/* * BIRD -- The Border Gateway Protocol * * (c) 2000 Martin Mares * (c) 2008--2016 Ondrej Zajicek * (c) 2008--2016 CZ.NIC z.s.p.o. * * Can be freely distributed and used under the terms of the GNU GPL. */ /** * DOC: Border Gateway Protocol * * The BGP protocol is implemented in three parts: |bgp.c| which takes care of * the connection and most of the interface with BIRD core, |packets.c| handling * both incoming and outgoing BGP packets and |attrs.c| containing functions for * manipulation with BGP attribute lists. * * As opposed to the other existing routing daemons, BIRD has a sophisticated * core architecture which is able to keep all the information needed by BGP in * the primary routing table, therefore no complex data structures like a * central BGP table are needed. This increases memory footprint of a BGP router * with many connections, but not too much and, which is more important, it * makes BGP much easier to implement. * * Each instance of BGP (corresponding to a single BGP peer) is described by a * &bgp_proto structure to which are attached individual connections represented * by &bgp_connection (usually, there exists only one connection, but during BGP * session setup, there can be more of them). The connections are handled * according to the BGP state machine defined in the RFC with all the timers and * all the parameters configurable. * * In incoming direction, we listen on the connection's socket and each time we * receive some input, we pass it to bgp_rx(). It decodes packet headers and the * markers and passes complete packets to bgp_rx_packet() which distributes the * packet according to its type. * * In outgoing direction, we gather all the routing updates and sort them to * buckets (&bgp_bucket) according to their attributes (we keep a hash table for * fast comparison of &rta's and a &fib which helps us to find if we already * have another route for the same destination queued for sending, so that we * can replace it with the new one immediately instead of sending both * updates). There also exists a special bucket holding all the route * withdrawals which cannot be queued anywhere else as they don't have any * attributes. If we have any packet to send (due to either new routes or the * connection tracking code wanting to send a Open, Keepalive or Notification * message), we call bgp_schedule_packet() which sets the corresponding bit in a * @packet_to_send bit field in &bgp_conn and as soon as the transmit socket * buffer becomes empty, we call bgp_fire_tx(). It inspects state of all the * packet type bits and calls the corresponding bgp_create_xx() functions, * eventually rescheduling the same packet type if we have more data of the same * type to send. * * The processing of attributes consists of two functions: bgp_decode_attrs() * for checking of the attribute blocks and translating them to the language of * BIRD's extended attributes and bgp_encode_attrs() which does the * converse. Both functions are built around a @bgp_attr_table array describing * all important characteristics of all known attributes. Unknown transitive * attributes are attached to the route as %EAF_TYPE_OPAQUE byte streams. * * BGP protocol implements graceful restart in both restarting (local restart) * and receiving (neighbor restart) roles. The first is handled mostly by the * graceful restart code in the nest, BGP protocol just handles capabilities, * sets @gr_wait and locks graceful restart until end-of-RIB mark is received. * The second is implemented by internal restart of the BGP state to %BS_IDLE * and protocol state to %PS_START, but keeping the protocol up from the core * point of view and therefore maintaining received routes. Routing table * refresh cycle (rt_refresh_begin(), rt_refresh_end()) is used for removing * stale routes after reestablishment of BGP session during graceful restart. * * Supported standards: * RFC 4271 - Border Gateway Protocol 4 (BGP) * RFC 1997 - BGP Communities Attribute * RFC 2385 - Protection of BGP Sessions via TCP MD5 Signature * RFC 2545 - Use of BGP Multiprotocol Extensions for IPv6 * RFC 2918 - Route Refresh Capability * RFC 3107 - Carrying Label Information in BGP * RFC 4360 - BGP Extended Communities Attribute * RFC 4364 - BGP/MPLS IPv4 Virtual Private Networks * RFC 4456 - BGP Route Reflection * RFC 4486 - Subcodes for BGP Cease Notification Message * RFC 4659 - BGP/MPLS IPv6 Virtual Private Networks * RFC 4724 - Graceful Restart Mechanism for BGP * RFC 4760 - Multiprotocol extensions for BGP * RFC 4798 - Connecting IPv6 Islands over IPv4 MPLS * RFC 5065 - AS confederations for BGP * RFC 5082 - Generalized TTL Security Mechanism * RFC 5492 - Capabilities Advertisement with BGP * RFC 5549 - Advertising IPv4 NLRI with an IPv6 Next Hop * RFC 5575 - Dissemination of Flow Specification Rules * RFC 5668 - 4-Octet AS Specific BGP Extended Community * RFC 6286 - AS-Wide Unique BGP Identifier * RFC 6608 - Subcodes for BGP Finite State Machine Error * RFC 6793 - BGP Support for 4-Octet AS Numbers * RFC 7311 - Accumulated IGP Metric Attribute for BGP * RFC 7313 - Enhanced Route Refresh Capability for BGP * RFC 7606 - Revised Error Handling for BGP UPDATE Messages * RFC 7911 - Advertisement of Multiple Paths in BGP * RFC 7947 - Internet Exchange BGP Route Server * RFC 8092 - BGP Large Communities Attribute * RFC 8203 - BGP Administrative Shutdown Communication * RFC 8212 - Default EBGP Route Propagation Behavior without Policies * RFC 8654 - Extended Message Support for BGP * RFC 9117 - Revised Validation Procedure for BGP Flow Specifications * draft-ietf-idr-ext-opt-param-07 * draft-uttaro-idr-bgp-persistence-04 * draft-walton-bgp-hostname-capability-02 */ #undef LOCAL_DEBUG #include #include "nest/bird.h" #include "nest/iface.h" #include "nest/protocol.h" #include "nest/route.h" #include "nest/cli.h" #include "nest/locks.h" #include "conf/conf.h" #include "filter/filter.h" #include "lib/socket.h" #include "lib/resource.h" #include "lib/string.h" #include "bgp.h" static list STATIC_LIST_INIT(bgp_sockets); /* Global list of listening sockets */ static void bgp_connect(struct bgp_proto *p); static void bgp_active(struct bgp_proto *p); static void bgp_setup_conn(struct bgp_proto *p, struct bgp_conn *conn); static void bgp_setup_sk(struct bgp_conn *conn, sock *s); static void bgp_send_open(struct bgp_conn *conn); static void bgp_update_bfd(struct bgp_proto *p, const struct bfd_options *bfd); static int bgp_incoming_connection(sock *sk, uint dummy UNUSED); static void bgp_listen_sock_err(sock *sk UNUSED, int err); /** * bgp_open - open a BGP instance * @p: BGP instance * * This function allocates and configures shared BGP resources, mainly listening * sockets. Should be called as the last step during initialization (when lock * is acquired and neighbor is ready). When error, caller should change state to * PS_DOWN and return immediately. */ static int bgp_open(struct bgp_proto *p) { struct bgp_socket *bs = NULL; struct iface *ifa = p->cf->strict_bind ? p->cf->iface : NULL; ip_addr addr = p->cf->strict_bind ? p->cf->local_ip : (p->ipv4 ? IPA_NONE4 : IPA_NONE6); uint port = p->cf->local_port; uint flags = p->cf->free_bind ? SKF_FREEBIND : 0; uint flag_mask = SKF_FREEBIND; /* We assume that cf->iface is defined iff cf->local_ip is link-local */ WALK_LIST(bs, bgp_sockets) if (ipa_equal(bs->sk->saddr, addr) && (bs->sk->sport == port) && (bs->sk->iface == ifa) && (bs->sk->vrf == p->p.vrf) && ((bs->sk->flags & flag_mask) == flags)) { bs->uc++; p->sock = bs; return 0; } sock *sk = sk_new(proto_pool); sk->type = SK_TCP_PASSIVE; sk->ttl = 255; sk->saddr = addr; sk->sport = port; sk->iface = ifa; sk->vrf = p->p.vrf; sk->flags = flags; sk->tos = IP_PREC_INTERNET_CONTROL; sk->rbsize = BGP_RX_BUFFER_SIZE; sk->tbsize = BGP_TX_BUFFER_SIZE; sk->rx_hook = bgp_incoming_connection; sk->err_hook = bgp_listen_sock_err; if (sk_open(sk) < 0) goto err; bs = mb_allocz(proto_pool, sizeof(struct bgp_socket)); bs->sk = sk; bs->uc = 1; p->sock = bs; sk->data = bs; add_tail(&bgp_sockets, &bs->n); return 0; err: sk_log_error(sk, p->p.name); log(L_ERR "%s: Cannot open listening socket", p->p.name); rfree(sk); return -1; } /** * bgp_close - close a BGP instance * @p: BGP instance * * This function frees and deconfigures shared BGP resources. */ static void bgp_close(struct bgp_proto *p) { struct bgp_socket *bs = p->sock; ASSERT(bs && bs->uc); if (--bs->uc) return; rfree(bs->sk); rem_node(&bs->n); mb_free(bs); } static inline int bgp_setup_auth(struct bgp_proto *p, int enable) { if (p->cf->password) { ip_addr prefix = p->cf->remote_ip; int pxlen = -1; if (p->cf->remote_range) { prefix = net_prefix(p->cf->remote_range); pxlen = net_pxlen(p->cf->remote_range); } int rv = sk_set_md5_auth(p->sock->sk, p->cf->local_ip, prefix, pxlen, p->cf->iface, enable ? p->cf->password : NULL, p->cf->setkey); if (rv < 0) sk_log_error(p->sock->sk, p->p.name); return rv; } else return 0; } static inline struct bgp_channel * bgp_find_channel(struct bgp_proto *p, u32 afi) { struct bgp_channel *c; WALK_LIST(c, p->p.channels) if (c->afi == afi) return c; return NULL; } static void bgp_startup(struct bgp_proto *p) { BGP_TRACE(D_EVENTS, "Started"); p->start_state = BSS_CONNECT; if (!p->passive) bgp_active(p); if (p->postponed_sk) { /* Apply postponed incoming connection */ bgp_setup_conn(p, &p->incoming_conn); bgp_setup_sk(&p->incoming_conn, p->postponed_sk); bgp_send_open(&p->incoming_conn); p->postponed_sk = NULL; } } static void bgp_startup_timeout(timer *t) { bgp_startup(t->data); } static void bgp_initiate(struct bgp_proto *p) { int err_val; if (bgp_open(p) < 0) { err_val = BEM_NO_SOCKET; goto err1; } if (bgp_setup_auth(p, 1) < 0) { err_val = BEM_INVALID_MD5; goto err2; } if (p->cf->bfd) bgp_update_bfd(p, p->cf->bfd); if (p->startup_delay) { p->start_state = BSS_DELAY; BGP_TRACE(D_EVENTS, "Startup delayed by %d seconds due to errors", p->startup_delay); bgp_start_timer(p->startup_timer, p->startup_delay); } else bgp_startup(p); return; err2: bgp_close(p); err1: p->p.disabled = 1; bgp_store_error(p, NULL, BE_MISC, err_val); p->neigh = NULL; proto_notify_state(&p->p, PS_DOWN); return; } /** * bgp_start_timer - start a BGP timer * @t: timer * @value: time (in seconds) to fire (0 to disable the timer) * * This functions calls tm_start() on @t with time @value and the amount of * randomization suggested by the BGP standard. Please use it for all BGP * timers. */ void bgp_start_timer(timer *t, uint value) { if (value) { /* The randomization procedure is specified in RFC 4271 section 10 */ btime time = value S; btime randomize = random() % ((time / 4) + 1); tm_start(t, time - randomize); } else tm_stop(t); } /** * bgp_close_conn - close a BGP connection * @conn: connection to close * * This function takes a connection described by the &bgp_conn structure, closes * its socket and frees all resources associated with it. */ void bgp_close_conn(struct bgp_conn *conn) { // struct bgp_proto *p = conn->bgp; DBG("BGP: Closing connection\n"); conn->packets_to_send = 0; conn->channels_to_send = 0; rfree(conn->connect_timer); conn->connect_timer = NULL; rfree(conn->keepalive_timer); conn->keepalive_timer = NULL; rfree(conn->hold_timer); conn->hold_timer = NULL; rfree(conn->tx_ev); conn->tx_ev = NULL; rfree(conn->sk); conn->sk = NULL; mb_free(conn->local_caps); conn->local_caps = NULL; mb_free(conn->remote_caps); conn->remote_caps = NULL; } /** * bgp_update_startup_delay - update a startup delay * @p: BGP instance * * This function updates a startup delay that is used to postpone next BGP * connect. It also handles disable_after_error and might stop BGP instance * when error happened and disable_after_error is on. * * It should be called when BGP protocol error happened. */ void bgp_update_startup_delay(struct bgp_proto *p) { const struct bgp_config *cf = p->cf; DBG("BGP: Updating startup delay\n"); if (p->last_proto_error && ((current_time() - p->last_proto_error) >= cf->error_amnesia_time S)) p->startup_delay = 0; p->last_proto_error = current_time(); if (cf->disable_after_error) { p->startup_delay = 0; p->p.disabled = 1; return; } if (!p->startup_delay) p->startup_delay = cf->error_delay_time_min; else p->startup_delay = MIN(2 * p->startup_delay, cf->error_delay_time_max); } static void bgp_graceful_close_conn(struct bgp_conn *conn, int subcode, byte *data, uint len) { switch (conn->state) { case BS_IDLE: case BS_CLOSE: return; case BS_CONNECT: case BS_ACTIVE: bgp_conn_enter_idle_state(conn); return; case BS_OPENSENT: case BS_OPENCONFIRM: case BS_ESTABLISHED: if (subcode < 0) { bgp_conn_enter_close_state(conn); bgp_schedule_packet(conn, NULL, PKT_SCHEDULE_CLOSE); } else bgp_error(conn, 6, subcode, data, len); return; default: bug("bgp_graceful_close_conn: Unknown state %d", conn->state); } } static void bgp_down(struct bgp_proto *p) { if (p->start_state > BSS_PREPARE) { bgp_setup_auth(p, 0); bgp_close(p); } p->neigh = NULL; BGP_TRACE(D_EVENTS, "Down"); proto_notify_state(&p->p, PS_DOWN); } static void bgp_decision(void *vp) { struct bgp_proto *p = vp; DBG("BGP: Decision start\n"); if ((p->p.proto_state == PS_START) && (p->outgoing_conn.state == BS_IDLE) && (p->incoming_conn.state != BS_OPENCONFIRM) && !p->passive) bgp_active(p); if ((p->p.proto_state == PS_STOP) && (p->outgoing_conn.state == BS_IDLE) && (p->incoming_conn.state == BS_IDLE)) bgp_down(p); } static struct bgp_proto * bgp_spawn(struct bgp_proto *pp, ip_addr remote_ip) { struct symbol *sym; char fmt[SYM_MAX_LEN]; bsprintf(fmt, "%s%%0%dd", pp->cf->dynamic_name, pp->cf->dynamic_name_digits); /* This is hack, we would like to share config, but we need to copy it now */ new_config = config; cfg_mem = config->mem; conf_this_scope = config->root_scope; sym = cf_default_name(fmt, &(pp->dynamic_name_counter)); proto_clone_config(sym, pp->p.cf); new_config = NULL; cfg_mem = NULL; /* Just pass remote_ip to bgp_init() */ ((struct bgp_config *) sym->proto)->remote_ip = remote_ip; return (void *) proto_spawn(sym->proto, 0); } void bgp_stop(struct bgp_proto *p, int subcode, byte *data, uint len) { proto_notify_state(&p->p, PS_STOP); bgp_graceful_close_conn(&p->outgoing_conn, subcode, data, len); bgp_graceful_close_conn(&p->incoming_conn, subcode, data, len); ev_schedule(p->event); } static inline void bgp_conn_set_state(struct bgp_conn *conn, uint new_state) { if (conn->bgp->p.mrtdump & MD_STATES) bgp_dump_state_change(conn, conn->state, new_state); conn->state = new_state; } void bgp_conn_enter_openconfirm_state(struct bgp_conn *conn) { /* Really, most of the work is done in bgp_rx_open(). */ bgp_conn_set_state(conn, BS_OPENCONFIRM); } static const struct bgp_af_caps dummy_af_caps = { }; static const struct bgp_af_caps basic_af_caps = { .ready = 1 }; void bgp_conn_enter_established_state(struct bgp_conn *conn) { struct bgp_proto *p = conn->bgp; struct bgp_caps *local = conn->local_caps; struct bgp_caps *peer = conn->remote_caps; struct bgp_channel *c; BGP_TRACE(D_EVENTS, "BGP session established"); p->last_established = current_time(); p->stats.fsm_established_transitions++; /* For multi-hop BGP sessions */ if (ipa_zero(p->local_ip)) p->local_ip = conn->sk->saddr; /* For promiscuous sessions */ if (!p->remote_as) p->remote_as = conn->received_as; /* In case of LLv6 is not valid during BGP start */ if (ipa_zero(p->link_addr) && p->neigh && p->neigh->iface && p->neigh->iface->llv6) p->link_addr = p->neigh->iface->llv6->ip; conn->sk->fast_rx = 0; p->conn = conn; p->last_error_class = 0; p->last_error_code = 0; p->as4_session = conn->as4_session; p->route_refresh = peer->route_refresh; p->enhanced_refresh = local->enhanced_refresh && peer->enhanced_refresh; /* Whether we may handle possible GR/LLGR of peer (it has some AF GR-able) */ p->gr_ready = p->llgr_ready = 0; /* Updated later */ /* Whether peer is ready to handle our GR recovery */ int peer_gr_ready = peer->gr_aware && !