// SPDX-License-Identifier: GPL-2.0-or-later /********************************************************************* * Copyright 2013 Cumulus Networks, LLC. All rights reserved. * Copyright 2014,2015,2016,2017 Cumulus Networks, Inc. All rights reserved. * * bfd.c: implements the BFD protocol. * * Authors * ------- * Shrijeet Mukherjee [shm@cumulusnetworks.com] * Kanna Rajagopal [kanna@cumulusnetworks.com] * Radhika Mahankali [Radhika@cumulusnetworks.com] */ #include #include "lib/jhash.h" #include "lib/network.h" #include "bfd.h" DEFINE_MTYPE_STATIC(BFDD, BFDD_CONFIG, "long-lived configuration memory"); DEFINE_MTYPE_STATIC(BFDD, BFDD_PROFILE, "long-lived profile memory"); DEFINE_MTYPE_STATIC(BFDD, BFDD_SESSION_OBSERVER, "Session observer"); DEFINE_MTYPE_STATIC(BFDD, BFDD_VRF, "BFD VRF"); /* * Prototypes */ static uint32_t ptm_bfd_gen_ID(void); static void ptm_bfd_echo_xmt_TO(struct bfd_session *bfd); static struct bfd_session *bfd_find_disc(struct sockaddr_any *sa, uint32_t ldisc); static int bfd_session_update(struct bfd_session *bs, struct bfd_peer_cfg *bpc); static const char *get_diag_str(int diag); static void bs_admin_down_handler(struct bfd_session *bs, int nstate); static void bs_down_handler(struct bfd_session *bs, int nstate); static void bs_init_handler(struct bfd_session *bs, int nstate); static void bs_up_handler(struct bfd_session *bs, int nstate); /** * Remove BFD profile from all BFD sessions so we don't leave dangling * pointers. */ static void bfd_profile_detach(struct bfd_profile *bp); /* Zeroed array with the size of an IPv6 address. */ struct in6_addr zero_addr; /** BFD profiles list. */ struct bfdproflist bplist; /* * Functions */ struct bfd_profile *bfd_profile_lookup(const char *name) { struct bfd_profile *bp; TAILQ_FOREACH (bp, &bplist, entry) { if (strcmp(name, bp->name)) continue; return bp; } return NULL; } static void bfd_profile_set_default(struct bfd_profile *bp) { bp->admin_shutdown = false; bp->detection_multiplier = BFD_DEFDETECTMULT; bp->echo_mode = false; bp->passive = false; bp->minimum_ttl = BFD_DEF_MHOP_TTL; bp->min_echo_rx = BFD_DEF_REQ_MIN_ECHO_RX; bp->min_echo_tx = BFD_DEF_DES_MIN_ECHO_TX; bp->min_rx = BFD_DEFREQUIREDMINRX; bp->min_tx = BFD_DEFDESIREDMINTX; } struct bfd_profile *bfd_profile_new(const char *name) { struct bfd_profile *bp; /* Search for duplicates. */ if (bfd_profile_lookup(name) != NULL) return NULL; /* Allocate, name it and put into list. */ bp = XCALLOC(MTYPE_BFDD_PROFILE, sizeof(*bp)); strlcpy(bp->name, name, sizeof(bp->name)); TAILQ_INSERT_TAIL(&bplist, bp, entry); /* Set default values. */ bfd_profile_set_default(bp); return bp; } void bfd_profile_free(struct bfd_profile *bp) { /* Detach from any session. */ if (bglobal.bg_shutdown == false) bfd_profile_detach(bp); /* Remove from global list. */ TAILQ_REMOVE(&bplist, bp, entry); XFREE(MTYPE_BFDD_PROFILE, bp); } void bfd_profile_apply(const char *profname, struct bfd_session *bs) { struct bfd_profile *bp; /* Remove previous profile if any. */ if (bs->profile_name) { /* We are changing profiles. */ if (strcmp(bs->profile_name, profname)) { XFREE(MTYPE_BFDD_PROFILE, bs->profile_name); bs->profile_name = XSTRDUP(MTYPE_BFDD_PROFILE, profname); } } else /* Save the current profile name (in case it doesn't exist). */ bs->profile_name = XSTRDUP(MTYPE_BFDD_PROFILE, profname); /* Look up new profile to apply. */ bp = bfd_profile_lookup(profname); /* Point to profile if it exists. */ bs->profile = bp; /* Apply configuration. */ bfd_session_apply(bs); } void bfd_session_apply(struct bfd_session *bs) { struct bfd_profile *bp; uint32_t min_tx = bs->timers.desired_min_tx; uint32_t min_rx = bs->timers.required_min_rx; /* Pick the source of configuration. */ bp = bs->profile ? bs->profile : &bs->peer_profile; /* Set multiplier if not the default. */ if (bs->peer_profile.detection_multiplier == BFD_DEFDETECTMULT) bs->detect_mult = bp->detection_multiplier; else bs->detect_mult = bs->peer_profile.detection_multiplier; /* Set timers if not the default. */ if (bs->peer_profile.min_tx == BFD_DEFDESIREDMINTX) bs->timers.desired_min_tx = bp->min_tx; else bs->timers.desired_min_tx = bs->peer_profile.min_tx; if (bs->peer_profile.min_rx == BFD_DEFREQUIREDMINRX) bs->timers.required_min_rx = bp->min_rx; else bs->timers.required_min_rx = bs->peer_profile.min_rx; /* We can only apply echo options on single hop sessions. */ if (!CHECK_FLAG(bs->flags, BFD_SESS_FLAG_MH)) { /* Configure echo timers if they were default. */ if (bs->peer_profile.min_echo_rx == BFD_DEF_REQ_MIN_ECHO_RX) bs->timers.required_min_echo_rx = bp->min_echo_rx; else bs->timers.required_min_echo_rx = bs->peer_profile.min_echo_rx; if (bs->peer_profile.min_echo_tx == BFD_DEF_DES_MIN_ECHO_TX) bs->timers.desired_min_echo_tx = bp->min_echo_tx; else bs->timers.desired_min_echo_tx = bs->peer_profile.min_echo_tx; /* Toggle echo if default value. */ if (bs->peer_profile.echo_mode == false) bfd_set_echo(bs, bp->echo_mode); else bfd_set_echo(bs, bs->peer_profile.echo_mode); } else { /* Configure the TTL packet filter. */ if (bs->peer_profile.minimum_ttl == BFD_DEF_MHOP_TTL) bs->mh_ttl = bp->minimum_ttl; else bs->mh_ttl = bs->peer_profile.minimum_ttl; } /* Toggle 'passive-mode' if default value. */ if (bs->peer_profile.passive == false) bfd_set_passive_mode(bs, bp->passive); else bfd_set_passive_mode(bs, bs->peer_profile.passive); /* Toggle 'no shutdown' if default value. */ if (bs->peer_profile.admin_shutdown == false) bfd_set_shutdown(bs, bp->admin_shutdown); else bfd_set_shutdown(bs, bs->peer_profile.admin_shutdown); /* If session interval changed negotiate new timers. */ if (bs->ses_state == PTM_BFD_UP && (bs->timers.desired_min_tx != min_tx || bs->timers.required_min_rx != min_rx)) bfd_set_polling(bs); /* Send updated information to data plane. */ bfd_dplane_update_session(bs); } void bfd_profile_remove(struct bfd_session *bs) { /* Remove any previous set profile name. */ XFREE(MTYPE_BFDD_PROFILE, bs->profile_name); bs->profile = NULL; bfd_session_apply(bs); } void gen_bfd_key(struct bfd_key *key, struct sockaddr_any *peer, struct sockaddr_any *local, bool mhop, const char *ifname, const char *vrfname) { memset(key, 0, sizeof(*key)); switch (peer->sa_sin.sin_family) { case AF_INET: key->family = AF_INET; memcpy(&key->peer, &peer->sa_sin.sin_addr, sizeof(peer->sa_sin.sin_addr)); memcpy(&key->local, &local->sa_sin.sin_addr, sizeof(local->sa_sin.sin_addr)); break; case AF_INET6: key->family = AF_INET6; memcpy(&key->peer, &peer->sa_sin6.sin6_addr, sizeof(peer->sa_sin6.sin6_addr)); memcpy(&key->local, &local->sa_sin6.sin6_addr, sizeof(local->sa_sin6.sin6_addr)); break; } key->mhop = mhop; if (ifname && ifname[0]) strlcpy(key->ifname, ifname, sizeof(key->ifname)); if (vrfname && vrfname[0]) strlcpy(key->vrfname, vrfname, sizeof(key->vrfname)); else strlcpy(key->vrfname, VRF_DEFAULT_NAME, sizeof(key->vrfname)); } struct bfd_session *bs_peer_find(struct bfd_peer_cfg *bpc) { struct bfd_session *bs; struct peer_label *pl; struct bfd_key key; /* Try to find label first. */ if (bpc->bpc_has_label) { pl = pl_find(bpc->bpc_label); if (pl != NULL) { bs = pl->pl_bs; return bs; } } /* Otherwise fallback to peer/local hash lookup. */ gen_bfd_key(&key, &bpc->bpc_peer, &bpc->bpc_local, bpc->bpc_mhop, bpc->bpc_localif, bpc->bpc_vrfname); return bfd_key_lookup(key); } /* * Starts a disabled BFD session. * * A session is disabled when the specified interface/VRF doesn't exist * yet. It might happen on FRR boot or with virtual interfaces. */ int bfd_session_enable(struct bfd_session *bs) { struct interface *ifp = NULL; struct vrf *vrf = NULL; int psock; /* We are using data plane, we don't need software. */ if (bs->bdc) return 0; /* * If the interface or VRF doesn't exist, then we must register * the session but delay its start. */ if (bs->key.vrfname[0]) { vrf = vrf_lookup_by_name(bs->key.vrfname); if (vrf == NULL) { zlog_err( "session-enable: specified VRF %s doesn't exists.", bs->key.vrfname); return 0; } } else { vrf = vrf_lookup_by_id(VRF_DEFAULT); } assert(vrf); if (bs->key.ifname[0]) { ifp = if_lookup_by_name(bs->key.ifname, vrf->vrf_id); if (ifp == NULL) { zlog_err( "session-enable: specified interface %s (VRF %s) doesn't exist.", bs->key.ifname, vrf->name); return 0; } } /* Assign interface/VRF pointers. */ bs->vrf = vrf; /* Assign interface pointer (if any). */ bs->ifp = ifp; /* Attempt to use data plane. */ if (bglobal.bg_use_dplane && bfd_dplane_add_session(bs) == 0) { control_notify_config(BCM_NOTIFY_CONFIG_ADD, bs); return 0; } /* Sanity check: don't leak open sockets. */ if (bs->sock != -1) { if (bglobal.debug_peer_event) zlog_debug("%s: previous socket open", __func__); close(bs->sock); bs->sock = -1; } /* * Get socket for transmitting control packets. Note that if we * could use the destination port (3784) for the source * port we wouldn't need a socket per session. */ if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_IPV6) == 0) { psock = bp_peer_socket(bs); if (psock == -1) return 0; } else { psock = bp_peer_socketv6(bs); if (psock == -1) return 0; } /* * We've got a valid socket, lets start the timers and the * protocol. */ bs->sock = psock; /* Only start timers if we are using active mode. */ if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_PASSIVE) == 0) { bfd_recvtimer_update(bs); ptm_bfd_start_xmt_timer(bs, false); } /* initialize RTT */ bfd_rtt_init(bs); return 0; } /* * Disabled a running BFD session. * * A session is disabled when the specified interface/VRF gets removed * (e.g. virtual interfaces). */ void bfd_session_disable(struct bfd_session *bs) { /* We are using data plane, we don't need software. */ if (bs->bdc) return; /* Free up socket resources. */ if (bs->sock != -1) { close(bs->sock); bs->sock = -1; } /* Disable all timers. */ bfd_recvtimer_delete(bs); bfd_xmttimer_delete(bs); ptm_bfd_echo_stop(bs); /* Set session down so it doesn't report UP and disabled. */ ptm_bfd_sess_dn(bs, BD_PATH_DOWN); } static uint32_t ptm_bfd_gen_ID(void) { uint32_t session_id; /* * RFC 5880, Section 6.8.1. recommends that we should generate * random session identification numbers. */ do { session_id = ((frr_weak_random() << 16) & 0xFFFF0000) | (frr_weak_random() & 0x0000FFFF); } while (session_id == 0 || bfd_id_lookup(session_id) != NULL); return session_id; } void ptm_bfd_start_xmt_timer(struct bfd_session *bfd, bool is_echo) { uint64_t jitter, xmt_TO; int maxpercent; xmt_TO = is_echo ? bfd->echo_xmt_TO : bfd->xmt_TO; /* * From section 6.5.2: trasmit interval should be randomly jittered * between * 75% and 100% of nominal value, unless detect_mult is 1, then should * be * between 75% and 90%. */ maxpercent = (bfd->detect_mult == 1) ? 16 : 26; jitter = (xmt_TO * (75 + (frr_weak_random() % maxpercent))) / 100; /* XXX remove that division above */ if (is_echo) bfd_echo_xmttimer_update(bfd, jitter); else bfd_xmttimer_update(bfd, jitter); } static void ptm_bfd_echo_xmt_TO(struct bfd_session *bfd) { /* Send the scheduled echo packet */ /* if ipv4 use the new echo implementation that causes * the packet to be looped in forwarding plane of peer */ if (CHECK_FLAG(bfd->flags, BFD_SESS_FLAG_IPV6) == 0) #ifdef BFD_LINUX ptm_bfd_echo_fp_snd(bfd); #else ptm_bfd_echo_snd(bfd); #endif else ptm_bfd_echo_snd(bfd); /* Restart the timer for next time */ ptm_bfd_start_xmt_timer(bfd, true); } void ptm_bfd_xmt_TO(struct bfd_session *bfd, int fbit) { /* Send the scheduled control packet */ ptm_bfd_snd(bfd, fbit); /* Restart the timer for next time */ ptm_bfd_start_xmt_timer(bfd, false); } void ptm_bfd_echo_stop(struct bfd_session *bfd) { bfd->echo_xmt_TO = 0; bfd->echo_detect_TO = 0; UNSET_FLAG(bfd->flags, BFD_SESS_FLAG_ECHO_ACTIVE); bfd_echo_xmttimer_delete(bfd); bfd_echo_recvtimer_delete(bfd); } void ptm_bfd_echo_start(struct bfd_session *bfd) { bfd->echo_detect_TO = (bfd->remote_detect_mult * bfd->echo_xmt_TO); if (bfd->echo_detect_TO > 