/* * BIRD -- BGP Packet Processing * * (c) 2000 Martin Mares * * Can be freely distributed and used under the terms of the GNU GPL. */ #undef LOCAL_DEBUG #include "nest/bird.h" #include "nest/iface.h" #include "nest/protocol.h" #include "nest/route.h" #include "nest/attrs.h" #include "proto/mrt/mrt.h" #include "conf/conf.h" #include "lib/unaligned.h" #include "lib/socket.h" #include "nest/cli.h" #include "bgp.h" #define BGP_RR_REQUEST 0 #define BGP_RR_BEGIN 1 #define BGP_RR_END 2 static struct tbf rl_rcv_update = TBF_DEFAULT_LOG_LIMITS; static struct tbf rl_snd_update = TBF_DEFAULT_LOG_LIMITS; /* Table for state -> RFC 6608 FSM error subcodes */ static byte fsm_err_subcode[BS_MAX] = { [BS_OPENSENT] = 1, [BS_OPENCONFIRM] = 2, [BS_ESTABLISHED] = 3 }; static void init_mrt_bgp_data(struct bgp_conn *conn, struct mrt_bgp_data *d) { struct bgp_proto *p = conn->bgp; int p_ok = conn->state >= BS_OPENCONFIRM; memset(d, 0, sizeof(struct mrt_bgp_data)); d->peer_as = p->remote_as; d->local_as = p->local_as; d->index = (p->neigh && p->neigh->iface) ? p->neigh->iface->index : 0; d->af = BGP_AF; d->peer_ip = conn->sk ? conn->sk->daddr : IPA_NONE; d->local_ip = conn->sk ? conn->sk->saddr : IPA_NONE; d->as4 = p_ok ? p->as4_session : 0; d->add_path = p_ok ? p->add_path_rx : 0; } static void bgp_dump_message(struct bgp_conn *conn, byte *pkt, uint len) { struct mrt_bgp_data d; init_mrt_bgp_data(conn, &d); d.message = pkt; d.msg_len = len; mrt_dump_bgp_message(&d); } void bgp_dump_state_change(struct bgp_conn *conn, uint old, uint new) { struct mrt_bgp_data d; init_mrt_bgp_data(conn, &d); d.old_state = old; d.new_state = new; mrt_dump_bgp_state_change(&d); } static byte * bgp_create_notification(struct bgp_conn *conn, byte *buf) { struct bgp_proto *p = conn->bgp; BGP_TRACE(D_PACKETS, "Sending NOTIFICATION(code=%d.%d)", conn->notify_code, conn->notify_subcode); buf[0] = conn->notify_code; buf[1] = conn->notify_subcode; memcpy(buf+2, conn->notify_data, conn->notify_size); return buf + 2 + conn->notify_size; } #ifdef IPV6 static byte * bgp_put_cap_ipv6(struct bgp_proto *p UNUSED, byte *buf) { *buf++ = 1; /* Capability 1: Multiprotocol extensions */ *buf++ = 4; /* Capability data length */ *buf++ = 0; /* We support AF IPv6 */ *buf++ = BGP_AF_IPV6; *buf++ = 0; /* RFU */ *buf++ = 1; /* and SAFI 1 */ return buf; } #else static byte * bgp_put_cap_ipv4(struct bgp_proto *p UNUSED, byte *buf) { *buf++ = 1; /* Capability 1: Multiprotocol extensions */ *buf++ = 4; /* Capability data length */ *buf++ = 0; /* We support AF IPv4 */ *buf++ = BGP_AF_IPV4; *buf++ = 0; /* RFU */ *buf++ = 1; /* and SAFI 1 */ return buf; } #endif static byte * bgp_put_cap_rr(struct bgp_proto *p UNUSED, byte *buf) { *buf++ = 2; /* Capability 2: Support for route refresh */ *buf++ = 0; /* Capability data length */ return buf; } static byte * bgp_put_cap_ext_msg(struct bgp_proto *p UNUSED, byte *buf) { *buf++ = 6; /* Capability 6: Support for extended messages */ *buf++ = 0; /* Capability data length */ return buf; } static byte * bgp_put_cap_gr1(struct bgp_proto *p, byte *buf) { *buf++ = 64; /* Capability 64: Support for graceful restart */ *buf++ = 6; /* Capability data length */ put_u16(buf, p->cf->gr_time); if (p->p.gr_recovery) buf[0] |= BGP_GRF_RESTART; buf += 2; *buf++ = 0; /* Appropriate AF */ *buf++ = BGP_AF; *buf++ = 1; /* and SAFI 1 */ *buf++ = p->p.gr_recovery ? BGP_GRF_FORWARDING : 0; return buf; } static byte * bgp_put_cap_gr2(struct bgp_proto *p UNUSED, byte *buf) { *buf++ = 64; /* Capability 64: Support for graceful restart */ *buf++ = 2; /* Capability data length */ put_u16(buf, 0); return buf + 2; } static byte * bgp_put_cap_as4(struct bgp_proto *p, byte *buf) { *buf++ = 65; /* Capability 65: Support for 4-octet AS number */ *buf++ = 4; /* Capability data length */ put_u32(buf, p->local_as); return buf + 4; } static byte * bgp_put_cap_add_path(struct bgp_proto *p, byte *buf) { *buf++ = 69; /* Capability 69: Support for ADD-PATH */ *buf++ = 4; /* Capability data length */ *buf++ = 0; /* Appropriate AF */ *buf++ = BGP_AF; *buf++ = 1; /* SAFI 1 */ *buf++ = p->cf->add_path; return buf; } static byte * bgp_put_cap_err(struct bgp_proto *p UNUSED, byte *buf) { *buf++ = 70; /* Capability 70: Support for enhanced route refresh */ *buf++ = 0; /* Capability data length */ return buf; } static byte * bgp_put_cap_llgr1(struct bgp_proto *p, byte *buf) { *buf++ = 71; /* Capability 71: Support for long-lived graceful restart */ *buf++ = 7; /* Capability data length */ *buf++ = 0; /* Appropriate AF */ *buf++ = BGP_AF; *buf++ = 1; /* and SAFI 1 */ /* Next is 8bit flags and 24bit time */ put_u32(buf, p->cf->llgr_time); buf[0] = p->p.gr_recovery ? BGP_LLGRF_FORWARDING : 0; buf += 4; return buf; } static byte * bgp_put_cap_llgr2(struct bgp_proto *p UNUSED, byte *buf) { *buf++ = 71; /* Capability 71: Support for long-lived graceful restart */ *buf++ = 0; /* Capability data length */ return buf; } static byte * bgp_create_open(struct bgp_conn *conn, byte *buf) { struct bgp_proto *p = conn->bgp; byte *cap; int