(peer->gr_flags & BGP_GRF_RESTART); if (p->gr_active_num) tm_stop(p->gr_timer); /* Number of active channels */ int num = 0; /* Summary state of ADD_PATH RX for active channels */ uint summary_add_path_rx = 0; WALK_LIST(c, p->p.channels) { const struct bgp_af_caps *loc = bgp_find_af_caps(local, c->afi); const struct bgp_af_caps *rem = bgp_find_af_caps(peer, c->afi); /* Use default if capabilities were not announced */ if (!local->length && (c->afi == BGP_AF_IPV4)) loc = &basic_af_caps; if (!peer->length && (c->afi == BGP_AF_IPV4)) rem = &basic_af_caps; /* Ignore AFIs that were not announced in multiprotocol capability */ if (!loc || !loc->ready) loc = &dummy_af_caps; if (!rem || !rem->ready) rem = &dummy_af_caps; int active = loc->ready && rem->ready; c->c.disabled = !active; c->c.reloadable = p->route_refresh || c->cf->import_table; c->index = active ? num++ : 0; c->feed_state = BFS_NONE; c->load_state = BFS_NONE; /* Channels where peer may do GR */ uint gr_ready = active && local->gr_aware && rem->gr_able; uint llgr_ready = active && local->llgr_aware && rem->llgr_able; c->gr_ready = gr_ready || llgr_ready; p->gr_ready = p->gr_ready || c->gr_ready; p->llgr_ready = p->llgr_ready || llgr_ready; /* Remember last LLGR stale time */ c->stale_time = local->llgr_aware ? rem->llgr_time : 0; /* Channels not able to recover gracefully */ if (p->p.gr_recovery && (!active || !peer_gr_ready)) channel_graceful_restart_unlock(&c->c); /* Channels waiting for local convergence */ if (p->p.gr_recovery && loc->gr_able && peer_gr_ready) c->c.gr_wait = 1; /* Channels where regular graceful restart failed */ if ((c->gr_active == BGP_GRS_ACTIVE) && !(active && rem->gr_able && (rem->gr_af_flags & BGP_GRF_FORWARDING))) bgp_graceful_restart_done(c); /* Channels where regular long-lived restart failed */ if ((c->gr_active == BGP_GRS_LLGR) && !(active && rem->llgr_able && (rem->gr_af_flags & BGP_LLGRF_FORWARDING))) bgp_graceful_restart_done(c); /* GR capability implies that neighbor will send End-of-RIB */ if (peer->gr_aware) c->load_state = BFS_LOADING; c->ext_next_hop = c->cf->ext_next_hop && (bgp_channel_is_ipv6(c) || rem->ext_next_hop); c->add_path_rx = (loc->add_path & BGP_ADD_PATH_RX) && (rem->add_path & BGP_ADD_PATH_TX); c->add_path_tx = (loc->add_path & BGP_ADD_PATH_TX) && (rem->add_path & BGP_ADD_PATH_RX); if (active) summary_add_path_rx |= !c->add_path_rx ? 1 : 2; /* Update RA mode */ if (c->add_path_tx) c->c.ra_mode = RA_ANY; else if (c->cf->secondary) c->c.ra_mode = RA_ACCEPTED; else c->c.ra_mode = RA_OPTIMAL; } p->afi_map = mb_alloc(p->p.pool, num * sizeof(u32)); p->channel_map = mb_alloc(p->p.pool, num * sizeof(void *)); p->channel_count = num; p->summary_add_path_rx = summary_add_path_rx; WALK_LIST(c, p->p.channels) { if (c->c.disabled) continue; p->afi_map[c->index] = c->afi; p->channel_map[c->index] = c; } /* proto_notify_state() will likely call bgp_feed_begin(), setting c->feed_state */ bgp_conn_set_state(conn, BS_ESTABLISHED); proto_notify_state(&p->p, PS_UP); } static void bgp_conn_leave_established_state(struct bgp_proto *p) { BGP_TRACE(D_EVENTS, "BGP session closed"); p->last_established = current_time(); p->conn = NULL; if (p->p.proto_state == PS_UP) bgp_stop(p, 0, NULL, 0); } void bgp_conn_enter_close_state(struct bgp_conn *conn) { struct bgp_proto *p = conn->bgp; int os = conn->state; bgp_conn_set_state(conn, BS_CLOSE); tm_stop(conn->keepalive_timer); conn->sk->rx_hook = NULL; /* Timeout for CLOSE state, if we cannot send notification soon then we just hangup */ bgp_start_timer(conn->hold_timer, 10); if (os == BS_ESTABLISHED) bgp_conn_leave_established_state(p); } void bgp_conn_enter_idle_state(struct bgp_conn *conn) { struct bgp_proto *p = conn->bgp; int os = conn->state; bgp_close_conn(conn); bgp_conn_set_state(conn, BS_IDLE); ev_schedule(p->event); if (os == BS_ESTABLISHED) bgp_conn_leave_established_state(p); } /** * bgp_handle_graceful_restart - handle detected BGP graceful restart * @p: BGP instance * * This function is called when a BGP graceful restart of the neighbor is * detected (when the TCP connection fails or when a new TCP connection * appears). The function activates processing of the restart - starts routing * table refresh cycle and activates BGP restart timer. The protocol state goes * back to %PS_START, but changing BGP state back to %BS_IDLE is left for the * caller. */ void bgp_handle_graceful_restart(struct bgp_proto *p) { ASSERT(p->conn && (p->conn->state == BS_ESTABLISHED) && p->gr_ready); BGP_TRACE(D_EVENTS, "Neighbor graceful restart detected%s", p->gr_active_num ? " - already pending" : ""); p->gr_active_num = 0; struct bgp_channel *c; WALK_LIST(c, p->p.channels) { /* FIXME: perhaps check for channel state instead of disabled flag? */ if (c->c.disabled) continue; if (c->gr_ready) { p->gr_active_num++; switch (c->gr_active) { case BGP_GRS_NONE: c->gr_active = BGP_GRS_ACTIVE; rt_refresh_begin(c->c.table, &c->c.in_req); break; case BGP_GRS_ACTIVE: rt_refresh_end(c->c.table, &c->c.in_req); rt_refresh_begin(c->c.table, &c->c.in_req); break; case BGP_GRS_LLGR: rt_refresh_begin(c->c.table, &c->c.in_req); rt_modify_stale(c->c.table, &c->c.in_req); break; } } else { /* Just flush the routes */ rt_refresh_begin(c->c.table, &c->c.in_req); rt_refresh_end(c->c.table, &c->c.in_req); } /* Reset bucket and prefix tables */ bgp_free_bucket_table(c); bgp_free_prefix_table(c); bgp_init_bucket_table(c); bgp_init_prefix_table(c); c->packets_to_send = 0; } /* p->gr_ready -> at least one active channel is c->gr_ready */ ASSERT(p->gr_active_num > 0); proto_notify_state(&p->p, PS_START); tm_start(p->gr_timer, p->conn->remote_caps->gr_time S); } /** * bgp_graceful_restart_done - finish active BGP graceful restart * @c: BGP channel * * This function is called when the active BGP graceful restart of the neighbor * should be finished for channel @c - either successfully (the neighbor sends * all paths and reports end-of-RIB for given AFI/SAFI on the new session) or * unsuccessfully (the neighbor does not support BGP graceful restart on the new * session). The function ends the routing table refresh cycle. */ void bgp_graceful_restart_done(struct bgp_channel *c) { struct bgp_proto *p = (void *) c->c.proto; ASSERT(c->gr_active); c->gr_active = 0; p->gr_active_num--; if (!p->gr_active_num) BGP_TRACE(D_EVENTS, "Neighbor graceful restart done"); tm_stop(c->stale_timer); rt_refresh_end(c->c.table, &c->c.in_req); } /** * bgp_graceful_restart_timeout - timeout of graceful restart 'restart timer' * @t: timer * * This function is a timeout hook for @gr_timer, implementing BGP restart time * limit for reestablisment of the BGP session after the graceful restart. When * fired, we just proceed with the usual protocol restart. */ static void bgp_graceful_restart_timeout(timer *t) { struct bgp_proto *p = t->data; BGP_TRACE(D_EVENTS, "Neighbor graceful restart timeout"); if (p->llgr_ready) { struct bgp_channel *c; WALK_LIST(c, p->p.channels) { /* Channel is not in GR and is already flushed */ if (!c->gr_active) continue; /* Channel is already in LLGR from past restart */ if (c->gr_active == BGP_GRS_LLGR) continue; /* Channel is in GR, but does not support LLGR -> stop GR */ if (!c->stale_time) { bgp_graceful_restart_done(c); continue; } /* Channel is in GR, and supports LLGR -> start LLGR */ c->gr_active = BGP_GRS_LLGR; tm_start(c->stale_timer, c->stale_time S); rt_modify_stale(c->c.table, &c->c.in_req); } } else bgp_stop(p, 0, NULL, 0); } static void bgp_long_lived_stale_timeout(timer *t) { struct bgp_channel *c = t->data; struct bgp_proto *p = (void *) c->c.proto; BGP_TRACE(D_EVENTS, "Long-lived stale timeout"); bgp_graceful_restart_done(c); } /** * bgp_refresh_begin - start incoming enhanced route refresh sequence * @c: BGP channel * * This function is called when an incoming enhanced route refresh sequence is * started by the neighbor, demarcated by the BoRR packet. The function updates * the load state and starts the routing table refresh cycle. Note that graceful * restart also uses routing table refresh cycle, but RFC 7313 and load states * ensure that these two sequences do not overlap. */ void bgp_refresh_begin(struct bgp_channel *c) { struct bgp_proto *p = (void *) c->c.proto; if (c->load_state == BFS_LOADING) { log(L_WARN "%s: BEGIN-OF-RR received before END-OF-RIB, ignoring", p->p.name); return; } c->load_state = BFS_REFRESHING; rt_refresh_begin(c->c.table, &c->c.in_req); if (c->c.in_table) rt_refresh_begin(c->c.in_table, &c->c.in_req); } /** * bgp_refresh_end - finish incoming enhanced route refresh sequence * @c: BGP channel * * This function is called when an incoming enhanced route refresh sequence is * finished by the neighbor, demarcated by the EoRR packet. The function updates * the load state and ends the routing table refresh cycle. Routes not received * during the sequence are removed by the nest. */ void bgp_refresh_end(struct bgp_channel *c) { struct bgp_proto *p = (void *) c->c.proto; if (c->load_state != BFS_REFRESHING) { log(L_WARN "%s: END-OF-RR received without prior BEGIN-OF-RR, ignoring", p->p.name); return; } c->load_state = BFS_NONE; rt_refresh_end(c->c.table, &c->c.in_req); if (c->c.in_table) rt_prune_sync(c->c.in_table, 0); } static void bgp_send_open(struct bgp_conn *conn) { DBG("BGP: Sending open\n"); conn->sk->rx_hook = bgp_rx; conn->sk->tx_hook = bgp_tx; tm_stop(conn->connect_timer); bgp_prepare_capabilities(conn); bgp_schedule_packet(conn, NULL, PKT_OPEN); bgp_conn_set_state(conn, BS_OPENSENT); bgp_start_timer(conn->hold_timer, conn->bgp->cf->initial_hold_time); } static void bgp_connected(sock *sk) { struct bgp_conn *conn = sk->data; struct bgp_proto *p = conn->bgp; BGP_TRACE(D_EVENTS, "Connected"); bgp_send_open(conn); } static void bgp_connect_timeout(timer *t) { struct bgp_conn *conn = t->data; struct bgp_proto *p = conn->bgp; DBG("BGP: connect_timeout\n"); if (p->p.proto_state == PS_START) { bgp_close_conn(conn); bgp_connect(p); } else bgp_conn_enter_idle_state(conn); } static void bgp_sock_err(sock *sk, int err) { struct bgp_conn *conn = sk->data; struct bgp_proto *p = conn->bgp; /* * This error hook may be called either asynchronously from main * loop, or synchronously from sk_send(). But sk_send() is called * only from bgp_tx() and bgp_kick_tx(), which are both called * asynchronously from main loop. Moreover, they end if err hook is * called. Therefore, we could suppose that it is always called * asynchronously. */ bgp_store_error(p, conn, BE_SOCKET, err); if (err) BGP_TRACE(D_EVENTS, "Connection lost (%M)", err); else BGP_TRACE(D_EVENTS, "Connection closed"); if ((conn->state == BS_ESTABLISHED) && p->gr_ready) bgp_handle_graceful_restart(p); bgp_conn_enter_idle_state(conn); } static void bgp_hold_timeout(timer *t) { struct bgp_conn *conn = t->data; struct bgp_proto *p = conn->bgp; DBG("BGP: Hold timeout\n"); /* We are already closing the connection - just do hangup */ if (conn->state == BS_CLOSE) { BGP_TRACE(D_EVENTS, "Connection stalled"); bgp_conn_enter_idle_state(conn); return; } /* If there is something in input queue, we are probably congested and perhaps just not processed BGP packets in time. */ if (sk_rx_ready(conn->sk) > 0) bgp_start_timer(conn->hold_timer, 10); else if ((conn->state == BS_ESTABLISHED) && p->llgr_ready) { BGP_TRACE(D_EVENTS, "Hold timer expired"); bgp_handle_graceful_restart(p); bgp_conn_enter_idle_state(conn); } else bgp_error(conn, 4, 0, NULL, 0); } static void bgp_keepalive_timeout(timer *t) { struct bgp_conn *conn = t->data; DBG("BGP: Keepalive timer\n"); bgp_schedule_packet(conn, NULL, PKT_KEEPALIVE); /* Kick TX a bit faster */ if (ev_active(conn->tx_ev)) ev_run(conn->tx_ev); } static void bgp_setup_conn(struct bgp_proto *p, struct bgp_conn *conn) { conn->sk = NULL; conn->bgp = p; conn->packets_to_send = 0; conn->channels_to_send = 0; conn->last_channel = 0; conn->last_channel_count = 0; conn->connect_timer = tm_new_init(p->p.pool, bgp_connect_timeout, conn, 0, 0); conn->hold_timer = tm_new_init(p->p.pool, bgp_hold_timeout, conn, 0, 0); conn->keepalive_timer = tm_new_init(p->p.pool, bgp_keepalive_timeout, conn, 0, 0); conn->tx_ev = ev_new_init(p->p.pool, bgp_kick_tx, conn); } static void bgp_setup_sk(struct bgp_conn *conn, sock *s) { s->data = conn; s->err_hook = bgp_sock_err; s->fast_rx = 1; conn->sk = s; } static void bgp_active(struct bgp_proto *p) { int delay = MAX(1, p->cf->connect_delay_time); struct bgp_conn *conn = &p->outgoing_conn; BGP_TRACE(D_EVENTS, "Connect delayed by %d seconds", delay); bgp_setup_conn(p, conn); bgp_conn_set_state(conn, BS_ACTIVE); bgp_start_timer(conn->connect_timer, delay); } /** * bgp_connect - initiate an outgoing connection * @p: BGP instance * * The bgp_connect() function creates a new &bgp_conn and initiates * a TCP connection to the peer. The rest of connection setup is governed * by the BGP state machine as described in the standard. */ static void bgp_connect(struct bgp_proto *p) /* Enter Connect state and start establishing connection */ { struct bgp_conn *conn = &p->outgoing_conn; int hops = p->cf->multihop ? : 1; DBG("BGP: Connecting\n"); sock *s = sk_new(p->p.pool); s->type = SK_TCP_ACTIVE; s->saddr = p->local_ip; s->daddr = p->remote_ip; s->dport = p->cf->remote_port; s->iface = p->neigh ? p->neigh->iface : NULL; s->vrf = p->p.vrf; s->ttl = p->cf->ttl_security ? 255 : hops; s->rbsize = p->cf->enable_extended_messages ? BGP_RX_BUFFER_EXT_SIZE : BGP_RX_BUFFER_SIZE; s->tbsize = p->cf->enable_extended_messages ? BGP_TX_BUFFER_EXT_SIZE : BGP_TX_BUFFER_SIZE; s->tos = IP_PREC_INTERNET_CONTROL; s->password = p->cf->password; s->tx_hook = bgp_connected; BGP_TRACE(D_EVENTS, "Connecting to %I%J from local address %I%J", s->daddr, ipa_is_link_local(s->daddr) ? p->cf->iface : NULL, s->saddr, ipa_is_link_local(s->saddr) ? s->iface : NULL); bgp_setup_conn(p, conn); bgp_setup_sk(conn, s); bgp_conn_set_state(conn, BS_CONNECT); if (sk_open(s) < 0) goto err; /* Set minimal receive TTL if needed */ if (p->cf->ttl_security) if (sk_set_min_ttl(s, 256 - hops) < 0) goto err; DBG("BGP: Waiting for connect success\n"); bgp_start_timer(conn->connect_timer, p->cf->connect_retry_time); return; err: sk_log_error(s, p->p.name); bgp_sock_err(s, 0); return; } static inline int bgp_is_dynamic(struct bgp_proto *p) { return ipa_zero(p->remote_ip); } /** * bgp_find_proto - find existing proto for incoming connection * @sk: TCP socket * */ static struct bgp_proto * bgp_find_proto(sock *sk) { struct bgp_proto *best = NULL; struct bgp_proto *p; /* sk->iface is valid only if src or dst address is link-local */ int link = ipa_is_link_local(sk->saddr) || ipa_is_link_local(sk->daddr); WALK_LIST(p, proto_list) if ((p->p.proto == &proto_bgp) && (ipa_equal(p->remote_ip, sk->daddr) || bgp_is_dynamic(p)) && (!p->cf->remote_range || ipa_in_netX(sk->daddr, p->cf->remote_range)) && (p->p.vrf == sk->vrf) && (p->cf->local_port == sk->sport) && (!link || (p->cf->iface == sk->iface)) && (ipa_zero(p->cf->local_ip) || ipa_equal(p->cf->local_ip, sk->saddr))) { best = p; if (!bgp_is_dynamic(p)) break; } return best; } /** * bgp_incoming_connection - handle an incoming connection * @sk: TCP socket * @dummy: unused * * This function serves as a socket hook for accepting of new BGP * connections. It searches a BGP instance corresponding to the peer * which has connected and if such an instance exists, it creates a * &bgp_conn structure, attaches it to the instance and either sends * an Open message or (if there already is an active connection) it * closes the new connection by sending a Notification message. */ static int bgp_incoming_connection(sock *sk, uint dummy UNUSED) { struct bgp_proto *p; int acc, hops; DBG("BGP: Incoming connection from %I port %d\n", sk->daddr, sk->dport); p = bgp_find_proto(sk); if (!p) { log(L_WARN "BGP: Unexpected connect from unknown address %I%J (port %d)", sk->daddr, ipa_is_link_local(sk->daddr) ? sk->iface : NULL, sk->dport); rfree(sk); return 0; } /* * BIRD should keep multiple incoming connections in OpenSent state (for * details RFC 4271 8.2.1 par 3), but it keeps just one. Duplicate incoming * connections are rejected istead. The exception is the case where an * incoming connection triggers a graceful restart. */ acc = (p->p.proto_state == PS_START || p->p.proto_state == PS_UP) && (p->start_state >= BSS_CONNECT) && (!p->incoming_conn.sk); if (p->conn && (p->conn->state == BS_ESTABLISHED) && p->gr_ready) { bgp_store_error(p, NULL, BE_MISC, BEM_GRACEFUL_RESTART); bgp_handle_graceful_restart(p); bgp_conn_enter_idle_state(p->conn); acc = 1; /* There might be separate incoming connection in OpenSent state */ if (p->incoming_conn.state > BS_ACTIVE) bgp_close_conn(&p->incoming_conn); } BGP_TRACE(D_EVENTS, "Incoming connection from %I%J (port %d) %s", sk->daddr, ipa_is_link_local(sk->daddr) ? sk->iface : NULL, sk->dport, acc ? "accepted" : "rejected"); if (!acc) { rfree(sk); return 0; } hops = p->cf->multihop ? : 1; if (sk_set_ttl(sk, p->cf->ttl_security ? 