/* $OpenBSD: mta.c,v 1.220 2018/07/08 13:06:37 gilles Exp $ */ /* * Copyright (c) 2008 Pierre-Yves Ritschard * Copyright (c) 2008 Gilles Chehade * Copyright (c) 2009 Jacek Masiulaniec * Copyright (c) 2012 Eric Faurot * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "smtpd.h" #include "log.h" #define MAXERROR_PER_ROUTE 4 #define DELAY_CHECK_SOURCE 1 #define DELAY_CHECK_SOURCE_SLOW 10 #define DELAY_CHECK_SOURCE_FAST 0 #define DELAY_CHECK_LIMIT 5 #define DELAY_QUADRATIC 1 #define DELAY_ROUTE_BASE 15 #define DELAY_ROUTE_MAX 3600 #define RELAY_ONHOLD 0x01 #define RELAY_HOLDQ 0x02 static void mta_handle_envelope(struct envelope *, const char *); static void mta_query_smarthost(struct envelope *); static void mta_on_smarthost(struct envelope *, const char *); static void mta_query_mx(struct mta_relay *); static void mta_query_secret(struct mta_relay *); static void mta_query_preference(struct mta_relay *); static void mta_query_source(struct mta_relay *); static void mta_on_mx(void *, void *, void *); static void mta_on_secret(struct mta_relay *, const char *); static void mta_on_preference(struct mta_relay *, int); static void mta_on_source(struct mta_relay *, struct mta_source *); static void mta_on_timeout(struct runq *, void *); static void mta_connect(struct mta_connector *); static void mta_route_enable(struct mta_route *); static void mta_route_disable(struct mta_route *, int, int); static void mta_drain(struct mta_relay *); static void mta_delivery_flush_event(int, short, void *); static void mta_flush(struct mta_relay *, int, const char *); static struct mta_route *mta_find_route(struct mta_connector *, time_t, int*, time_t*); static void mta_log(const struct mta_envelope *, const char *, const char *, const char *, const char *); SPLAY_HEAD(mta_relay_tree, mta_relay); static struct mta_relay *mta_relay(struct envelope *, struct relayhost *); static void mta_relay_ref(struct mta_relay *); static void mta_relay_unref(struct mta_relay *); static void mta_relay_show(struct mta_relay *, struct mproc *, uint32_t, time_t); static int mta_relay_cmp(const struct mta_relay *, const struct mta_relay *); SPLAY_PROTOTYPE(mta_relay_tree, mta_relay, entry, mta_relay_cmp); SPLAY_HEAD(mta_host_tree, mta_host); static struct mta_host *mta_host(const struct sockaddr *); static void mta_host_ref(struct mta_host *); static void mta_host_unref(struct mta_host *); static int mta_host_cmp(const struct mta_host *, const struct mta_host *); SPLAY_PROTOTYPE(mta_host_tree, mta_host, entry, mta_host_cmp); SPLAY_HEAD(mta_domain_tree, mta_domain); static struct mta_domain *mta_domain(char *, int); #if 0 static void mta_domain_ref(struct mta_domain *); #endif static void mta_domain_unref(struct mta_domain *); static int mta_domain_cmp(const struct mta_domain *, const struct mta_domain *); SPLAY_PROTOTYPE(mta_domain_tree, mta_domain, entry, mta_domain_cmp); SPLAY_HEAD(mta_source_tree, mta_source); static struct mta_source *mta_source(const struct sockaddr *); static void mta_source_ref(struct mta_source *); static void mta_source_unref(struct