cap_len; BGP_TRACE(D_PACKETS, "Sending OPEN(ver=%d,as=%d,hold=%d,id=%08x)", BGP_VERSION, p->local_as, p->cf->hold_time, p->local_id); buf[0] = BGP_VERSION; put_u16(buf+1, (p->local_as < 0xFFFF) ? p->local_as : AS_TRANS); put_u16(buf+3, p->cf->hold_time); put_u32(buf+5, p->local_id); if (conn->start_state == BSS_CONNECT_NOCAP) { BGP_TRACE(D_PACKETS, "Skipping capabilities"); buf[9] = 0; return buf + 10; } /* Skipped 3 B for length field and Capabilities parameter header */ cap = buf + 12; #ifndef IPV6 if (p->cf->advertise_ipv4) cap = bgp_put_cap_ipv4(p, cap); #endif #ifdef IPV6 cap = bgp_put_cap_ipv6(p, cap); #endif if (p->cf->enable_refresh) cap = bgp_put_cap_rr(p, cap); if (p->cf->gr_mode == BGP_GR_ABLE) cap = bgp_put_cap_gr1(p, cap); else if (p->cf->gr_mode == BGP_GR_AWARE) cap = bgp_put_cap_gr2(p, cap); if (p->cf->enable_as4) cap = bgp_put_cap_as4(p, cap); if (p->cf->add_path) cap = bgp_put_cap_add_path(p, cap); if (p->cf->enable_refresh) cap = bgp_put_cap_err(p, cap); if (p->cf->enable_extended_messages) cap = bgp_put_cap_ext_msg(p, cap); if (p->cf->llgr_mode == BGP_LLGR_ABLE) cap = bgp_put_cap_llgr1(p, cap); else if (p->cf->llgr_mode == BGP_LLGR_AWARE) cap = bgp_put_cap_llgr2(p, cap); cap_len = cap - buf - 12; if (cap_len > 0) { buf[9] = cap_len + 2; /* Optional params len */ buf[10] = 2; /* Option: Capability list */ buf[11] = cap_len; /* Option length */ return cap; } else { buf[9] = 0; /* No optional parameters */ return buf + 10; } } static uint bgp_encode_prefixes(struct bgp_proto *p, byte *w, struct bgp_bucket *buck, uint remains) { byte *start = w; ip_addr a; int bytes; while (!EMPTY_LIST(buck->prefixes) && (remains >= (5+sizeof(ip_addr)))) { struct bgp_prefix *px = SKIP_BACK(struct bgp_prefix, bucket_node, HEAD(buck->prefixes)); DBG("\tDequeued route %I/%d\n", px->n.prefix, px->n.pxlen); if (p->add_path_tx) { put_u32(w, px->path_id); w += 4; remains -= 4; } *w++ = px->n.pxlen; bytes = (px->n.pxlen + 7) / 8; a = px->n.prefix; ipa_hton(a); memcpy(w, &a, bytes); w += bytes; remains -= bytes + 1; rem_node(&px->bucket_node); bgp_free_prefix(p, px); // fib_delete(&p->prefix_fib, px); } return w - start; } static void bgp_flush_prefixes(struct bgp_proto *p, struct bgp_bucket *buck) { while (!EMPTY_LIST(buck->prefixes)) { struct bgp_prefix *px = SKIP_BACK(struct bgp_prefix, bucket_node, HEAD(buck->prefixes)); log(L_ERR "%s: - route %I/%d skipped", p->p.name, px->n.prefix, px->n.pxlen); rem_node(&px->bucket_node); bgp_free_prefix(p, px); // fib_delete(&p->prefix_fib, px); } } #ifndef IPV6 /* IPv4 version */ static byte * bgp_create_update(struct bgp_conn *conn, byte *buf) { struct bgp_proto *p = conn->bgp; struct bgp_bucket *buck; int remains = bgp_max_packet_length(p) - BGP_HEADER_LENGTH - 4; byte *w; int wd_size = 0; int r_size = 0; int a_size = 0; w = buf+2; if ((buck = p->withdraw_bucket) && !EMPTY_LIST(buck->prefixes)) { DBG("Withdrawn routes:\n"); wd_size = bgp_encode_prefixes(p, w, buck, remains); w += wd_size; remains -= wd_size; } put_u16(buf, wd_size); if (!wd_size) { while ((buck = (struct bgp_bucket *) HEAD(p->bucket_queue))->send_node.next) { if (EMPTY_LIST(buck->prefixes)) { DBG("Deleting empty bucket %p\n", buck); rem_node(&buck->send_node); bgp_free_bucket(p, buck); continue; } DBG("Processing bucket %p\n", buck); a_size = bgp_encode_attrs(p, w+2, buck->eattrs, remains - 1024); if (a_size < 0) { log(L_ERR "%s: Attribute list too long, skipping corresponding routes", p->p.name); bgp_flush_prefixes(p, buck); rem_node(&buck->send_node); bgp_free_bucket(p, buck); continue; } put_u16(w, a_size); w += a_size + 2; r_size = bgp_encode_prefixes(p, w, buck, remains - a_size); w += r_size; break; } } if (!a_size) /* Attributes not already encoded */ { put_u16(w, 0); w += 2; } if (wd_size || r_size) { BGP_TRACE_RL(&rl_snd_update, D_PACKETS, "Sending UPDATE"); return w; } else return NULL; } static byte * bgp_create_end_mark(struct bgp_conn *conn, byte *buf) { struct bgp_proto *p = conn->bgp; BGP_TRACE(D_PACKETS, "Sending END-OF-RIB"); put_u32(buf, 0); return buf+4; } #else /* IPv6 version */ static inline int same_iface(struct bgp_proto *p, ip_addr *ip) { neighbor *n = neigh_find(&p->p, ip, 0); return n && p->neigh && n->iface == p->neigh->iface; } static byte * bgp_create_update(struct bgp_conn *conn, byte *buf) { struct bgp_proto *p = conn->bgp; struct bgp_bucket *buck; int size, second, rem_stored; int remains = bgp_max_packet_length(p) - BGP_HEADER_LENGTH - 4; byte *w, *w_stored, *tmp, *tstart; ip_addr *ipp, ip, ip_ll; ea_list *ea; eattr *nh; put_u16(buf, 0); w = buf+4; if ((buck = p->withdraw_bucket) && !EMPTY_LIST(buck->prefixes)) { DBG("Withdrawn routes:\n"); tmp = bgp_attach_attr_wa(&ea, bgp_linpool, BA_MP_UNREACH_NLRI, remains-8); *tmp++ = 0; *tmp++ = BGP_AF_IPV6; *tmp++ = 1; ea->attrs[0].u.ptr->length = 3 + bgp_encode_prefixes(p, tmp, buck, remains-11); size = bgp_encode_attrs(p, w, ea, remains); ASSERT(size >= 0); w += size; remains -= size; } else { while ((buck = (struct bgp_bucket *) HEAD(p->bucket_queue))->send_node.next) { if (EMPTY_LIST(buck->prefixes)) { DBG("Deleting empty bucket %p\n", buck); rem_node(&buck->send_node); bgp_free_bucket(p, buck); continue; } DBG("Processing bucket %p\n", buck); rem_stored = remains; w_stored = w; size = bgp_encode_attrs(p, w, buck->eattrs, remains - 1024); if (size < 0) { log(L_ERR "%s: Attribute list too long, skipping corresponding routes", p->p.name); bgp_flush_prefixes(p, buck); rem_node(&buck->send_node); bgp_free_bucket(p, buck); continue; } w += size; remains -= size; /* We have two addresses here in NEXT_HOP eattr. Really. Unless NEXT_HOP was modified by filter */ nh = ea_find(buck->eattrs, EA_CODE(EAP_BGP, BA_NEXT_HOP)); ASSERT(nh); second = (nh->u.ptr->length == NEXT_HOP_LENGTH); ipp = (ip_addr *) nh->u.ptr->data; ip = ipp[0]; ip_ll = IPA_NONE; if (ipa_equal(ip, p->source_addr)) ip_ll = p->local_link; else { /* If we send a route with 'third party' next hop destinated * in the same interface, we should also send a link local * next hop address. We use the received one (stored in the * other part of BA_NEXT_HOP eattr). If we didn't received * it (for example it is a static route), we can't use * 'third party' next hop and we have to use local IP address * as next hop. Sending original next hop address without * link local address seems to be a natural way to solve that * problem, but it is contrary to RFC 2545 and Quagga does not * accept such routes. * * There are two cases, either we have global IP, or * IPA_NONE if the neighbor is link-local. For IPA_NONE, * we suppose it is on the same iface, see bgp_update_attrs(). */ if (ipa_zero(ip) || same_iface(p, &ip)) { if (second && ipa_nonzero(ipp[1])) ip_ll = ipp[1]; else { switch (p->cf->missing_lladdr) { case MLL_SELF: ip = p->source_addr; ip_ll = p->local_link; break; case MLL_DROP: log(L_ERR "%s: Missing link-local next hop address, skipping corresponding routes", p->p.name); w = w_stored; remains = rem_stored; bgp_flush_prefixes(p, buck); rem_node(&buck->send_node); bgp_free_bucket(p, buck); continue; case MLL_IGNORE: break; } } } } tstart = tmp = bgp_attach_attr_wa(&ea, bgp_linpool, BA_MP_REACH_NLRI, remains-8); *tmp++ = 0; *tmp++ = BGP_AF_IPV6; *tmp++ = 1; if (ipa_is_link_local(ip)) ip = IPA_NONE; if (ipa_nonzero(ip_ll)) { *tmp++ = 32; ipa_hton(ip); memcpy(tmp, &ip, 16); ipa_hton(ip_ll); memcpy(tmp+16, &ip_ll, 16); tmp += 32; } else { *tmp++ = 16; ipa_hton(ip); memcpy(tmp, &ip, 16); tmp += 16; } *tmp++ = 0; /* No SNPA information */ tmp += bgp_encode_prefixes(p, tmp, buck, remains - (8+3+32+1)); ea->attrs[0].u.ptr->length = tmp - tstart; size = bgp_encode_attrs(p, w, ea, remains); ASSERT(size >= 0); w += size; break; } } size = w - (buf+4); put_u16(buf+2, size); lp_flush(bgp_linpool); if (size) { BGP_TRACE_RL(&rl_snd_update, D_PACKETS, "Sending UPDATE"); return w; } else return NULL; } static byte * bgp_create_end_mark(struct bgp_conn *conn, byte *buf) { struct bgp_proto *p = conn->bgp; BGP_TRACE(D_PACKETS, "Sending END-OF-RIB"); put_u16(buf+0, 0); put_u16(buf+2, 6); /* length 4-9 */ buf += 4; /* Empty MP_UNREACH_NLRI atribute */ *buf++ = BAF_OPTIONAL; *buf++ = BA_MP_UNREACH_NLRI; *buf++ = 3; /* Length 7-9 */ *buf++ = 0; /* AFI */ *buf++ = BGP_AF_IPV6; *buf++ = 1; /* SAFI */ return buf; } #endif static inline byte * bgp_create_route_refresh(struct bgp_conn *conn, byte *buf) { struct bgp_proto *p = conn->bgp; BGP_TRACE(D_PACKETS, "Sending ROUTE-REFRESH"); /* Original original route refresh request, RFC 2918 */ *buf++ = 0; *buf++ = BGP_AF; *buf++ = BGP_RR_REQUEST; *buf++ = 1; /* SAFI */ return buf; } static inline byte * bgp_create_begin_refresh(struct bgp_conn *conn, byte *buf) { struct bgp_proto *p = conn->bgp; BGP_TRACE(D_PACKETS, "Sending BEGIN-OF-RR"); /* Demarcation of beginning of route refresh (BoRR), RFC 7313 */ *buf++ = 0; *buf++ = BGP_AF; *buf++ = BGP_RR_BEGIN; *buf++ = 1; /* SAFI */ return buf; } static inline byte * bgp_create_end_refresh(struct bgp_conn *conn, byte *buf) { struct bgp_proto *p = conn->bgp; BGP_TRACE(D_PACKETS, "Sending END-OF-RR"); /* Demarcation of ending of route refresh (EoRR), RFC 7313 */ *buf++ = 0; *buf++ = BGP_AF; *buf++ = BGP_RR_END; *buf++ = 1; /* SAFI */ return buf; } static void bgp_create_header(byte *buf, uint len, uint type) { memset(buf, 0xff, 16); /* Marker */ put_u16(buf+16, len); buf[18] = type; } /** * bgp_fire_tx - transmit packets * @conn: connection * * Whenever the transmit buffers of the underlying TCP connection * are free and we have any packets queued for sending, the socket functions * call bgp_fire_tx() which takes care of selecting the highest priority packet * queued (Notification > Keepalive > Open > Update), assembling its header * and body and sending it to the connection. */ static int bgp_fire_tx(struct bgp_conn *conn) { struct bgp_proto *p = conn->bgp; uint s = conn->packets_to_send; sock *sk = conn->sk; byte *buf, *pkt, *end; int type; if (!sk) { conn->packets_to_send = 0; return 0; } buf = sk->tbuf; pkt = buf + BGP_HEADER_LENGTH; if (s & (1 << PKT_SCHEDULE_CLOSE)) { /* We can finally close connection and enter idle state */ bgp_conn_enter_idle_state(conn); return 0; } if (s & (1 << PKT_NOTIFICATION)) { s = 1 << PKT_SCHEDULE_CLOSE; type = PKT_NOTIFICATION; end = bgp_create_notification(conn, pkt); } else if (s & (1 << PKT_KEEPALIVE)) { s &= ~(1 << PKT_KEEPALIVE); type = PKT_KEEPALIVE; end = pkt; /* Keepalives carry no data */ BGP_TRACE(D_PACKETS, "Sending KEEPALIVE"); bgp_start_timer(conn->keepalive_timer, conn->keepalive_time); } else if (s & (1 << PKT_OPEN)) { s &= ~(1 << PKT_OPEN); type = PKT_OPEN; end = bgp_create_open(conn, pkt); } else if (s & (1 << PKT_ROUTE_REFRESH)) { s &= ~(1 << PKT_ROUTE_REFRESH); type = PKT_ROUTE_REFRESH; end = bgp_create_route_refresh(conn, pkt); } else if (s & (1 << PKT_BEGIN_REFRESH)) { s &= ~(1 << PKT_BEGIN_REFRESH); type = PKT_ROUTE_REFRESH; /* BoRR is a subtype of RR */ end = bgp_create_begin_refresh(conn, pkt); } else if (s & (1 << PKT_UPDATE)) { type = PKT_UPDATE; end = bgp_create_update(conn, pkt); if (!end) { /* No update to send, perhaps we need to send End-of-RIB or EoRR */ conn->packets_to_send = 0; if (p->feed_state == BFS_LOADED) { type = PKT_UPDATE; end = bgp_create_end_mark(conn, pkt); } else if (p->feed_state == BFS_REFRESHED) { type = PKT_ROUTE_REFRESH; end = bgp_create_end_refresh(conn, pkt); } else /* Really nothing to send */ return 0; p->feed_state = BFS_NONE; } } else return 0; conn->packets_to_send = s; bgp_create_header(buf, end - buf, type); return sk_send(sk, end - buf); } /** * bgp_schedule_packet - schedule a packet for transmission * @conn: connection * @type: packet type * * Schedule a packet of type @type to be sent as soon as possible. */ void bgp_schedule_packet(struct bgp_conn *conn, int type) { DBG("BGP: Scheduling packet type %d\n", type); conn->packets_to_send |= 1 << type; if (conn->sk && conn->sk->tpos == conn->sk->tbuf && !ev_active(conn->tx_ev)) ev_schedule(conn->tx_ev); } void bgp_kick_tx(void *vconn) { struct bgp_conn *conn = vconn; DBG("BGP: kicking TX\n"); uint max = 1024; while (--max && (bgp_fire_tx(conn) > 0)) ; if (!max && !ev_active(conn->tx_ev)) ev_schedule(conn->tx_ev); } void bgp_tx(sock *sk) { struct bgp_conn *conn = sk->data; DBG("BGP: TX hook\n"); uint max = 1024; while (--max && (bgp_fire_tx(conn) > 0)) ; if (!max && !ev_active(conn->tx_ev)) ev_schedule(conn->tx_ev); } /* Capatibility negotiation as per RFC 2842 */ void bgp_parse_capabilities(struct bgp_conn *conn, byte *opt, int len) { // struct bgp_proto *p = conn->bgp; int i, cl; while (len > 0) { if (len < 2 || len < 2 + opt[1]) goto err; cl = opt[1]; switch (opt[0]) { case 2: /* Route refresh capability, RFC 2918 */ if (cl != 0) goto err; conn->peer_refresh_support = 1; break; case 6: /* Extended message length capability, draft */ if (cl != 0) goto err; conn->peer_ext_messages_support = 1; break; case 64: /* Graceful restart capability, RFC 4724 */ if (cl % 4 != 2) goto err; conn->peer_gr_aware = 1; conn->peer_gr_able = 0; conn->peer_gr_time = get_u16(opt + 2) & 0x0fff; conn->peer_gr_flags = opt[2] & 0xf0; conn->peer_gr_aflags = 0; for (i = 2; i < cl; i += 4) if (opt[2+i+0] == 0 && opt[2+i+1] == BGP_AF && opt[2+i+2] == 1) /* Match AFI/SAFI */ { conn->peer_gr_able = 1; conn->peer_gr_aflags = opt[2+i+3]; } break; case 65: /* AS4 capability, RFC 4893 */ if (cl != 4) goto err; conn->peer_as4_support = 1; if (conn->bgp->cf->enable_as4) conn->advertised_as = get_u32(opt + 2); break; case 69: /* ADD-PATH capability, RFC 7911 */ if (cl % 4) goto err; for (i = 0; i < cl; i += 4) if (opt[2+i+0] == 0 && opt[2+i+1] == BGP_AF && opt[2+i+2] == 1) /* Match AFI/SAFI */ conn->peer_add_path = opt[2+i+3]; if (conn->peer_add_path > ADD_PATH_FULL) goto err; break; case 70: /* Enhanced route refresh capability, RFC 7313 */ if (cl != 0) goto err; conn->peer_enhanced_refresh_support = 1; break; case 71: /* Long-lived graceful restart capability, RFC draft */ if (cl % 7) goto err; conn->peer_llgr_aware = 1; conn->peer_llgr_able = 0; conn->peer_llgr_time = 0; conn->peer_llgr_aflags = 0; for (i = 0; i < cl; i += 7) if (opt[2+i+0] == 0 && opt[2+i+1] == BGP_AF && opt[2+i+2] == 1) /* Match AFI/SAFI */ { conn->peer_llgr_able = 1; conn->peer_llgr_time = get_u32(opt + 2+i+3) & 0xffffff; conn->peer_llgr_aflags = opt[2+i+3]; } break; /* We can safely ignore all other capabilities */ } len -= 2 + cl; opt += 2 + cl; } /* The LLGR capability must be advertised together with the GR capability, otherwise it must be disregarded */ if (!conn->peer_gr_aware && conn->peer_llgr_aware) { conn->peer_llgr_aware = 0; conn->peer_llgr_able = 0; conn->peer_llgr_time = 0; conn->peer_llgr_aflags = 0; } return; err: bgp_error(conn, 2, 0, NULL, 0); return; } static int bgp_parse_options(struct bgp_conn *conn, byte *opt, int len) { struct bgp_proto *p = conn->bgp; int ol; while (len > 0) { if (len < 2 || len < 2 + opt[1]) { bgp_error(conn, 2, 0, NULL, 0); return 0; } #ifdef LOCAL_DEBUG { int i; DBG("\tOption %02x:", opt[0]); for(i=0; istart_state == BSS_CONNECT_NOCAP) BGP_TRACE(D_PACKETS, "Ignoring received capabilities"); else bgp_parse_capabilities(conn, opt + 2, ol); break; default: /* * BGP