255 : hops) < 0) goto err; if (p->cf->ttl_security) if (sk_set_min_ttl(sk, 256 - hops) < 0) goto err; if (p->cf->enable_extended_messages) { sk->rbsize = BGP_RX_BUFFER_EXT_SIZE; sk->tbsize = BGP_TX_BUFFER_EXT_SIZE; sk_reallocate(sk); } /* For dynamic BGP, spawn new instance and postpone the socket */ if (bgp_is_dynamic(p)) { p = bgp_spawn(p, sk->daddr); p->postponed_sk = sk; rmove(sk, p->p.pool); return 0; } rmove(sk, p->p.pool); bgp_setup_conn(p, &p->incoming_conn); bgp_setup_sk(&p->incoming_conn, sk); bgp_send_open(&p->incoming_conn); return 0; err: sk_log_error(sk, p->p.name); log(L_ERR "%s: Incoming connection aborted", p->p.name); rfree(sk); return 0; } static void bgp_listen_sock_err(sock *sk UNUSED, int err) { if (err == ECONNABORTED) log(L_WARN "BGP: Incoming connection aborted"); else log(L_ERR "BGP: Error on listening socket: %M", err); } static void bgp_start_neighbor(struct bgp_proto *p) { /* Called only for single-hop BGP sessions */ if (ipa_zero(p->local_ip)) p->local_ip = p->neigh->ifa->ip; if (ipa_is_link_local(p->local_ip)) p->link_addr = p->local_ip; else if (p->neigh->iface->llv6) p->link_addr = p->neigh->iface->llv6->ip; bgp_initiate(p); } static void bgp_neigh_notify(neighbor *n) { struct bgp_proto *p = (struct bgp_proto *) n->proto; int ps = p->p.proto_state; if (n != p->neigh) return; if ((ps == PS_DOWN) || (ps == PS_STOP)) return; int prepare = (ps == PS_START) && (p->start_state == BSS_PREPARE); if (n->scope <= 0) { if (!prepare) { BGP_TRACE(D_EVENTS, "Neighbor lost"); bgp_store_error(p, NULL, BE_MISC, BEM_NEIGHBOR_LOST); /* Perhaps also run bgp_update_startup_delay(p)? */ bgp_stop(p, 0, NULL, 0); } } else if (p->cf->check_link && !(n->iface->flags & IF_LINK_UP)) { if (!prepare) { BGP_TRACE(D_EVENTS, "Link down"); bgp_store_error(p, NULL, BE_MISC, BEM_LINK_DOWN); if (ps == PS_UP) bgp_update_startup_delay(p); bgp_stop(p, 0, NULL, 0); } } else { if (prepare) { BGP_TRACE(D_EVENTS, "Neighbor ready"); bgp_start_neighbor(p); } } } static void bgp_bfd_notify(struct bfd_request *req) { struct bgp_proto *p = req->data; int ps = p->p.proto_state; if (req->down && ((ps == PS_START) || (ps == PS_UP))) { BGP_TRACE(D_EVENTS, "BFD session down"); bgp_store_error(p, NULL, BE_MISC, BEM_BFD_DOWN); if (req->opts.mode == BGP_BFD_GRACEFUL) { /* Trigger graceful restart */ if (p->conn && (p->conn->state == BS_ESTABLISHED) && p->gr_ready) bgp_handle_graceful_restart(p); if (p->incoming_conn.state > BS_IDLE) bgp_conn_enter_idle_state(&p->incoming_conn); if (p->outgoing_conn.state > BS_IDLE) bgp_conn_enter_idle_state(&p->outgoing_conn); } else { /* Trigger session down */ if (ps == PS_UP) bgp_update_startup_delay(p); bgp_stop(p, 0, NULL, 0); } } } static void bgp_update_bfd(struct bgp_proto *p, const struct bfd_options *bfd) { if (bfd && p->bfd_req) bfd_update_request(p->bfd_req, bfd); if (bfd && !p->bfd_req && !bgp_is_dynamic(p)) p->bfd_req = bfd_request_session(p->p.pool, p->remote_ip, p->local_ip, p->cf->multihop ? NULL : p->neigh->iface, p->p.vrf, bgp_bfd_notify, p, bfd); if (!bfd && p->bfd_req) { rfree(p->bfd_req); p->bfd_req = NULL; } } static void bgp_reload_routes(struct channel *C) { struct bgp_proto *p = (void *) C->proto; struct bgp_channel *c = (void *) C; ASSERT(p->conn && (p->route_refresh || c->c.in_table)); if (c->c.in_table) channel_schedule_reload(C); else bgp_schedule_packet(p->conn, c, PKT_ROUTE_REFRESH); } static void bgp_feed_begin(struct channel *C, int initial) { struct bgp_proto *p = (void *) C->proto; struct bgp_channel *c = (void *) C; /* This should not happen */ if (!p->conn) return; if (initial && p->cf->gr_mode) c->feed_state = BFS_LOADING; /* It is refeed and both sides support enhanced route refresh */ if (!initial && p->enhanced_refresh) { /* BoRR must not be sent before End-of-RIB */ if (c->feed_state == BFS_LOADING || c->feed_state == BFS_LOADED) return; c->feed_state = BFS_REFRESHING; bgp_schedule_packet(p->conn, c, PKT_BEGIN_REFRESH); } } static void bgp_feed_end(struct channel *C) { struct bgp_proto *p = (void *) C->proto; struct bgp_channel *c = (void *) C; /* This should not happen */ if (!p->conn) return; /* Non-demarcated feed ended, nothing to do */ if (c->feed_state == BFS_NONE) return; /* Schedule End-of-RIB packet */ if (c->feed_state == BFS_LOADING) c->feed_state = BFS_LOADED; /* Schedule EoRR packet */ if (c->feed_state == BFS_REFRESHING) c->feed_state = BFS_REFRESHED; /* Kick TX hook */ bgp_schedule_packet(p->conn, c, PKT_UPDATE); } static void bgp_start_locked(struct object_lock *lock) { struct bgp_proto *p = lock->data; const struct bgp_config *cf = p->cf; if (p->p.proto_state != PS_START) { DBG("BGP: Got lock in different state %d\n", p->p.proto_state); return; } DBG("BGP: Got lock\n"); if (cf->multihop || bgp_is_dynamic(p)) { /* Multi-hop sessions do not use neighbor entries */ bgp_initiate(p); return; } neighbor *n = neigh_find(&p->p, p->remote_ip, cf->iface, NEF_STICKY); if (!n) { log(L_ERR "%s: Invalid remote address %I%J", p->p.name, p->remote_ip, cf->iface); /* As we do not start yet, we can just disable protocol */ p->p.disabled = 1; bgp_store_error(p, NULL, BE_MISC, BEM_INVALID_NEXT_HOP); proto_notify_state(&p->p, PS_DOWN); return; } p->neigh = n; if (n->scope <= 0) BGP_TRACE(D_EVENTS, "Waiting for %I%J to become my neighbor", p->remote_ip, cf->iface); else if (p->cf->check_link && !(n->iface->flags & IF_LINK_UP)) BGP_TRACE(D_EVENTS, "Waiting for link on %s", n->iface->name); else bgp_start_neighbor(p); } static int bgp_start(struct proto *P) { struct bgp_proto *p = (struct bgp_proto *) P; const struct bgp_config *cf = p->cf; p->local_ip = cf->local_ip; p->local_as = cf->local_as; p->remote_as = cf->remote_as; p->public_as = cf->local_as; /* For dynamic BGP childs, remote_ip is already set */ if (ipa_nonzero(cf->remote_ip)) p->remote_ip = cf->remote_ip; /* Confederation ID is used for truly external peers */ if (p->cf->confederation && !p->is_interior) p->public_as = cf->confederation; p->passive = cf->passive || bgp_is_dynamic(p); p->start_state = BSS_PREPARE; p->outgoing_conn.state = BS_IDLE; p->incoming_conn.state = BS_IDLE; p->neigh = NULL; p->bfd_req = NULL; p->postponed_sk = NULL; p->gr_ready = 0; p->gr_active_num = 0; /* Reset some stats */ p->stats.rx_messages = p->stats.tx_messages = 0; p->stats.rx_updates = p->stats.tx_updates = 0; p->stats.rx_bytes = p->stats.tx_bytes = 0; p->last_rx_update = 0; p->event = ev_new_init(p->p.pool, bgp_decision, p); p->startup_timer = tm_new_init(p->p.pool, bgp_startup_timeout, p, 0, 0); p->gr_timer = tm_new_init(p->p.pool, bgp_graceful_restart_timeout, p, 0, 0); p->local_id = proto_get_router_id(P->cf); if (p->rr_client) p->rr_cluster_id = p->cf->rr_cluster_id ? p->cf->rr_cluster_id : p->local_id; p->remote_id = 0; p->link_addr = IPA_NONE; /* Lock all channels when in GR recovery mode */ if (p->p.gr_recovery && p->cf->gr_mode) { struct bgp_channel *c; WALK_LIST(c, p->p.channels) channel_graceful_restart_lock(&c->c); } /* * Before attempting to create the connection, we need to lock the port, * so that we are the only instance attempting to talk with that neighbor. */ struct object_lock *lock; lock = p->lock = olock_new(P->pool); lock->addr = p->remote_ip; lock->port = p->cf->remote_port; lock->iface = p->cf->iface; lock->vrf = p->cf->iface ? NULL : p->p.vrf; lock->type = OBJLOCK_TCP; lock->hook = bgp_start_locked; lock->data = p; /* For dynamic BGP, we use inst 1 to avoid collisions with regular BGP */ if (bgp_is_dynamic(p)) { lock->addr = net_prefix(p->cf->remote_range); lock->inst = 1; } olock_acquire(lock); return PS_START; } extern int proto_restart; static int bgp_shutdown(struct proto *P) { struct bgp_proto *p = (struct bgp_proto *) P; int subcode = 0; char *message = NULL; byte *data = NULL; uint len = 0; BGP_TRACE(D_EVENTS, "Shutdown requested"); switch (P->down_code) { case PDC_CF_REMOVE: case PDC_CF_DISABLE: subcode = 3; // Errcode 6, 3 - peer de-configured break; case PDC_CF_RESTART: subcode = 6; // Errcode 6, 6 - other configuration change break; case PDC_CMD_DISABLE: case PDC_CMD_SHUTDOWN: shutdown: subcode = 2; // Errcode 6, 2 - administrative shutdown message = P->message; break; case PDC_CMD_RESTART: subcode = 4; // Errcode 6, 4 - administrative reset message = P->message; break; case PDC_CMD_GR_DOWN: if ((p->cf->gr_mode != BGP_GR_ABLE) && (p->cf->llgr_mode != BGP_LLGR_ABLE)) goto shutdown; subcode = -1; // Do not send NOTIFICATION, just close the connection break; case PDC_RX_LIMIT_HIT: case PDC_IN_LIMIT_HIT: subcode = 1; // Errcode 6, 1 - max number of prefixes reached /* log message for compatibility */ log(L_WARN "%s: Route limit exceeded, shutting down", p->p.name); goto limit; case PDC_OUT_LIMIT_HIT: subcode = proto_restart ? 