// SPDX-License-Identifier: GPL-2.0-or-later /* * BFD PTM adapter code * Copyright (C) 2018 Network Device Education Foundation, Inc. ("NetDEF") */ #include #include "lib/libfrr.h" #include "lib/queue.h" #include "lib/stream.h" #include "lib/zclient.h" #include "lib/printfrr.h" #include "lib/bfd.h" #include "bfd.h" /* * Data structures */ struct ptm_client_notification { struct bfd_session *pcn_bs; struct ptm_client *pcn_pc; TAILQ_ENTRY(ptm_client_notification) pcn_entry; }; TAILQ_HEAD(pcnqueue, ptm_client_notification); struct ptm_client { uint32_t pc_pid; struct pcnqueue pc_pcnqueue; TAILQ_ENTRY(ptm_client) pc_entry; }; TAILQ_HEAD(pcqueue, ptm_client); static struct pcqueue pcqueue; static struct zclient *zclient; /* * Prototypes */ static int _ptm_msg_address(struct stream *msg, int family, const void *addr); static void _ptm_msg_read_address(struct stream *msg, struct sockaddr_any *sa); static int _ptm_msg_read(struct stream *msg, int command, vrf_id_t vrf_id, struct bfd_peer_cfg *bpc, struct ptm_client **pc); static struct ptm_client *pc_lookup(uint32_t pid); static struct ptm_client *pc_new(uint32_t pid); static void pc_free(struct ptm_client *pc); static void pc_free_all(void); static struct ptm_client_notification *pcn_new(struct ptm_client *pc, struct bfd_session *bs); static struct ptm_client_notification *pcn_lookup(struct ptm_client *pc, struct bfd_session *bs); static void pcn_free(struct ptm_client_notification *pcn); static void bfdd_dest_register(struct stream *msg, vrf_id_t vrf_id); static void bfdd_dest_deregister(struct stream *msg, vrf_id_t vrf_id); static void bfdd_client_register(struct stream *msg); static void bfdd_client_deregister(struct stream *msg); /* * Functions */ PRINTFRR(2, 3) static void debug_printbpc(const struct bfd_peer_cfg *bpc, const char *fmt, ...) { char timers[3][128] = {}; char minttl_str[32] = {}; char addr[3][128] = {}; char profile[128] = {}; char cbit_str[32]; char msgbuf[512]; va_list vl; /* Avoid debug calculations if it's disabled. */ if (bglobal.debug_zebra == false) return; snprintf(addr[0], sizeof(addr[0]), "peer:%s", satostr(&bpc->bpc_peer)); if (bpc->bpc_local.sa_sin.sin_family) snprintf(addr[1], sizeof(addr[1]), " local:%s", satostr(&bpc->bpc_local)); if (bpc->bpc_has_localif) snprintf(addr[2], sizeof(addr[2]), " ifname:%s", bpc->bpc_localif); if (bpc->bpc_has_vrfname) snprintf(addr[2], sizeof(addr[2]), " vrf:%s", bpc->bpc_vrfname); if (bpc->bpc_has_recvinterval) snprintfrr(timers[0], sizeof(timers[0]), " rx:%" PRIu64, bpc->bpc_recvinterval); if (bpc->bpc_has_txinterval) snprintfrr(timers[1], sizeof(timers[1]), " tx:%" PRIu64, bpc->bpc_recvinterval); if (bpc->bpc_has_detectmultiplier) snprintf(timers[2], sizeof(timers[2]), " detect-multiplier:%d", bpc->bpc_detectmultiplier); snprintf(cbit_str, sizeof(cbit_str), " cbit:0x%02x", bpc->bpc_cbit); if (bpc->bpc_has_minimum_ttl) snprintf(minttl_str, sizeof(minttl_str), " minimum-ttl:%d", bpc->bpc_minimum_ttl); if (bpc->bpc_has_profile) snprintf(profile, sizeof(profile), " profile:%s", bpc->bpc_profile); va_start(vl, fmt); vsnprintf(msgbuf, sizeof(msgbuf), fmt, vl); va_end(vl); zlog_debug("%s [mhop:%s %s%s%s%s%s%s%s%s%s]", msgbuf, bpc->bpc_mhop ? "yes" : "no", addr[0], addr[1], addr[2], timers[0], timers[1], timers[2], cbit_str, minttl_str, profile); } static void _ptm_bfd_session_del(struct bfd_session *bs, uint8_t diag) { if (bglobal.debug_peer_event) zlog_debug("session-delete: %s", bs_to_string(bs)); /* Change state and notify peer. */ bs->ses_state = PTM_BFD_DOWN; bs->local_diag = diag; ptm_bfd_snd(bs, 0); /* Session reached refcount == 0, lets delete it. */ if (bs->refcount == 0) { /* * Sanity check: if there is a refcount bug, we can't delete * the session a user configured manually. Lets leave a * message here so we can catch the bug if it exists. */ if (CHECK_FLAG(bs->flags, BFD_SESS_FLAG_CONFIG)) { zlog_err( "ptm-del-session: [%s] session refcount is zero but it was configured by CLI", bs_to_string(bs)); } else { bfd_session_free(bs); } } } static int _ptm_msg_address(struct stream *msg, int family, const void *addr) { stream_putc(msg, family); switch (family) { case AF_INET: stream_put(msg, addr, sizeof(struct in_addr)); stream_putc(msg, 32); break; case AF_INET6: stream_put(msg, addr, sizeof(struct in6_addr)); stream_putc(msg, 128); break; default: assert(0); break; } return 0; } int ptm_bfd_notify(struct bfd_session *bs, uint8_t notify_state) { struct stream *msg; bs->stats.znotification++; /* * Message format: * - header: command, vrf * - l: interface index * - c: family * - AF_INET: * - 4 bytes: ipv4 * - AF_INET6: * - 16 bytes: ipv6 * - c: prefix length * - l: bfd status * - c: family * - AF_INET: * - 4 bytes: ipv4 * - AF_INET6: * - 16 bytes: ipv6 * - c: prefix length * - c: cbit * * Commands: ZEBRA_BFD_DEST_REPLAY * * q(64), l(32), w(16), c(8) */ msg = zclient->obuf; stream_reset(msg); /* TODO: VRF handling */ if (bs->vrf) zclient_create_header(msg, ZEBRA_BFD_DEST_REPLAY, bs->vrf->vrf_id); else zclient_create_header(msg, ZEBRA_BFD_DEST_REPLAY, VRF_DEFAULT); /* This header will be handled by `zebra_ptm.c`. */ stream_putl(msg, ZEBRA_INTERFACE_BFD_DEST_UPDATE); /* NOTE: Interface is a shortcut to avoid comparing source address. */ if (!CHECK_FLAG(bs->flags, BFD_SESS_FLAG_MH) && bs->ifp != NULL) stream_putl(msg, bs->ifp->ifindex); else stream_putl(msg, IFINDEX_INTERNAL); /* BFD destination prefix information. */ _ptm_msg_address(msg, bs->key.family, &bs->key.peer); /* BFD status */ switch (notify_state) { case PTM_BFD_UP: stream_putl(msg, BFD_STATUS_UP); break; case PTM_BFD_ADM_DOWN: stream_putl(msg, BFD_STATUS_ADMIN_DOWN); break; case PTM_BFD_DOWN: case PTM_BFD_INIT: stream_putl(msg, BFD_STATUS_DOWN); break; default: stream_putl(msg, BFD_STATUS_UNKNOWN); break; } /* BFD source prefix information. */ _ptm_msg_address(msg, bs->key.family, &bs->key.local); stream_putc(msg, bs->remote_cbit); /* Write packet size. */ stream_putw_at(msg, 0, stream_get_endp(msg)); return zclient_send_message(zclient); } static void _ptm_msg_read_address(struct stream *msg, struct sockaddr_any *sa) { uint16_t