mta_source *); static const char *mta_source_to_text(struct mta_source *); static int mta_source_cmp(const struct mta_source *, const struct mta_source *); SPLAY_PROTOTYPE(mta_source_tree, mta_source, entry, mta_source_cmp); static struct mta_connector *mta_connector(struct mta_relay *, struct mta_source *); static void mta_connector_free(struct mta_connector *); static const char *mta_connector_to_text(struct mta_connector *); SPLAY_HEAD(mta_route_tree, mta_route); static struct mta_route *mta_route(struct mta_source *, struct mta_host *); static void mta_route_ref(struct mta_route *); static void mta_route_unref(struct mta_route *); static const char *mta_route_to_text(struct mta_route *); static int mta_route_cmp(const struct mta_route *, const struct mta_route *); SPLAY_PROTOTYPE(mta_route_tree, mta_route, entry, mta_route_cmp); struct mta_block { SPLAY_ENTRY(mta_block) entry; struct mta_source *source; char *domain; }; SPLAY_HEAD(mta_block_tree, mta_block); void mta_block(struct mta_source *, char *); void mta_unblock(struct mta_source *, char *); int mta_is_blocked(struct mta_source *, char *); static int mta_block_cmp(const struct mta_block *, const struct mta_block *); SPLAY_PROTOTYPE(mta_block_tree, mta_block, entry, mta_block_cmp); static struct mta_relay_tree relays; static struct mta_domain_tree domains; static struct mta_host_tree hosts; static struct mta_source_tree sources; static struct mta_route_tree routes; static struct mta_block_tree blocks; static struct tree wait_mx; static struct tree wait_preference; static struct tree wait_secret; static struct tree wait_smarthost; static struct tree wait_source; static struct tree flush_evp; static struct event ev_flush_evp; static struct runq *runq_relay; static struct runq *runq_connector; static struct runq *runq_route; static struct runq *runq_hoststat; static time_t max_seen_conndelay_route; static time_t max_seen_discdelay_route; #define HOSTSTAT_EXPIRE_DELAY (4 * 3600) struct hoststat { char name[HOST_NAME_MAX+1]; time_t tm; char error[LINE_MAX]; struct tree deferred; }; static struct dict hoststat; void mta_hoststat_update(const char *, const char *); void mta_hoststat_cache(const char *, uint64_t); void mta_hoststat_uncache(const char *, uint64_t); void mta_hoststat_reschedule(const char *); static void mta_hoststat_remove_entry(struct hoststat *); void mta_imsg(struct mproc *p, struct imsg *imsg) { struct mta_relay *relay; struct mta_domain *domain; struct mta_host *host; struct mta_route *route; struct mta_block *block; struct mta_mx *mx, *imx; struct mta_source *source; struct hoststat *hs; struct sockaddr_storage ss; struct envelope evp, *e; struct msg m; const char *secret; const char *hostname; const char *dom; const char *smarthost; uint64_t reqid; time_t t; char buf[LINE_MAX]; int dnserror, preference, v, status; void *iter; uint64_t u64; switch (imsg->hdr.type) { case IMSG_QUEUE_TRANSFER: m_msg(&m, imsg); m_get_envelope(&m, &evp); m_end(&m); mta_handle_envelope(&evp, NULL); return; case IMSG_MTA_OPEN_MESSAGE: mta_session_imsg(p, imsg); return; case IMSG_MTA_LOOKUP_CREDENTIALS: m_msg(&m, imsg); m_get_id(&m, &reqid); m_get_string(&m, &secret); m_end(&m); relay = tree_xpop(&wait_secret, reqid); mta_on_secret(relay, secret[0] ? secret : NULL); return; case IMSG_MTA_LOOKUP_SOURCE: m_msg(&m, imsg); m_get_id(&m, &reqid); m_get_int(&m, &status); if (status == LKA_OK) m_get_sockaddr(&m, (struct sockaddr*)&ss); m_end(&m); relay = tree_xpop(&wait_source, reqid); mta_on_source(relay, (status == LKA_OK) ? mta_source((struct sockaddr *)&ss) : NULL); return; case IMSG_MTA_LOOKUP_SMARTHOST: m_msg(&m, imsg); m_get_id(&m, &reqid); m_get_int(&m, &status); smarthost = NULL; if (status == LKA_OK) m_get_string(&m, &smarthost); m_end(&m); e = tree_xpop(&wait_smarthost, reqid); mta_on_smarthost(e, smarthost); return; case IMSG_MTA_LOOKUP_HELO: mta_session_imsg(p, imsg); return; case IMSG_MTA_DNS_HOST: m_msg(&m, imsg); m_get_id(&m, &reqid); m_get_sockaddr(&m, (struct sockaddr*)&ss); m_get_int(&m, &preference); m_end(&m); domain = tree_xget(&wait_mx, reqid); mx = xcalloc(1, sizeof *mx); mx->host = mta_host((struct sockaddr*)&ss); mx->preference = preference; TAILQ_FOREACH(imx, &domain->mxs, entry) { if (imx->preference > mx->preference) { TAILQ_INSERT_BEFORE(imx, mx, entry); return; } } TAILQ_INSERT_TAIL(&domain->mxs, mx, entry); return; case IMSG_MTA_DNS_HOST_END: m_msg(&m, imsg); m_get_id(&m, &reqid); m_get_int(&m, &dnserror); m_end(&m); domain = tree_xpop(&wait_mx, reqid); domain->mxstatus = dnserror; if (domain->mxstatus == DNS_OK) { log_debug("debug: MXs for domain %s:", domain->name); TAILQ_FOREACH(mx, &domain->mxs, entry) log_debug(" %s preference %d", sa_to_text(mx->host->sa), mx->preference); } else { log_debug("debug: Failed MX query for %s:", domain->name); } domain->lastmxquery = time(NULL); waitq_run(&domain->mxs, domain); return; case IMSG_MTA_DNS_MX_PREFERENCE: m_msg(&m, imsg); m_get_id(&m, &reqid); m_get_int(&m, &dnserror); if (dnserror == 0) m_get_int(&m, &preference); m_end(&m); relay = tree_xpop(&wait_preference, reqid); if (dnserror) { log_warnx("warn: Couldn't find backup " "preference for %s: error %d", mta_relay_to_text(relay), dnserror); preference = INT_MAX; } mta_on_preference(relay, preference); return; case IMSG_MTA_DNS_PTR: mta_session_imsg(p, imsg); return; case IMSG_MTA_TLS_INIT: mta_session_imsg(p, imsg); return; case IMSG_MTA_TLS_VERIFY: mta_session_imsg(p, imsg); return; case IMSG_CTL_RESUME_ROUTE: u64 = *((uint64_t *)imsg->data); if (u64) log_debug("resuming route: %llu", (unsigned long long)u64); else log_debug("resuming all routes"); SPLAY_FOREACH(route, mta_route_tree, &routes) { if (u64 && route->id != u64) continue; if (route->flags & ROUTE_DISABLED) { log_info("smtp-out: Enabling route %s per admin request", mta_route_to_text(route)); if (!runq_cancel(runq_route, NULL, route)) { log_warnx("warn: route not on runq"); fatalx("exiting"); } route->flags &= ~ROUTE_DISABLED; route->flags |= ROUTE_NEW; route->nerror = 0; route->penalty = 0; mta_route_unref(route); /* from mta_route_disable */ } if (u64) break; } return; case