4 : 2; // Administrative reset or shutdown limit: bgp_store_error(p, NULL, BE_AUTO_DOWN, BEA_ROUTE_LIMIT_EXCEEDED); if (proto_restart) bgp_update_startup_delay(p); else p->startup_delay = 0; goto done; } bgp_store_error(p, NULL, BE_MAN_DOWN, 0); p->startup_delay = 0; /* RFC 8203 - shutdown communication */ if (message) { uint msg_len = strlen(message); msg_len = MIN(msg_len, 255); /* Buffer will be freed automatically by protocol shutdown */ data = mb_alloc(p->p.pool, msg_len + 1); len = msg_len + 1; data[0] = msg_len; memcpy(data+1, message, msg_len); } done: bgp_stop(p, subcode, data, len); return p->p.proto_state; } static struct proto * bgp_init(struct proto_config *CF) { struct proto *P = proto_new(CF); struct bgp_proto *p = (struct bgp_proto *) P; struct bgp_config *cf = (struct bgp_config *) CF; P->rt_notify = bgp_rt_notify; P->preexport = bgp_preexport; P->neigh_notify = bgp_neigh_notify; P->reload_routes = bgp_reload_routes; P->feed_begin = bgp_feed_begin; P->feed_end = bgp_feed_end; P->rte_better = bgp_rte_better; P->rte_mergable = bgp_rte_mergable; P->rte_recalculate = cf->deterministic_med ? bgp_rte_recalculate : NULL; P->rte_modify = bgp_rte_modify_stale; P->rte_igp_metric = bgp_rte_igp_metric; p->cf = cf; p->is_internal = (cf->local_as == cf->remote_as); p->is_interior = p->is_internal || cf->confederation_member; p->rs_client = cf->rs_client; p->rr_client = cf->rr_client; p->ipv4 = ipa_nonzero(cf->remote_ip) ? ipa_is_ip4(cf->remote_ip) : (cf->remote_range && (cf->remote_range->type == NET_IP4)); p->remote_ip = cf->remote_ip; p->remote_as = cf->remote_as; /* Hack: We use cf->remote_ip just to pass remote_ip from bgp_spawn() */ if (cf->c.parent) cf->remote_ip = IPA_NONE; /* Add all channels */ struct bgp_channel_config *cc; WALK_LIST(cc, CF->channels) proto_add_channel(P, &cc->c); return P; } static void bgp_channel_init(struct channel *C, struct channel_config *CF) { struct bgp_channel *c = (void *) C; struct bgp_channel_config *cf = (void *) CF; c->cf = cf; c->afi = cf->afi; c->desc = cf->desc; if (cf->igp_table_ip4) c->igp_table_ip4 = cf->igp_table_ip4->table; if (cf->igp_table_ip6) c->igp_table_ip6 = cf->igp_table_ip6->table; if (cf->base_table) c->base_table = cf->base_table->table; } static int bgp_channel_start(struct channel *C) { struct bgp_proto *p = (void *) C->proto; struct bgp_channel *c = (void *) C; ip_addr src = p->local_ip; if (c->igp_table_ip4) rt_lock_table(c->igp_table_ip4); if (c->igp_table_ip6) rt_lock_table(c->igp_table_ip6); if (c->base_table) { rt_lock_table(c->base_table); rt_flowspec_link(c->base_table, c->c.table); } c->pool = p->p.pool; // XXXX bgp_init_bucket_table(c); bgp_init_prefix_table(c); if (c->cf->import_table) channel_setup_in_table(C); if (c->cf->export_table) channel_setup_out_table(C); c->stale_timer = tm_new_init(c->pool, bgp_long_lived_stale_timeout, c, 0, 0); c->next_hop_addr = c->cf->next_hop_addr; c->link_addr = IPA_NONE; c->packets_to_send = 0; /* Try to use source address as next hop address */ if (ipa_zero(c->next_hop_addr)) { if (bgp_channel_is_ipv4(c) && (ipa_is_ip4(src) || c->ext_next_hop)) c->next_hop_addr = src; if (bgp_channel_is_ipv6(c) && (ipa_is_ip6(src) || c->ext_next_hop)) c->next_hop_addr = src; } /* Use preferred addresses associated with interface / source address */ if (ipa_zero(c->next_hop_addr)) { /* We know the iface for single-hop, we make lookup for multihop */ struct neighbor *nbr = p->neigh ?: neigh_find(&p->p, src, NULL, 0); struct iface *iface = nbr ? nbr->iface : NULL; if (bgp_channel_is_ipv4(c) && iface && iface->addr4) c->next_hop_addr = iface->addr4->ip; if (bgp_channel_is_ipv6(c) && iface && iface->addr6) c->next_hop_addr = iface->addr6->ip; } /* Exit if no feasible next hop address is found */ if (ipa_zero(c->next_hop_addr)) { log(L_WARN "%s: Missing next hop address", p->p.name); return 0; } /* Set link-local address for IPv6 single-hop BGP */ if (ipa_is_ip6(c->next_hop_addr) && p->neigh) { c->link_addr = p->link_addr; if (ipa_zero(c->link_addr)) log(L_WARN "%s: Missing link-local address", p->p.name); } /* Link local address is already in c->link_addr */ if (ipa_is_link_local(c->next_hop_addr)) c->next_hop_addr = IPA_NONE; return 0; /* XXXX: Currently undefined */ } static void bgp_channel_shutdown(struct channel *C) { struct bgp_channel *c = (void *) C; c->next_hop_addr = IPA_NONE; c->link_addr = IPA_NONE; c->packets_to_send = 0; } static void bgp_channel_cleanup(struct channel *C) { struct bgp_channel *c = (void *) C; if (c->igp_table_ip4) rt_unlock_table(c->igp_table_ip4); if (c->igp_table_ip6) rt_unlock_table(c->igp_table_ip6); if (c->base_table) { rt_flowspec_unlink(c->base_table, c->c.table); rt_unlock_table(c->base_table); } c->index = 0; /* Cleanup rest of bgp_channel starting at pool field */ memset(&(c->pool), 0, sizeof(struct bgp_channel) - OFFSETOF(struct bgp_channel, pool)); } static inline struct bgp_channel_config * bgp_find_channel_config(struct bgp_config *cf, u32 afi) { struct bgp_channel_config *cc; WALK_LIST(cc, cf->c.channels) if (cc->afi == afi) return cc; return NULL; } struct rtable_config * bgp_default_igp_table(struct bgp_config *cf, struct bgp_channel_config *cc, u32 type) { struct bgp_channel_config *cc2; struct rtable_config *tab; /* First, try table connected by the channel */ if (cc->c.table->addr_type == type) return cc->c.table; /* Find paired channel with the same SAFI but the other AFI */ u32 afi2 = cc->afi ^ 0x30000; cc2 = bgp_find_channel_config(cf, afi2); /* Second, try IGP table configured in the paired channel */ if (cc2 && (tab = (type == NET_IP4) ? cc2->igp_table_ip4 : cc2->igp_table_ip6)) return tab; /* Third, try table connected by the paired channel */ if (cc2 && (cc2->c.table->addr_type == type)) return cc2->c.table; /* Last, try default table of given type */ if (tab = cf->c.global->def_tables[type]) return tab; cf_error("Undefined IGP table"); } static struct rtable_config * bgp_default_base_table(struct bgp_config *cf, struct bgp_channel_config *cc) { /* Expected table type */ u32 type = (cc->afi == BGP_AF_FLOW4) ? NET_IP4 : NET_IP6; /* First, try appropriate IP channel */ u32 afi2 = BGP_AF(BGP_AFI(cc->afi), BGP_SAFI_UNICAST); struct bgp_channel_config *cc2 = bgp_find_channel_config(cf, afi2); if (cc2 && (cc2->c.table->addr_type == type)) return cc2->c.table; /* Last, try default table of given type */ struct rtable_config *tab = cf->c.global->def_tables[type]; if (tab) return tab; cf_error("Undefined base table"); } void bgp_postconfig(struct proto_config *CF) { struct bgp_config *cf = (void *) CF; /* Do not check templates at all */ if (cf->c.class == SYM_TEMPLATE) return; /* Handle undefined remote_as, zero should mean unspecified external */ if (!cf->remote_as && (cf->peer_type == BGP_PT_INTERNAL)) cf->remote_as = cf->local_as; int internal = (cf->local_as == cf->remote_as); int interior = internal || cf->confederation_member; /* EBGP direct by default, IBGP multihop by default */ if (cf->multihop < 0) cf->multihop = internal ? 64 : 0; /* LLGR mode default based on GR mode */ if (cf->llgr_mode < 0) cf->llgr_mode = cf->gr_mode ? BGP_LLGR_AWARE : 0; /* Link check for single-hop BGP by default */ if (cf->check_link < 0) cf->check_link = !cf->multihop; if (!cf->local_as) cf_error("Local AS number must be set"); if (ipa_zero(cf->remote_ip) && !cf->remote_range) cf_error("Neighbor must be configured"); if (ipa_zero(cf->local_ip) && cf->strict_bind) cf_error("Local address must be configured for strict bind"); if (!cf->remote_as && !cf->peer_type) cf_error("Remote AS number (or peer type) must be set"); if ((cf->peer_type == BGP_PT_INTERNAL) && !internal) cf_error("IBGP cannot have different ASNs"); if ((cf->peer_type == BGP_PT_EXTERNAL) && internal) cf_error("EBGP cannot have the same ASNs"); if (!cf->iface && (ipa_is_link_local(cf->local_ip) || ipa_is_link_local(cf->remote_ip))) cf_error("Link-local addresses require defined interface"); if (!