specs don't tell us to send which option * we didn't recognize, but it's common practice * to do so. Also, capability negotiation with * Cisco routers doesn't work without that. */ bgp_error(conn, 2, 4, opt, ol); return 0; } len -= 2 + ol; opt += 2 + ol; } return 0; } static void bgp_rx_open(struct bgp_conn *conn, byte *pkt, uint len) { struct bgp_conn *other; struct bgp_proto *p = conn->bgp; unsigned hold; u16 base_as; u32 id; /* Check state */ if (conn->state != BS_OPENSENT) { bgp_error(conn, 5, fsm_err_subcode[conn->state], NULL, 0); return; } /* Check message contents */ if (len < 29 || len != 29U + pkt[28]) { bgp_error(conn, 1, 2, pkt+16, 2); return; } if (pkt[19] != BGP_VERSION) { bgp_error(conn, 2, 1, pkt+19, 1); return; } /* RFC 1771 says 16 bits, draft-09 tells to use 8 */ conn->advertised_as = base_as = get_u16(pkt+20); hold = get_u16(pkt+22); id = get_u32(pkt+24); BGP_TRACE(D_PACKETS, "Got OPEN(as=%d,hold=%d,id=%08x)", conn->advertised_as, hold, id); if (bgp_parse_options(conn, pkt+29, pkt[28])) return; if (hold > 0 && hold < 3) { bgp_error(conn, 2, 6, pkt+22, 2); return; } /* RFC 6286 2.2 - router ID is nonzero and AS-wide unique */ if (!id || (p->is_internal && id == p->local_id)) { bgp_error(conn, 2, 3, pkt+24, -4); return; } if ((conn->advertised_as != base_as) && (base_as != AS_TRANS)) log(L_WARN "%s: Peer advertised inconsistent AS numbers", p->p.name); if (conn->advertised_as != p->remote_as) { if (conn->peer_as4_support) { u32 val = htonl(conn->advertised_as); bgp_error(conn, 2, 2, (byte *) &val, 4); } else bgp_error(conn, 2, 2, pkt+20, 2); return; } /* Check the other connection */ other = (conn == &p->outgoing_conn) ? &p->incoming_conn : &p->outgoing_conn; switch (other->state) { case BS_CONNECT: case BS_ACTIVE: /* Stop outgoing connection attempts */ bgp_conn_enter_idle_state(other); break; case BS_IDLE: case BS_OPENSENT: case BS_CLOSE: break; case BS_OPENCONFIRM: /* * Description of collision detection rules in RFC 4271 is confusing and * contradictory, but it is essentially: * * 1. Router with higher ID is dominant * 2. If both have the same ID, router with higher ASN is dominant [RFC6286] * 3. When both connections are in OpenConfirm state, one initiated by * the dominant router is kept. * * The first line in the expression below evaluates whether the neighbor * is dominant, the second line whether the new connection was initiated * by the neighbor. If both are true (or both are false), we keep the new * connection, otherwise we keep the old one. */ if (((p->local_id < id) || ((p->local_id == id) && (p->local_as < p->remote_as))) == (conn == &p->incoming_conn)) { /* Should close the other connection */ BGP_TRACE(D_EVENTS, "Connection collision, giving up the other connection"); bgp_error(other, 6, 7, NULL, 0); break; } /* Fall thru */ case BS_ESTABLISHED: /* Should close this connection */ BGP_TRACE(D_EVENTS, "Connection collision, giving up this connection"); bgp_error(conn, 6, 7, NULL, 0); return; default: bug("bgp_rx_open: Unknown state"); } /* Update our local variables */ conn->hold_time = MIN(hold, p->cf->hold_time); conn->keepalive_time = p->cf->keepalive_time ? : conn->hold_time / 3; p->remote_id = id; p->as4_session = p->cf->enable_as4 && conn->peer_as4_support; p->add_path_rx = (p->cf->add_path & ADD_PATH_RX) && (conn->peer_add_path & ADD_PATH_TX); p->add_path_tx = (p->cf->add_path & ADD_PATH_TX) && (conn->peer_add_path & ADD_PATH_RX); p->gr_ready = (p->cf->gr_mode && conn->peer_gr_able) || (p->cf->llgr_mode && conn->peer_llgr_able); p->ext_messages = p->cf->enable_extended_messages && conn->peer_ext_messages_support; /* Update RA mode */ if (p->add_path_tx) p->p.accept_ra_types = RA_ANY; else if (p->cf->secondary) p->p.accept_ra_types = RA_ACCEPTED; else p->p.accept_ra_types = RA_OPTIMAL; DBG("BGP: Hold timer set to %d, keepalive to %d, AS to %d, ID to %x, AS4 session to %d\n", conn->hold_time, conn->keepalive_time, p->remote_as, p->remote_id, p->as4_session); bgp_schedule_packet(conn, PKT_KEEPALIVE); bgp_start_timer(conn->hold_timer, conn->hold_time); bgp_conn_enter_openconfirm_state(conn); } static inline void bgp_rx_end_mark(struct bgp_proto *p) { BGP_TRACE(D_PACKETS, "Got END-OF-RIB"); if (p->load_state == BFS_LOADING) p->load_state = BFS_NONE; if (p->p.gr_recovery) proto_graceful_restart_unlock(&p->p); if (p->gr_active) bgp_graceful_restart_done(p); } #define DECODE_PREFIX(pp, ll) do { \ if (p->add_path_rx) \ { \ if (ll < 5) { err=1; goto done; } \ path_id = get_u32(pp); \ pp += 4; \ ll -= 4; \ } \ int b = *pp++; \ int q; \ ll--; \ if (b > BITS_PER_IP_ADDRESS) { err=10; goto done; } \ q = (b+7) / 8; \ if (ll < q) { err=1; goto done; } \ memcpy(&prefix, pp, q); \ pp += q; \ ll -= q; \ ipa_ntoh(prefix); \ prefix = ipa_and(prefix, ipa_mkmask(b)); \ pxlen = b; \ } while (0) static inline void bgp_rte_update(struct bgp_proto *p, ip_addr prefix, int pxlen, u32 path_id, u32 *last_id, struct rte_src **src, rta *a0, rta **a) { if (path_id != *last_id) { *src = rt_get_source(&p->p, path_id); *last_id = path_id; if (*a) { rta_free(*a); *a = NULL; } } /* Prepare cached route attributes */ if (!