/* * BIRD -- The Resource Public Key Infrastructure (RPKI) to Router Protocol * * (c) 2015 CZ.NIC * (c) 2015 Pavel Tvrdik * * Using RTRlib: http://rpki.realmv6.org/ * * Can be freely distributed and used under the terms of the GNU GPL. */ /** * DOC: RPKI To Router (RPKI-RTR) * * The RPKI-RTR protocol is implemented in several files: |rpki.c| containing * the routes handling, protocol logic, timer events, cache connection, * reconfiguration, configuration and protocol glue with BIRD core, |packets.c| * containing the RPKI packets handling and finally all transports files: * |transport.c|, |tcp_transport.c| and |ssh_transport.c|. * * The |transport.c| is a middle layer and interface for each specific * transport. Transport is a way how to wrap a communication with a cache * server. There is supported an unprotected TCP transport and an encrypted * SSHv2 transport. The SSH transport requires LibSSH library. LibSSH is * loading dynamically using |dlopen()| function. SSH support is integrated in * |sysdep/unix/io.c|. Each transport must implement an initialization * function, an open function and a socket identification function. That's all. * * This implementation is based on the RTRlib (http://rpki.realmv6.org/). The * BIRD takes over files |packets.c|, |rtr.c| (inside |rpki.c|), |transport.c|, * |tcp_transport.c| and |ssh_transport.c| from RTRlib. * * A RPKI-RTR connection is described by a structure &rpki_cache. The main * logic is located in |rpki_cache_change_state()| function. There is a state * machine. The standard starting state flow looks like |Down| ~> |Connecting| * ~> |Sync-Start| ~> |Sync-Running| ~> |Established| and then the last three * states are periodically repeated. * * |Connecting| state establishes the transport connection. The state from a * call |rpki_cache_change_state(CONNECTING)| to a call |rpki_connected_hook()| * * |Sync-Start| state starts with sending |Reset Query| or |Serial Query| and * then waits for |Cache Response|. The state from |rpki_connected_hook()| to * |rpki_handle_cache_response_pdu()| * * During |Sync-Running| BIRD receives data with IPv4/IPv6 Prefixes from cache * server. The state starts from |rpki_handle_cache_response_pdu()| and ends * in |rpki_handle_end_of_data_pdu()|. * * |Established| state means that BIRD has synced all data with cache server. * Schedules a refresh timer event that invokes |Sync-Start|. Schedules Expire * timer event and stops a Retry timer event. * * |Transport Error| state means that we have some troubles with a network * connection. We cannot connect to a cache server or we wait too long for some * expected PDU for received - |Cache Response| or |End of Data|. It closes * current connection and schedules a Retry timer event. * * |Fatal Protocol Error| is occurred e.g. by received a bad Session ID. We * restart a protocol, so all ROAs are flushed immediately. * * The RPKI-RTR protocol (RFC 6810 bis) defines configurable refresh, retry and * expire intervals. For maintaining a connection are used timer events that * are scheduled by |rpki_schedule_next_refresh()|, * |rpki_schedule_next_retry()| and |rpki_schedule_next_expire()| functions. * * A Refresh timer event performs a sync of |Established| connection. So it * shifts state to |Sync-Start|. If at the beginning of second call of a * refresh event is connection in |Sync-Start| state then we didn't receive a * |Cache Response| from a cache server and we invoke |Transport Error| state. * * A Retry timer event attempts to connect cache server. It is activated after * |Transport Error| state and terminated by reaching |Established| state. * If cache connection is still connecting to the