0) { bfd_echo_recvtimer_update(bfd); ptm_bfd_echo_xmt_TO(bfd); } } void ptm_bfd_sess_up(struct bfd_session *bfd) { int old_state = bfd->ses_state; bfd->local_diag = 0; bfd->ses_state = PTM_BFD_UP; monotime(&bfd->uptime); /* Connection is up, lets negotiate timers. */ bfd_set_polling(bfd); /* Start sending control packets with poll bit immediately. */ ptm_bfd_snd(bfd, 0); control_notify(bfd, bfd->ses_state); if (old_state != bfd->ses_state) { bfd->stats.session_up++; if (bglobal.debug_peer_event) zlog_debug("state-change: [%s] %s -> %s", bs_to_string(bfd), state_list[old_state].str, state_list[bfd->ses_state].str); } } void ptm_bfd_sess_dn(struct bfd_session *bfd, uint8_t diag) { int old_state = bfd->ses_state; bfd->local_diag = diag; bfd->discrs.remote_discr = 0; bfd->ses_state = PTM_BFD_DOWN; bfd->polling = 0; bfd->demand_mode = 0; monotime(&bfd->downtime); /* * Only attempt to send if we have a valid socket: * this function might be called by session disablers and in * this case we won't have a valid socket (i.e. interface was * removed or VRF doesn't exist anymore). */ if (bfd->sock != -1) ptm_bfd_snd(bfd, 0); /* Slow down the control packets, the connection is down. */ bs_set_slow_timers(bfd); /* only signal clients when going from up->down state */ if (old_state == PTM_BFD_UP) control_notify(bfd, PTM_BFD_DOWN); /* Stop echo packet transmission if they are active */ if (CHECK_FLAG(bfd->flags, BFD_SESS_FLAG_ECHO_ACTIVE)) ptm_bfd_echo_stop(bfd); /* Stop attempting to transmit or expect control packets if passive. */ if (CHECK_FLAG(bfd->flags, BFD_SESS_FLAG_PASSIVE)) { bfd_recvtimer_delete(bfd); bfd_xmttimer_delete(bfd); } if (old_state != bfd->ses_state) { bfd->stats.session_down++; if (bglobal.debug_peer_event) zlog_debug("state-change: [%s] %s -> %s reason:%s", bs_to_string(bfd), state_list[old_state].str, state_list[bfd->ses_state].str, get_diag_str(bfd->local_diag)); } /* clear peer's mac address */ UNSET_FLAG(bfd->flags, BFD_SESS_FLAG_MAC_SET); memset(bfd->peer_hw_addr, 0, sizeof(bfd->peer_hw_addr)); /* reset local address ,it might has been be changed after bfd is up*/ memset(&bfd->local_address, 0, sizeof(bfd->local_address)); /* reset RTT */ bfd_rtt_init(bfd); } static struct bfd_session *bfd_find_disc(struct sockaddr_any *sa, uint32_t ldisc) { struct bfd_session *bs; bs = bfd_id_lookup(ldisc); if (bs == NULL) return NULL; switch (bs->key.family) { case AF_INET: if (memcmp(&sa->sa_sin.sin_addr, &bs->key.peer, sizeof(sa->sa_sin.sin_addr))) return NULL; break; case AF_INET6: if (memcmp(&sa->sa_sin6.sin6_addr, &bs->key.peer, sizeof(sa->sa_sin6.sin6_addr))) return NULL; break; } return bs; } struct bfd_session *ptm_bfd_sess_find(struct bfd_pkt *cp, struct sockaddr_any *peer, struct sockaddr_any *local, struct interface *ifp, vrf_id_t vrfid, bool is_mhop) { struct vrf *vrf; struct bfd_key key; /* Find our session using the ID signaled by the remote end. */ if (cp->discrs.remote_discr) return bfd_find_disc(peer, ntohl(cp->discrs.remote_discr)); /* Search for session without using discriminator. */ vrf = vrf_lookup_by_id(vrfid); gen_bfd_key(&key, peer, local, is_mhop, ifp ? ifp->name : NULL, vrf ? vrf->name : VRF_DEFAULT_NAME); /* XXX maybe remoteDiscr should be checked for remoteHeard cases. */ return bfd_key_lookup(key); } void bfd_xmt_cb(struct event *t) { struct bfd_session *bs = EVENT_ARG(t); ptm_bfd_xmt_TO(bs, 0); } void bfd_echo_xmt_cb(struct event *t) { struct bfd_session *bs = EVENT_ARG(t); if (bs->echo_xmt_TO > 0) ptm_bfd_echo_xmt_TO(bs); } /* Was ptm_bfd_detect_TO() */ void bfd_recvtimer_cb(struct event *t) { struct bfd_session *bs = EVENT_ARG(t); switch (bs->ses_state) { case PTM_BFD_INIT: case PTM_BFD_UP: ptm_bfd_sess_dn(bs, BD_CONTROL_EXPIRED); break; } } /* Was ptm_bfd_echo_detect_TO() */ void bfd_echo_recvtimer_cb(struct event *t) { struct bfd_session *bs = EVENT_ARG(t); switch (bs->ses_state) { case PTM_BFD_INIT: case PTM_BFD_UP: ptm_bfd_sess_dn(bs, BD_ECHO_FAILED); break; } } struct bfd_session *bfd_session_new(void) { struct bfd_session *bs; bs = XCALLOC(MTYPE_BFDD_CONFIG, sizeof(*bs)); /* Set peer session defaults. */ bfd_profile_set_default(&bs->peer_profile); bs->timers.desired_min_tx = BFD_DEFDESIREDMINTX; bs->timers.required_min_rx = BFD_DEFREQUIREDMINRX; bs->timers.required_min_echo_rx = BFD_DEF_REQ_MIN_ECHO_RX; bs->timers.desired_min_echo_tx = BFD_DEF_DES_MIN_ECHO_TX; bs->detect_mult = BFD_DEFDETECTMULT; bs->mh_ttl = BFD_DEF_MHOP_TTL; bs->ses_state = PTM_BFD_DOWN; /* Initiate connection with slow timers. */ bs_set_slow_timers(bs); /* Initiate remote settings as well. */ bs->remote_timers = bs->cur_timers; bs->remote_detect_mult = BFD_DEFDETECTMULT; bs->sock = -1; monotime(&bs->uptime); bs->downtime = bs->uptime; return bs; } int bfd_session_update_label(struct bfd_session *bs, const char *nlabel) { /* New label treatment: * - Check if the label is taken; * - Try to allocate the memory for it and register; */ if (bs->pl == NULL) { if (pl_find(nlabel) != NULL) { /* Someone is already using it. */ return -1; } pl_new(nlabel, bs); return 0; } /* * Test label change consistency: * - Do nothing if it's the same label; * - Check if the future label is already taken; * - Change label; */ if (strcmp(nlabel, bs->pl->pl_label) == 0) return -1; if (pl_find(nlabel) != NULL) return -1; strlcpy(bs->pl->pl_label, nlabel, sizeof(bs->pl->pl_label)); return 0; } static void _bfd_session_update(struct bfd_session *bs, struct bfd_peer_cfg *bpc) { if (bpc->bpc_has_txinterval) { bs->timers.desired_min_tx = bpc->bpc_txinterval * 1000; bs->peer_profile.min_tx = bs->timers.desired_min_tx; } if (bpc->bpc_has_recvinterval) { bs->timers.required_min_rx = bpc->bpc_recvinterval * 1000; bs->peer_profile.min_rx = bs->timers.required_min_rx; } if (bpc->bpc_has_detectmultiplier) { bs->detect_mult = bpc->bpc_detectmultiplier; bs->peer_profile.detection_multiplier = bs->detect_mult; } if (bpc->bpc_has_echorecvinterval) { bs->timers.required_min_echo_rx = bpc->bpc_echorecvinterval * 1000; bs->peer_profile.min_echo_rx = bs->timers.required_min_echo_rx; } if (bpc->bpc_has_echotxinterval) { bs->timers.desired_min_echo_tx = bpc->bpc_echotxinterval * 1000; bs->peer_profile.min_echo_tx = bs->timers.desired_min_echo_tx; } if (bpc->bpc_has_label) bfd_session_update_label(bs, bpc->bpc_label); if (bpc->bpc_cbit) SET_FLAG(bs->flags, BFD_SESS_FLAG_CBIT); else UNSET_FLAG(bs->flags, BFD_SESS_FLAG_CBIT); if (bpc->bpc_has_minimum_ttl) { bs->mh_ttl = bpc->bpc_minimum_ttl; bs->peer_profile.minimum_ttl = bpc->bpc_minimum_ttl; } bs->peer_profile.echo_mode = bpc->bpc_echo; bfd_set_echo(bs, bpc->bpc_echo); /* * Shutdown needs to be the last in order to avoid timers enable when * the session is disabled. */ bs->peer_profile.admin_shutdown = bpc->bpc_shutdown; bfd_set_passive_mode(bs, bpc->bpc_passive); bfd_set_shutdown(bs, bpc->bpc_shutdown); /* * Apply profile last: it also calls `bfd_set_shutdown`. * * There is no problem calling `shutdown` twice if the value doesn't * change or if it is overridden by peer specific configuration. */ if (bpc->bpc_has_profile) bfd_profile_apply(bpc->bpc_profile, bs); } static int bfd_session_update(struct bfd_session *bs, struct bfd_peer_cfg *bpc) { /* User didn't want to update, return failure. */ if (bpc->bpc_createonly) return -1; _bfd_session_update(bs, bpc); control_notify_config(BCM_NOTIFY_CONFIG_UPDATE, bs); return 0; } void bfd_session_free(struct bfd_session *bs) { struct bfd_session_observer *bso; bfd_session_disable(bs); /* Remove session from data plane if any. */ bfd_dplane_delete_session(bs); bfd_key_delete(bs->key); bfd_id_delete(bs->discrs.my_discr); /* Remove observer if any. */ TAILQ_FOREACH(bso, &bglobal.bg_obslist, bso_entry) { if (bso->bso_bs != bs) continue; break; } if (bso != NULL) bs_observer_del(bso); pl_free(bs->pl); XFREE(MTYPE_BFDD_PROFILE, bs->profile_name); XFREE(MTYPE_BFDD_CONFIG, bs); } struct bfd_session *ptm_bfd_sess_new(struct bfd_peer_cfg *bpc) { struct bfd_session *bfd, *l_bfd; /* check to see if this needs a new session */ l_bfd = bs_peer_find(bpc); if (l_bfd) { /* Requesting a duplicated peer means update configuration. */ if (bfd_session_update(l_bfd, bpc) == 0) return l_bfd; else return NULL; } /* Get BFD session storage with its defaults. */ bfd = bfd_session_new(); /* * Store interface/VRF name in case we need to delay session * start. See `bfd_session_enable` for more information. */ if (bpc->bpc_has_localif) strlcpy(bfd->key.ifname, bpc->bpc_localif, sizeof(bfd->key.ifname)); if (bpc->bpc_has_vrfname) strlcpy(bfd->key.vrfname, bpc->bpc_vrfname, sizeof(bfd->key.vrfname)); else strlcpy(bfd->key.vrfname, VRF_DEFAULT_NAME, sizeof(bfd->key.vrfname)); /* Copy remaining data. */ if (bpc->bpc_ipv4 == false) SET_FLAG(bfd->flags, BFD_SESS_FLAG_IPV6); bfd->key.family = (bpc->bpc_ipv4) ? AF_INET : AF_INET6; switch (bfd->key.family) { case AF_INET: memcpy(&bfd->key.peer, &bpc->bpc_peer.sa_sin.sin_addr, sizeof(bpc->bpc_peer.sa_sin.sin_addr)); memcpy(&bfd->key.local, &bpc->bpc_local.sa_sin.sin_addr, sizeof(bpc->bpc_local.sa_sin.sin_addr)); break; case AF_INET6: memcpy(&bfd->key.peer, &bpc->bpc_peer.sa_sin6.sin6_addr, sizeof(bpc->bpc_peer.sa_sin6.sin6_addr)); memcpy(&bfd->key.local, &bpc->bpc_local.sa_sin6.sin6_addr, sizeof(bpc->bpc_local.sa_sin6.sin6_addr)); break; default: assert(1); break; } if (bpc->bpc_mhop) SET_FLAG(bfd->flags, BFD_SESS_FLAG_MH); bfd->key.mhop = bpc->bpc_mhop; if (bs_registrate(bfd) == NULL) return NULL; /* Apply other configurations. */ _bfd_session_update(bfd, bpc); return bfd; } struct bfd_session *bs_registrate(struct bfd_session *bfd) { /* Registrate session into data structures. */ bfd_key_insert(bfd); bfd->discrs.my_discr = ptm_bfd_gen_ID(); bfd_id_insert(bfd); /* Try to enable session and schedule for packet receive/send. */ if (bfd_session_enable(bfd) == -1) { /* Unrecoverable failure, remove the session/peer. */ bfd_session_free(bfd); return NULL; } /* Add observer if we have moving parts. */ if (bfd->key.ifname[0] || bfd->key.vrfname[0] || bfd->sock == -1) bs_observer_add(bfd); if (bglobal.debug_peer_event) zlog_debug("session-new: %s", bs_to_string(bfd)); control_notify_config(BCM_NOTIFY_CONFIG_ADD, bfd); return bfd; } int ptm_bfd_sess_del(struct bfd_peer_cfg *bpc) { struct bfd_session *bs; /* Find session and call free(). */ bs = bs_peer_find(bpc); if (bs == NULL) return -1; /* This pointer is being referenced, don't let it be deleted. */ if (bs->refcount > 0) { zlog_err("session-delete: refcount failure: %" PRIu64" references", bs->refcount); return -1; } if (bglobal.debug_peer_event) zlog_debug("%s: %s", __func__, bs_to_string(bs)); control_notify_config(BCM_NOTIFY_CONFIG_DELETE, bs); bfd_session_free(bs); return 0; } void bfd_set_polling(struct bfd_session *bs) { /* * Start polling procedure: the only timers that require polling * to change value without losing connection are: * * - Desired minimum transmission interval; * - Required minimum receive interval; * * RFC 5880, Section 6.8.3. */ bs->polling = 1; } /* * bs__handler() functions implement the BFD state machine * transition mechanism. `` is the current session state and * the parameter `nstate` is the peer new state. */ static void bs_admin_down_handler(struct bfd_session *bs __attribute__((__unused__)), int nstate __attribute__((__unused__))) { /* * We are administratively down, there is no state machine * handling. */ } static void bs_down_handler(struct bfd_session *bs, int nstate) { switch (nstate) { case PTM_BFD_ADM_DOWN: /* * Remote peer doesn't want to talk, so lets keep the * connection down. */ case PTM_BFD_UP: /* Peer can't be up yet, wait it go to 'init' or 'down'. */ break; case PTM_BFD_DOWN: /* * Remote peer agreed that the path is down, lets try to * bring it up. */ bs->ses_state = PTM_BFD_INIT; /* * RFC 5880, Section 6.1. * A system taking the Passive role MUST NOT begin * sending BFD packets for a particular session until * it has received a BFD