*a) { a0->src = *src; /* Workaround for rta_lookup() breaking eattrs */ ea_list *ea = a0->eattrs; *a = rta_lookup(a0); a0->eattrs = ea; } net *n = net_get(p->p.table, prefix, pxlen); rte *e = rte_get_temp(rta_clone(*a)); e->net = n; e->pflags = 0; e->u.bgp.suppressed = 0; e->u.bgp.stale = -1; rte_update2(p->p.main_ahook, n, e, *src); } static inline void bgp_rte_withdraw(struct bgp_proto *p, ip_addr prefix, int pxlen, u32 path_id, u32 *last_id, struct rte_src **src) { if (path_id != *last_id) { *src = rt_find_source(&p->p, path_id); *last_id = path_id; } net *n = net_find(p->p.table, prefix, pxlen); rte_update2( p->p.main_ahook, n, NULL, *src); } static inline int bgp_set_next_hop(struct bgp_proto *p, rta *a) { struct eattr *nh = ea_find(a->eattrs, EA_CODE(EAP_BGP, BA_NEXT_HOP)); ip_addr *nexthop = (ip_addr *) nh->u.ptr->data; #ifdef IPV6 int second = (nh->u.ptr->length == NEXT_HOP_LENGTH) && ipa_nonzero(nexthop[1]); /* First address should not be link-local, but may be zero in direct mode */ if (ipa_is_link_local(*nexthop)) *nexthop = IPA_NONE; #else int second = 0; #endif if (p->cf->gw_mode == GW_DIRECT) { neighbor *ng = NULL; if (ipa_nonzero(*nexthop)) ng = neigh_find(&p->p, nexthop, 0); else if (second) /* GW_DIRECT -> single_hop -> p->neigh != NULL */ ng = neigh_find2(&p->p, nexthop + 1, p->neigh->iface, 0); /* Fallback */ if (!ng) ng = p->neigh; if (ng->scope == SCOPE_HOST) return 0; a->dest = RTD_ROUTER; a->gw = ng->addr; a->iface = ng->iface; a->hostentry = NULL; a->igp_metric = 0; } else /* GW_RECURSIVE */ { if (ipa_zero(*nexthop)) return 0; rta_set_recursive_next_hop(p->p.table, a, p->igp_table, nexthop, nexthop + second); } return 1; } #ifndef IPV6 /* IPv4 version */ static void bgp_do_rx_update(struct bgp_conn *conn, byte *withdrawn, int withdrawn_len, byte *nlri, int nlri_len, byte *attrs, int attr_len) { struct bgp_proto *p = conn->bgp; struct rte_src *src = p->p.main_source; rta *a0, *a = NULL; ip_addr prefix; int pxlen, err = 0; u32 path_id = 0; u32 last_id = 0; /* Check for End-of-RIB marker */ if (!withdrawn_len && !attr_len && !nlri_len) { bgp_rx_end_mark(p); return; } /* Withdraw routes */ while (withdrawn_len) { DECODE_PREFIX(withdrawn, withdrawn_len); DBG("Withdraw %I/%d\n", prefix, pxlen); bgp_rte_withdraw(p, prefix, pxlen, path_id, &last_id, &src); } if (!attr_len && !nlri_len) /* shortcut */ return; a0 = bgp_decode_attrs(conn, attrs, attr_len, bgp_linpool, nlri_len); if (conn->state != BS_ESTABLISHED) /* fatal error during decoding */ return; if (a0 && nlri_len && !bgp_set_next_hop(p, a0)) a0 = NULL; last_id = 0; src = p->p.main_source; while (nlri_len) { DECODE_PREFIX(nlri, nlri_len); DBG("Add %I/%d\n", prefix, pxlen); if (a0) bgp_rte_update(p, prefix, pxlen, path_id, &last_id, &src, a0, &a); else /* Forced withdraw as a result of soft error */ bgp_rte_withdraw(p, prefix, pxlen, path_id, &last_id, &src); } done: if (a) rta_free(a); if (err) bgp_error(conn, 3, err, NULL, 0); return; } #else /* IPv6 version */ #define DO_NLRI(name) \ x = p->name##_start; \ len = len0 = p->name##_len; \ if (len) \ { \ if (len < 3) { err=9; goto done; } \ af = get_u16(x); \ x += 3; \ len -= 3; \ DBG("\tNLRI AF=%d sub=%d len=%d\n", af, x[-1], len);\ } \ else \ af = 0; \ if (af == BGP_AF_IPV6) static void bgp_attach_next_hop(rta *a0, byte *x) { ip_addr *nh = (ip_addr *) bgp_attach_attr_wa(&a0->eattrs, bgp_linpool, BA_NEXT_HOP, NEXT_HOP_LENGTH); memcpy(nh, x+1, 16); ipa_ntoh(nh[0]); /* We store received link local address in the other part of BA_NEXT_HOP eattr. */ if (*x == 32) { memcpy(nh+1, x+17, 16); ipa_ntoh(nh[1]); } else nh[1] = IPA_NONE; } static void bgp_do_rx_update(struct bgp_conn *conn, byte *withdrawn UNUSED, int withdrawn_len, byte *nlri UNUSED, int nlri_len, byte *attrs, int attr_len) { struct bgp_proto *p = conn->bgp; struct rte_src *src = p->p.main_source; byte *x; int len, len0; unsigned af; rta *a0, *a = NULL; ip_addr prefix; int pxlen, err = 0; u32 path_id = 0; u32 last_id = 0; p->mp_reach_len = 0; p->mp_unreach_len = 0; a0 = bgp_decode_attrs(conn, attrs, attr_len, bgp_linpool, 0); if (conn->state != BS_ESTABLISHED) /* fatal error during decoding */ return; /* Check for End-of-RIB marker */ if ((attr_len < 8) && !withdrawn_len && !nlri_len && !p->mp_reach_len && (p->mp_unreach_len == 3) && (get_u16(p->mp_unreach_start) == BGP_AF_IPV6)) { bgp_rx_end_mark(p); return; } DO_NLRI(mp_unreach) { while (len) { DECODE_PREFIX(x, len); DBG("Withdraw %I/%d\n", prefix, pxlen); bgp_rte_withdraw(p, prefix, pxlen, path_id, &last_id, &src); } } DO_NLRI(mp_reach) { /* Create fake NEXT_HOP attribute */ if (len < 1 || (*x != 16 && *x != 32) || len < *x + 2) { err = 9; goto done; } if (a0) bgp_attach_next_hop(a0, x); /* Also ignore one reserved byte */ len -= *x + 2; x += *x + 2; if (a0 && ! bgp_set_next_hop(p, a0)) a0 = NULL; last_id = 0; src = p->p.main_source; while (len) { DECODE_PREFIX(x, len); DBG("Add %I/%d\n", prefix, pxlen); if (a0) bgp_rte_update(p, prefix, pxlen, path_id, &last_id, &src, a0, &a); else /* Forced withdraw as a result of soft error */ bgp_rte_withdraw(p, prefix, pxlen, path_id, &last_id, &src); } } done: if (a) rta_free(a); if (err) /* Use subcode 9, not err */ bgp_error(conn, 3, 9, NULL, 0); return; } #endif static void bgp_rx_update(struct bgp_conn *conn, byte *pkt, uint len) { struct bgp_proto *p = conn->bgp; byte *withdrawn, *attrs, *nlri; uint withdrawn_len, attr_len, nlri_len; BGP_TRACE_RL(&rl_rcv_update, D_PACKETS, "Got UPDATE"); /* Workaround for some BGP implementations that skip initial KEEPALIVE */ if (conn->state == BS_OPENCONFIRM) bgp_conn_enter_established_state(conn); if (conn->state != BS_ESTABLISHED) { bgp_error(conn, 5, fsm_err_subcode[conn->state], NULL, 0); return; } bgp_start_timer(conn->hold_timer, conn->hold_time); /* Find parts of the packet and check sizes */ if (len < 23) { bgp_error(conn, 1, 2, pkt+16, 2); return; } withdrawn = pkt + 21; withdrawn_len = get_u16(pkt + 19); if (withdrawn_len + 23 > len) goto malformed; attrs = withdrawn + withdrawn_len + 2; attr_len = get_u16(attrs - 2); if (withdrawn_len + attr_len + 23 > len) goto malformed; nlri = attrs + attr_len; nlri_len = len - withdrawn_len - attr_len - 23; if (!attr_len && nlri_len) goto malformed; DBG("Sizes: withdrawn=%d, attrs=%d, NLRI=%d\n", withdrawn_len, attr_len, nlri_len); lp_flush(bgp_linpool); bgp_do_rx_update(conn, withdrawn, withdrawn_len, nlri, nlri_len, attrs, attr_len); return; malformed: bgp_error(conn, 3, 1, NULL, 0); } static struct { byte major, minor; byte *msg; } bgp_msg_table[] = { { 1, 0, "Invalid message header" }, { 1, 1, "Connection not synchronized" }, { 1, 2, "Bad message length" }, { 1, 3, "Bad message type" }, { 2, 0, "Invalid OPEN message" }, { 2, 1, "Unsupported version number" }, { 2, 2, "Bad peer AS" }, { 2, 3, "Bad BGP identifier" }, { 2, 4, "Unsupported optional parameter" }, { 2, 5, "Authentication failure" }, { 2, 6, "Unacceptable hold time" }, { 2, 7, "Required capability missing" }, /* [RFC5492] */ { 2, 8, "No supported AFI/SAFI" }, /* This error msg is nonstandard */ { 3, 0, "Invalid UPDATE message" }, { 3, 1, "Malformed attribute list" }, { 3, 2, "Unrecognized well-known attribute" }, { 3, 3, "Missing mandatory attribute" }, { 3, 4, "Invalid attribute flags" }, { 3, 5, "Invalid attribute length" }, { 3, 6, "Invalid ORIGIN attribute" }, { 3, 7, "AS routing loop" }, /* Deprecated */ { 3, 8, "Invalid NEXT_HOP attribute" }, { 3, 9, "Optional attribute error" }, { 3, 10, "Invalid network field" }, { 3, 11, "Malformed AS_PATH" }, { 4, 0, "Hold timer expired" }, { 5, 0, "Finite state machine error" }, /* Subcodes are according to [RFC6608] */ { 5, 1, "Unexpected message in OpenSent state" }, { 5, 2, "Unexpected message in OpenConfirm state" }, { 5, 3, "Unexpected message in Established state" }, { 6, 0, "Cease" }, /* Subcodes are according to [RFC4486] */ { 6, 1, "Maximum number of prefixes reached" }, { 6, 2, "Administrative shutdown" }, { 6, 3, "Peer de-configured" }, { 6, 4, "Administrative reset" }, { 6, 5, "Connection rejected" }, { 6, 6, "Other configuration change" }, { 6, 7, "Connection collision resolution" }, { 6, 8, "Out of Resources" }, { 7, 0, "Invalid ROUTE-REFRESH message" }, /* [RFC7313] */ { 7, 1, "Invalid ROUTE-REFRESH message length" } /* [RFC7313] */ }; /** * bgp_error_dsc - return BGP error description * @code: BGP error code * @subcode: BGP error subcode * * bgp_error_dsc() returns error description for BGP errors * which might be static string or given temporary buffer. */ const char * bgp_error_dsc(unsigned code, unsigned subcode) { static char buff[32]; unsigned i; for (i=0; i < ARRAY_SIZE(bgp_msg_table); i++) if (bgp_msg_table[i].major == code && bgp_msg_table[i].minor == subcode) { return bgp_msg_table[i].msg; } bsprintf(buff, "Unknown error %d.%d", code, subcode); return buff; } /* RFC 8203 - shutdown communication message */ static int bgp_handle_message(struct bgp_proto *p, byte *data, uint len, byte **bp) { byte *msg = data + 1; uint msg_len = data[0]; uint i; /* Handle zero length message */ if (msg_len == 0) return 1; /* Handle proper message */ if ((msg_len > 128) && (msg_len + 1 > len)) return 0; /* Some elementary cleanup */ for (i = 0; i < msg_len; i++) if (msg[i] < ' ') msg[i] = ' '; proto_set_message(&p->p, msg, msg_len); *bp += bsprintf(*bp, ": \"%s\"", p->p.message); return 1; } void bgp_log_error(struct bgp_proto *p, u8 class, char *msg, unsigned code, unsigned subcode, byte *data, unsigned len) { byte argbuf[256], *t = argbuf; unsigned i; /* Don't report Cease messages generated by myself */ if (code == 6 && class == BE_BGP_TX) return; /* Reset shutdown message */ if ((code == 6) && ((subcode == 2) || (subcode == 4))) proto_set_message(&p->p, NULL, 0); if (len) { /* Bad peer AS - we would like to print the AS */ if ((code == 2) && (subcode == 2) && ((len == 2) || (len == 4))) { t += bsprintf(t, ": %u", (len == 2) ? get_u16(data) : get_u32(data)); goto done; } /* RFC 8203 - shutdown communication */ if (((code == 6) && ((subcode == 2) || (subcode == 