cache server at the beginning * of an event call then the Retry timer event invokes |Transport Error| state. * * An Expire timer event checks expiration of ROAs. If a last successful sync * was more ago than the expire interval then the Expire timer event invokes a * protocol restart thereby removes all ROAs learned from that cache server and * continue trying to connect to cache server. The Expire event is activated * by initial successful loading of ROAs, receiving End of Data PDU. * * A reconfiguration of cache connection works well without restarting when we * change only intervals values. * * Supported standards: * - RFC 6810 - main RPKI-RTR standard * - RFC 6810 bis - an explicit timing parameters and protocol version number negotiation */ #include #include #undef LOCAL_DEBUG #include "rpki.h" #include "lib/string.h" #include "nest/cli.h" /* Return values for reconfiguration functions */ #define NEED_RESTART 0 #define SUCCESSFUL_RECONF 1 static int rpki_open_connection(struct rpki_cache *cache); static void rpki_close_connection(struct rpki_cache *cache); static void rpki_schedule_next_refresh(struct rpki_cache *cache); static void rpki_schedule_next_retry(struct rpki_cache *cache); static void rpki_schedule_next_expire_check(struct rpki_cache *cache); static void rpki_stop_refresh_timer_event(struct rpki_cache *cache); static void rpki_stop_retry_timer_event(struct rpki_cache *cache); static void rpki_stop_expire_timer_event(struct rpki_cache *cache); /* * Routes handling */ void rpki_table_add_roa(struct rpki_cache *cache, struct channel *channel, const net_addr_union *pfxr) { struct rpki_proto *p = cache->p; rta a0 = { .dest = RTD_NONE, }; ea_set_attr_u32(&a0.eattrs, &ea_gen_preference, 0, channel->preference); ea_set_attr_u32(&a0.eattrs, &ea_gen_source, 0, RTS_RPKI); rta *a = rta_lookup(&a0); rte *e = rte_get_temp(a, p->p.main_source); e->pflags = 0; rte_update2(channel, &pfxr->n, e, e->src); } void rpki_table_remove_roa(struct rpki_cache *cache, struct channel *channel, const net_addr_union *pfxr) { struct rpki_proto *p = cache->p; rte_update2(channel, &pfxr->n, NULL, p->p.main_source); } /* * RPKI Protocol Logic */ static const char *str_cache_states[] = { [RPKI_CS_CONNECTING] = "Connecting", [RPKI_CS_ESTABLISHED] = "Established", [RPKI_CS_RESET] = "Reseting", [RPKI_CS_SYNC_START] = "Sync-Start", [RPKI_CS_SYNC_RUNNING] = "Sync-Running", [RPKI_CS_FAST_RECONNECT] = "Fast-Reconnect", [RPKI_CS_NO_INCR_UPDATE_AVAIL]= "No-Increment-Update-Available", [RPKI_CS_ERROR_NO_DATA_AVAIL] = "Cache-Error-No-Data-Available", [RPKI_CS_ERROR_FATAL] = "Fatal-Protocol-Error", [RPKI_CS_ERROR_TRANSPORT] = "Transport-Error", [RPKI_CS_SHUTDOWN] = "Down" }; /** * rpki_cache_state_to_str - give a text representation of cache state * @state: A cache state * * The function converts logic cache state into string. */ const char * rpki_cache_state_to_str(enum rpki_cache_state state) { return str_cache_states[state]; } /** * rpki_start_cache - connect to a cache server * @cache: RPKI connection instance * * This function is a high level method to kick up a connection to a cache server. */ static void rpki_start_cache(struct rpki_cache *cache) { rpki_cache_change_state(cache, RPKI_CS_CONNECTING); } /** * rpki_force_restart_proto - force shutdown and start protocol again * @p: RPKI protocol instance * * This function calls shutdown and frees all protocol resources as well. * After calling this function should be no operations with protocol data, * they could be freed already. */ static void rpki_force_restart_proto(struct rpki_proto *p) { if (p->cache) { CACHE_DBG(p->cache, "Connection object destroying"); } /* Sign as freed */ p->cache = NULL; proto_notify_state(&p->p, PS_DOWN); } /** * rpki_cache_change_state - check and change cache state * @cache: RPKI cache instance * @new_state: suggested new state * * This function makes transitions between internal states. * It represents the core of logic management of RPKI protocol. * Cannot transit into the same state as cache is in already. */ void rpki_cache_change_state(struct rpki_cache *cache, const enum rpki_cache_state new_state) { const enum rpki_cache_state old_state = cache->state; if (old_state == new_state) return; cache->state = new_state; CACHE_TRACE(D_EVENTS, cache, "Changing from %s to %s state", rpki_cache_state_to_str(old_state), rpki_cache_state_to_str(new_state)); switch (new_state) { case RPKI_CS_CONNECTING: { sock *sk = cache->tr_sock->sk; if (sk == NULL || sk->fd < 0) rpki_open_connection(cache); else rpki_cache_change_state(cache, RPKI_CS_SYNC_START); rpki_schedule_next_retry(cache); break; } case RPKI_CS_ESTABLISHED: rpki_schedule_next_refresh(cache); rpki_schedule_next_expire_check(cache); rpki_stop_retry_timer_event(cache); break; case RPKI_CS_RESET: /* Resetting cache connection. */ cache->request_session_id = 1; cache->serial_num = 0; rpki_cache_change_state(cache, RPKI_CS_SYNC_START); break; case RPKI_CS_SYNC_START: /* Requesting for receive ROAs from a cache server. */ if (cache->request_session_id) { /* Send request for Session ID */ if (rpki_send_reset_query(cache) != RPKI_SUCCESS) rpki_cache_change_state(cache, RPKI_CS_ERROR_TRANSPORT); } else { /* We have already a session_id. So send a Serial Query and start an incremental sync */ if (rpki_send_serial_query(cache) != RPKI_SUCCESS) rpki_cache_change_state(cache, RPKI_CS_ERROR_TRANSPORT); } break; case RPKI_CS_SYNC_RUNNING: /* The state between Cache Response and End of Data. Only waiting for * receiving all IP Prefix PDUs and finally a End of Data PDU. */ break; case RPKI_CS_NO_INCR_UPDATE_AVAIL: /* Server was unable to answer the last Serial Query and sent Cache Reset. */ rpki_cache_change_state(cache, RPKI_CS_RESET); break; case RPKI_CS_ERROR_NO_DATA_AVAIL: /* No validation records are available on the cache server. */ rpki_cache_change_state(cache, RPKI_CS_RESET); break; case RPKI_CS_ERROR_FATAL: /* Fatal protocol error occurred. */ rpki_force_restart_proto(cache->p); break; case RPKI_CS_ERROR_TRANSPORT: /* Error on the transport socket occurred. */ rpki_close_connection(cache); rpki_schedule_next_retry(cache); rpki_stop_refresh_timer_event(cache); break; case RPKI_CS_FAST_RECONNECT: /* Reconnect without any waiting period */ rpki_close_connection(cache); rpki_cache_change_state(cache, RPKI_CS_CONNECTING); break; case RPKI_CS_SHUTDOWN: bug("This isn't never really called."); break; }; } /* * RPKI Timer Events */ static void rpki_schedule_next_refresh(struct rpki_cache *cache) { btime t = cache->refresh_interval S; CACHE_DBG(cache, "after %t s", t); tm_start(cache->refresh_timer, t); } static void rpki_schedule_next_retry(struct rpki_cache *cache) { btime t = cache->retry_interval S; CACHE_DBG(cache, "after %t s", t); tm_start(cache->retry_timer, t); } static void rpki_schedule_next_expire_check(struct rpki_cache *cache) { /* A minimum time to wait is 1 second */ btime t = cache->last_update + cache->expire_interval S - current_time(); t = MAX(t, 1 S); CACHE_DBG(cache, "after %t s", t); tm_start(cache->expire_timer, t); } static void rpki_stop_refresh_timer_event(struct rpki_cache *cache) { CACHE_DBG(cache, "Stop"); tm_stop(cache->refresh_timer); } static void rpki_stop_retry_timer_event(struct rpki_cache *cache) { CACHE_DBG(cache, "Stop"); tm_stop(cache->retry_timer); } static void UNUSED