS_START; TAILQ_FOREACH(la, conf->listen_addrs, entry) { if (pauseaccept == 0) { pfd[i].fd = la->fd; pfd[i].events = POLLIN; } else pfd[i].fd = -1; i++; } idx_listeners = i; timeout = 240; /* loop every 240s at least */ for (p = peers; p != NULL; p = p->next) { time_t nextaction; struct peer_timer *pt; /* check timers */ if ((pt = timer_nextisdue(p)) != NULL) { switch (pt->type) { case Timer_Hold: bgp_fsm(p, EVNT_TIMER_HOLDTIME); break; case Timer_ConnectRetry: bgp_fsm(p, EVNT_TIMER_CONNRETRY); break; case Timer_Keepalive: bgp_fsm(p, EVNT_TIMER_KEEPALIVE); break; case Timer_IdleHold: bgp_fsm(p, EVNT_START); break; case Timer_IdleHoldReset: p->IdleHoldTime /= 2; if (p->IdleHoldTime <= INTERVAL_IDLE_HOLD_INITIAL) { p->IdleHoldTime = INTERVAL_IDLE_HOLD_INITIAL; timer_stop(p, Timer_IdleHoldReset); p->errcnt = 0; } else timer_set(p, Timer_IdleHoldReset, p->IdleHoldTime); break; case Timer_CarpUndemote: timer_stop(p, Timer_CarpUndemote); if (p->demoted && p->state == STATE_ESTABLISHED) session_demote(p, -1); break; case Timer_RestartTimeout: timer_stop(p, Timer_RestartTimeout); session_graceful_stop(p); break; default: fatalx("King Bula lost in time"); } } if ((nextaction = timer_nextduein(p)) != -1 && nextaction < timeout) timeout = nextaction; /* are we waiting for a write? */ events = POLLIN; if (p->wbuf.queued > 0 || p->state == STATE_CONNECT) events |= POLLOUT; /* is there still work to do? */ if (p->rbuf && p->rbuf->wpos) timeout = 0; /* poll events */ if (p->fd != -1 && events != 0) { pfd[i].fd = p->fd; pfd[i].events = events; peer_l[i - idx_listeners] = p; i++; } } idx_peers = i; LIST_FOREACH(m, &mrthead, entry) if (m->wbuf.queued) { pfd[i].fd = m->wbuf.fd; pfd[i].events = POLLOUT; mrt_l[i - idx_peers] = m; i++; } idx_mrts = i; TAILQ_FOREACH(ctl_conn, &ctl_conns, entry) { pfd[i].fd = ctl_conn->ibuf.fd; pfd[i].events = POLLIN; if (ctl_conn->ibuf.w.queued > 0) pfd[i].events |= POLLOUT; i++; } if (pauseaccept && timeout > 1) timeout = 1; if (timeout < 0) timeout = 0; if (poll(pfd, i, timeout * 1000) == -1) if (errno != EINTR) fatal("poll error"); /* * If we previously saw fd exhaustion, we stop accept() * for 1 second to throttle the accept() loop. */ if (pauseaccept && getmonotime() > pauseaccept + 1) pauseaccept = 0; if (handle_pollfd(&pfd[PFD_PIPE_MAIN], ibuf_main) == -1) { log_warnx("SE: Lost connection to parent"); session_quit = 1; continue; } else session_dispatch_imsg(ibuf_main, PFD_PIPE_MAIN, &listener_cnt); if (handle_pollfd(&pfd[PFD_PIPE_ROUTE], ibuf_rde) == -1) { log_warnx("SE: Lost connection to RDE"); msgbuf_clear(&ibuf_rde->w); free(ibuf_rde); ibuf_rde = NULL; } else session_dispatch_imsg(ibuf_rde, PFD_PIPE_ROUTE, &listener_cnt); if (handle_pollfd(&pfd[PFD_PIPE_ROUTE_CTL], ibuf_rde_ctl) == -1) { log_warnx("SE: Lost connection to RDE control"); msgbuf_clear(&ibuf_rde_ctl->w); free(ibuf_rde_ctl); ibuf_rde_ctl = NULL; } else session_dispatch_imsg(ibuf_rde_ctl, PFD_PIPE_ROUTE_CTL, &listener_cnt); if (pfd[PFD_SOCK_CTL].revents & POLLIN) ctl_cnt += control_accept(csock, 0); if (pfd[PFD_SOCK_RCTL].revents & POLLIN) ctl_cnt += control_accept(rcsock, 1); if (pfd[PFD_SOCK_PFKEY].revents & POLLIN) { if (pfkey_read(pfkeysock, NULL) == -1) { log_warnx("pfkey_read failed, exiting..."); session_quit = 1; } } for (j = PFD_LISTENERS_START; j < idx_listeners; j++) if (pfd[j].revents & POLLIN) session_accept(pfd[j].fd); for (; j < idx_peers; j++) session_dispatch_msg(&pfd[j], peer_l[j - idx_listeners]); for (p = peers; p != NULL; p = p->next) if (p->rbuf && p->rbuf->wpos) session_process_msg(p); for (; j < idx_mrts; j++) if (pfd[j].revents & POLLOUT) mrt_write(mrt_l[j - idx_peers]); for (; j < i; j++) control_dispatch_msg(&pfd[j], &ctl_cnt); } while ((p = peers) != NULL) { peers = p->next; strlcpy(p->conf.shutcomm, "bgpd shutting down", sizeof(p->conf.shutcomm)); session_stop(p, ERR_CEASE_ADMIN_DOWN); pfkey_remove(p); free(p); } while ((m = LIST_FIRST(&mrthead)) != NULL) { mrt_clean(m); LIST_REMOVE(m, entry); free(m); } while ((la = TAILQ_FIRST(conf->listen_addrs)) != NULL) { TAILQ_REMOVE(conf->listen_addrs, la, entry); free(la); } free(conf->listen_addrs); free(peer_l); free(mrt_l); free(pfd); /* close pipes */ if (ibuf_rde) { msgbuf_write(&ibuf_rde->w); msgbuf_clear(&ibuf_rde->w); close(ibuf_rde->fd); free(ibuf_rde); } if (ibuf_rde_ctl) { msgbuf_clear(&ibuf_rde_ctl->w); close(ibuf_rde_ctl->fd); free(ibuf_rde_ctl); } msgbuf_write(&ibuf_main->w); msgbuf_clear(&ibuf_main->w); close(ibuf_main->fd); free(ibuf_main); control_shutdown(csock); control_shutdown(rcsock); log_info("session engine exiting"); exit(0); } void init_conf(struct bgpd_config *c) { if (!c->holdtime) c->holdtime = INTERVAL_HOLD; if (!c->connectretry) c->connectretry = INTERVAL_CONNECTRETRY; } void init_peer(struct peer *p) { TAILQ_INIT(&p->timers); p->fd = p->wbuf.fd = -1; if (p->conf.if_depend[0]) imsg_compose(ibuf_main, IMSG_IFINFO, 0, 0, -1, p->conf.if_depend, sizeof(p->conf.if_depend)); else p->depend_ok = 1; peer_cnt++; change_state(p, STATE_IDLE, EVNT_NONE); if (p->conf.down) timer_stop(p, Timer_IdleHold); /* no autostart */ else timer_set(p, Timer_IdleHold, 0); /* start ASAP */ /* * on startup, demote if requested. * do not handle new peers. they must reach ESTABLISHED beforehands. * peers added at runtime have reconf_action set to RECONF_REINIT. */ if (p->conf.reconf_action != RECONF_REINIT && p->conf.demote_group[0]) session_demote(p, +1); } void bgp_fsm(struct peer *peer, enum session_events event) { switch (peer->state) { case STATE_NONE: /* nothing */ break; case STATE_IDLE: switch (event) { case EVNT_START: timer_stop(peer, Timer_Hold); timer_stop(peer, Timer_Keepalive); timer_stop(peer, Timer_IdleHold); /* allocate read buffer */ peer->rbuf = calloc(1, sizeof(struct ibuf_read)); if (peer->rbuf == NULL) fatal(NULL); /* init write buffer */ msgbuf_init(&peer->wbuf); /* init pfkey - remove old if any, load new ones */ pfkey_remove(peer); if (pfkey_establish(peer) == -1) { log_peer_warnx(&peer->conf, "pfkey setup failed"); return; } peer->stats.last_sent_errcode = 0; peer->stats.last_sent_suberr = 0; if (!peer->depend_ok) timer_stop(peer, Timer_ConnectRetry); else if (peer->passive || peer->conf.passive || peer->conf.template) { change_state(peer, STATE_ACTIVE, event); timer_stop(peer, Timer_ConnectRetry); } else { change_state(peer, STATE_CONNECT, event); timer_set(peer, Timer_ConnectRetry, conf->connectretry); session_connect(peer); } peer->passive = 0; break; default: /* ignore */ break; } break; case STATE_CONNECT: switch (event) { case EVNT_START: /* ignore */ break; case EVNT_CON_OPEN: session_tcp_established(peer); session_open(peer); timer_stop(peer, Timer_ConnectRetry); peer->holdtime = INTERVAL_HOLD_INITIAL; start_timer_holdtime(peer); change_state(peer, STATE_OPENSENT, event); break; case EVNT_CON_OPENFAIL: timer_set(peer, Timer_ConnectRetry, conf->connectretry); session_close_connection(peer); change_state(peer, STATE_ACTIVE, event); break; case EVNT_TIMER_CONNRETRY: timer_set(peer, Timer_ConnectRetry, conf->connectretry); session_connect(peer); break; default: change_state(peer, STATE_IDLE, event); break; } break; case STATE_ACTIVE: switch (event) { case EVNT_START: /* ignore */ break; case EVNT_CON_OPEN: session_tcp_established(peer); session_open(peer); timer_stop(peer, Timer_ConnectRetry); peer->holdtime = INTERVAL_HOLD_INITIAL; start_timer_holdtime(peer); change_state(peer, STATE_OPENSENT, event); break; case EVNT_CON_OPENFAIL: timer_set(peer, Timer_ConnectRetry, conf->connectretry); session_close_connection(peer); change_state(peer, STATE_ACTIVE, event); break; case EVNT_TIMER_CONNRETRY: timer_set(peer, Timer_ConnectRetry, peer->holdtime); change_state(peer, STATE_CONNECT, event); session_connect(peer); break; default: change_state(peer, STATE_IDLE, event); break; } break; case STATE_OPENSENT: switch (event) { case EVNT_START: /* ignore */ break; case EVNT_STOP: change_state(peer, STATE_IDLE, event); break; case EVNT_CON_CLOSED: session_close_connection(peer); timer_set(peer, Timer_ConnectRetry, conf->connectretry); change_state(peer, STATE_ACTIVE, event); break; case EVNT_CON_FATAL: change_state(peer, STATE_IDLE, event); break; case EVNT_TIMER_HOLDTIME: session_notification(peer, ERR_HOLDTIMEREXPIRED, 