family; STREAM_GETW(msg, family); switch (family) { case AF_INET: sa->sa_sin.sin_family = family; STREAM_GET(&sa->sa_sin.sin_addr, msg, sizeof(sa->sa_sin.sin_addr)); #ifdef HAVE_STRUCT_SOCKADDR_SA_LEN sa->sa_sin.sin_len = sizeof(sa->sa_sin); #endif /* HAVE_STRUCT_SOCKADDR_SA_LEN */ return; case AF_INET6: sa->sa_sin6.sin6_family = family; STREAM_GET(&sa->sa_sin6.sin6_addr, msg, sizeof(sa->sa_sin6.sin6_addr)); #ifdef HAVE_STRUCT_SOCKADDR_SA_LEN sa->sa_sin6.sin6_len = sizeof(sa->sa_sin6); #endif /* HAVE_STRUCT_SOCKADDR_SA_LEN */ return; default: zlog_warn("ptm-read-address: invalid family: %d", family); break; } stream_failure: memset(sa, 0, sizeof(*sa)); } static int _ptm_msg_read(struct stream *msg, int command, vrf_id_t vrf_id, struct bfd_peer_cfg *bpc, struct ptm_client **pc) { uint32_t pid; size_t ifnamelen; /* * Register/Deregister/Update Message format: * * Old format (being used by PTM BFD). * - header: Command, VRF * - l: pid * - w: family * - AF_INET: * - l: destination ipv4 * - AF_INET6: * - 16 bytes: destination IPv6 * - command != ZEBRA_BFD_DEST_DEREGISTER * - l: min_rx * - l: min_tx * - c: detect multiplier * - c: is_multihop? * - multihop: * - w: family * - AF_INET: * - l: source IPv4 address * - AF_INET6: * - 16 bytes: source IPv6 address * - c: ttl * - no multihop * - AF_INET6: * - w: family * - 16 bytes: source IPv6 address * - c: ifname length * - X bytes: interface name * * New format: * - header: Command, VRF * - l: pid * - w: family * - AF_INET: * - l: destination IPv4 address * - AF_INET6: * - 16 bytes: destination IPv6 address * - l: min_rx * - l: min_tx * - c: detect multiplier * - c: is_multihop? * - w: family * - AF_INET: * - l: source IPv4 address * - AF_INET6: * - 16 bytes: source IPv6 address * - c: ttl * - c: ifname length * - X bytes: interface name * - c: bfd_cbit * - c: profile name length. * - X bytes: profile name. * * q(64), l(32), w(16), c(8) */ /* Initialize parameters return values. */ memset(bpc, 0, sizeof(*bpc)); *pc = NULL; /* Find or allocate process context data. */ STREAM_GETL(msg, pid); *pc = pc_new(pid); /* Register/update peer information. */ _ptm_msg_read_address(msg, &bpc->bpc_peer); /* Determine IP type from peer destination. */ bpc->bpc_ipv4 = (bpc->bpc_peer.sa_sin.sin_family == AF_INET); /* Get peer configuration. */ STREAM_GETL(msg, bpc->bpc_recvinterval); bpc->bpc_has_recvinterval = (bpc->bpc_recvinterval != BPC_DEF_RECEIVEINTERVAL); STREAM_GETL(msg, bpc->bpc_txinterval); bpc->bpc_has_txinterval = (bpc->bpc_txinterval != BPC_DEF_TRANSMITINTERVAL); STREAM_GETC(msg, bpc->bpc_detectmultiplier); bpc->bpc_has_detectmultiplier = (bpc->bpc_detectmultiplier != BPC_DEF_DETECTMULTIPLIER); /* Read (single|multi)hop and its options. */ STREAM_GETC(msg, bpc->bpc_mhop); /* Read multihop source address and TTL. */ _ptm_msg_read_address(msg, &bpc->bpc_local); /* Read the minimum TTL (0 means unset or invalid). */ STREAM_GETC(msg, bpc->bpc_minimum_ttl); if (bpc->bpc_minimum_ttl == 0) { bpc->bpc_minimum_ttl = BFD_DEF_MHOP_TTL; bpc->bpc_has_minimum_ttl = false; } else { bpc->bpc_minimum_ttl = (BFD_TTL_VAL + 1) - bpc->bpc_minimum_ttl; bpc->bpc_has_minimum_ttl = true; } /* * Read interface name and make sure it fits our data * structure, otherwise fail. */ STREAM_GETC(msg, ifnamelen); if (ifnamelen >= sizeof(bpc->bpc_localif)) { zlog_err("ptm-read: interface name is too big"); return -1; } bpc->bpc_has_localif = ifnamelen > 0; if (bpc->bpc_has_localif) { STREAM_GET(bpc->bpc_localif, msg, ifnamelen); bpc->bpc_localif[ifnamelen] = 0; } if (vrf_id != VRF_DEFAULT) { struct vrf *vrf; vrf = vrf_lookup_by_id(vrf_id); if (vrf) { bpc->bpc_has_vrfname = true; strlcpy(bpc->bpc_vrfname, vrf->name, sizeof(bpc->bpc_vrfname)); } else { zlog_err("ptm-read: vrf id %u could not be identified", vrf_id); return -1; } } else { bpc->bpc_has_vrfname = true; strlcpy(bpc->bpc_vrfname, VRF_DEFAULT_NAME, sizeof(bpc->bpc_vrfname)); } /* Read control plane independant configuration. */ STREAM_GETC(msg, bpc->bpc_cbit); /* Handle profile names. */ STREAM_GETC(msg, ifnamelen); bpc->bpc_has_profile = ifnamelen > 0; if (bpc->bpc_has_profile) { STREAM_GET(bpc->bpc_profile, msg, ifnamelen); bpc->bpc_profile[ifnamelen] = 0; } /* Sanity check: peer and local address must match IP types. */ if (bpc->bpc_local.sa_sin.sin_family != AF_UNSPEC && (bpc->bpc_local.sa_sin.sin_family != bpc->bpc_peer.sa_sin.sin_family)) { zlog_warn("ptm-read: peer family doesn't match local type"); return -1; } return 0; stream_failure: return -1; } static void bfdd_dest_register(struct stream *msg, vrf_id_t vrf_id) { struct ptm_client *pc; struct bfd_session *bs; struct bfd_peer_cfg bpc; /* Read the client context and peer data. */ if (_ptm_msg_read(msg, ZEBRA_BFD_DEST_REGISTER, vrf_id, &bpc, &pc) == -1) return; debug_printbpc(&bpc, "ptm-add-dest: register peer"); /* Find or start new BFD session. */ bs = bs_peer_find(&bpc); if (bs == NULL) { bs = ptm_bfd_sess_new(&bpc); if (bs == NULL) { if (bglobal.debug_zebra) zlog_debug( "ptm-add-dest: failed to create BFD session"); return; } } else { /* * BFD session was already created, we are just updating the * current peer. * * `ptm-bfd` (or `HAVE_BFDD == 0`) is the only implementation * that allow users to set peer specific timers via protocol. * BFD daemon (this code) on the other hand only supports * changing peer configuration manually (through `peer` node) * or via profiles. */ if (bpc.bpc_has_profile) bfd_profile_apply(bpc.bpc_profile, bs); } /* Create client peer notification register. */ pcn_new(pc, bs); ptm_bfd_notify(bs, bs->ses_state); } static void bfdd_dest_deregister(struct stream *msg, vrf_id_t vrf_id) { struct ptm_client *pc; struct ptm_client_notification *pcn; struct bfd_session *bs; struct bfd_peer_cfg bpc; /* Read the client context and peer data. */ if (_ptm_msg_read(msg, ZEBRA_BFD_DEST_DEREGISTER, vrf_id, &bpc, &pc) == -1) return; debug_printbpc(&bpc, "ptm-del-dest: deregister peer"); /* Find or start new BFD session. */ bs = bs_peer_find(&bpc); if (bs == NULL) { if (bglobal.debug_zebra) zlog_debug("ptm-del-dest: failed to find BFD session"); return; } /* Unregister