packet for that session, and thus * has learned the remote system's discriminator value. * * Now we can start transmission timer in passive mode. */ if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_PASSIVE)) ptm_bfd_xmt_TO(bs, 0); break; case PTM_BFD_INIT: /* * Remote peer told us his path is up, lets turn * activate the session. */ ptm_bfd_sess_up(bs); break; default: if (bglobal.debug_peer_event) zlog_debug("state-change: unhandled neighbor state: %d", nstate); break; } } static void bs_init_handler(struct bfd_session *bs, int nstate) { switch (nstate) { case PTM_BFD_ADM_DOWN: /* * Remote peer doesn't want to talk, so lets make the * connection down. */ ptm_bfd_sess_dn(bs, BD_NEIGHBOR_DOWN); break; case PTM_BFD_DOWN: /* Remote peer hasn't moved to first stage yet. */ break; case PTM_BFD_INIT: case PTM_BFD_UP: /* We agreed on the settings and the path is up. */ ptm_bfd_sess_up(bs); break; default: if (bglobal.debug_peer_event) zlog_debug("state-change: unhandled neighbor state: %d", nstate); break; } } static void bs_up_handler(struct bfd_session *bs, int nstate) { switch (nstate) { case PTM_BFD_ADM_DOWN: case PTM_BFD_DOWN: /* Peer lost or asked to shutdown connection. */ ptm_bfd_sess_dn(bs, BD_NEIGHBOR_DOWN); break; case PTM_BFD_INIT: case PTM_BFD_UP: /* Path is up and working. */ break; default: if (bglobal.debug_peer_event) zlog_debug("state-change: unhandled neighbor state: %d", nstate); break; } } void bs_state_handler(struct bfd_session *bs, int nstate) { switch (bs->ses_state) { case PTM_BFD_ADM_DOWN: bs_admin_down_handler(bs, nstate); break; case PTM_BFD_DOWN: bs_down_handler(bs, nstate); break; case PTM_BFD_INIT: bs_init_handler(bs, nstate); break; case PTM_BFD_UP: bs_up_handler(bs, nstate); break; default: if (bglobal.debug_peer_event) zlog_debug("state-change: [%s] is in invalid state: %d", bs_to_string(bs), nstate); break; } } /* * Handles echo timer manipulation after updating timer. */ void bs_echo_timer_handler(struct bfd_session *bs) { uint32_t old_timer; /* * Before doing any echo handling, check if it is possible to * use it. * * - Check for `echo-mode` configuration. * - Check that we are not using multi hop (RFC 5883, * Section 3). * - Check that we are already at the up state. */ if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_ECHO) == 0 || CHECK_FLAG(bs->flags, BFD_SESS_FLAG_MH) || bs->ses_state != PTM_BFD_UP) return; /* Remote peer asked to stop echo. */ if (bs->remote_timers.required_min_echo == 0) { if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_ECHO_ACTIVE)) ptm_bfd_echo_stop(bs); return; } /* * Calculate the echo transmission timer: we must not send * echo packets faster than the minimum required time * announced by the remote system. * * RFC 5880, Section 6.8.9. */ old_timer = bs->echo_xmt_TO; if (bs->remote_timers.required_min_echo > bs->timers.desired_min_echo_tx) bs->echo_xmt_TO = bs->remote_timers.required_min_echo; else bs->echo_xmt_TO = bs->timers.desired_min_echo_tx; if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_ECHO_ACTIVE) == 0 || old_timer != bs->echo_xmt_TO) ptm_bfd_echo_start(bs); } /* * RFC 5880 Section 6.5. * * When a BFD control packet with the final bit is received, we must * update the session parameters. */ void bs_final_handler(struct bfd_session *bs) { /* Start using our new timers. */ bs->cur_timers.desired_min_tx = bs->timers.desired_min_tx; bs->cur_timers.required_min_rx = bs->timers.required_min_rx; /* * TODO: demand mode. See RFC 5880 Section 6.1. * * When using demand mode we must disable the detection timer * for lost control packets. */ if (bs->demand_mode) { /* Notify watchers about changed timers. */ control_notify_config(BCM_NOTIFY_CONFIG_UPDATE, bs); return; } /* * Calculate transmission time based on new timers. * * Transmission calculation: * Unless specified by exceptions at the end of Section 6.8.7, the * transmission time will be determined by the system with the * slowest rate. * * RFC 5880, Section 6.8.7. */ if (bs->timers.desired_min_tx > bs->remote_timers.required_min_rx) bs->xmt_TO = bs->timers.desired_min_tx; else bs->xmt_TO = bs->remote_timers.required_min_rx; /* Apply new transmission timer immediately. */ ptm_bfd_start_xmt_timer(bs, false); /* Notify watchers about changed timers. */ control_notify_config(BCM_NOTIFY_CONFIG_UPDATE, bs); } void bs_set_slow_timers(struct bfd_session *bs) { /* * BFD connection must use slow timers before going up or after * losing connectivity to avoid wasting bandwidth. * * RFC 5880, Section 6.8.3. */ bs->cur_timers.desired_min_tx = BFD_DEF_SLOWTX; bs->cur_timers.required_min_rx = BFD_DEF_SLOWTX; bs->cur_timers.required_min_echo = 0; /* Set the appropriated timeouts for slow connection. */ bs->detect_TO = (BFD_DEFDETECTMULT * BFD_DEF_SLOWTX); bs->xmt_TO = BFD_DEF_SLOWTX; } void bfd_set_echo(struct bfd_session *bs, bool echo) { if (echo) { /* Check if echo mode is already active. */ if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_ECHO)) return; SET_FLAG(bs->flags, BFD_SESS_FLAG_ECHO); /* Activate/update echo receive timeout timer. */ if (bs->bdc == NULL) bs_echo_timer_handler(bs); } else { /* Check if echo mode is already disabled. */ if (!CHECK_FLAG(bs->flags, BFD_SESS_FLAG_ECHO)) return; UNSET_FLAG(bs->flags, BFD_SESS_FLAG_ECHO); /* Deactivate timeout timer. */ if (bs->bdc == NULL) ptm_bfd_echo_stop(bs); } } void bfd_set_shutdown(struct bfd_session *bs, bool shutdown) { bool is_shutdown; /* * Special case: we are batching changes and the previous state was * not shutdown. Instead of potentially disconnect a running peer, * we'll get the current status to validate we were really down. */ if (bs->ses_state == PTM_BFD_UP) is_shutdown = false; else is_shutdown = CHECK_FLAG(bs->flags, BFD_SESS_FLAG_SHUTDOWN); if (shutdown) { /* Already shutdown. */ if (is_shutdown) return; SET_FLAG(bs->flags, BFD_SESS_FLAG_SHUTDOWN); /* Handle data plane shutdown case. */ if (bs->bdc) { bs->ses_state = PTM_BFD_ADM_DOWN; bfd_dplane_update_session(bs); control_notify(bs, bs->ses_state); return; } /* Disable all events. */ bfd_recvtimer_delete(bs); bfd_echo_recvtimer_delete(bs); bfd_xmttimer_delete(bs); bfd_echo_xmttimer_delete(bs); /* Change and notify state change. */ bs->ses_state = PTM_BFD_ADM_DOWN; control_notify(bs, bs->ses_state); /* Don't try to send packets with a disabled session. */ if (bs->sock != -1) ptm_bfd_snd(bs, 0); } else { /* Already working. */ if (!is_shutdown) return; UNSET_FLAG(bs->flags, BFD_SESS_FLAG_SHUTDOWN); /* Handle data plane shutdown case. */ if (bs->bdc) { bs->ses_state = PTM_BFD_DOWN; bfd_dplane_update_session(bs); control_notify(bs, bs->ses_state); return; } /* Change and notify state change. */ bs->ses_state = PTM_BFD_DOWN; control_notify(bs, bs->ses_state); /* Enable timers if non passive, otherwise stop them. */ if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_PASSIVE)) { bfd_recvtimer_delete(bs); bfd_xmttimer_delete(bs); } else { bfd_recvtimer_update(bs); bfd_xmttimer_update(bs, bs->xmt_TO); } } } void bfd_set_passive_mode(struct bfd_session *bs, bool passive) { if (passive) { SET_FLAG(bs->flags, BFD_SESS_FLAG_PASSIVE); /* Session is already up and running, nothing to do now. */ if (bs->ses_state != PTM_BFD_DOWN) return; /* Lets disable the timers since we are now passive. */ bfd_recvtimer_delete(bs); bfd_xmttimer_delete(bs); } else { UNSET_FLAG(bs->flags, BFD_SESS_FLAG_PASSIVE); /* Session is already up and running, nothing to do now. */ if (bs->ses_state != PTM_BFD_DOWN) return; /* Session is down, let it attempt to start the connection. */ bfd_xmttimer_update(bs, bs->xmt_TO); bfd_recvtimer_update(bs); } } /* * Helper functions. */ static const char *get_diag_str(int diag) { for (int i = 0; diag_list[i].str; i++) { if (diag_list[i].type == diag) return diag_list[i].str; } return "N/A"; } const char *satostr(const struct sockaddr_any *sa) { #define INETSTR_BUFCOUNT 8 static char buf[INETSTR_BUFCOUNT][INET6_ADDRSTRLEN]; static int bufidx; const struct sockaddr_in *sin = &sa->sa_sin; const struct sockaddr_in6 *sin6 = &sa->sa_sin6; bufidx += (bufidx + 1) % INETSTR_BUFCOUNT; buf[bufidx][0] = 0; switch (sin->sin_family) { case AF_INET: inet_ntop(AF_INET, &sin->sin_addr, buf[bufidx], sizeof(buf[bufidx])); break; case AF_INET6: inet_ntop(AF_INET6, &sin6->sin6_addr, buf[bufidx], sizeof(buf[bufidx])); break; default: strlcpy(buf[bufidx], "unknown", sizeof(buf[bufidx])); break; } return buf[bufidx]; } const char *diag2str(uint8_t diag) { switch (diag) { case 0: return "ok"; case 1: return "control detection time expired"; case 2: return "echo function failed"; case 3: return "neighbor signaled session down"; case 4: return "forwarding plane reset"; case 5: return "path down"; case 6: return "concatenated path down"; case 7: return "administratively down"; case 8: return "reverse concatenated path down"; default: return "unknown"; } } int strtosa(const char *addr, struct sockaddr_any *sa) { memset(sa, 0, sizeof(*sa)); if (inet_pton(AF_INET, addr, &sa->sa_sin.sin_addr) == 1) { sa->sa_sin.sin_family = AF_INET; #ifdef HAVE_STRUCT_SOCKADDR_SA_LEN sa->sa_sin.sin_len = sizeof(sa->sa_sin); #endif /* HAVE_STRUCT_SOCKADDR_SA_LEN */ return 0; } if (inet_pton(AF_INET6, addr, &sa->sa_sin6.sin6_addr) == 1) { sa->sa_sin6.sin6_family = AF_INET6; #ifdef HAVE_STRUCT_SOCKADDR_SA_LEN sa->sa_sin6.sin6_len = sizeof(sa->sa_sin6); #endif /* HAVE_STRUCT_SOCKADDR_SA_LEN */ return 0; } return -1; } void integer2timestr(uint64_t time, char *buf, size_t buflen) { uint64_t year, month, day, hour, minute, second; int rv; #define MINUTES (60) #define HOURS (60 * MINUTES) #define DAYS (24 * HOURS) #define MONTHS (30 * DAYS) #define YEARS (12 * MONTHS) if (time >= YEARS) { year = time / YEARS; time -= year * YEARS; rv = snprintfrr(buf, buflen, "%" PRIu64 " year(s), ", year); buf += rv; buflen -= rv; } if (time >= MONTHS) { month = time / MONTHS; time -= month * MONTHS; rv = snprintfrr(buf, buflen, "%" PRIu64 " month(s), ", month); buf += rv; buflen -= rv; } if (time >= DAYS) { day = time / DAYS; time -= day * DAYS; rv = snprintfrr(buf, buflen, "%" PRIu64 " day(s), ", day); buf += rv; buflen -= rv; } if (time >= HOURS) { hour = time / HOURS; time -= hour * HOURS; rv = snprintfrr(buf, buflen, "%" PRIu64 " hour(s), ", hour); buf += rv; buflen -= rv; } if (time >= MINUTES) { minute = time / MINUTES; time -= minute * MINUTES; rv = snprintfrr(buf, buflen, "%" PRIu64 " minute(s), ", minute); buf += rv; buflen -= rv; } second = time % MINUTES; snprintfrr(buf, buflen, "%" PRIu64 " second(s)", second); } const char *bs_to_string(const struct bfd_session *bs) { static char buf[256]; char addr_buf[INET6_ADDRSTRLEN]; int pos; bool is_mhop = CHECK_FLAG(bs->flags, BFD_SESS_FLAG_MH); pos = snprintf(buf, sizeof(buf), "mhop:%s", is_mhop ? "yes" : "no"); pos += snprintf(buf + pos, sizeof(buf) - pos, " peer:%s", inet_ntop(bs->key.family, &bs->key.peer, addr_buf, sizeof(addr_buf))); pos += snprintf(buf + pos, sizeof(buf) - pos, " local:%s", inet_ntop(bs->key.family, &bs->key.local, addr_buf, sizeof(addr_buf))); if (bs->key.vrfname[0]) pos += snprintf(buf + pos, sizeof(buf) - pos, " vrf:%s", bs->key.vrfname); if (bs->key.ifname[0]) pos += snprintf(buf + pos, sizeof(buf) - pos, " ifname:%s", bs->key.ifname); (void)pos; return buf; } int bs_observer_add(struct bfd_session *bs) { struct bfd_session_observer *bso; bso = XCALLOC(MTYPE_BFDD_SESSION_OBSERVER, sizeof(*bso)); bso->bso_bs = bs; bso->bso_addr.family = bs->key.family; memcpy(&bso->bso_addr.u.prefix, &bs->key.local, sizeof(bs->key.local)); TAILQ_INSERT_TAIL(&bglobal.bg_obslist, bso, bso_entry); return 0; } void bs_observer_del(struct bfd_session_observer *bso) { TAILQ_REMOVE(&bglobal.bg_obslist, bso, bso_entry); XFREE(MTYPE_BFDD_SESSION_OBSERVER, bso); } void bs_to_bpc(struct bfd_session *bs, struct bfd_peer_cfg *bpc) { memset(bpc, 0, sizeof(*bpc)); bpc->bpc_ipv4 = (bs->key.family == AF_INET); bpc->bpc_mhop = bs->key.mhop; switch (bs->key.family) { case AF_INET: bpc->bpc_peer.sa_sin.sin_family = AF_INET; memcpy(&bpc->bpc_peer.sa_sin.sin_addr, &bs->key.peer, sizeof(bpc->bpc_peer.sa_sin.sin_addr)); if (memcmp(&bs->key.local, &zero_addr, sizeof(bs->key.local))) { bpc->bpc_local.sa_sin.sin_family = AF_INET6; memcpy(&bpc->bpc_local.sa_sin.sin_addr, &bs->key.local, sizeof(bpc->bpc_local.sa_sin.sin_addr)); } break; case AF_INET6: bpc->bpc_peer.sa_sin.sin_family = AF_INET6; memcpy(&bpc->bpc_peer.sa_sin6.sin6_addr, &bs->key.peer, sizeof(bpc->bpc_peer.sa_sin6.sin6_addr)); bpc->bpc_local.sa_sin6.sin6_family = AF_INET6; memcpy(&bpc->bpc_local.sa_sin6.sin6_addr, &bs->key.local, sizeof(bpc->bpc_local.sa_sin6.sin6_addr)); break; } if (bs->key.ifname[0]) { bpc->bpc_has_localif = true; strlcpy(bpc->bpc_localif, bs->key.ifname, sizeof(bpc->bpc_localif)); } if (bs->key.vrfname[0]) { bpc->bpc_has_vrfname = true; strlcpy(bpc->bpc_vrfname, bs->key.vrfname, sizeof(bpc->bpc_vrfname)); } } /* * BFD hash data structures to find sessions. */ static struct hash *bfd_id_hash; static struct hash *bfd_key_hash; static unsigned int bfd_id_hash_do(const void *p); static unsigned int bfd_key_hash_do(const void *p); static void _bfd_free(struct hash_bucket *hb, void *arg __attribute__((__unused__))); /* BFD hash for our discriminator. */ static unsigned int bfd_id_hash_do(const void *p) { const struct bfd_session *bs = p; return jhash_1word(bs->discrs.my_discr, 0); } static bool bfd_id_hash_cmp(const void *n1, const void *n2) { const struct bfd_session *bs1 = n1, *bs2 = n2; return bs1->discrs.my_discr == bs2->discrs.my_discr; } /* BFD hash for single hop. */ static unsigned int bfd_key_hash_do(const void *p) { const struct bfd_session *bs = p; struct bfd_key key = bs->key; /* * Local address and interface name are optional and * can be filled any time after session creation. * Hash key should not depend on these fields. */ memset(&key.local, 0, sizeof(key.local)); memset(key.ifname, 0, sizeof(key.ifname)); return jhash(&key, sizeof(key), 0); } static bool bfd_key_hash_cmp(const void *n1, const void *n2) { const struct bfd_session *bs1 = n1, *bs2 = n2; if (bs1->key.family != bs2->key.family) return false; if (bs1->key.mhop != bs2->key.mhop) return false; if (memcmp(&bs1->key.peer, &bs2->key.peer, sizeof(bs1->key.peer))) return false; if (memcmp(bs1->key.vrfname, bs2->key.vrfname, sizeof(bs1->key.vrfname))) return false; /* * Local address is optional and can be empty. * If both addresses are not empty and different, * then the keys are different. */ if (memcmp(&bs1->key.local, &zero_addr, sizeof(bs1->key.local)) && memcmp(&bs2->key.local, &zero_addr, sizeof(bs2->key.local)) && memcmp(&bs1->key.local, &bs2->key.local, sizeof(bs1->key.local))) return false; /* * Interface name is optional and can be empty. * If both names are not empty and different, * then the keys are different. */ if (bs1->key.ifname[0] && bs2->key.ifname[0] && memcmp(bs1->key.ifname, bs2->key.ifname, sizeof(bs1->key.ifname))) return false; return true; } /* * Hash public interface / exported functions. */ /* Lookup functions. */ struct bfd_session *bfd_id_lookup(uint32_t id) { struct bfd_session bs; bs.discrs.my_discr = id; return hash_lookup(bfd_id_hash, &bs); } struct bfd_session *bfd_key_lookup(struct bfd_key key) { struct bfd_session bs; bs.key = key; return hash_lookup(bfd_key_hash, &bs); } /* * Delete functions. * * Delete functions searches and remove the item from the hash and * returns a pointer to the removed item data. If the item was not found * then it returns NULL. * * The data stored inside the hash is not free()ed, so you must do it * manually after getting the pointer back. */ struct bfd_session *bfd_id_delete(uint32_t id) { struct bfd_session bs; bs.discrs.my_discr = id; return hash_release(bfd_id_hash, &bs); } struct bfd_session *bfd_key_delete(struct bfd_key key) { struct bfd_session bs; bs.key = key; return hash_release(bfd_key_hash, &bs); } /* Iteration functions. */ void bfd_id_iterate(hash_iter_func hif, void *arg) { hash_iterate(bfd_id_hash, hif, arg); } void bfd_key_iterate(hash_iter_func hif, void *arg) { hash_iterate(bfd_key_hash, hif, arg); } /* * Insert functions. * * Inserts session into hash and returns `true` on success, otherwise * `false`. */ bool bfd_id_insert(struct bfd_session *bs) { return (hash_get(bfd_id_hash, bs, hash_alloc_intern) == bs); } bool bfd_key_insert(struct bfd_session *bs) { return (hash_get(bfd_key_hash, bs, hash_alloc_intern) == bs); } void bfd_initialize(void) { bfd_id_hash = hash_create(bfd_id_hash_do, bfd_id_hash_cmp, "BFD session discriminator hash"); bfd_key_hash = hash_create(bfd_key_hash_do, bfd_key_hash_cmp, "BFD session hash"); TAILQ_INIT(&bplist); } static void _bfd_free(struct hash_bucket *hb, void *arg __attribute__((__unused__))) { struct bfd_session *bs = hb->data; bfd_session_free(bs); } void bfd_shutdown(void) { struct bfd_profile *bp; /* * Close and free all BFD sessions. * * _bfd_free() will call bfd_session_free() which will take care * of removing the session from all hashes, so we just run an * assert() here to make sure it really happened. */ bfd_id_iterate(_bfd_free, NULL); assert(bfd_key_hash->count == 0); /* Now free the hashes themselves. */ hash_free(bfd_id_hash); hash_free(bfd_key_hash); /* Free all profile allocations. */ while ((bp = TAILQ_FIRST(&bplist)) != NULL) bfd_profile_free(bp); } struct bfd_session_iterator { int bsi_stop; bool bsi_mhop; const struct bfd_session *bsi_bs; }; static int _bfd_session_next(struct hash_bucket *hb, void *arg) { struct bfd_session_iterator *bsi = arg; struct bfd_session *bs = hb->data; /* Previous entry signaled stop. */ if (bsi->bsi_stop == 1) { /* Match the single/multi hop sessions. */ if (bs->key.mhop != bsi->bsi_mhop) return HASHWALK_CONTINUE; bsi->bsi_bs = bs; return HASHWALK_ABORT; } /* We found the current item, stop in the next one. */ if (bsi->bsi_bs == hb->data) { bsi->bsi_stop = 1; /* Set