rpki_stop_expire_timer_event(struct rpki_cache *cache) { CACHE_DBG(cache, "Stop"); tm_stop(cache->expire_timer); } static int rpki_do_we_recv_prefix_pdu_in_last_seconds(struct rpki_cache *cache) { if (!cache->last_rx_prefix) return 0; return ((current_time() - cache->last_rx_prefix) <= 2 S); } /** * rpki_refresh_hook - control a scheduling of downloading data from cache server * @tm: refresh timer with cache connection instance in data * * This function is periodically called during &ESTABLISHED or &SYNC* state * cache connection. The first refresh schedule is invoked after receiving a * |End of Data| PDU and has run by some &ERROR is occurred. */ static void rpki_refresh_hook(timer *tm) { struct rpki_cache *cache = tm->data; CACHE_DBG(cache, "%s", rpki_cache_state_to_str(cache->state)); switch (cache->state) { case RPKI_CS_ESTABLISHED: rpki_cache_change_state(cache, RPKI_CS_SYNC_START); break; case RPKI_CS_SYNC_START: /* We sent Serial/Reset Query in last refresh hook call * and didn't receive Cache Response yet. It is probably * troubles with network. */ case RPKI_CS_SYNC_RUNNING: /* We sent Serial/Reset Query in last refresh hook call * and we got Cache Response but didn't get End-Of-Data yet. * It could be a trouble with network or only too long synchronization. */ if (!rpki_do_we_recv_prefix_pdu_in_last_seconds(cache)) { CACHE_TRACE(D_EVENTS, cache, "Sync takes more time than refresh interval %us, resetting connection", cache->refresh_interval); rpki_cache_change_state(cache, RPKI_CS_ERROR_TRANSPORT); } break; default: break; } if (cache->state != RPKI_CS_SHUTDOWN && cache->state != RPKI_CS_ERROR_TRANSPORT) rpki_schedule_next_refresh(cache); else rpki_stop_refresh_timer_event(cache); } /** * rpki_retry_hook - control a scheduling of retrying connection to cache server * @tm: retry timer with cache connection instance in data * * This function is periodically called during &ERROR* state cache connection. * The first retry schedule is invoked after any &ERROR* state occurred and * ends by reaching of &ESTABLISHED state again. */ static void rpki_retry_hook(timer *tm) { struct rpki_cache *cache = tm->data; CACHE_DBG(cache, "%s", rpki_cache_state_to_str(cache->state)); switch (cache->state) { case RPKI_CS_ESTABLISHED: case RPKI_CS_SHUTDOWN: break; case RPKI_CS_CONNECTING: case RPKI_CS_SYNC_START: case RPKI_CS_SYNC_RUNNING: if (!rpki_do_we_recv_prefix_pdu_in_last_seconds(cache)) { /* We tried to establish a connection in last retry hook call and haven't done * yet. It looks like troubles with network. We are aggressive here. */ CACHE_TRACE(D_EVENTS, cache, "Sync takes more time than retry interval %us, resetting connection.", cache->retry_interval); rpki_cache_change_state(cache, RPKI_CS_ERROR_TRANSPORT); } break; default: rpki_cache_change_state(cache, RPKI_CS_CONNECTING); break; } if (cache->state != RPKI_CS_ESTABLISHED) rpki_schedule_next_retry(cache); else rpki_stop_retry_timer_event(cache); } /** * rpki_expire_hook - control a expiration of ROA entries * @tm: expire timer with cache connection instance in data * * This function is scheduled after received a |End of Data| PDU. * A waiting interval is calculated dynamically by last update. * If we reach an expiration time then we invoke a restarting * of the protocol. */ static void rpki_expire_hook(timer *tm) { struct rpki_cache *cache = tm->data; if (!cache->last_update) return; CACHE_DBG(cache, "%s", rpki_cache_state_to_str(cache->state)); btime t = cache->last_update + cache->expire_interval S - current_time(); if (t <= 0) { CACHE_TRACE(D_EVENTS, cache, "All ROAs expired"); rpki_force_restart_proto(cache->p); } else { CACHE_DBG(cache, "Remains %t