client peer notification. */ pcn = pcn_lookup(pc, bs); if (pcn != NULL) { pcn_free(pcn); return; } if (bglobal.debug_zebra) zlog_debug("ptm-del-dest: failed to find BFD session"); /* * XXX: We either got a double deregistration or the daemon who * created this is no longer around. Lets try to delete it anyway * and the worst case is the refcount will detain us. */ _ptm_bfd_session_del(bs, BD_NEIGHBOR_DOWN); } /* * header: command, VRF * l: pid */ static void bfdd_client_register(struct stream *msg) { uint32_t pid; /* Find or allocate process context data. */ STREAM_GETL(msg, pid); pc_new(pid); return; stream_failure: zlog_err("ptm-add-client: failed to register client"); } /* * header: command, VRF * l: pid */ static void bfdd_client_deregister(struct stream *msg) { struct ptm_client *pc; uint32_t pid; /* Find or allocate process context data. */ STREAM_GETL(msg, pid); pc = pc_lookup(pid); if (pc == NULL) { if (bglobal.debug_zebra) zlog_debug("ptm-del-client: failed to find client: %u", pid); return; } if (bglobal.debug_zebra) zlog_debug("ptm-del-client: client pid %u", pid); pc_free(pc); return; stream_failure: zlog_err("ptm-del-client: failed to deregister client"); } static int bfdd_replay(ZAPI_CALLBACK_ARGS) { struct stream *msg = zclient->ibuf; uint32_t rcmd; STREAM_GETL(msg, rcmd); switch (rcmd) { case ZEBRA_BFD_DEST_REGISTER: case ZEBRA_BFD_DEST_UPDATE: bfdd_dest_register(msg, vrf_id); break; case ZEBRA_BFD_DEST_DEREGISTER: bfdd_dest_deregister(msg, vrf_id); break; case ZEBRA_BFD_CLIENT_REGISTER: bfdd_client_register(msg); break; case ZEBRA_BFD_CLIENT_DEREGISTER: bfdd_client_deregister(msg); break; default: if (bglobal.debug_zebra) zlog_debug("ptm-replay: invalid message type %u", rcmd); return -1; } return 0; stream_failure: zlog_err("ptm-replay: failed to find command"); return -1; } static void bfdd_zebra_connected(struct zclient *zc) { struct stream *msg = zc->obuf; /* Clean-up and free ptm clients data memory. */ pc_free_all(); /* * The replay is an empty message just to trigger client daemons * configuration replay. */ stream_reset(msg); zclient_create_header(msg, ZEBRA_BFD_DEST_REPLAY, VRF_DEFAULT); stream_putl(msg, ZEBRA_BFD_DEST_REPLAY); stream_putw_at(msg, 0, stream_get_endp(msg)); /* Ask for interfaces information. */ zclient_create_header(msg, ZEBRA_INTERFACE_ADD, VRF_DEFAULT); /* Send requests. */ zclient_send_message(zclient); } static void bfdd_sessions_enable_interface(struct interface *ifp) { struct bfd_session_observer *bso; struct bfd_session *bs; struct vrf *vrf; vrf = ifp->vrf; TAILQ_FOREACH(bso, &bglobal.bg_obslist, bso_entry) { bs = bso->bso_bs; /* check vrf name */ if (bs->key.vrfname[0] && strcmp(vrf->name, bs->key.vrfname)) continue; /* If Interface matches vrfname, then bypass iface check */ if (vrf_is_backend_netns() || strcmp(ifp->name, vrf->name)) { /* Interface name mismatch. */ if (bs->key.ifname[0] && strcmp(ifp->name, bs->key.ifname)) continue; } /* Skip enabled sessions. */ if (bs->sock != -1) continue; /* Try to enable it. */ bfd_session_enable(bs); } } static