entry to NULL to signal end of list. */ bsi->bsi_bs = NULL; } else if (bsi->bsi_bs == NULL && bsi->bsi_mhop == bs->key.mhop) { /* We want the first list item. */ bsi->bsi_stop = 1; bsi->bsi_bs = hb->data; return HASHWALK_ABORT; } return HASHWALK_CONTINUE; } /* * bfd_session_next: uses the current session to find the next. * * `bs` might point to NULL to get the first item of the data structure. */ const struct bfd_session *bfd_session_next(const struct bfd_session *bs, bool mhop) { struct bfd_session_iterator bsi; bsi.bsi_stop = 0; bsi.bsi_bs = bs; bsi.bsi_mhop = mhop; hash_walk(bfd_key_hash, _bfd_session_next, &bsi); if (bsi.bsi_stop == 0) return NULL; return bsi.bsi_bs; } static void _bfd_session_remove_manual(struct hash_bucket *hb, void *arg __attribute__((__unused__))) { struct bfd_session *bs = hb->data; /* Delete only manually configured sessions. */ if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_CONFIG) == 0) return; bs->refcount--; UNSET_FLAG(bs->flags, BFD_SESS_FLAG_CONFIG); /* Don't delete sessions still in use. */ if (bs->refcount != 0) return; bfd_session_free(bs); } /* * bfd_sessions_remove_manual: remove all manually configured sessions. * * NOTE: this function doesn't remove automatically created sessions. */ void bfd_sessions_remove_manual(void) { hash_iterate(bfd_key_hash, _bfd_session_remove_manual, NULL); } void bfd_profiles_remove(void) { struct bfd_profile *bp; while ((bp = TAILQ_FIRST(&bplist)) != NULL) bfd_profile_free(bp); } /* * Profile related hash functions. */ static void _bfd_profile_update(struct hash_bucket *hb, void *arg) { struct bfd_profile *bp = arg; struct bfd_session *bs = hb->data; /* This session is not using the profile. */ if (bs->profile_name == NULL || strcmp(bs->profile_name, bp->name) != 0) return; bfd_profile_apply(bp->name, bs); } void bfd_profile_update(struct bfd_profile *bp) { hash_iterate(bfd_key_hash, _bfd_profile_update, bp); } static void _bfd_profile_detach(struct hash_bucket *hb, void *arg) { struct bfd_profile *bp = arg; struct bfd_session *bs = hb->data; /* This session is not using the profile. */ if (bs->profile_name == NULL || strcmp(bs->profile_name, bp->name) != 0) return; bfd_profile_remove(bs); } static void bfd_profile_detach(struct bfd_profile *bp) { hash_iterate(bfd_key_hash, _bfd_profile_detach, bp); } /* * VRF related functions. */ static int bfd_vrf_new(struct vrf *vrf) { if (bglobal.debug_zebra) zlog_debug("VRF Created: %s(%u)", vrf->name, vrf->vrf_id); return 0; } static int bfd_vrf_delete(struct vrf *vrf) { if (bglobal.debug_zebra) zlog_debug("VRF Deletion: %s(%u)", vrf->name, vrf->vrf_id); return 0; } static int bfd_vrf_enable(struct vrf *vrf) { struct bfd_vrf_global *bvrf; /* a different name */ if (!vrf->info) { bvrf = XCALLOC(MTYPE_BFDD_VRF, sizeof(struct bfd_vrf_global)); bvrf->vrf = vrf; vrf->info = (void *)bvrf; /* Disable sockets if using data plane. */ if (bglobal.bg_use_dplane) { bvrf->bg_shop = -1; bvrf->bg_mhop = -1; bvrf->bg_shop6 = -1; bvrf->bg_mhop6 = -1; bvrf->bg_echo = -1; bvrf->bg_echov6 = -1; } } else bvrf = vrf->info; if (bglobal.debug_zebra) zlog_debug("VRF enable add %s id %u", vrf->name, vrf->vrf_id); if (!bvrf->bg_shop) bvrf->bg_shop = bp_udp_shop(vrf); if (!bvrf->bg_mhop) bvrf->bg_mhop = bp_udp_mhop(vrf); if (!bvrf->bg_shop6) bvrf->bg_shop6 = bp_udp6_shop(vrf); if (!bvrf->bg_mhop6) bvrf->bg_mhop6 = bp_udp6_mhop(vrf); if (!bvrf->bg_echo) bvrf->bg_echo = bp_echo_socket(vrf); if (!bvrf->bg_echov6) bvrf->bg_echov6 = bp_echov6_socket(vrf); if (!bvrf->bg_ev[0] && bvrf->bg_shop != -1) event_add_read(master, bfd_recv_cb, bvrf, bvrf->bg_shop, &bvrf->bg_ev[0]); if (!bvrf->bg_ev[1] && bvrf->bg_mhop != -1) event_add_read(master, bfd_recv_cb, bvrf, bvrf->bg_mhop, &bvrf->bg_ev[1]); if (!bvrf->bg_ev[2] && bvrf->bg_shop6 != -1) event_add_read(master, bfd_recv_cb, bvrf, bvrf->bg_shop6, &bvrf->bg_ev[2]); if (!bvrf->bg_ev[3] && bvrf->bg_mhop6 != -1) event_add_read(master, bfd_recv_cb, bvrf, bvrf->bg_mhop6, &bvrf->bg_ev[3]); if (!bvrf->bg_ev[4] && bvrf->bg_echo != -1) event_add_read(master, bfd_recv_cb, bvrf, bvrf->bg_echo, &bvrf->bg_ev[4]); if (!bvrf->bg_ev[5] && bvrf->bg_echov6 != -1) event_add_read(master, bfd_recv_cb, bvrf, bvrf->bg_echov6, &bvrf->bg_ev[5]); if (vrf->vrf_id != VRF_DEFAULT) { bfdd_zclient_register(vrf->vrf_id); bfdd_sessions_enable_vrf(vrf); } return 0; } static int bfd_vrf_disable(struct vrf *vrf) { struct bfd_vrf_global *bvrf; if (!vrf->info) return 0; bvrf = vrf->info; if (vrf->vrf_id != VRF_DEFAULT) { bfdd_sessions_disable_vrf(vrf); bfdd_zclient_unregister(vrf->vrf_id); } if (bglobal.debug_zebra) zlog_debug("VRF disable %s id %d", vrf->name, vrf->vrf_id); /* Disable read/write poll triggering. */ EVENT_OFF(bvrf->bg_ev[0]); EVENT_OFF(bvrf->bg_ev[1]); EVENT_OFF(bvrf->bg_ev[2]); EVENT_OFF(bvrf->bg_ev[3]); EVENT_OFF(bvrf->bg_ev[4]); EVENT_OFF(bvrf->bg_ev[5]); /* Close all descriptors. */ socket_close(&bvrf->bg_echo); socket_close(&bvrf->bg_shop); socket_close(&bvrf->bg_mhop); if (bvrf->bg_shop6 != -1) socket_close(&bvrf->bg_shop6); if (bvrf->bg_mhop6 != -1) socket_close(&bvrf->bg_mhop6); socket_close(&bvrf->bg_echo); if (bvrf->bg_echov6 != -1) socket_close(&bvrf->bg_echov6); /* free context */ XFREE(MTYPE_BFDD_VRF, bvrf); vrf->info = NULL; return 0; } void bfd_vrf_init(void) { vrf_init(bfd_vrf_new, bfd_vrf_enable, bfd_vrf_disable, bfd_vrf_delete); } void bfd_vrf_terminate(void) { vrf_terminate(); } struct bfd_vrf_global *bfd_vrf_look_by_session(struct bfd_session *bfd) { struct vrf *vrf; if (!vrf_is_backend_netns()) { vrf = vrf_lookup_by_id(VRF_DEFAULT); if (vrf) return (struct bfd_vrf_global *)vrf->info; return NULL; } if (!bfd) return NULL; if (!bfd->vrf) return NULL; return bfd->vrf->info; } unsigned long bfd_get_session_count(void) { return bfd_key_hash->count; } void bfd_rtt_init(struct bfd_session *bfd) { uint8_t i; /* initialize RTT */ bfd->rtt_valid = 0; bfd->rtt_index = 0; for (i = 0; i < BFD_RTT_SAMPLE; i++) bfd->rtt[i] = 0; }