seconds to become ROAs obsolete", t); rpki_schedule_next_expire_check(cache); } } /** * rpki_check_refresh_interval - check validity of refresh interval value * @seconds: suggested value * * This function validates value and should return |NULL|. * If the check doesn't pass then returns error message. */ const char * rpki_check_refresh_interval(uint seconds) { if (seconds < 1) return "Minimum allowed refresh interval is 1 second"; if (seconds > 86400) return "Maximum allowed refresh interval is 86400 seconds"; return NULL; } /** * rpki_check_retry_interval - check validity of retry interval value * @seconds: suggested value * * This function validates value and should return |NULL|. * If the check doesn't pass then returns error message. */ const char * rpki_check_retry_interval(uint seconds) { if (seconds < 1) return "Minimum allowed retry interval is 1 second"; if (seconds > 7200) return "Maximum allowed retry interval is 7200 seconds"; return NULL; } /** * rpki_check_expire_interval - check validity of expire interval value * @seconds: suggested value * * This function validates value and should return |NULL|. * If the check doesn't pass then returns error message. */ const char * rpki_check_expire_interval(uint seconds) { if (seconds < 600) return "Minimum allowed expire interval is 600 seconds"; if (seconds > 172800) return "Maximum allowed expire interval is 172800 seconds"; return NULL; } /* * RPKI Cache */ static struct rpki_cache * rpki_init_cache(struct rpki_proto *p, struct rpki_config *cf) { pool *pool = rp_new(p->p.pool, cf->hostname); struct rpki_cache *cache = mb_allocz(pool, sizeof(struct rpki_cache)); cache->pool = pool; cache->p = p; cache->state = RPKI_CS_SHUTDOWN; cache->request_session_id = 1; cache->version = RPKI_MAX_VERSION; cache->refresh_interval = cf->refresh_interval; cache->retry_interval = cf->retry_interval; cache->expire_interval = cf->expire_interval; cache->refresh_timer = tm_new_init(pool, &rpki_refresh_hook, cache, 0, 0); cache->retry_timer = tm_new_init(pool, &rpki_retry_hook, cache, 0, 0); cache->expire_timer = tm_new_init(pool, &rpki_expire_hook, cache, 0, 0); cache->tr_sock = mb_allocz(pool, sizeof(struct rpki_tr_sock)); cache->tr_sock->cache = cache; switch (cf->tr_config.type) { case RPKI_TR_TCP: rpki_tr_tcp_init(cache->tr_sock); break; #if HAVE_LIBSSH case RPKI_TR_SSH: rpki_tr_ssh_init(cache->tr_sock); break; #endif }; CACHE_DBG(cache, "Connection object created"); return cache; } /** * rpki_get_cache_ident - give a text representation of cache server name * @cache: RPKI connection instance * * The function converts cache connection into string. */ const char * rpki_get_cache_ident(struct rpki_cache *cache) { return rpki_tr_ident(cache->tr_sock); } static int rpki_open_connection(struct rpki_cache *cache) { CACHE_TRACE(D_EVENTS, cache, "Opening a connection"); if (rpki_tr_open(cache->tr_sock) == RPKI_TR_ERROR) { rpki_cache_change_state(cache, RPKI_CS_ERROR_TRANSPORT); return RPKI_TR_ERROR; } return RPKI_TR_SUCCESS; } static void rpki_close_connection(struct rpki_cache *cache) { CACHE_TRACE(D_EVENTS, cache, "Closing a connection"); rpki_tr_close(cache->tr_sock); proto_notify_state(&cache->p->p, PS_START); } static int rpki_shutdown(struct proto *P) { struct rpki_proto *p = (void *) P; rpki_force_restart_proto(p); /* Protocol memory pool will be automatically freed */ return PS_DOWN; } /* * RPKI Reconfiguration */ /** * rpki_reconfigure_cache - a cache reconfiguration * @p: RPKI protocol instance * @cache: a cache connection * @new: new RPKI configuration * @old: old RPKI configuration * * This function reconfigures existing single cache server connection with