void bfdd_sessions_disable_interface(struct interface *ifp) { struct bfd_session_observer *bso; struct bfd_session *bs; TAILQ_FOREACH(bso, &bglobal.bg_obslist, bso_entry) { bs = bso->bso_bs; if (bs->ifp != ifp) continue; /* Skip disabled sessions. */ if (bs->sock == -1) { bs->ifp = NULL; continue; } bfd_session_disable(bs); bs->ifp = NULL; } } void bfdd_sessions_enable_vrf(struct vrf *vrf) { struct bfd_session_observer *bso; struct bfd_session *bs; /* it may affect configs without interfaces */ TAILQ_FOREACH(bso, &bglobal.bg_obslist, bso_entry) { bs = bso->bso_bs; if (bs->vrf) continue; if (bs->key.vrfname[0] && strcmp(vrf->name, bs->key.vrfname)) continue; /* need to update the vrf information on * bs so that callbacks are handled */ bs->vrf = vrf; /* Skip enabled sessions. */ if (bs->sock != -1) continue; /* Try to enable it. */ bfd_session_enable(bs); } } void bfdd_sessions_disable_vrf(struct vrf *vrf) { struct bfd_session_observer *bso; struct bfd_session *bs; TAILQ_FOREACH(bso, &bglobal.bg_obslist, bso_entry) { bs = bso->bso_bs; if (bs->key.vrfname[0] && strcmp(vrf->name, bs->key.vrfname)) continue; /* Skip disabled sessions. */ if (bs->sock == -1) continue; bfd_session_disable(bs); bs->vrf = NULL; } } static int bfd_ifp_destroy(struct interface *ifp) { if (bglobal.debug_zebra) zlog_debug("zclient: delete interface %s (VRF %s(%u))", ifp->name, ifp->vrf->name, ifp->vrf->vrf_id); bfdd_sessions_disable_interface(ifp); return 0; } static void bfdd_sessions_enable_address(struct connected *ifc) { struct bfd_session_observer *bso; struct bfd_session *bs; struct prefix prefix; TAILQ_FOREACH(bso, &bglobal.bg_obslist, bso_entry) { /* Skip enabled sessions. */ bs = bso->bso_bs; if (bs->sock != -1) continue; /* Check address. */ prefix = bso->bso_addr; prefix.prefixlen = ifc->address->prefixlen; if (prefix_cmp(&prefix, ifc->address)) continue; /* Try to enable it. */ bfd_session_enable(bs); } } static int bfdd_interface_address_update(ZAPI_CALLBACK_ARGS) { struct connected *ifc; ifc = zebra_interface_address_read(cmd, zclient->ibuf, vrf_id); if (ifc == NULL) return 0; if (bglobal.debug_zebra) zlog_debug("zclient: %s local address %pFX (VRF %u)", cmd == ZEBRA_INTERFACE_ADDRESS_ADD ? "add" : "delete", ifc->address, vrf_id); if (cmd == ZEBRA_INTERFACE_ADDRESS_ADD) bfdd_sessions_enable_address(ifc); else connected_free(&ifc); return 0; } static int bfd_ifp_create(struct interface *ifp) { if (bglobal.debug_zebra) zlog_debug("zclient: add interface %s (VRF %s(%u))", ifp->name, ifp->vrf->name, ifp->vrf->vrf_id); bfdd_sessions_enable_interface(ifp); return 0; } static zclient_handler *const bfd_handlers[] = { /* * We'll receive all messages through replay, however it will * contain a special field with the real command inside so we * avoid having to create too many handlers. */ [ZEBRA_BFD_DEST_REPLAY] = bfdd_replay, /* Learn about new addresses being registered. */ [ZEBRA_INTERFACE_ADDRESS_ADD] = bfdd_interface_address_update, [ZEBRA_INTERFACE_ADDRESS_DELETE] = bfdd_interface_address_update, }; void