0, NULL, 0); change_state(peer, STATE_IDLE, event); break; case EVNT_RCVD_OPEN: /* parse_open calls change_state itself on failure */ if (parse_open(peer)) break; session_keepalive(peer); change_state(peer, STATE_OPENCONFIRM, event); break; case EVNT_RCVD_NOTIFICATION: if (parse_notification(peer)) { change_state(peer, STATE_IDLE, event); /* don't punish, capa negotiation */ timer_set(peer, Timer_IdleHold, 0); peer->IdleHoldTime /= 2; } else change_state(peer, STATE_IDLE, event); break; default: session_notification(peer, ERR_FSM, ERR_FSM_UNEX_OPENSENT, NULL, 0); change_state(peer, STATE_IDLE, event); break; } break; case STATE_OPENCONFIRM: switch (event) { case EVNT_START: /* ignore */ break; case EVNT_STOP: change_state(peer, STATE_IDLE, event); break; case EVNT_CON_CLOSED: case EVNT_CON_FATAL: change_state(peer, STATE_IDLE, event); break; case EVNT_TIMER_HOLDTIME: session_notification(peer, ERR_HOLDTIMEREXPIRED, 0, NULL, 0); change_state(peer, STATE_IDLE, event); break; case EVNT_TIMER_KEEPALIVE: session_keepalive(peer); break; case EVNT_RCVD_KEEPALIVE: start_timer_holdtime(peer); change_state(peer, STATE_ESTABLISHED, event); break; case EVNT_RCVD_NOTIFICATION: parse_notification(peer); change_state(peer, STATE_IDLE, event); break; default: session_notification(peer, ERR_FSM, ERR_FSM_UNEX_OPENCONFIRM, NULL, 0); change_state(peer, STATE_IDLE, event); break; } break; case STATE_ESTABLISHED: switch (event) { case EVNT_START: /* ignore */ break; case EVNT_STOP: change_state(peer, STATE_IDLE, event); break; case EVNT_CON_CLOSED: case EVNT_CON_FATAL: change_state(peer, STATE_IDLE, event); break; case EVNT_TIMER_HOLDTIME: session_notification(peer, ERR_HOLDTIMEREXPIRED, 0, NULL, 0); change_state(peer, STATE_IDLE, event); break; case EVNT_TIMER_KEEPALIVE: session_keepalive(peer); break; case EVNT_RCVD_KEEPALIVE: start_timer_holdtime(peer); break; case EVNT_RCVD_UPDATE: start_timer_holdtime(peer); if (parse_update(peer)) change_state(peer, STATE_IDLE, event); else start_timer_holdtime(peer); break; case EVNT_RCVD_NOTIFICATION: parse_notification(peer); change_state(peer, STATE_IDLE, event); break; default: session_notification(peer, ERR_FSM, ERR_FSM_UNEX_ESTABLISHED, NULL, 0); change_state(peer, STATE_IDLE, event); break; } break; } } void start_timer_holdtime(struct peer *peer) { if (peer->holdtime > 0) timer_set(peer, Timer_Hold, peer->holdtime); else timer_stop(peer, Timer_Hold); } void start_timer_keepalive(struct peer *peer) { if (peer->holdtime > 0) timer_set(peer, Timer_Keepalive, peer->holdtime / 3); else timer_stop(peer, Timer_Keepalive); } void session_close_connection(struct peer *peer) { if (peer->fd != -1) { close(peer->fd); pauseaccept = 0; } peer->fd = peer->wbuf.fd = -1; } void change_state(struct peer *peer, enum session_state state, enum session_events event) { struct mrt *mrt; switch (state) { case STATE_IDLE: /* carp demotion first. new peers handled in init_peer */ if (peer->state == STATE_ESTABLISHED && peer->conf.demote_group[0] && !peer->demoted) session_demote(peer, +1); /* * try to write out what's buffered (maybe a notification), * don't bother if it fails */ if (peer->state >= STATE_OPENSENT && peer->wbuf.queued) msgbuf_write(&peer->wbuf); /* * we must start the timer for the next EVNT_START * if we are coming here due to an error and the * session was not established successfully before, the * starttimerinterval needs to be exponentially increased */ if (peer->IdleHoldTime == 0) peer->IdleHoldTime = INTERVAL_IDLE_HOLD_INITIAL; peer->holdtime = INTERVAL_HOLD_INITIAL; timer_stop(peer, Timer_ConnectRetry); timer_stop(peer, Timer_Keepalive); timer_stop(peer, Timer_Hold); timer_stop(peer, Timer_IdleHold); timer_stop(peer, Timer_IdleHoldReset); session_close_connection(peer); msgbuf_clear(&peer->wbuf); free(peer->rbuf); peer->rbuf = NULL; bzero(&peer->capa.peer, sizeof(peer->capa.peer)); if (event != EVNT_STOP) { timer_set(peer, Timer_IdleHold, peer->IdleHoldTime); if (event != EVNT_NONE && peer->IdleHoldTime < MAX_IDLE_HOLD/2) peer->IdleHoldTime *= 2; } if (peer->state == STATE_ESTABLISHED) { if (peer->capa.neg.grestart.restart == 2 && (event == EVNT_CON_CLOSED || event == EVNT_CON_FATAL)) { /* don't punish graceful restart */ timer_set(peer, Timer_IdleHold, 0); peer->IdleHoldTime /= 2; session_graceful_restart(peer); } else session_down(peer); } if (peer->state == STATE_NONE || peer->state == STATE_ESTABLISHED) { /* initialize capability negotiation structures */ memcpy(&peer->capa.ann, &peer->conf.capabilities, sizeof(peer->capa.ann)); if (!peer->conf.announce_capa) session_capa_ann_none(peer); } break; case STATE_CONNECT: if (peer->state == STATE_ESTABLISHED && peer->capa.neg.grestart.restart == 2) { /* do the graceful restart dance */ session_graceful_restart(peer); peer->holdtime = INTERVAL_HOLD_INITIAL; timer_stop(peer, Timer_ConnectRetry); timer_stop(peer, Timer_Keepalive); timer_stop(peer, Timer_Hold); timer_stop(peer, Timer_IdleHold); timer_stop(peer, Timer_IdleHoldReset); session_close_connection(peer); msgbuf_clear(&peer->wbuf); bzero(&peer->capa.peer, sizeof(peer->capa.peer)); } break; case STATE_ACTIVE: break; case STATE_OPENSENT: break; case STATE_OPENCONFIRM: break; case STATE_ESTABLISHED: timer_set(peer, Timer_IdleHoldReset, peer->IdleHoldTime); if (peer->demoted) timer_set(peer, Timer_CarpUndemote, INTERVAL_HOLD_DEMOTED); session_up(peer); break; default: /* something seriously fucked */ break; } log_statechange(peer, state, event); LIST_FOREACH(mrt, &mrthead, entry) { if (!(mrt->type == MRT_ALL_IN || mrt->type == MRT_ALL_OUT)) continue; if ((mrt->peer_id == 0 && mrt->group_id == 0) || mrt->peer_id == peer->conf.id || (mrt->group_id != 0 && mrt->group_id == peer->conf.groupid)) mrt_dump_state(mrt, peer->state, state, peer); } peer->prev_state = peer->state; peer->state = state; } void session_accept(int listenfd) { int connfd; int opt; socklen_t len; struct sockaddr_storage cliaddr; struct peer *p = NULL; len = sizeof(cliaddr); if ((connfd = accept4(listenfd, (struct sockaddr *)&cliaddr, &len, SOCK_CLOEXEC | SOCK_NONBLOCK)) == -1) { if (errno == ENFILE || errno == EMFILE) pauseaccept = getmonotime(); else if (errno != EWOULDBLOCK && errno != EINTR && errno != ECONNABORTED) log_warn("accept"); return; } p = getpeerbyip((struct sockaddr *)&cliaddr); if (p != NULL && p->state == STATE_IDLE && p->errcnt < 2) { if (timer_running(p, Timer_IdleHold, NULL)) { /* fast reconnect after clear */ p->passive = 1; bgp_fsm(p, EVNT_START); } } if (p != NULL && (p->state == STATE_CONNECT || p->state == STATE_ACTIVE)) { if (p->fd != -1) { if (p->state == STATE_CONNECT) session_close_connection(p); else { close(connfd); return; } } open: if (p->conf.auth.method != AUTH_NONE && sysdep.no_pfkey) { log_peer_warnx(&p->conf, "ipsec or md5sig configured but not available"); close(connfd); return; } if (p->conf.auth.method == AUTH_MD5SIG) { if (sysdep.no_md5sig) { log_peer_warnx(&p->conf, "md5sig configured but not available"); close(connfd); return; } len = sizeof(opt); if (getsockopt(connfd, IPPROTO_TCP, TCP_MD5SIG, &opt, &len) == -1) fatal("getsockopt TCP_MD5SIG"); if (!opt) { /* non-md5'd connection! */ log_peer_warnx(&p->conf, "connection attempt without md5 signature"); close(connfd); return; } } p->fd = p->wbuf.fd = connfd; if (session_setup_socket(p)) { close(connfd); return; } bgp_fsm(p, EVNT_CON_OPEN); return; } else if (p != NULL && p->state == STATE_ESTABLISHED && p->capa.neg.grestart.restart == 2) { /* first do the graceful restart dance */ change_state(p, STATE_CONNECT, EVNT_CON_CLOSED); /* then do part of the open dance */ goto open; } else { log_conn_attempt(p, (struct sockaddr *)&cliaddr); close(connfd); } } int session_connect(struct peer *peer) { int opt = 1; struct sockaddr *sa; /* * we do not need the overcomplicated collision detection RFC 1771 * describes; we simply make sure there is only ever one concurrent * tcp connection per peer. */ if (peer->fd != -1) return (-1); if ((peer->fd = socket(aid2af(peer->conf.remote_addr.aid), SOCK_STREAM | SOCK_CLOEXEC | SOCK_NONBLOCK, IPPROTO_TCP)) == -1) { log_peer_warn(&peer->conf, "session_connect socket"); bgp_fsm(peer, EVNT_CON_OPENFAIL); return (-1); } if (peer->conf.auth.method != AUTH_NONE && sysdep.no_pfkey) { log_peer_warnx(&peer->conf, "ipsec or md5sig configured but not available"); bgp_fsm(peer, EVNT_CON_OPENFAIL); return (-1); } if (peer->conf.auth.method == AUTH_MD5SIG) { if (sysdep.no_md5sig) { log_peer_warnx(&peer->conf, "md5sig configured but not available"); bgp_fsm(peer, EVNT_CON_OPENFAIL); return (-1); } if (setsockopt(peer->fd, IPPROTO_TCP, TCP_MD5SIG, &opt, sizeof(opt)) == -1) { log_peer_warn(&peer->conf, "setsockopt md5sig"); bgp_fsm(peer, EVNT_CON_OPENFAIL); return (-1); } } peer->wbuf.fd = peer->fd; /* if update source is set we need to bind() */ if ((sa = addr2sa(&peer->conf.local_addr, 0)) != NULL) { if (bind(peer->fd, sa, sa->sa_len) == -1) { log_peer_warn(&peer->conf, "session_connect bind"); bgp_fsm(peer, EVNT_CON_OPENFAIL); return (-1); } } if (session_setup_socket(peer)) { bgp_fsm(peer, EVNT_CON_OPENFAIL); return (-1); } sa = addr2sa(&peer->conf.remote_addr, BGP_PORT); if (connect(peer->fd, sa, sa->sa_len) == -1) { if (errno != EINPROGRESS) { if (errno != peer->lasterr) log_peer_warn(&peer->conf, "connect"); peer->lasterr = errno; bgp_fsm(peer, EVNT_CON_OPENFAIL); return (-1); } } else bgp_fsm(peer, EVNT_CON_OPEN); return (0); } int session_setup_socket(struct peer *p) { int ttl = p->conf.distance; int pre = IPTOS_PREC_INTERNETCONTROL; int nodelay = 1; int bsize; switch (p->conf.remote_addr.aid) { case AID_INET: /* set precedence, see RFC 1771 appendix 5 */ if (setsockopt(p->fd, IPPROTO_IP, IP_TOS, &pre, sizeof(pre)) == -1) { log_peer_warn(&p->conf, "session_setup_socket setsockopt TOS"); return (-1); } if (p->conf.ebgp) { /* set TTL to foreign router's distance 1=direct n=multihop with ttlsec, we always use 255 */ if (p->conf.ttlsec) { ttl = 256 - p->conf.distance; if (setsockopt(p->fd, IPPROTO_IP, IP_MINTTL, &ttl, sizeof(ttl)) == -1) { log_peer_warn(&p->conf, "session_setup_socket: " "setsockopt MINTTL"); return (-1); } ttl = 255; } if (setsockopt(p->fd, IPPROTO_IP, IP_TTL, &ttl, sizeof(ttl)) == -1) { log_peer_warn(&p->conf, "session_setup_socket setsockopt TTL"); return (-1); } } break; case AID_INET6: if (p->conf.ebgp) { /* set hoplimit to foreign router's distance 1=direct n=multihop with ttlsec, we always use 255 */ if (p->conf.ttlsec) { ttl = 256 - p->conf.distance; if (setsockopt(p->fd, IPPROTO_IPV6, IPV6_MINHOPCOUNT, &ttl, sizeof(ttl)) == -1) { log_peer_warn(&p->conf, "session_setup_socket: " "setsockopt MINHOPCOUNT"); return (-1); } ttl = 255; } if (setsockopt(p->fd, IPPROTO_IPV6, IPV6_UNICAST_HOPS, &ttl, sizeof(ttl)) == -1) { log_peer_warn(&p->conf, "session_setup_socket setsockopt hoplimit"); return (-1); } } break; } /* set TCP_NODELAY */ if (setsockopt(p->fd, IPPROTO_TCP, TCP_NODELAY, &nodelay, sizeof(nodelay)) == -1) { log_peer_warn(&p->conf, "session_setup_socket setsockopt TCP_NODELAY"); return (-1); } /* only increase bufsize (and thus window) if md5 or ipsec is in use */ if (p->conf.auth.method != AUTH_NONE) { /* try to increase bufsize. no biggie if it fails */ bsize = 65535; while (bsize > 8192 && setsockopt(p->fd, SOL_SOCKET, SO_RCVBUF, &bsize, sizeof(bsize)) == -1 && errno != EINVAL) bsize /= 2; bsize = 65535; while (bsize > 8192 && setsockopt(p->fd, SOL_SOCKET, SO_SNDBUF, &bsize, sizeof(bsize)) == -1 && errno != EINVAL) bsize /= 2; } return (0); } void session_tcp_established(struct peer *peer) { socklen_t len; len = sizeof(peer->sa_local); if (getsockname(peer->fd, (struct sockaddr *)&peer->sa_local, &len) == -1) log_warn("getsockname"); len = sizeof(peer->sa_remote); if (getpeername(peer->fd, (struct sockaddr *)&peer->sa_remote, &len) == -1) log_warn("getpeername"); } void session_capa_ann_none(struct peer *peer) { bzero(&peer->capa.ann, sizeof(peer->capa.ann)); } int session_capa_add(struct ibuf *opb, u_int8_t capa_code, u_int8_t capa_len) { int errs = 0; errs += ibuf_add(opb, &capa_code, sizeof(capa_code)); errs += ibuf_add(opb, &capa_len, sizeof(capa_len)); return (errs); } int session_capa_add_mp(struct ibuf *buf, u_int8_t aid) { u_int8_t safi, pad = 0; u_int16_t afi; int errs = 0; if (aid2afi(aid, &afi, &safi) == -1) fatalx("session_capa_add_mp: bad afi/safi pair"); afi = htons(afi); errs += ibuf_add(buf, &afi, sizeof(afi)); errs += ibuf_add(buf, &pad, sizeof(pad)); errs += ibuf_add(buf, &safi, sizeof(safi)); return (errs); } int session_capa_add_gr(struct peer *p, struct ibuf *b, u_int8_t aid) { u_int errs = 0; u_int16_t afi; u_int8_t flags, safi; if (aid2afi(aid, &afi, &safi)) { log_warn("session_capa_add_gr: bad AID"); return (1); } if (p->capa.neg.grestart.flags[aid] & CAPA_GR_RESTARTING) flags = CAPA_GR_F_FLAG; else flags = 0; afi = htons(afi); errs += ibuf_add(b, &afi, sizeof(afi)); errs += ibuf_add(b, &safi, sizeof(safi)); errs += ibuf_add(b, &flags, sizeof(flags)); return (errs); } struct bgp_msg * session_newmsg(enum msg_type msgtype, u_int16_t len) { struct bgp_msg *msg; struct msg_header hdr; struct ibuf *buf; int errs = 0; memset(&hdr.marker, 0xff, sizeof(hdr.marker)); hdr.len = htons(len); hdr.type = msgtype; if ((buf = ibuf_open(len)) == NULL) return (NULL); errs += ibuf_add(buf, &hdr.marker, sizeof(hdr.marker)); errs += ibuf_add(buf, &hdr.len, sizeof(hdr.len)); errs += ibuf_add(buf, &hdr.type, sizeof(hdr.type)); if (errs || (msg = calloc(1, sizeof(*msg))) == NULL) { ibuf_free(buf); return (NULL); } msg->buf = buf; msg->type = msgtype; msg->len = len; return (msg); } int session_sendmsg(struct bgp_msg *msg, struct peer *p) { struct mrt *mrt; LIST_FOREACH(mrt, &mrthead, entry) { if (!(mrt->type == MRT_ALL_OUT || (msg->type == UPDATE && mrt->type == MRT_UPDATE_OUT))) continue; if ((mrt->peer_id == 0 && mrt->group_id == 0) || mrt->peer_id == p->conf.id || (mrt->group_id != 0 && mrt->group_id == p->conf.groupid)) mrt_dump_bgp_msg(mrt, msg->buf->buf, msg->len, p); } ibuf_close(&p->wbuf, msg->buf); if (!p->throttled && p->wbuf.queued > SESS_MSG_HIGH_MARK) { if (imsg_rde(IMSG_XOFF, p->conf.id, NULL, 0) == -1) log_peer_warn(&p->conf, "imsg_compose XOFF"); else p->throttled = 1; } free(msg); return (0); } void session_open(struct peer *p) { struct bgp_msg *buf; struct ibuf *opb; struct msg_open msg; u_int16_t len; u_int8_t i, op_type, optparamlen = 0; int errs = 0; int mpcapa = 0; if ((opb = ibuf_dynamic(0, UCHAR_MAX - sizeof(op_type) - sizeof(optparamlen))) == NULL) { bgp_fsm(p, EVNT_CON_FATAL); return; } /* multiprotocol extensions, RFC 4760 */ for (i = 0; i < AID_MAX; i++) if (p->capa.ann.mp[i]) { /* 4 bytes data */ errs += session_capa_add(opb, CAPA_MP, 4); errs += session_capa_add_mp(opb, i); mpcapa++; } /* route refresh, RFC 2918 */ if (p->capa.ann.refresh) /* no data */ errs += session_capa_add(opb, CAPA_REFRESH, 0); /* graceful restart and End-of-RIB marker, RFC 4724 */ if (p->capa.ann.grestart.restart) { int rst = 0; u_int16_t hdr; u_int8_t grlen; if (mpcapa) { grlen = 2 + 4 * mpcapa; for (i = 0; i < AID_MAX; i++) { if (p->capa.neg.grestart.flags[i] & CAPA_GR_RESTARTING) rst++; } } else { /* AID_INET */ grlen = 2 + 4; if (p->capa.neg.grestart.flags[AID_INET] & CAPA_GR_RESTARTING) rst++; } hdr = conf->holdtime; /* default timeout */ /* if client does graceful restart don't set R flag */ if (!rst) hdr |= CAPA_GR_R_FLAG; hdr = htons(hdr); errs += session_capa_add(opb, CAPA_RESTART, grlen); errs += ibuf_add(opb, &hdr, sizeof(hdr)); if (mpcapa) { for (i = 0; i < AID_MAX; i++) { if (p->capa.ann.mp[i]) { errs += session_capa_add_gr(p, opb, i); } } } else { /* AID_INET */ errs += session_capa_add_gr(p, opb, AID_INET); } } /* 4-bytes AS numbers, draft-ietf-idr-as4bytes-13 */ if (p->capa.ann.as4byte) { /* 4 bytes data */ u_int32_t nas; nas = htonl(p->conf.local_as); errs += session_capa_add(opb, CAPA_AS4BYTE, sizeof(nas)); errs += ibuf_add(opb, &nas, sizeof(nas)); } if (ibuf_size(opb)) optparamlen = ibuf_size(opb) + sizeof(op_type) + sizeof(optparamlen); len = MSGSIZE_OPEN_MIN + optparamlen; if (errs || (buf = session_newmsg(OPEN, len)) == NULL) { ibuf_free(opb); bgp_fsm(p, EVNT_CON_FATAL); return; } msg.version = 4; msg.myas = htons(p->conf.local_short_as); if (p->conf.holdtime) msg.holdtime = htons(p->conf.holdtime); else msg.holdtime = htons(conf->holdtime); msg.bgpid = conf->bgpid; /* is already in network byte order */ msg.optparamlen = optparamlen; errs += ibuf_add(buf->buf, &msg.version, sizeof(msg.version)); errs += ibuf_add(buf->buf, &msg.myas, sizeof(msg.myas)); errs += ibuf_add(buf->buf, &msg.holdtime, sizeof(msg.holdtime)); errs += ibuf_add(buf->buf, &msg.bgpid, sizeof(msg.bgpid)); errs += ibuf_add(buf->buf, &msg.optparamlen, sizeof(msg.optparamlen)); if (optparamlen) { op_type = OPT_PARAM_CAPABILITIES; optparamlen = ibuf_size(opb); errs += ibuf_add(buf->buf, &op_type, sizeof(op_type)); errs += ibuf_add(buf->buf, &optparamlen, sizeof(optparamlen)); errs += ibuf_add(buf->buf, opb->buf, ibuf_size(opb)); } ibuf_free(opb); if (errs) { ibuf_free(buf->buf); free(buf); bgp_fsm(p, EVNT_CON_FATAL); return; } if (session_sendmsg(buf, p) == -1) { bgp_fsm(p, EVNT_CON_FATAL); return; } p->stats.msg_sent_open++; } void session_keepalive(struct peer *p) { struct bgp_msg *buf; if ((buf = session_newmsg(KEEPALIVE, MSGSIZE_KEEPALIVE)) == NULL || session_sendmsg(buf, p) == -1) { bgp_fsm(p, EVNT_CON_FATAL); return; } start_timer_keepalive(p); p->stats.msg_sent_keepalive++; } void session_update(u_int32_t peerid, void *data, size_t datalen) { struct peer *p; struct bgp_msg *buf; if ((p = getpeerbyid(peerid)) == NULL) { log_warnx("no such peer: id=%u", peerid); return; } if (p->state != STATE_ESTABLISHED) return; if ((buf = session_newmsg(UPDATE, MSGSIZE_HEADER + datalen)) == NULL) { bgp_fsm(p, EVNT_CON_FATAL); return; } if (ibuf_add(buf->buf, data, datalen)) { ibuf_free(buf->buf); free(buf); bgp_fsm(p, EVNT_CON_FATAL); return; } if (session_sendmsg(buf, p) == -1) { bgp_fsm(p, EVNT_CON_FATAL); return; } start_timer_keepalive(p); p->stats.msg_sent_update++; } void session_notification(struct peer *p, u_int8_t errcode, u_int8_t subcode, void *data, ssize_t datalen) { struct bgp_msg *buf; int errs = 0; if (p->stats.last_sent_errcode) /* some notification already sent */ return; log_notification(p, errcode, subcode, data, datalen, "sending"); if ((buf = session_newmsg(NOTIFICATION, MSGSIZE_NOTIFICATION_MIN + datalen)) == NULL) { bgp_fsm(p, EVNT_CON_FATAL); return; } errs += ibuf_add(buf->buf, &errcode, sizeof(errcode)); errs += ibuf_add(buf->buf, &subcode, sizeof(subcode)); if (datalen > 0) errs += ibuf_add(buf->buf, data, datalen); if (errs) { ibuf_free(buf->buf); free(buf); bgp_fsm(p, EVNT_CON_FATAL); return; } if (session_sendmsg(buf, p) == -1) { bgp_fsm(p, EVNT_CON_FATAL); return; } p->stats.msg_sent_notification++; p->stats.last_sent_errcode = errcode; p->stats.last_sent_suberr = subcode; } int session_neighbor_rrefresh(struct peer *p) { u_int8_t i; if (!p->capa.peer.refresh) return (-1); for (i = 0; i < AID_MAX; i++) { if (p->capa.peer.mp[i] != 0) session_rrefresh(p, i); } return (0); } void session_rrefresh(struct peer *p, u_int8_t aid) { struct bgp_msg *buf; int errs = 0; u_int16_t afi; u_int8_t safi, null8 = 0; if (aid2afi(aid, &afi, &safi) == -1) fatalx("session_rrefresh: bad afi/safi pair"); if ((buf = session_newmsg(RREFRESH, MSGSIZE_RREFRESH)) == NULL) { bgp_fsm(p, EVNT_CON_FATAL); return; } afi = htons(afi); errs += ibuf_add(buf->buf, &afi, sizeof(afi)); errs += ibuf_add(buf->buf, &null8, sizeof(null8)); errs += ibuf_add(buf->buf, &safi, sizeof(safi)); if (errs) { ibuf_free(buf->buf); free(buf); bgp_fsm(p, EVNT_CON_FATAL); return; } if (session_sendmsg(buf, p) == -1) { bgp_fsm(p, EVNT_CON_FATAL); return; } p->stats.msg_sent_rrefresh++; } int session_graceful_restart(struct peer *p) { u_int8_t i; timer_set(p, Timer_RestartTimeout, p->capa.neg.grestart.timeout); for (i = 0; i < AID_MAX; i++) { if (p->capa.neg.grestart.flags[i] & CAPA_GR_PRESENT) { if (imsg_rde(IMSG_SESSION_STALE, p->conf.id, &i, sizeof(i)) == -1) return (-1); log_peer_warnx(&p->conf, "graceful restart of %s, keeping routes", aid2str(i)); p->capa.neg.grestart.flags[i] |= CAPA_GR_RESTARTING; } else if (p->capa.neg.mp[i]) { if (imsg_rde(IMSG_SESSION_FLUSH, p->conf.id, &i, sizeof(i)) == -1) return (-1); log_peer_warnx(&p->conf, "graceful restart of %s, flushing routes", aid2str(i)); } } return (0); } int session_graceful_stop(struct peer *p) { u_int8_t i; for (i = 0; i < AID_MAX; i++) { /* * Only flush if the peer is restarting and the timeout fired. * In all other cases the session was already flushed when the * session went down or when the new open message was parsed. */ if (p->capa.neg.grestart.flags[i] & CAPA_GR_RESTARTING) { log_peer_warnx(&p->conf, "graceful restart of %s, " "time-out, flushing", aid2str(i)); if (imsg_rde(IMSG_SESSION_FLUSH, p->conf.id, &i, sizeof(i)) == -1) return (-1); } p->capa.neg.grestart.flags[i] &= ~CAPA_GR_RESTARTING; } return (0); } int session_dispatch_msg(struct pollfd *pfd, struct peer *p) { ssize_t n; socklen_t len; int error; if (p->state == STATE_CONNECT) { if (pfd->revents & POLLOUT) { if (pfd->revents & POLLIN) { /* error occurred */ len = sizeof(error); if (getsockopt(pfd->fd, SOL_SOCKET, SO_ERROR, &error, &len) == -1 || error) { if (error) errno = error; if (errno != p->lasterr) { log_peer_warn(&p->conf, "socket error"); p->lasterr = errno; } bgp_fsm(p, EVNT_CON_OPENFAIL); return (1); } } bgp_fsm(p, EVNT_CON_OPEN); return (1); } if (pfd->revents & POLLHUP) { bgp_fsm(p, EVNT_CON_OPENFAIL); return (1); } if (pfd->revents & (POLLERR|POLLNVAL)) { bgp_fsm(p, EVNT_CON_FATAL); return (1); } return (0); } if (pfd->revents & POLLHUP) { bgp_fsm(p, EVNT_CON_CLOSED); return (1); } if (pfd->revents & (POLLERR|POLLNVAL)) { bgp_fsm(p, EVNT_CON_FATAL); return (1); } if (pfd->revents & POLLOUT && p->wbuf.queued) { if ((error = msgbuf_write(&p->wbuf)) <= 0 && errno != EAGAIN) { if (error == 0) log_peer_warnx(&p->conf, "Connection closed"); else if (error == -1) log_peer_warn(&p->conf, "write error"); bgp_fsm(p, EVNT_CON_FATAL); return (1); } if (p->throttled && p->wbuf.queued < SESS_MSG_LOW_MARK) { if (imsg_rde(IMSG_XON, p->conf.id, NULL, 0) == -1) log_peer_warn(&p->conf, "imsg_compose XON"); else p->throttled = 0; } if (!(pfd->revents & POLLIN)) return (1); } if (p->rbuf && pfd->revents & POLLIN) { if ((n = read(p->fd, p->rbuf->buf + p->rbuf->wpos, sizeof(p->rbuf->buf) - p->rbuf->wpos)) == -1) { if (errno != EINTR && errno != EAGAIN) { log_peer_warn(&p->conf, "read error"); bgp_fsm(p, EVNT_CON_FATAL); } return (1); } if (n == 0) { /* connection closed */ bgp_fsm(p, EVNT_CON_CLOSED); return (1); } p->rbuf->wpos += n; p->stats.last_read = time(NULL); return (1); } return (0); } int session_process_msg(struct peer *p) { struct mrt *mrt; ssize_t rpos, av, left; int processed = 0; u_int16_t msglen; u_int8_t msgtype; rpos = 0; av = p->rbuf->wpos; /* * session might drop to IDLE -> buffers deallocated * we MUST check rbuf != NULL before use */ for (;;) { if (rpos + MSGSIZE_HEADER > av) break; if (p->rbuf == NULL) break; if (parse_header(p, p->rbuf->buf + rpos, &msglen, &msgtype) == -1) return (0); if (rpos + msglen > av) break; p->rbuf->rptr = p->rbuf->buf + rpos; /* dump to MRT as soon as we have a full packet */ LIST_FOREACH(mrt, &mrthead, entry) { if (!(mrt->type == MRT_ALL_IN || (msgtype == UPDATE && mrt->type == MRT_UPDATE_IN))) continue; if ((mrt->peer_id == 0 && mrt->group_id == 0) || mrt->peer_id == p->conf.id || (mrt->group_id != 0 && mrt->group_id == p->conf.groupid)) mrt_dump_bgp_msg(mrt, p->rbuf->rptr, msglen, p); } switch (msgtype) { case OPEN: bgp_fsm(p, EVNT_RCVD_OPEN); p->stats.msg_rcvd_open++; break; case UPDATE: bgp_fsm(p, EVNT_RCVD_UPDATE); p->stats.msg_rcvd_update++; break; case NOTIFICATION: bgp_fsm(p, EVNT_RCVD_NOTIFICATION); p->stats.msg_rcvd_notification++; break; case KEEPALIVE: bgp_fsm(p, EVNT_RCVD_KEEPALIVE); p->stats.msg_rcvd_keepalive++; break; case RREFRESH: parse_refresh(p); p->stats.msg_rcvd_rrefresh++; break; default: /* cannot happen */ session_notification(p, ERR_HEADER, ERR_HDR_TYPE, &msgtype, 1); log_warnx("received message with unknown type %u", msgtype); bgp_fsm(p, EVNT_CON_FATAL); } rpos += msglen; if (++processed > MSG_PROCESS_LIMIT) break; } if (p->rbuf == NULL) return (1); if (rpos < av) { left = av - rpos; memmove(&p->rbuf->buf, p->rbuf->buf + rpos, left); p->rbuf->wpos = left; } else p->rbuf->wpos = 0; return (1); } int parse_header(struct peer *peer, u_char *data, u_int16_t *len, u_int8_t *type) { u_char *p; u_int16_t olen; static const u_int8_t marker[MSGSIZE_HEADER_MARKER] = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff }; /* caller MUST make sure we are getting 19 bytes! */ p = data; if (memcmp(p, marker, sizeof(marker))) { log_peer_warnx(&peer->conf, "sync error"); session_notification(peer, ERR_HEADER, ERR_HDR_SYNC, NULL, 0); bgp_fsm(peer, EVNT_CON_FATAL); return (-1); } p += MSGSIZE_HEADER_MARKER; memcpy(&olen, p, 2); *len = ntohs(olen); p += 2; memcpy(type, p, 1); if (*len < MSGSIZE_HEADER || *len > MAX_PKTSIZE) { log_peer_warnx(&peer->conf, "received message: illegal length: %u byte", *len); session_notification(peer, ERR_HEADER, ERR_HDR_LEN, &olen, sizeof(olen)); bgp_fsm(peer, EVNT_CON_FATAL); return (-1); } switch (*type) { case OPEN: if (*len < MSGSIZE_OPEN_MIN) { log_peer_warnx(&peer->conf, "received OPEN: illegal len: %u byte", *len); session_notification(peer, ERR_HEADER, ERR_HDR_LEN, &olen, sizeof(olen)); bgp_fsm(peer, EVNT_CON_FATAL); return (-1); } break; case NOTIFICATION: if (*len < MSGSIZE_NOTIFICATION_MIN) { log_peer_warnx(&peer->conf, "received NOTIFICATION: illegal len: %u byte", *len); session_notification(peer, ERR_HEADER, ERR_HDR_LEN, &olen, sizeof(olen)); bgp_fsm(peer, EVNT_CON_FATAL); return (-1); } break; case UPDATE: if (*len < MSGSIZE_UPDATE_MIN) { log_peer_warnx(&peer->conf, "received UPDATE: illegal len: %u byte", *len); session_notification(peer, ERR_HEADER, ERR_HDR_LEN, &olen, sizeof(olen)); bgp_fsm(peer, EVNT_CON_FATAL); return (-1); } break; case KEEPALIVE: if (*len != MSGSIZE_KEEPALIVE) { log_peer_warnx(&peer->conf, "received KEEPALIVE: illegal len: %u byte", *len); session_notification(peer, ERR_HEADER, ERR_HDR_LEN, &olen, sizeof(olen)); bgp_fsm(peer, EVNT_CON_FATAL); return (-1); } break; case RREFRESH: if (*len != MSGSIZE_RREFRESH) { log_peer_warnx(&peer->conf, "received RREFRESH: illegal len: %u byte", *len); session_notification(peer, ERR_HEADER, ERR_HDR_LEN, &olen, sizeof(olen)); bgp_fsm(peer, EVNT_CON_FATAL); return (-1); } break; default: log_peer_warnx(&peer->conf, "received msg with unknown type %u", *type); session_notification(peer, ERR_HEADER, ERR_HDR_TYPE, type, 1); bgp_fsm(peer, EVNT_CON_FATAL); return (-1); } return (0); } int parse_open(struct peer *peer) { u_char *p, *op_val; u_int8_t version, rversion; u_int16_t short_as, msglen; u_int16_t holdtime, oholdtime, myholdtime; u_int32_t as, bgpid; u_int8_t optparamlen, plen; u_int8_t op_type, op_len; p = peer->rbuf->rptr; p += MSGSIZE_HEADER_MARKER; memcpy(&msglen, p, sizeof(msglen)); msglen = ntohs(msglen); p = peer->rbuf->rptr; p += MSGSIZE_HEADER; /* header is already checked */ memcpy(&version, p, sizeof(version)); p += sizeof(version); if (version != BGP_VERSION) { log_peer_warnx(&peer->conf, "peer wants unrecognized version %u", version); if (version > BGP_VERSION) rversion = version - BGP_VERSION; else rversion = BGP_VERSION; session_notification(peer, ERR_OPEN, ERR_OPEN_VERSION, &rversion, sizeof(rversion)); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } memcpy(&short_as, p, sizeof(short_as)); p += sizeof(short_as); as = peer->short_as = ntohs(short_as); if (as == 0) { log_peer_warnx(&peer->conf, "peer requests unacceptable AS %u", as); session_notification(peer, ERR_OPEN, ERR_OPEN_AS, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } memcpy(&oholdtime, p, sizeof(oholdtime)); p += sizeof(oholdtime); holdtime = ntohs(oholdtime); if (holdtime && holdtime < peer->conf.min_holdtime) { log_peer_warnx(&peer->conf, "peer requests unacceptable holdtime %u", holdtime); session_notification(peer, ERR_OPEN, ERR_OPEN_HOLDTIME, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } myholdtime = peer->conf.holdtime; if (!myholdtime) myholdtime = conf->holdtime; if (holdtime < myholdtime) peer->holdtime = holdtime; else peer->holdtime = myholdtime; memcpy(&bgpid, p, sizeof(bgpid)); p += sizeof(bgpid); /* check bgpid for validity - just disallow 0 */ if (ntohl(bgpid) == 0) { log_peer_warnx(&peer->conf, "peer BGPID %u unacceptable", ntohl(bgpid)); session_notification(peer, ERR_OPEN, ERR_OPEN_BGPID, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } peer->remote_bgpid = bgpid; memcpy(&optparamlen, p, sizeof(optparamlen)); p += sizeof(optparamlen); if (optparamlen != msglen - MSGSIZE_OPEN_MIN) { log_peer_warnx(&peer->conf, "corrupt OPEN message received: length mismatch"); session_notification(peer, ERR_OPEN, 0, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } plen = optparamlen; while (plen > 0) { if (plen < 2) { log_peer_warnx(&peer->conf, "corrupt OPEN message received, len wrong"); session_notification(peer, ERR_OPEN, 0, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } memcpy(&op_type, p, sizeof(op_type)); p += sizeof(op_type); plen -= sizeof(op_type); memcpy(&op_len, p, sizeof(op_len)); p += sizeof(op_len); plen -= sizeof(op_len); if (op_len > 0) { if (plen < op_len) { log_peer_warnx(&peer->conf, "corrupt OPEN message received, len wrong"); session_notification(peer, ERR_OPEN, 0, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } op_val = p; p += op_len; plen -= op_len; } else op_val = NULL; switch (op_type) { case OPT_PARAM_CAPABILITIES: /* RFC 3392 */ if (parse_capabilities(peer, op_val, op_len, &as) == -1) { session_notification(peer, ERR_OPEN, 0, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } break; case OPT_PARAM_AUTH: /* deprecated */ default: /* * unsupported type * the RFCs tell us to leave the data section empty * and notify the peer with ERR_OPEN, ERR_OPEN_OPT. * How the peer should know _which_ optional parameter * we don't support is beyond me. */ log_peer_warnx(&peer->conf, "received OPEN message with unsupported optional " "parameter: type %u", op_type); session_notification(peer, ERR_OPEN, ERR_OPEN_OPT, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); timer_set(peer, Timer_IdleHold, 0); /* no punish */ peer->IdleHoldTime /= 2; return (-1); } } /* if remote-as is zero and it's a cloned neighbor, accept any */ if (peer->template && !peer->conf.remote_as && as != AS_TRANS) { peer->conf.remote_as = as; peer->conf.ebgp = (peer->conf.remote_as != peer->conf.local_as); if (!peer->conf.ebgp) /* force enforce_as off for iBGP sessions */ peer->conf.enforce_as = ENFORCE_AS_OFF; } if (peer->conf.remote_as != as) { log_peer_warnx(&peer->conf, "peer sent wrong AS %s", log_as(as)); session_notification(peer, ERR_OPEN, ERR_OPEN_AS, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } if (capa_neg_calc(peer) == -1) { log_peer_warnx(&peer->conf, "capability negotiation calculation failed"); session_notification(peer, ERR_OPEN, 0, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } return (0); } int parse_update(struct peer *peer) { u_char *p; u_int16_t datalen; /* * we pass the message verbatim to the rde. * in case of errors the whole session is reset with a * notification anyway, we only need to know the peer */ p = peer->rbuf->rptr; p += MSGSIZE_HEADER_MARKER; memcpy(&datalen, p, sizeof(datalen)); datalen = ntohs(datalen); p = peer->rbuf->rptr; p += MSGSIZE_HEADER; /* header is already checked */ datalen -= MSGSIZE_HEADER; if (imsg_rde(IMSG_UPDATE, peer->conf.id, p, datalen) == -1) return (-1); return (0); } int parse_refresh(struct peer *peer) { u_char *p; u_int16_t afi; u_int8_t aid, safi; p = peer->rbuf->rptr; p += MSGSIZE_HEADER; /* header is already checked */ /* * We could check if we actually announced the capability but * as long as the message is correctly encoded we don't care. */ /* afi, 2 byte */ memcpy(&afi, p, sizeof(afi)); afi = ntohs(afi); p += 2; /* reserved, 1 byte */ p += 1; /* safi, 1 byte */ memcpy(&safi, p, sizeof(safi)); /* afi/safi unchecked - unrecognized values will be ignored anyway */ if (afi2aid(afi, safi, &aid) == -1) { log_peer_warnx(&peer->conf, "peer sent bad refresh, " "invalid afi/safi pair"); return (0); } if (imsg_rde(IMSG_REFRESH, peer->conf.id, &aid, sizeof(aid)) == -1) return (-1); return (0); } int parse_notification(struct peer *peer) { u_char *p; u_int16_t datalen; u_int8_t errcode; u_int8_t subcode; u_int8_t capa_code; u_int8_t capa_len; u_int8_t shutcomm_len; u_int8_t i; /* just log */ p = peer->rbuf->rptr; p += MSGSIZE_HEADER_MARKER; memcpy(&datalen, p, sizeof(datalen)); datalen = ntohs(datalen); p = peer->rbuf->rptr; p += MSGSIZE_HEADER; /* header is already checked */ datalen -= MSGSIZE_HEADER; memcpy(&errcode, p, sizeof(errcode)); p += sizeof(errcode); datalen -= sizeof(errcode); memcpy(&subcode, p, sizeof(subcode)); p += sizeof(subcode); datalen -= sizeof(subcode); log_notification(peer, errcode, subcode, p, datalen, "received"); peer->errcnt++; if (errcode == ERR_OPEN && subcode == ERR_OPEN_CAPA) { if (datalen == 0) { /* zebra likes to send those.. humbug */ log_peer_warnx(&peer->conf, "received \"unsupported " "capability\" notification without data part, " "disabling capability announcements altogether"); session_capa_ann_none(peer); } while (datalen > 0) { if (datalen < 2) { log_peer_warnx(&peer->conf, "parse_notification: " "expect len >= 2, len is %u", datalen); return (-1); } memcpy(&capa_code, p, sizeof(capa_code)); p += sizeof(capa_code); datalen -= sizeof(capa_code); memcpy(&capa_len, p, sizeof(capa_len)); p += sizeof(capa_len); datalen -= sizeof(capa_len); if (datalen < capa_len) { log_peer_warnx(&peer->conf, "parse_notification: capa_len %u exceeds " "remaining msg length %u", capa_len, datalen); return (-1); } p += capa_len; datalen -= capa_len; switch (capa_code) { case CAPA_MP: for (i = 0; i < AID_MAX; i++) peer->capa.ann.mp[i] = 0; log_peer_warnx(&peer->conf, "disabling multiprotocol capability"); break; case CAPA_REFRESH: peer->capa.ann.refresh = 0; log_peer_warnx(&peer->conf, "disabling route refresh capability"); break; case CAPA_RESTART: peer->capa.ann.grestart.restart = 0; log_peer_warnx(&peer->conf, "disabling restart capability"); break; case CAPA_AS4BYTE: peer->capa.ann.as4byte = 0; log_peer_warnx(&peer->conf, "disabling 4-byte AS num capability"); break; default: /* should not happen... */ log_peer_warnx(&peer->conf, "received " "\"unsupported capability\" notification " "for unknown capability %u, disabling " "capability announcements altogether", capa_code); session_capa_ann_none(peer); break; } } return (1); } if (errcode == ERR_OPEN && subcode == ERR_OPEN_OPT) { session_capa_ann_none(peer); return (1); } if (errcode == ERR_CEASE && (subcode == ERR_CEASE_ADMIN_DOWN || subcode == ERR_CEASE_ADMIN_RESET)) { if (datalen >= sizeof(shutcomm_len)) { memcpy(&shutcomm_len, p, sizeof(shutcomm_len)); p += sizeof(shutcomm_len); datalen -= sizeof(shutcomm_len); if(datalen < shutcomm_len) { log_peer_warnx(&peer->conf, "received truncated shutdown reason"); return (0); } if (shutcomm_len > (SHUT_COMM_LEN-1)) { log_peer_warnx(&peer->conf, "received overly long shutdown reason"); return (0); } memcpy(peer->stats.last_shutcomm, p, shutcomm_len); peer->stats.last_shutcomm[shutcomm_len] = '\0'; log_peer_warnx(&peer->conf, "received shutdown reason: \"%s\"", log_shutcomm(peer->stats.last_shutcomm)); p += shutcomm_len; datalen -= shutcomm_len; } } return (0); } int parse_capabilities(struct peer *peer, u_char *d, u_int16_t dlen, u_int32_t *as) { u_char *capa_val; u_int32_t remote_as; u_int16_t len; u_int16_t afi; u_int16_t gr_header; u_int8_t safi; u_int8_t aid; u_int8_t gr_flags; u_int8_t capa_code; u_int8_t capa_len; u_int8_t i; len = dlen; while (len > 0) { if (len < 2) { log_peer_warnx(&peer->conf, "Bad capabilities attr " "length: %u, too short", len); return (-1); } memcpy(&capa_code, d, sizeof(capa_code)); d += sizeof(capa_code); len -= sizeof(capa_code); memcpy(&capa_len, d, sizeof(capa_len)); d += sizeof(capa_len); len -= sizeof(capa_len); if (capa_len > 0) { if (len < capa_len) { log_peer_warnx(&peer->conf, "Bad capabilities attr length: " "len %u smaller than capa_len %u", len, capa_len); return (-1); } capa_val = d; d += capa_len; len -= capa_len; } else capa_val = NULL; switch (capa_code) { case CAPA_MP: /* RFC 4760 */ if (capa_len != 4) { log_peer_warnx(&peer->conf, "Bad multi protocol capability length: " "%u", capa_len); break; } memcpy(&afi, capa_val, sizeof(afi)); afi = ntohs(afi); memcpy(&safi, capa_val + 3, sizeof(safi)); if (afi2aid(afi, safi, &aid) == -1) { log_peer_warnx(&peer->conf, "Received multi protocol capability: " " unknown AFI %u, safi %u pair", afi, safi); break; } peer->capa.peer.mp[aid] = 1; break; case CAPA_REFRESH: peer->capa.peer.refresh = 1; break; case CAPA_RESTART: if (capa_len == 2) { /* peer only supports EoR marker */ peer->capa.peer.grestart.restart = 1; peer->capa.peer.grestart.timeout = 0; break; } else if (capa_len % 4 != 2) { log_peer_warnx(&peer->conf, "Bad graceful restart capability length: " "%u", capa_len); peer->capa.peer.grestart.restart = 0; peer->capa.peer.grestart.timeout = 0; break; } memcpy(&gr_header, capa_val, sizeof(gr_header)); gr_header = ntohs(gr_header); peer->capa.peer.grestart.timeout = gr_header & CAPA_GR_TIMEMASK; if (peer->capa.peer.grestart.timeout == 0) { log_peer_warnx(&peer->conf, "Received " "graceful restart timeout is zero"); peer->capa.peer.grestart.restart = 0; break; } for (i = 2; i <= capa_len - 4; i += 4) { memcpy(&afi, capa_val + i, sizeof(afi)); afi = ntohs(afi); memcpy(&safi, capa_val + i + 2, sizeof(safi)); if (afi2aid(afi, safi, &aid) == -1) { log_peer_warnx(&peer->conf, "Received graceful restart capa: " " unknown AFI %u, safi %u pair", afi, safi); continue; } memcpy(&gr_flags, capa_val + i + 3, sizeof(gr_flags)); peer->capa.peer.grestart.flags[aid] |= CAPA_GR_PRESENT; if (gr_flags & CAPA_GR_F_FLAG) peer->capa.peer.grestart.flags[aid] |= CAPA_GR_FORWARD; if (gr_header & CAPA_GR_R_FLAG) peer->capa.peer.grestart.flags[aid] |= CAPA_GR_RESTART; peer->capa.peer.grestart.restart = 2; } break; case CAPA_AS4BYTE: if (capa_len != 4) { log_peer_warnx(&peer->conf, "Bad AS4BYTE capability length: " "%u", capa_len); peer->capa.peer.as4byte = 0; break; } memcpy(&remote_as, capa_val, sizeof(remote_as)); *as = ntohl(remote_as); if (*as == 0) { log_peer_warnx(&peer->conf, "peer requests unacceptable AS %u", *as); session_notification(peer, ERR_OPEN, ERR_OPEN_AS, NULL, 0); change_state(peer, STATE_IDLE, EVNT_RCVD_OPEN); return (-1); } peer->capa.peer.as4byte = 1; break; default: break; } } return (0); } int capa_neg_calc(struct peer *p) { u_int8_t i, hasmp = 0; /* refresh: does not realy matter here, use peer setting */ p->capa.neg.refresh = p->capa.peer.refresh; /* as4byte: both side must announce capability */ if (p->capa.ann.as4byte && p->capa.peer.as4byte) p->capa.neg.as4byte = 1; else p->capa.neg.as4byte = 0; /* MP: both side must announce capability */ for (i = 0; i < AID_MAX; i++) { if (p->capa.ann.mp[i] && p->capa.peer.mp[i]) { p->capa.neg.mp[i] = 1; hasmp = 1; } else p->capa.neg.mp[i] = 0; } /* if no MP capability present default to IPv4 unicast mode */ if (!hasmp) p->capa.neg.mp[AID_INET] = 1; /* * graceful restart: only the peer capabilities are of interest here. * It is necessary to compare the new values with the previous ones * and act acordingly. AFI/SAFI that are not part in the MP capability * are treated as not being present. */ for (i = 0; i < AID_MAX; i++) { int8_t negflags; /* disable GR if the AFI/SAFI is not present */ if (p->capa.peer.grestart.flags[i] & CAPA_GR_PRESENT && p->capa.neg.mp[i] == 0) p->capa.peer.grestart.flags[i] = 0; /* disable */ /* look at current GR state and decide what to do */ negflags = p->capa.neg.grestart.flags[i]; p->capa.neg.grestart.flags[i] = p->capa.peer.grestart.flags[i]; if (negflags & CAPA_GR_RESTARTING) { if (!