new * existing configuration. Generally, a change of time intervals could be * reconfigured without restarting and all others changes requires a restart of * protocol. Returns |NEED_TO_RESTART| or |SUCCESSFUL_RECONF|. */ static int rpki_reconfigure_cache(struct rpki_proto *p UNUSED, struct rpki_cache *cache, struct rpki_config *new, struct rpki_config *old) { u8 try_reset = 0; u8 try_fast_reconnect = 0; if (strcmp(old->hostname, new->hostname) != 0) { CACHE_TRACE(D_EVENTS, cache, "Cache server address changed to %s", new->hostname); return NEED_RESTART; } if (old->port != new->port) { CACHE_TRACE(D_EVENTS, cache, "Cache server port changed to %u", new->port); return NEED_RESTART; } if (old->tr_config.type != new->tr_config.type) { CACHE_TRACE(D_EVENTS, cache, "Transport type changed"); return NEED_RESTART; } if (old->ignore_max_length != new->ignore_max_length) { CACHE_TRACE(D_EVENTS, cache, "Ignore max length changed"); try_reset = 1; } #if HAVE_LIBSSH else if (new->tr_config.type == RPKI_TR_SSH) { struct rpki_tr_ssh_config *ssh_old = (void *) old->tr_config.spec; struct rpki_tr_ssh_config *ssh_new = (void *) new->tr_config.spec; if (bstrcmp(ssh_old->bird_private_key, ssh_new->bird_private_key) || bstrcmp(ssh_old->cache_public_key, ssh_new->cache_public_key) || bstrcmp(ssh_old->user, ssh_new->user)) { CACHE_TRACE(D_EVENTS, cache, "Settings of SSH transport configuration changed"); try_fast_reconnect = 1; } } #endif #define TEST_INTERVAL(name, Name) \ if (old->name##_interval != new->name##_interval || \ old->keep_##name##_interval != new->keep_##name##_interval) \ { \ cache->name##_interval = new->name##_interval; \ CACHE_TRACE(D_EVENTS, cache, #Name " interval changed to %u seconds %s", cache->name##_interval, (new->keep_##name##_interval ? "and keep it" : "")); \ try_fast_reconnect = 1; \ } TEST_INTERVAL(refresh, Refresh); TEST_INTERVAL(retry, Retry); TEST_INTERVAL(expire, Expire); #undef TEST_INTERVAL if (try_reset || try_fast_reconnect) { if (cache->state != RPKI_CS_ESTABLISHED) return NEED_RESTART; if (try_reset && !try_fast_reconnect) rpki_cache_change_state(cache, RPKI_CS_RESET); if (try_fast_reconnect) { if (try_reset) { /* Force reset during reconnect */ cache->request_session_id = 1; cache->serial_num = 0; } rpki_cache_change_state(cache, RPKI_CS_FAST_RECONNECT); } } return SUCCESSFUL_RECONF; } /** * rpki_reconfigure - a protocol reconfiguration hook * @P: a protocol instance * @CF: a new protocol configuration * * This function reconfigures whole protocol. * It sets new protocol configuration into a protocol structure. * Returns |NEED_TO_RESTART| or |SUCCESSFUL_RECONF|. */ static int rpki_reconfigure(struct proto *P, struct proto_config *CF) { struct rpki_proto *p = (void *) P; struct rpki_config *new = (void *) CF; struct rpki_config *old = (void *) p->p.cf; struct rpki_cache *cache = p->cache; if (!proto_configure_channel(&p->p, &p->roa4_channel, proto_cf_find_channel(CF, NET_ROA4)) || !proto_configure_channel(&p->p, &p->roa6_channel, proto_cf_find_channel(CF, NET_ROA6))) return NEED_RESTART; if (rpki_reconfigure_cache(p, cache, new, old) != SUCCESSFUL_RECONF) return NEED_RESTART; return SUCCESSFUL_RECONF; } /* * RPKI Protocol Glue */ static struct proto * rpki_init(struct proto_config *CF) { struct proto *P = proto_new(CF); struct rpki_proto *p = (void *) P; proto_configure_channel(&p->p, &p->roa4_channel, proto_cf_find_channel(CF, NET_ROA4)); proto_configure_channel(&p->p, &p->roa6_channel, proto_cf_find_channel(CF, NET_ROA6)); return P; } static int rpki_start(struct proto *P) { struct rpki_proto *p = (void *) P; struct rpki_config *cf = (void *) P->cf; p->cache = rpki_init_cache(p, cf); rpki_start_cache(p->cache); return PS_START; } static void rpki_get_status(struct proto *P, byte *buf) { struct rpki_proto *p = (struct rpki_proto *) P; if (P->proto_state == PS_DOWN) { *buf = 0; return; } if (p->cache) bsprintf(buf, "%s", rpki_cache_state_to_str(p->cache->state)); else bsprintf(buf, "No cache server configured"); } static void rpki_show_proto_info_timer(const char *name, uint num, timer *t) { if (tm_active(t)) cli_msg(-1006, " %-16s: %t/%u", name, tm_remains(t), num); else cli_msg(-1006, " %-16s: ---", name); } static void rpki_show_proto_info(struct proto *P) { struct rpki_proto *p = (struct rpki_proto *) P; struct rpki_config *cf = (void *) p->p.cf; struct rpki_cache *cache = p->cache; if (P->proto_state == PS_DOWN) return; if (cache) { const char *transport_name = "---"; switch (cf->tr_config.type) { #if HAVE_LIBSSH case RPKI_TR_SSH: transport_name = "SSHv2"; break; #endif case RPKI_TR_TCP: transport_name = "Unprotected over TCP"; break; }; cli_msg(-1006, " Cache server: %s", cf->hostname); cli_msg(-1006, " Status: %s", rpki_cache_state_to_str(cache->state)); cli_msg(-1006, " Transport: %s", transport_name); cli_msg(-1006, " Protocol version: %u", cache->version); if (cache->request_session_id) cli_msg(-1006, " Session ID: ---"); else cli_msg(-1006, " Session ID: %u", cache->session_id); if (cache->last_update) { cli_msg(-1006, " Serial number: %u", cache->serial_num); cli_msg(-1006, " Last update: before %t s", current_time() - cache->last_update); } else { cli_msg(-1006, " Serial number: ---"); cli_msg(-1006, " Last update: ---"); } rpki_show_proto_info_timer("Refresh timer", cache->refresh_interval, cache->refresh_timer); rpki_show_proto_info_timer("Retry timer", cache->retry_interval, cache->retry_timer); rpki_show_proto_info_timer("Expire timer", cache->expire_interval, cache->expire_timer); if (p->roa4_channel) channel_show_info(p->roa4_channel); else cli_msg(-1006, " No roa4 channel"); if (p->roa6_channel) channel_show_info(p->roa6_channel); else cli_msg(-1006, " No roa6 channel"); } } /* * RPKI Protocol Configuration */ /** * rpki_check_config - check and complete configuration of RPKI protocol * @cf: RPKI configuration * * This function is called at the end of parsing RPKI protocol configuration. */ void rpki_check_config(struct rpki_config *cf) { /* Do not check templates at all */ if (cf->c.class == SYM_TEMPLATE) return; if (ipa_zero(cf->ip) && cf->hostname == NULL) cf_error("IP address or hostname of cache server must be set"); /* Set default transport type */ if (cf->tr_config.spec == NULL) { cf->tr_config.spec = cfg_allocz(sizeof(struct rpki_tr_tcp_config)); cf->tr_config.type = RPKI_TR_TCP; } if (cf->port == 0) { /* Set default port numbers */ switch (cf->tr_config.type) { #if HAVE_LIBSSH case RPKI_TR_SSH: cf->port = RPKI_SSH_PORT; break; #endif default: cf->port = RPKI_TCP_PORT; } } } static void rpki_postconfig(struct proto_config *CF) { /* Define default channel */ if (EMPTY_LIST(CF->channels)) cf_error("Channel not specified"); } static void rpki_copy_config(struct proto_config *dest UNUSED, struct proto_config *src UNUSED) { /* FIXME: Should copy transport */ } struct protocol proto_rpki = { .name = "RPKI", .template = "rpki%d", .preference = DEF_PREF_RPKI, .proto_size = sizeof(struct rpki_proto), .config_size = sizeof(struct rpki_config), .init = rpki_init, .start = rpki_start, .postconfig = rpki_postconfig, .channel_mask = (NB_ROA4 | NB_ROA6), .show_proto_info = rpki_show_proto_info, .shutdown = rpki_shutdown, .copy_config = rpki_copy_config, .reconfigure = rpki_reconfigure, .get_status = rpki_get_status, }; void rpki_build(void) { proto_build(&proto_rpki); }