(cf->capabilities && cf->enable_as4) && (cf->remote_as > 0xFFFF)) cf_error("Neighbor AS number out of range (AS4 not available)"); if (!internal && cf->rr_client) cf_error("Only internal neighbor can be RR client"); if (internal && cf->rs_client) cf_error("Only external neighbor can be RS client"); if (!cf->confederation && cf->confederation_member) cf_error("Confederation ID must be set for member sessions"); if (cf->multihop && (ipa_is_link_local(cf->local_ip) || ipa_is_link_local(cf->remote_ip))) cf_error("Multihop BGP cannot be used with link-local addresses"); if (cf->multihop && cf->iface) cf_error("Multihop BGP cannot be bound to interface"); if (cf->multihop && cf->check_link) cf_error("Multihop BGP cannot depend on link state"); if (cf->multihop && cf->bfd && ipa_zero(cf->local_ip)) cf_error("Multihop BGP with BFD requires specified local address"); if (!cf->gr_mode && cf->llgr_mode) cf_error("Long-lived graceful restart requires basic graceful restart"); if (internal && cf->enforce_first_as) cf_error("Enforce first AS check is requires EBGP sessions"); struct bgp_channel_config *cc; WALK_LIST(cc, CF->channels) { /* Handle undefined import filter */ if (cc->c.in_filter == FILTER_UNDEF) if (interior) cc->c.in_filter = FILTER_ACCEPT; else cf_error("EBGP requires explicit import policy"); /* Handle undefined export filter */ if (cc->c.out_filter == FILTER_UNDEF) if (interior) cc->c.out_filter = FILTER_REJECT; else cf_error("EBGP requires explicit export policy"); /* Disable after error incompatible with restart limit action */ if ((cc->c.in_limit.action == PLA_RESTART) && cf->disable_after_error) cc->c.in_limit.action = PLA_DISABLE; /* Different default based on rr_client, rs_client */ if (cc->next_hop_keep == 0xff) cc->next_hop_keep = cf->rr_client ? NH_IBGP : (cf->rs_client ? NH_ALL : NH_NO); /* Different default for gw_mode */ if (!cc->gw_mode) cc->gw_mode = cf->multihop ? GW_RECURSIVE : GW_DIRECT; /* Defaults based on proto config */ if (cc->gr_able == 0xff) cc->gr_able = (cf->gr_mode == BGP_GR_ABLE); if (cc->llgr_able == 0xff) cc->llgr_able = (cf->llgr_mode == BGP_LLGR_ABLE); if (cc->llgr_time == ~0U) cc->llgr_time = cf->llgr_time; /* AIGP enabled by default on interior sessions */ if (cc->aigp == 0xff) cc->aigp = interior; /* Default values of IGP tables */ if ((cc->gw_mode == GW_RECURSIVE) && !cc->desc->no_igp) { if (!cc->igp_table_ip4 && (bgp_cc_is_ipv4(cc) || cc->ext_next_hop)) cc->igp_table_ip4 = bgp_default_igp_table(cf, cc, NET_IP4); if (!cc->igp_table_ip6 && (bgp_cc_is_ipv6(cc) || cc->ext_next_hop)) cc->igp_table_ip6 = bgp_default_igp_table(cf, cc, NET_IP6); if (cc->igp_table_ip4 && bgp_cc_is_ipv6(cc) && !cc->ext_next_hop) cf_error("Mismatched IGP table type"); if (cc->igp_table_ip6 && bgp_cc_is_ipv4(cc) && !cc->ext_next_hop) cf_error("Mismatched IGP table type"); } /* Default value of base table */ if ((BGP_SAFI(cc->afi) == BGP_SAFI_FLOW) && cc->validate && !cc->base_table) cc->base_table = bgp_default_base_table(cf, cc); if (cc->base_table && !cc->base_table->trie_used) cf_error("Flowspec validation requires base table (%s) with trie", cc->base_table->name); if (cf->multihop && (cc->gw_mode == GW_DIRECT)) cf_error("Multihop BGP cannot use direct gateway mode"); if ((cc->gw_mode == GW_RECURSIVE) && cc->c.table->sorted) cf_error("BGP in recursive mode prohibits sorted table"); if (cf->deterministic_med && cc->c.table->sorted) cf_error("BGP with deterministic MED prohibits sorted table"); if (cc->secondary && !cc->c.table->sorted) cf_error("BGP with secondary option requires sorted table"); } } static int bgp_reconfigure(struct proto *P, struct proto_config *CF) { struct bgp_proto *p = (void *) P; const struct bgp_config *new = (void *) CF; const struct bgp_config *old = p->cf; if (proto_get_router_id(CF) != p->local_id) return 0; int same = !memcmp(((byte *) old) + sizeof(struct proto_config), ((byte *) new) + sizeof(struct proto_config), // password item is last and must be checked separately OFFSETOF(struct bgp_config, password) - sizeof(struct proto_config)) && !bstrcmp(old->password, new->password) && ((!old->remote_range && !new->remote_range) || (old->remote_range && new->remote_range && net_equal(old->remote_range, new->remote_range))) && !bstrcmp(old->dynamic_name, new->dynamic_name) && (old->dynamic_name_digits == new->dynamic_name_digits); /* FIXME: Move channel reconfiguration to generic protocol code ? */ struct channel *C, *C2; struct bgp_channel_config *cc; WALK_LIST(C, p->p.channels) C->stale = 1; WALK_LIST(cc, new->c.channels) { C = (struct channel *) bgp_find_channel(p, cc->afi); same = proto_configure_channel(P, &C, &cc->c) && same; if (C) C->stale = 0; } WALK_LIST_DELSAFE(C, C2, p->p.channels) if (C->stale) same = proto_configure_channel(P, &C, NULL) && same; if (same && (p->start_state > BSS_PREPARE)) bgp_update_bfd(p, new->bfd); /* We should update our copy of configuration ptr as old configuration will be freed */ if (same) p->cf = new; /* Reset name counter */ p->dynamic_name_counter = 0; return same; } #define TABLE(cf, NAME) ((cf)->NAME ? (cf)->NAME->table : NULL ) static int bgp_channel_reconfigure(struct channel *C, struct channel_config *CC, int *import_changed, int *export_changed) { struct bgp_proto *p = (void *) C->proto; struct bgp_channel *c = (void *) C; struct bgp_channel_config *new = (void *) CC; struct bgp_channel_config *old = c->cf; if ((new->secondary != old->secondary) || (new->validate != old->validate) || (new->gr_able != old->gr_able) || (new->llgr_able != old->llgr_able) || (new->llgr_time != old->llgr_time) || (new->ext_next_hop != old->ext_next_hop) || (new->add_path != old->add_path) || (new->import_table != old->import_table) || (new->export_table != old->export_table) || (TABLE(new, igp_table_ip4) != TABLE(old, igp_table_ip4)) || (TABLE(new, igp_table_ip6) != TABLE(old, igp_table_ip6)) || (TABLE(new, base_table) != TABLE(old, base_table))) return 0; if (new->mandatory && !old->mandatory && (C->channel_state != CS_UP)) return 0; if ((new->gw_mode != old->gw_mode) || (new->aigp != old->aigp) || (new->cost != old->cost)) { /* import_changed itself does not force ROUTE_REFRESH when import_table is active */ if (c->c.in_table && (c->c.channel_state == CS_UP)) bgp_schedule_packet(p->conn, c, PKT_ROUTE_REFRESH); *import_changed = 1; } if (!ipa_equal(new->next_hop_addr, old->next_hop_addr) || (new->next_hop_self != old->next_hop_self) || (new->next_hop_keep != old->next_hop_keep) || (new->aigp != old->aigp) || (new->aigp_originate != old->aigp_originate)) *export_changed = 1; c->cf = new; return 1; } static void bgp_copy_config(struct proto_config *dest, struct proto_config *src) { struct bgp_config *d = (void *) dest; struct bgp_config *s = (void *) src; /* Copy BFD options */ if (s->bfd) { struct bfd_options *opts = cfg_alloc(sizeof(struct bfd_options)); memcpy(opts, s->bfd, sizeof(struct bfd_options)); d->bfd = opts; } } /** * bgp_error - report a protocol error * @c: connection * @code: error code (according to the RFC) * @subcode: error sub-code * @data: data to be passed in the Notification message * @len: length of the data * * bgp_error() sends a notification packet to tell the other side that a protocol * error has occurred (including the data considered erroneous if possible) and * closes the connection. */ void bgp_error(struct bgp_conn *c, uint code, uint subcode, byte *data, int len) { struct bgp_proto *p = c->bgp; if (c->state == BS_CLOSE) return; bgp_log_error(p, BE_BGP_TX, "Error", code, subcode, data, ABS(len)); bgp_store_error(p, c, BE_BGP_TX, (code << 16) | subcode); bgp_conn_enter_close_state(c); c->notify_code = code; c->notify_subcode = subcode; c->notify_data = data; c->notify_size = (len > 0) ? len : 0; bgp_schedule_packet(c, NULL, PKT_NOTIFICATION); if (code != 6) { bgp_update_startup_delay(p); bgp_stop(p, 0, NULL, 0); } } /** * bgp_store_error - store last error for status report * @p: BGP instance * @c: connection * @class: error class (BE_xxx constants) * @code: error code (class specific) * * bgp_store_error() decides whether given error is interesting enough * and store that error to last_error variables of @p */ void bgp_store_error(struct bgp_proto *p, struct bgp_conn *c, u8 class, u32 code) { /* During PS_UP, we ignore errors on secondary connection */ if ((p->p.proto_state == PS_UP) && c && (c != p->conn)) return; /* During PS_STOP, we ignore any errors, as we want to report * the error that caused transition to PS_STOP */ if (p->p.proto_state == PS_STOP) return; p->last_error_class = class; p->last_error_code = code; } static char *bgp_state_names[] = { "Idle", "Connect", "Active", "OpenSent", "OpenConfirm", "Established", "Close" }; static char *bgp_err_classes[] = { "", "Error: ", "Socket: ", "Received: ", "BGP Error: ", "Automatic shutdown: ", ""}; static char *bgp_misc_errors[] = { "", "Neighbor