(p->capa.peer.grestart.flags[i] & CAPA_GR_FORWARD)) { if (imsg_rde(IMSG_SESSION_FLUSH, p->conf.id, &i, sizeof(i)) == -1) return (-1); log_peer_warnx(&p->conf, "graceful restart of " "%s, not restarted, flushing", aid2str(i)); } else p->capa.neg.grestart.flags[i] |= CAPA_GR_RESTARTING; } } p->capa.neg.grestart.timeout = p->capa.peer.grestart.timeout; p->capa.neg.grestart.restart = p->capa.peer.grestart.restart; return (0); } void session_dispatch_imsg(struct imsgbuf *ibuf, int idx, u_int *listener_cnt) { struct imsg imsg; struct mrt xmrt; struct mrt *mrt; struct imsgbuf *i; struct peer_config *pconf; struct peer *p, *next; struct listen_addr *la, *nla; struct kif *kif; u_char *data; enum reconf_action reconf; int n, fd, depend_ok, restricted; u_int8_t aid, errcode, subcode; while (ibuf) { if ((n = imsg_get(ibuf, &imsg)) == -1) fatal("session_dispatch_imsg: imsg_get error"); if (n == 0) break; switch (imsg.hdr.type) { case IMSG_SOCKET_CONN: case IMSG_SOCKET_CONN_CTL: if (idx != PFD_PIPE_MAIN) fatalx("reconf request not from parent"); if ((fd = imsg.fd) == -1) { log_warnx("expected to receive imsg fd to " "RDE but didn't receive any"); break; } if ((i = malloc(sizeof(struct imsgbuf))) == NULL) fatal(NULL); imsg_init(i, fd); if (imsg.hdr.type == IMSG_SOCKET_CONN) { if (ibuf_rde) { log_warnx("Unexpected imsg connection " "to RDE received"); msgbuf_clear(&ibuf_rde->w); free(ibuf_rde); } ibuf_rde = i; } else { if (ibuf_rde_ctl) { log_warnx("Unexpected imsg ctl " "connection to RDE received"); msgbuf_clear(&ibuf_rde_ctl->w); free(ibuf_rde_ctl); } ibuf_rde_ctl = i; } break; case IMSG_RECONF_CONF: if (idx != PFD_PIPE_MAIN) fatalx("reconf request not from parent"); if ((nconf = malloc(sizeof(struct bgpd_config))) == NULL) fatal(NULL); memcpy(nconf, imsg.data, sizeof(struct bgpd_config)); if ((nconf->listen_addrs = calloc(1, sizeof(struct listen_addrs))) == NULL) fatal(NULL); TAILQ_INIT(nconf->listen_addrs); npeers = NULL; init_conf(nconf); pending_reconf = 1; break; case IMSG_RECONF_PEER: if (idx != PFD_PIPE_MAIN) fatalx("reconf request not from parent"); pconf = imsg.data; p = getpeerbyaddr(&pconf->remote_addr); if (p == NULL) { if ((p = calloc(1, sizeof(struct peer))) == NULL) fatal("new_peer"); p->state = p->prev_state = STATE_NONE; p->next = npeers; npeers = p; reconf = RECONF_REINIT; } else reconf = RECONF_KEEP; memcpy(&p->conf, pconf, sizeof(struct peer_config)); p->conf.reconf_action = reconf; /* sync the RDE in case we keep the peer */ if (reconf == RECONF_KEEP) { if (imsg_rde(IMSG_SESSION_ADD, p->conf.id, &p->conf, sizeof(struct peer_config)) == -1) fatalx("imsg_compose error"); if (p->conf.template) { /* apply the conf to all clones */ struct peer *np; for (np = peers; np; np = np->next) { if (np->template != p) continue; session_template_clone(np, NULL, np->conf.id, np->conf.remote_as); if (imsg_rde(IMSG_SESSION_ADD, np->conf.id, &np->conf, sizeof(struct peer_config)) == -1) fatalx("imsg_compose" " error"); } } } break; case IMSG_RECONF_LISTENER: if (idx != PFD_PIPE_MAIN) fatalx("reconf request not from parent"); if (nconf == NULL) fatalx("IMSG_RECONF_LISTENER but no config"); nla = imsg.data; TAILQ_FOREACH(la, conf->listen_addrs, entry) if (!la_cmp(la, nla)) break; if (la == NULL) { if (nla->reconf != RECONF_REINIT) fatalx("king bula sez: " "expected REINIT"); if ((nla->fd = imsg.fd) == -1) log_warnx("expected to receive fd for " "%s but didn't receive any", log_sockaddr((struct sockaddr *) &nla->sa)); la = calloc(1, sizeof(struct listen_addr)); if (la == NULL) fatal(NULL); memcpy(&la->sa, &nla->sa, sizeof(la->sa)); la->flags = nla->flags; la->fd = nla->fd; la->reconf = RECONF_REINIT; TAILQ_INSERT_TAIL(nconf->listen_addrs, la, entry); } else { if (nla->reconf != RECONF_KEEP) fatalx("king bula sez: expected KEEP"); la->reconf = RECONF_KEEP; } break; case IMSG_RECONF_CTRL: if (idx != PFD_PIPE_MAIN) fatalx("reconf request not from parent"); if (imsg.hdr.len != IMSG_HEADER_SIZE + sizeof(restricted)) fatalx("IFINFO imsg with wrong len"); memcpy(&restricted, imsg.data, sizeof(restricted)); if (imsg.fd == -1) { log_warnx("expected to receive fd for control " "socket but didn't receive any"); break; } if (restricted) { control_shutdown(rcsock); rcsock = imsg.fd; } else { control_shutdown(csock); csock = imsg.fd; } break; case IMSG_RECONF_DRAIN: if (idx != PFD_PIPE_MAIN) fatalx("reconf request not from parent"); imsg_compose(ibuf_main, IMSG_RECONF_DRAIN, 0, 0, -1, NULL, 0); break; case IMSG_RECONF_DONE: if (idx != PFD_PIPE_MAIN) fatalx("reconf request not from parent"); if (nconf == NULL) fatalx("got IMSG_RECONF_DONE but no config"); conf->flags = nconf->flags; conf->log = nconf->log; conf->bgpid = nconf->bgpid; conf->clusterid = nconf->clusterid; conf->as = nconf->as; conf->short_as = nconf->short_as; conf->holdtime = nconf->holdtime; conf->min_holdtime = nconf->min_holdtime; conf->connectretry = nconf->connectretry; /* add new peers */ for (p = npeers; p != NULL; p = next) { next = p->next; p->next = peers; peers = p; } /* find ones that need attention */ for (p = peers; p != NULL; p = p->next) { /* needs to be deleted? */ if (p->conf.reconf_action == RECONF_NONE && !p->template) p->conf.reconf_action = RECONF_DELETE; /* had demotion, is demoted, demote removed? */ if (p->demoted && !p->conf.demote_group[0]) session_demote(p, -1); } /* delete old listeners */ for (la = TAILQ_FIRST(conf->listen_addrs); la != NULL; la = nla) { nla = TAILQ_NEXT(la, entry); if (la->reconf == RECONF_NONE) { log_info("not listening on %s any more", log_sockaddr( (struct sockaddr *)&la->sa)); TAILQ_REMOVE(conf->listen_addrs, la, entry); close(la->fd); free(la); } } /* add new listeners */ while ((la = TAILQ_FIRST(nconf->listen_addrs)) != NULL) { TAILQ_REMOVE(nconf->listen_addrs, la, entry); TAILQ_INSERT_TAIL(conf->listen_addrs, la, entry); } setup_listeners(listener_cnt); free(nconf->listen_addrs); free(nconf); nconf = NULL; pending_reconf = 0; log_info("SE reconfigured"); imsg_compose(ibuf_main, IMSG_RECONF_DONE, 0, 0, -1, NULL, 0); break; case IMSG_IFINFO: if (idx != PFD_PIPE_MAIN) fatalx("IFINFO message not from parent"); if (imsg.hdr.len != IMSG_HEADER_SIZE + sizeof(struct kif)) fatalx("IFINFO imsg with wrong len"); kif = imsg.data; depend_ok = session_link_state_is_up(kif->flags, kif->if_type, kif->link_state); for (p = peers; p != NULL; p = p->next) if (!strcmp(p->conf.if_depend, kif->ifname)) { if (depend_ok && !p->depend_ok) { p->depend_ok = depend_ok; bgp_fsm(p, EVNT_START); } else if (!depend_ok && p->depend_ok) { p->depend_ok = depend_ok; session_stop(p, ERR_CEASE_OTHER_CHANGE); } } break; case IMSG_MRT_OPEN: case IMSG_MRT_REOPEN: if (imsg.hdr.len > IMSG_HEADER_SIZE + sizeof(struct mrt)) { log_warnx("wrong imsg len"); break; } memcpy(&xmrt, imsg.data, sizeof(struct mrt)); if ((xmrt.wbuf.fd = imsg.fd) == -1) log_warnx("expected to receive fd for mrt dump " "but didn't receive any"); mrt = mrt_get(&mrthead, &xmrt); if (mrt == NULL) { /* new dump */ mrt = calloc(1, sizeof(struct mrt)); if (mrt == NULL) fatal("session_dispatch_imsg"); memcpy(mrt, &xmrt, sizeof(struct mrt)); TAILQ_INIT(&mrt->wbuf.bufs); LIST_INSERT_HEAD(&mrthead, mrt, entry); } else { /* old dump reopened */ close(mrt->wbuf.fd); mrt->wbuf.fd = xmrt.wbuf.fd; } break; case IMSG_MRT_CLOSE: if (imsg.hdr.len > IMSG_HEADER_SIZE + sizeof(struct mrt)) { log_warnx("wrong imsg len"); break; } memcpy(&xmrt, imsg.data, sizeof(struct mrt)); mrt = mrt_get(&mrthead, &xmrt); if (mrt != NULL) mrt_done(mrt); break; case IMSG_CTL_KROUTE: case IMSG_CTL_KROUTE_ADDR: case IMSG_CTL_SHOW_NEXTHOP: case IMSG_CTL_SHOW_INTERFACE: case IMSG_CTL_SHOW_FIB_TABLES: if (idx != PFD_PIPE_MAIN) fatalx("ctl kroute request not from parent"); control_imsg_relay(&imsg); break; case IMSG_CTL_SHOW_RIB: case IMSG_CTL_SHOW_RIB_PREFIX: case IMSG_CTL_SHOW_RIB_ATTR: case IMSG_CTL_SHOW_RIB_MEM: case IMSG_CTL_SHOW_RIB_HASH: case IMSG_CTL_SHOW_NETWORK: case IMSG_CTL_SHOW_NEIGHBOR: if (idx != PFD_PIPE_ROUTE_CTL) fatalx("ctl rib request not from RDE"); control_imsg_relay(&imsg); break; case IMSG_CTL_END: case IMSG_CTL_RESULT: control_imsg_relay(&imsg); break; case IMSG_UPDATE: if (idx != PFD_PIPE_ROUTE) fatalx("update request not from RDE"); if (imsg.hdr.len > IMSG_HEADER_SIZE + MAX_PKTSIZE - MSGSIZE_HEADER || imsg.hdr.len < IMSG_HEADER_SIZE + MSGSIZE_UPDATE_MIN - MSGSIZE_HEADER) log_warnx("RDE sent invalid update"); else session_update(imsg.hdr.peerid, imsg.data, imsg.hdr.len - IMSG_HEADER_SIZE); break; case IMSG_UPDATE_ERR: if (idx != PFD_PIPE_ROUTE) fatalx("update request not from RDE"); if (imsg.hdr.len < IMSG_HEADER_SIZE + 2) { log_warnx("RDE sent invalid notification"); break; } if ((p = getpeerbyid(imsg.hdr.peerid)) == NULL) { log_warnx("no such peer: id=%u", imsg.hdr.peerid); break; } data = imsg.data; errcode = *data++; subcode = *data++; if (imsg.hdr.len == IMSG_HEADER_SIZE + 2) data = NULL; session_notification(p, errcode, subcode, data, imsg.hdr.len - IMSG_HEADER_SIZE - 2); switch (errcode) { case ERR_CEASE: switch (subcode) { case ERR_CEASE_MAX_PREFIX: bgp_fsm(p, EVNT_STOP); if (p->conf.max_prefix_restart) timer_set(p, Timer_IdleHold, 60 * p->conf.max_prefix_restart); break; default: bgp_fsm(p, EVNT_CON_FATAL); break; } break; default: bgp_fsm(p, EVNT_CON_FATAL); break; } break; case