IMSG_CTL_MTA_SHOW_HOSTS: t = time(NULL); SPLAY_FOREACH(host, mta_host_tree, &hosts) { (void)snprintf(buf, sizeof(buf), "%s %s refcount=%d nconn=%zu lastconn=%s", sockaddr_to_text(host->sa), host->ptrname, host->refcount, host->nconn, host->lastconn ? duration_to_text(t - host->lastconn) : "-"); m_compose(p, IMSG_CTL_MTA_SHOW_HOSTS, imsg->hdr.peerid, 0, -1, buf, strlen(buf) + 1); } m_compose(p, IMSG_CTL_MTA_SHOW_HOSTS, imsg->hdr.peerid, 0, -1, NULL, 0); return; case IMSG_CTL_MTA_SHOW_RELAYS: t = time(NULL); SPLAY_FOREACH(relay, mta_relay_tree, &relays) mta_relay_show(relay, p, imsg->hdr.peerid, t); m_compose(p, IMSG_CTL_MTA_SHOW_RELAYS, imsg->hdr.peerid, 0, -1, NULL, 0); return; case IMSG_CTL_MTA_SHOW_ROUTES: SPLAY_FOREACH(route, mta_route_tree, &routes) { v = runq_pending(runq_route, NULL, route, &t); (void)snprintf(buf, sizeof(buf), "%llu. %s %c%c%c%c nconn=%zu nerror=%d penalty=%d timeout=%s", (unsigned long long)route->id, mta_route_to_text(route), route->flags & ROUTE_NEW ? 'N' : '-', route->flags & ROUTE_DISABLED ? 'D' : '-', route->flags & ROUTE_RUNQ ? 'Q' : '-', route->flags & ROUTE_KEEPALIVE ? 'K' : '-', route->nconn, route->nerror, route->penalty, v ? duration_to_text(t - time(NULL)) : "-"); m_compose(p, IMSG_CTL_MTA_SHOW_ROUTES, imsg->hdr.peerid, 0, -1, buf, strlen(buf) + 1); } m_compose(p, IMSG_CTL_MTA_SHOW_ROUTES, imsg->hdr.peerid, 0, -1, NULL, 0); return; case IMSG_CTL_MTA_SHOW_HOSTSTATS: iter = NULL; while (dict_iter(&hoststat, &iter, &hostname, (void **)&hs)) { (void)snprintf(buf, sizeof(buf), "%s|%llu|%s", hostname, (unsigned long long) hs->tm, hs->error); m_compose(p, IMSG_CTL_MTA_SHOW_HOSTSTATS, imsg->hdr.peerid, 0, -1, buf, strlen(buf) + 1); } m_compose(p, IMSG_CTL_MTA_SHOW_HOSTSTATS, imsg->hdr.peerid, 0, -1, NULL, 0); return; case IMSG_CTL_MTA_BLOCK: m_msg(&m, imsg); m_get_sockaddr(&m, (struct sockaddr*)&ss); m_get_string(&m, &dom); m_end(&m); source = mta_source((struct sockaddr*)&ss); if (*dom != '\0') { if (!(strlcpy(buf, dom, sizeof(buf)) >= sizeof(buf))) mta_block(source, buf); } else mta_block(source, NULL); mta_source_unref(source); m_compose(p, IMSG_CTL_OK, imsg->hdr.peerid, 0, -1, NULL, 0); return; case IMSG_CTL_MTA_UNBLOCK: m_msg(&m, imsg); m_get_sockaddr(&m, (struct sockaddr*)&ss); m_get_string(&m, &dom); m_end(&m); source = mta_source((struct sockaddr*)&ss); if (*dom != '\0') { if (!(strlcpy(buf, dom, sizeof(buf)) >= sizeof(buf))) mta_unblock(source, buf); } else mta_unblock(source, NULL); mta_source_unref(source); m_compose(p, IMSG_CTL_OK, imsg->hdr.peerid, 0, -1, NULL, 0); return; case IMSG_CTL_MTA_SHOW_BLOCK: SPLAY_FOREACH(block, mta_block_tree, &blocks) { (void)snprintf(buf, sizeof(buf), "%s -> %s", mta_source_to_text(block->source), block->domain ? block->domain : "*"); m_compose(p, IMSG_CTL_MTA_SHOW_BLOCK, imsg->hdr.peerid, 0, -1, buf, strlen(buf) + 1); } m_compose(p, IMSG_CTL_MTA_SHOW_BLOCK, imsg->hdr.peerid, 0, -1, NULL, 0); return; } errx(1, "mta_imsg: unexpected %s imsg", imsg_to_str(imsg->hdr.type)); } void mta_postfork(void) { } void