bfdd_zclient_init(struct zebra_privs_t *bfdd_priv) { hook_register_prio(if_real, 0, bfd_ifp_create); hook_register_prio(if_unreal, 0, bfd_ifp_destroy); zclient = zclient_new(master, &zclient_options_default, bfd_handlers, array_size(bfd_handlers)); assert(zclient != NULL); zclient_init(zclient, ZEBRA_ROUTE_BFD, 0, bfdd_priv); /* Send replay request on zebra connect. */ zclient->zebra_connected = bfdd_zebra_connected; } void bfdd_zclient_register(vrf_id_t vrf_id) { if (!zclient || zclient->sock < 0) return; zclient_send_reg_requests(zclient, vrf_id); } void bfdd_zclient_unregister(vrf_id_t vrf_id) { if (!zclient || zclient->sock < 0) return; zclient_send_dereg_requests(zclient, vrf_id); } void bfdd_zclient_stop(void) { zclient_stop(zclient); /* Clean-up and free ptm clients data memory. */ pc_free_all(); } void bfdd_zclient_terminate(void) { zclient_free(zclient); } /* * Client handling. */ static struct ptm_client *pc_lookup(uint32_t pid) { struct ptm_client *pc; TAILQ_FOREACH (pc, &pcqueue, pc_entry) { if (pc->pc_pid != pid) continue; break; } return pc; } static struct ptm_client *pc_new(uint32_t pid) { struct ptm_client *pc; /* Look up first, if not found create the client. */ pc = pc_lookup(pid); if (pc != NULL) return pc; /* Allocate the client data and save it. */ pc = XCALLOC(MTYPE_BFDD_CLIENT, sizeof(*pc)); pc->pc_pid = pid; TAILQ_INSERT_HEAD(&pcqueue, pc, pc_entry); return pc; } static void pc_free(struct ptm_client *pc) { struct ptm_client_notification *pcn; TAILQ_REMOVE(&pcqueue, pc, pc_entry); while (!TAILQ_EMPTY(&pc->pc_pcnqueue)) { pcn = TAILQ_FIRST(&pc->pc_pcnqueue); pcn_free(pcn); } XFREE(MTYPE_BFDD_CLIENT, pc); } static void pc_free_all(void) { struct ptm_client *pc; while (!TAILQ_EMPTY(&pcqueue)) { pc = TAILQ_FIRST(&pcqueue); pc_free(pc); } } static struct ptm_client_notification *pcn_new(struct ptm_client *pc, struct bfd_session *bs) { struct ptm_client_notification *pcn; /* Try to find an existing pcn fist. */ pcn = pcn_lookup(pc, bs); if (pcn != NULL) return pcn; /* Save the client notification data. */ pcn = XCALLOC(MTYPE_BFDD_CLIENT_NOTIFICATION, sizeof(*pcn)); TAILQ_INSERT_HEAD(&pc->pc_pcnqueue, pcn, pcn_entry); pcn->pcn_pc = pc; pcn->pcn_bs = bs; bs->refcount++; return pcn; } static struct ptm_client_notification *pcn_lookup(struct ptm_client *pc, struct bfd_session *bs) { struct ptm_client_notification *pcn; TAILQ_FOREACH (pcn, &pc->pc_pcnqueue, pcn_entry) { if (pcn->pcn_bs != bs) continue; break; } return pcn; } static void pcn_free(struct ptm_client_notification *pcn) { struct ptm_client *pc; struct bfd_session *bs; /* Handle session de-registration. */ bs = pcn->pcn_bs; pcn->pcn_bs = NULL; bs->refcount--; /* Log modification to users. */ if (bglobal.debug_zebra) zlog_debug("ptm-del-session: [%s] refcount=%" PRIu64, bs_to_string(bs), bs->refcount); /* Set session down. */ _ptm_bfd_session_del(bs, BD_NEIGHBOR_DOWN); /* Handle ptm_client deregistration. */ pc = pcn->pcn_pc; pcn->pcn_pc = NULL; TAILQ_REMOVE(&pc->pc_pcnqueue, pcn, pcn_entry); XFREE(MTYPE_BFDD_CLIENT_NOTIFICATION, pcn); }