IMSG_SESSION_RESTARTED: if (idx != PFD_PIPE_ROUTE) fatalx("update request not from RDE"); if (imsg.hdr.len < IMSG_HEADER_SIZE + sizeof(aid)) { log_warnx("RDE sent invalid restart msg"); break; } if ((p = getpeerbyid(imsg.hdr.peerid)) == NULL) { log_warnx("no such peer: id=%u", imsg.hdr.peerid); break; } memcpy(&aid, imsg.data, sizeof(aid)); if (aid >= AID_MAX) fatalx("IMSG_SESSION_RESTARTED: bad AID"); if (p->capa.neg.grestart.flags[aid] & CAPA_GR_RESTARTING) { log_peer_warnx(&p->conf, "graceful restart of %s finished", aid2str(aid)); p->capa.neg.grestart.flags[aid] &= ~CAPA_GR_RESTARTING; timer_stop(p, Timer_RestartTimeout); /* signal back to RDE to cleanup stale routes */ if (imsg_rde(IMSG_SESSION_RESTARTED, imsg.hdr.peerid, &aid, sizeof(aid)) == -1) fatal("imsg_compose: " "IMSG_SESSION_RESTARTED"); } break; case IMSG_SESSION_DOWN: if (idx != PFD_PIPE_ROUTE) fatalx("update request not from RDE"); if ((p = getpeerbyid(imsg.hdr.peerid)) == NULL) { log_warnx("no such peer: id=%u", imsg.hdr.peerid); break; } session_stop(p, ERR_CEASE_ADMIN_DOWN); break; default: break; } imsg_free(&imsg); } } int la_cmp(struct listen_addr *a, struct listen_addr *b) { struct sockaddr_in *in_a, *in_b; struct sockaddr_in6 *in6_a, *in6_b; if (a->sa.ss_family != b->sa.ss_family) return (1); switch (a->sa.ss_family) { case AF_INET: in_a = (struct sockaddr_in *)&a->sa; in_b = (struct sockaddr_in *)&b->sa; if (in_a->sin_addr.s_addr != in_b->sin_addr.s_addr) return (1); if (in_a->sin_port != in_b->sin_port) return (1); break; case AF_INET6: in6_a = (struct sockaddr_in6 *)&a->sa; in6_b = (struct sockaddr_in6 *)&b->sa; if (bcmp(&in6_a->sin6_addr, &in6_b->sin6_addr, sizeof(struct in6_addr))) return (1); if (in6_a->sin6_port != in6_b->sin6_port) return (1); break; default: fatal("king bula sez: unknown address family"); /* NOTREACHED */ } return (0); } struct peer * getpeerbyaddr(struct bgpd_addr *addr) { struct peer *p; /* we might want a more effective way to find peers by IP */ for (p = peers; p != NULL && memcmp(&p->conf.remote_addr, addr, sizeof(p->conf.remote_addr)); p = p->next) ; /* nothing */ return (p); } struct peer * getpeerbydesc(const char *descr) { struct peer *p, *res = NULL; int match = 0; for (p = peers; p != NULL; p = p->next) if (!strcmp(p->conf.descr, descr)) { res = p; match++; } if (match > 1) log_info("neighbor description \"%s\" not unique, request " "aborted", descr); if (match == 1) return (res); else return (NULL); } struct peer * getpeerbyip(struct sockaddr *ip) { struct bgpd_addr addr; struct peer *p, *newpeer, *loose = NULL; u_int32_t id; sa2addr(ip, &addr); /* we might want a more effective way to find peers by IP */ for (p = peers; p != NULL; p = p->next) if (!p->conf.template && !memcmp(&addr, &p->conf.remote_addr, sizeof(addr))) return (p); /* try template matching */ for (p = peers; p != NULL; p = p->next) if (p->conf.template && p->conf.remote_addr.aid == addr.aid && session_match_mask(p, &addr)) if (loose == NULL || loose->conf.remote_masklen < p->conf.remote_masklen) loose = p; if (loose != NULL) { /* clone */ if ((newpeer = malloc(sizeof(struct peer))) == NULL) fatal(NULL); memcpy(newpeer, loose, sizeof(struct peer)); for (id = UINT_MAX; id > UINT_MAX / 2; id--) { for (p = peers; p != NULL && p->conf.id != id; p = p->next) ; /* nothing */ if (p == NULL) { /* we found a free id */ break; } } newpeer->template = loose; session_template_clone(newpeer, ip, id, 0); newpeer->state = newpeer->prev_state = STATE_NONE; newpeer->conf.reconf_action = RECONF_KEEP; newpeer->rbuf = NULL; init_peer(newpeer); bgp_fsm(newpeer, EVNT_START); newpeer->next = peers; peers = newpeer; return (newpeer); } return (NULL); } void session_template_clone(struct peer *p, struct sockaddr *ip, u_int32_t id, u_int32_t as) { struct bgpd_addr remote_addr; if (ip) sa2addr(ip, &remote_addr); else memcpy(&remote_addr, &p->conf.remote_addr, sizeof(remote_addr)); memcpy(&p->conf, &p->template->conf, sizeof(struct peer_config)); p->conf.id = id; if (as) { p->conf.remote_as = as; p->conf.ebgp = (p->conf.remote_as != p->conf.local_as); if (!p->conf.ebgp) /* force enforce_as off for iBGP sessions */ p->conf.enforce_as = ENFORCE_AS_OFF; } memcpy(&p->conf.remote_addr, &remote_addr, sizeof(remote_addr)); switch (p->conf.remote_addr.aid) { case AID_INET: p->conf.remote_masklen = 32; break; case AID_INET6: p->conf.remote_masklen = 128; break; } p->conf.template = 0; } int session_match_mask(struct peer *p, struct bgpd_addr *a) { struct in_addr v4masked; struct in6_addr v6masked; switch (p->conf.remote_addr.aid) { case AID_INET: inet4applymask(&v4masked, &a->v4, p->conf.remote_masklen); if (p->conf.remote_addr.v4.s_addr == v4masked.s_addr) return (1); return (0); case AID_INET6: inet6applymask(&v6masked, &a->v6, p->conf.remote_masklen); if (memcmp(&v6masked, &p->conf.remote_addr.v6, sizeof(v6masked)) == 0) return (1); return (0); } return (0); } struct peer * getpeerbyid(u_int32_t peerid) { struct peer *p; /* we might want a more effective way to find peers by IP */ for (p = peers; p != NULL && p->conf.id != peerid; p = p->next) ; /* nothing */ return (p); } void session_down(struct peer *peer) { bzero(&peer->capa.neg, sizeof(peer->capa.neg)); peer->stats.last_updown = time(NULL); /* * session_down is called in the exit code path so check * if the RDE is still around, if not there is no need to * send the message. */ if (ibuf_rde == NULL) return; if (imsg_rde(IMSG_SESSION_DOWN, peer->conf.id, NULL, 0) == -1) fatalx("imsg_compose error"); } void session_up(struct peer *p) { struct session_up sup; if (imsg_rde(IMSG_SESSION_ADD, p->conf.id, &p->conf, sizeof(p->conf)) == -1) fatalx("imsg_compose error"); sa2addr((struct sockaddr *)&p->sa_local, &sup.local_addr); sa2addr((struct sockaddr *)&p->sa_remote, &sup.remote_addr); sup.remote_bgpid = p->remote_bgpid; sup.short_as = p->short_as; memcpy(&sup.capa, &p->capa.neg, sizeof(sup.capa)); p->stats.last_updown = time(NULL); if (imsg_rde(IMSG_SESSION_UP, p->conf.id, &sup, sizeof(sup)) == -1) fatalx("imsg_compose error"); } int imsg_ctl_parent(int type, u_int32_t peerid, pid_t pid, void *data, u_int16_t datalen) { return (imsg_compose(ibuf_main, type, peerid, pid, -1, data, datalen)); } int imsg_ctl_rde(int type, pid_t pid, void *data, u_int16_t datalen) { if (ibuf_rde_ctl == NULL) { log_warnx("Can't send message %u to RDE, ctl pipe closed", type); return (0); } /* * Use control socket to talk to RDE to bypass the queue of the * regular imsg socket. */ return (imsg_compose(ibuf_rde_ctl, type, 0, pid, -1, data, datalen)); } int imsg_rde(int type, uint32_t peerid, void *data, u_int16_t datalen) { if (ibuf_rde == NULL) { log_warnx("Can't send message %u to RDE, pipe closed", type); return (0); } return (imsg_compose(ibuf_rde, type, peerid, 0, -1, data, datalen)); } void session_demote(struct peer *p, int level) { struct demote_msg msg; strlcpy(msg.demote_group, p->conf.demote_group, sizeof(msg.demote_group)); msg.level = level; if (imsg_compose(ibuf_main, IMSG_DEMOTE, p->conf.id, 0, -1, &msg, sizeof(msg)) == -1) fatalx("imsg_compose error"); p->demoted += level; } void session_stop(struct peer *peer, u_int8_t subcode) { char data[SHUT_COMM_LEN]; uint8_t datalen; uint8_t shutcomm_len; char *communication; datalen = 0; communication = peer->conf.shutcomm; if ((subcode == ERR_CEASE_ADMIN_DOWN || subcode == ERR_CEASE_ADMIN_RESET) && communication && *communication) { shutcomm_len = strlen(communication); if(shutcomm_len < SHUT_COMM_LEN) { data[0] = shutcomm_len; datalen = shutcomm_len + sizeof(data[0]); memcpy(data + 1, communication, shutcomm_len); } } switch (peer->state) { case STATE_OPENSENT: case STATE_OPENCONFIRM: case STATE_ESTABLISHED: session_notification(peer, ERR_CEASE, subcode, data, datalen); break; default: /* session not open, no need to send notification */ break; } bgp_fsm(peer, EVNT_STOP); } /* * return 1 when the interface is up * and the link state is up or unknwown * except when this is a carp interface, then * return 1 only when link state is up */ int session_link_state_is_up(int flags, int type, int link_state) { if (!(flags & IFF_UP)) return (0); if (type == IFT_CARP && link_state == LINK_STATE_UNKNOWN) return (0); return LINK_STATE_IS_UP(link_state); }