lost", "Invalid next hop", "Kernel MD5 auth failed", "No listening socket", "Link down", "BFD session down", "Graceful restart"}; static char *bgp_auto_errors[] = { "", "Route limit exceeded"}; static char *bgp_gr_states[] = { "None", "Regular", "Long-lived"}; static const char * bgp_last_errmsg(struct bgp_proto *p) { switch (p->last_error_class) { case BE_MISC: return bgp_misc_errors[p->last_error_code]; case BE_SOCKET: return (p->last_error_code == 0) ? "Connection closed" : strerror(p->last_error_code); case BE_BGP_RX: case BE_BGP_TX: return bgp_error_dsc(p->last_error_code >> 16, p->last_error_code & 0xFF); case BE_AUTO_DOWN: return bgp_auto_errors[p->last_error_code]; default: return ""; } } static const char * bgp_state_dsc(struct bgp_proto *p) { if (p->p.proto_state == PS_DOWN) return "Down"; int state = MAX(p->incoming_conn.state, p->outgoing_conn.state); if ((state == BS_IDLE) && (p->start_state >= BSS_CONNECT) && p->passive) return "Passive"; return bgp_state_names[state]; } static void bgp_get_status(struct proto *P, byte *buf) { struct bgp_proto *p = (struct bgp_proto *) P; const char *err1 = bgp_err_classes[p->last_error_class]; const char *err2 = bgp_last_errmsg(p); if (P->proto_state == PS_DOWN) bsprintf(buf, "%s%s", err1, err2); else bsprintf(buf, "%-14s%s%s", bgp_state_dsc(p), err1, err2); } static void bgp_show_afis(int code, char *s, u32 *afis, uint count) { buffer b; LOG_BUFFER_INIT(b); buffer_puts(&b, s); for (u32 *af = afis; af < (afis + count); af++) { const struct bgp_af_desc *desc = bgp_get_af_desc(*af); if (desc) buffer_print(&b, " %s", desc->name); else buffer_print(&b, " <%u/%u>", BGP_AFI(*af), BGP_SAFI(*af)); } if (b.pos == b.end) strcpy(b.end - 32, " ... "); cli_msg(code, b.start); } static void bgp_show_capabilities(struct bgp_proto *p UNUSED, struct bgp_caps *caps) { struct bgp_af_caps *ac; uint any_mp_bgp = 0; uint any_gr_able = 0; uint any_add_path = 0; uint any_ext_next_hop = 0; uint any_llgr_able = 0; u32 *afl1 = alloca(caps->af_count * sizeof(u32)); u32 *afl2 = alloca(caps->af_count * sizeof(u32)); uint afn1, afn2; WALK_AF_CAPS(caps, ac) { any_mp_bgp |= ac->ready; any_gr_able |= ac->gr_able; any_add_path |= ac->add_path; any_ext_next_hop |= ac->ext_next_hop; any_llgr_able |= ac->llgr_able; } if (any_mp_bgp) { cli_msg(-1006, " Multiprotocol"); afn1 = 0; WALK_AF_CAPS(caps, ac) if (ac->ready) afl1[afn1++] = ac->afi; bgp_show_afis(-1006, " AF announced:", afl1, afn1); } if (caps->route_refresh) cli_msg(-1006, " Route refresh"); if (any_ext_next_hop) { cli_msg(-1006, " Extended next hop"); afn1 = 0; WALK_AF_CAPS(caps, ac) if (ac->ext_next_hop) afl1[afn1++] = ac->afi; bgp_show_afis(-1006, " IPv6 nexthop:", afl1, afn1); } if (caps->ext_messages) cli_msg(-1006, " Extended message"); if (caps->gr_aware) cli_msg(-1006, " Graceful restart"); if (any_gr_able) { /* Continues from gr_aware */ cli_msg(-1006, " Restart time: %u", caps->gr_time); if (caps->gr_flags & BGP_GRF_RESTART) cli_msg(-1006, " Restart recovery"); afn1 = afn2 = 0; WALK_AF_CAPS(caps, ac) { if (ac->gr_able) afl1[afn1++] = ac->afi; if (ac->gr_af_flags & BGP_GRF_FORWARDING) afl2[afn2++] = ac->afi; } bgp_show_afis(-1006, " AF supported:", afl1, afn1); bgp_show_afis(-1006, " AF preserved:", afl2, afn2); } if (caps->as4_support) cli_msg(-1006, " 4-octet AS numbers"); if (any_add_path) { cli_msg(-1006, " ADD-PATH"); afn1 = afn2 = 0; WALK_AF_CAPS(caps, ac) { if (ac->add_path & BGP_ADD_PATH_RX) afl1[afn1++] = ac->afi; if (ac->add_path & BGP_ADD_PATH_TX) afl2[afn2++] = ac->afi; } bgp_show_afis(-1006, " RX:", afl1, afn1); bgp_show_afis(-1006, " TX:", afl2, afn2); } if (caps->enhanced_refresh) cli_msg(-1006, " Enhanced refresh"); if (caps->llgr_aware) cli_msg(-1006, " Long-lived graceful restart"); if (any_llgr_able) { u32 stale_time = 0; afn1 = afn2 = 0; WALK_AF_CAPS(caps, ac) { stale_time = MAX(stale_time, ac->llgr_time); if (ac->llgr_able && ac->llgr_time) afl1[afn1++] = ac->afi; if (ac->llgr_flags & BGP_GRF_FORWARDING) afl2[afn2++] = ac->afi; } /* Continues from llgr_aware */ cli_msg(-1006, " LL stale time: %u", stale_time); bgp_show_afis(-1006, " AF supported:", afl1, afn1); bgp_show_afis(-1006, " AF preserved:", afl2, afn2); } if (caps->hostname) cli_msg(-1006, " Hostname: %s", caps->hostname); } static void bgp_show_proto_info(struct proto *P) { struct bgp_proto *p = (struct bgp_proto *) P; cli_msg(-1006, " BGP state: %s", bgp_state_dsc(p)); if (bgp_is_dynamic(p) && p->cf->remote_range) cli_msg(-1006, " Neighbor range: %N", p->cf->remote_range); else cli_msg(-1006, " Neighbor address: %I%J", p->remote_ip, p->cf->iface); cli_msg(-1006, " Neighbor AS: %u", p->remote_as); cli_msg(-1006, " Local AS: %u", p->cf->local_as); if (p->gr_active_num) cli_msg(-1006, " Neighbor graceful restart active"); if (P->proto_state == PS_START) { struct bgp_conn *oc = &p->outgoing_conn; if ((p->start_state < BSS_CONNECT) && (tm_active(p->startup_timer))) cli_msg(-1006, " Error wait: %t/%u", tm_remains(p->startup_timer), p->startup_delay); if ((oc->state == BS_ACTIVE) && (tm_active(oc->connect_timer))) cli_msg(-1006, " Connect delay: %t/%u", tm_remains(oc->connect_timer), p->cf->connect_delay_time); if (p->gr_active_num && tm_active(p->gr_timer)) cli_msg(-1006, " Restart timer: %t/-", tm_remains(p->gr_timer)); } else if (P->proto_state == PS_UP) { cli_msg(-1006, " Neighbor ID: %R", p->remote_id); cli_msg(-1006, " Local capabilities"); bgp_show_capabilities(p, p->conn->local_caps); cli_msg(-1006, " Neighbor capabilities"); bgp_show_capabilities(p, p->conn->remote_caps); cli_msg(-1006, " Session: %s%s%s%s%s", p->is_internal ? "internal" : "external", p->cf->multihop ? " multihop" : "", p->rr_client ? " route-reflector" : "", p->rs_client ? " route-server" : "", p->as4_session ? " AS4" : ""); cli_msg(-1006, " Source address: %I", p->local_ip); cli_msg(-1006, " Hold timer: %t/%u", tm_remains(p->conn->hold_timer), p->conn->hold_time); cli_msg(-1006, " Keepalive timer: %t/%u", tm_remains(p->conn->keepalive_timer), p->conn->keepalive_time); } #if 0 struct bgp_stats *s = &p->stats; cli_msg(-1006, " FSM established transitions: %u", s->fsm_established_transitions); cli_msg(-1006, " Rcvd messages: %u total / %u updates / %lu bytes", s->rx_messages, s->rx_updates, s->rx_bytes); cli_msg(-1006, " Sent messages: %u total / %u updates / %lu bytes", s->tx_messages, s->tx_updates, s->tx_bytes); cli_msg(-1006, " Last rcvd update elapsed time: %t s", p->last_rx_update ? (current_time() - p->last_rx_update) : 0); #endif if ((p->last_error_class != BE_NONE) && (p->last_error_class != BE_MAN_DOWN)) { const char *err1 = bgp_err_classes[p->last_error_class]; const char *err2 = bgp_last_errmsg(p); cli_msg(-1006, " Last error: %s%s", err1, err2); } { struct bgp_channel *c; WALK_LIST(c, p->p.channels) { channel_show_info(&c->c); if (p->gr_active_num) cli_msg(-1006, " Neighbor GR: %s", bgp_gr_states[c->gr_active]); if (c->stale_timer && tm_active(c->stale_timer)) cli_msg(-1006, " LL stale timer: %t/-", tm_remains(c->stale_timer)); if (c->c.channel_state == CS_UP) { if (ipa_zero(c->link_addr)) cli_msg(-1006, " BGP Next hop: %I", c->next_hop_addr); else cli_msg(-1006, " BGP Next hop: %I %I", c->next_hop_addr, c->link_addr); } if (c->igp_table_ip4) cli_msg(-1006, " IGP IPv4 table: %s", c->igp_table_ip4->name); if (c->igp_table_ip6) cli_msg(-1006, " IGP IPv6 table: %s", c->igp_table_ip6->name); if (c->base_table) cli_msg(-1006, " Base table: %s", c->base_table->name); } } } struct channel_class channel_bgp = { .channel_size = sizeof(struct bgp_channel), .config_size = sizeof(struct bgp_channel_config), .init = bgp_channel_init, .start = bgp_channel_start, .shutdown = bgp_channel_shutdown, .cleanup = bgp_channel_cleanup, .reconfigure = bgp_channel_reconfigure, }; struct protocol proto_bgp = { .name = "BGP", .template = "bgp%d", .class = PROTOCOL_BGP, .preference = DEF_PREF_BGP, .channel_mask = NB_IP | NB_VPN | NB_FLOW, .proto_size = sizeof(struct bgp_proto), .config_size = sizeof(struct bgp_config), .postconfig = bgp_postconfig, .init = bgp_init, .start = bgp_start, .shutdown = bgp_shutdown, .reconfigure = bgp_reconfigure, .copy_config = bgp_copy_config, .get_status = bgp_get_status, .get_attr = bgp_get_attr, .get_route_info = bgp_get_route_info, .show_proto_info = bgp_show_proto_info }; void bgp_build(void) { proto_build(&proto_bgp); }