4)))) if (bgp_handle_message(p, data, len, &t)) goto done; *t++ = ':'; *t++ = ' '; if (len > 16) len = 16; for (i=0; ip.name, msg, dsc, argbuf); } static void bgp_rx_notification(struct bgp_conn *conn, byte *pkt, uint len) { struct bgp_proto *p = conn->bgp; if (len < 21) { bgp_error(conn, 1, 2, pkt+16, 2); return; } unsigned code = pkt[19]; unsigned subcode = pkt[20]; int err = (code != 6); bgp_log_error(p, BE_BGP_RX, "Received", code, subcode, pkt+21, len-21); bgp_store_error(p, conn, BE_BGP_RX, (code << 16) | subcode); #ifndef IPV6 if ((code == 2) && ((subcode == 4) || (subcode == 7)) /* Error related to capability: * 4 - Peer does not support capabilities at all. * 7 - Peer request some capability. Strange unless it is IPv6 only peer. */ && (p->cf->capabilities == 2) /* Capabilities are not explicitly enabled or disabled, therefore heuristic is used */ && (conn->start_state == BSS_CONNECT) /* Failed connection attempt have used capabilities */ && (p->cf->remote_as <= 0xFFFF)) /* Not possible with disabled capabilities */ { /* We try connect without capabilities */ log(L_WARN "%s: Capability related error received, retry with capabilities disabled", p->p.name); p->start_state = BSS_CONNECT_NOCAP; err = 0; } #endif bgp_conn_enter_close_state(conn); bgp_schedule_packet(conn, PKT_SCHEDULE_CLOSE); if (err) { bgp_update_startup_delay(p); bgp_stop(p, 0, NULL, 0); } else { uint subcode_bit = 1 << ((subcode <= 8) ? subcode : 0); if (p->cf->disable_after_cease & subcode_bit) { log(L_INFO "%s: Disabled after Cease notification", p->p.name); p->startup_delay = 0; p->p.disabled = 1; } } } static void bgp_rx_keepalive(struct bgp_conn *conn) { struct bgp_proto *p = conn->bgp; BGP_TRACE(D_PACKETS, "Got KEEPALIVE"); bgp_start_timer(conn->hold_timer, conn->hold_time); switch (conn->state) { case BS_OPENCONFIRM: bgp_conn_enter_established_state(conn); break; case BS_ESTABLISHED: break; default: bgp_error(conn, 5, fsm_err_subcode[conn->state], NULL, 0); } } static void bgp_rx_route_refresh(struct bgp_conn *conn, byte *pkt, uint len) { struct bgp_proto *p = conn->bgp; if (conn->state != BS_ESTABLISHED) { bgp_error(conn, 5, fsm_err_subcode[conn->state], NULL, 0); return; } if (!p->cf->enable_refresh) { bgp_error(conn, 1, 3, pkt+18, 1); return; } if (len < (BGP_HEADER_LENGTH + 4)) { bgp_error(conn, 1, 2, pkt+16, 2); return; } if (len > (BGP_HEADER_LENGTH + 4)) { bgp_error(conn, 7, 1, pkt, MIN(len, 2048)); return; } /* FIXME - we ignore AFI/SAFI values, as we support just one value and even an error code for an invalid request is not defined */ /* RFC 7313 redefined reserved field as RR message subtype */ uint subtype = conn->peer_enhanced_refresh_support ? pkt[21] : BGP_RR_REQUEST; switch (subtype) { case BGP_RR_REQUEST: BGP_TRACE(D_PACKETS, "Got ROUTE-REFRESH"); proto_request_feeding(&p->p); break; case BGP_RR_BEGIN: BGP_TRACE(D_PACKETS, "Got BEGIN-OF-RR"); bgp_refresh_begin(p); break; case BGP_RR_END: BGP_TRACE(D_PACKETS, "Got END-OF-RR"); bgp_refresh_end(p); break; default: log(L_WARN "%s: Got ROUTE-REFRESH message with unknown subtype %u, ignoring", p->p.name, subtype); break; } } /** * bgp_rx_packet - handle a received packet * @conn: BGP connection * @pkt: start of the packet * @len: packet size * * bgp_rx_packet() takes a newly received packet and calls the corresponding * packet handler according to the packet type. */ static void bgp_rx_packet(struct bgp_conn *conn, byte *pkt, unsigned len) { byte type = pkt[18]; DBG("BGP: Got packet %02x (%d bytes)\n", type, len); if (conn->bgp->p.mrtdump & MD_MESSAGES) bgp_dump_message(conn, pkt, len); switch (type) { case PKT_OPEN: return bgp_rx_open(conn, pkt, len); case PKT_UPDATE: return bgp_rx_update(conn, pkt, len); case PKT_NOTIFICATION: return bgp_rx_notification(conn, pkt, len); case PKT_KEEPALIVE: return bgp_rx_keepalive(conn); case PKT_ROUTE_REFRESH: return bgp_rx_route_refresh(conn, pkt, len); default: bgp_error(conn, 1, 3, pkt+18, 1); } } /** * bgp_rx - handle received data * @sk: socket * @size: amount of data received * * bgp_rx() is called by the socket layer whenever new data arrive from * the underlying TCP connection. It assembles the data fragments to packets, * checks their headers and framing and passes complete packets to * bgp_rx_packet(). */ int bgp_rx(sock *sk, uint size) { struct bgp_conn *conn = sk->data; struct bgp_proto *p = conn->bgp; byte *pkt_start = sk->rbuf; byte *end = pkt_start + size; unsigned i, len; DBG("BGP: RX hook: Got %d bytes\n", size); while (end >= pkt_start + BGP_HEADER_LENGTH) { if ((conn->state == BS_CLOSE) || (conn->sk != sk)) return 0; for(i=0; i<16; i++) if (pkt_start[i] != 0xff) { bgp_error(conn, 1, 1, NULL, 0); break; } len = get_u16(pkt_start+16); if (len < BGP_HEADER_LENGTH || len > bgp_max_packet_length(p)) { bgp_error(conn, 1, 2, pkt_start+16, 2); break; } if (end < pkt_start + len) break; bgp_rx_packet(conn, pkt_start, len); pkt_start += len; } if (pkt_start != sk->rbuf) { memmove(sk->rbuf, pkt_start, end - pkt_start); sk->rpos = sk->rbuf + (end - pkt_start); } return 0; }