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bird/proto/rpki/rpki.c
Maria Matejka 44e351d152 RPKI: retry timer doesn't reset connections when more data is pending
With very busy deployments, RPKI may kill cache connection too early.
Instead of that, we want it to keep loading if any data is waiting to
be read and the reason for delay is just our congestion.

Also, when we kill the session because of actually slow cache, we want
to reload from scratch as the data we have is unreliable and nobody
knows whether the state is still valid.
2023-12-20 11:58:07 +01:00

973 lines
27 KiB
C

/*
* BIRD -- The Resource Public Key Infrastructure (RPKI) to Router Protocol
*
* (c) 2015 CZ.NIC
* (c) 2015 Pavel Tvrdik <pawel.tvrdik@gmail.com>
*
* 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 <stdlib.h>
#include <netdb.h>
#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 = {
.pref = channel->preference,
.source = RTS_RPKI,
.scope = SCOPE_UNIVERSE,
.dest = RTD_NONE,
};
rta *a = rta_lookup(&a0);
rte *e = rte_get_temp(a, p->p.main_source);
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. */
case RPKI_CS_ERROR_NO_DATA_AVAIL:
/* No validation records are available on the cache server. */
if (old_state == RPKI_CS_ESTABLISHED)
rpki_cache_change_state(cache, RPKI_CS_RESET);
else
rpki_schedule_next_retry(cache);
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);
cache->request_session_id = 1;
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_sync_is_stuck(struct rpki_cache *cache)
{
return !sk_rx_ready(cache->tr_sock->sk) && (
!cache->last_rx_prefix || (current_time() - cache->last_rx_prefix > 10 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_sync_is_stuck(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_sync_is_stuck(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;
case RPKI_CS_NO_INCR_UPDATE_AVAIL:
case RPKI_CS_ERROR_NO_DATA_AVAIL:
rpki_cache_change_state(cache, RPKI_CS_RESET);
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 = "---";
uint default_port = 0;
switch (cf->tr_config.type)
{
#if HAVE_LIBSSH
case RPKI_TR_SSH:
transport_name = "SSHv2";
default_port = RPKI_SSH_PORT;
break;
#endif
case RPKI_TR_TCP:
transport_name = "Unprotected over TCP";
default_port = RPKI_TCP_PORT;
break;
};
cli_msg(-1006, " Cache server: %s", cf->hostname);
if (cf->port != default_port)
cli_msg(-1006, " Cache port: %u", cf->port);
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",
.class = PROTOCOL_RPKI,
.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);
}