mta_postprivdrop(void) { SPLAY_INIT(&relays); SPLAY_INIT(&domains); SPLAY_INIT(&hosts); SPLAY_INIT(&sources); SPLAY_INIT(&routes); SPLAY_INIT(&blocks); tree_init(&wait_secret); tree_init(&wait_smarthost); tree_init(&wait_mx); tree_init(&wait_preference); tree_init(&wait_source); tree_init(&flush_evp); dict_init(&hoststat); evtimer_set(&ev_flush_evp, mta_delivery_flush_event, NULL); runq_init(&runq_relay, mta_on_timeout); runq_init(&runq_connector, mta_on_timeout); runq_init(&runq_route, mta_on_timeout); runq_init(&runq_hoststat, mta_on_timeout); } /* * Local error on the given source. */ void mta_source_error(struct mta_relay *relay, struct mta_route *route, const char *e) { struct mta_connector *c; /* * Remember the source as broken for this connector. */ c = mta_connector(relay, route->src); if (!(c->flags & CONNECTOR_ERROR_SOURCE)) log_info("smtp-out: Error on %s: %s", mta_route_to_text(route), e); c->flags |= CONNECTOR_ERROR_SOURCE; } void mta_route_error(struct mta_relay *relay, struct mta_route *route) { #if 0 route->nerror += 1; if (route->nerror > MAXERROR_PER_ROUTE) { log_info("smtp-out: Too many errors on %s: " "disabling for a while", mta_route_to_text(route)); mta_route_disable(route, 2, ROUTE_DISABLED_SMTP); } #endif } void mta_route_ok(struct mta_relay *relay, struct mta_route *route) { struct mta_connector *c; if (!(route->flags & ROUTE_NEW)) return; log_debug("debug: mta-routing: route %s is now valid.", mta_route_to_text(route)); route->nerror = 0; route->flags &= ~ROUTE_NEW; c = mta_connector(relay, route->src); mta_connect(c); } void mta_route_down(struct mta_relay *relay, struct mta_route *route) { #if 0 mta_route_disable(route, 2, ROUTE_DISABLED_SMTP); #endif } void mta_route_collect(struct mta_relay *relay, struct mta_route *route) { struct mta_connector *c; log_debug("debug: mta_route_collect(%s)", mta_route_to_text(route)); relay->nconn -= 1; relay->domain->nconn -= 1; route->nconn -= 1; route->src->nconn -= 1; route->dst->nconn -= 1; route->lastdisc = time(NULL); /* First connection failed */ if (route->flags & ROUTE_NEW) mta_route_disable(route, 1, ROUTE_DISABLED_NET); c = mta_connector(relay, route->src); c->nconn -= 1; mta_connect(c); mta_route_unref(route); /* from mta_find_route() */ mta_relay_unref(relay); /* from mta_connect() */ } struct mta_task * mta_route_next_task(struct mta_relay *relay, struct mta_route *route) { struct mta_task *task; if ((task = TAILQ_FIRST(&relay->tasks))) { TAILQ_REMOVE(&relay->tasks, task, entry); relay->ntask -= 1; task->relay = NULL; /* When the number of tasks is down to lowat, query some evp */ if (relay->ntask == (size_t)relay->limits->task_lowat) { if (relay->state & RELAY_ONHOLD) { log_info("smtp-out: back to lowat on %s: releasing", mta_relay_to_text(relay)); relay->state &= ~RELAY_ONHOLD; } if (relay->state & RELAY_HOLDQ) { m_create(p_queue, IMSG_MTA_HOLDQ_RELEASE, 0, 0, -1); m_add_id(p_queue, relay->id); m_add_int(p_queue, relay->limits->task_release); m_close(p_queue); } } else if (relay->ntask == 0 && relay->state & RELAY_HOLDQ) { m_create(p_queue, IMSG_MTA_HOLDQ_RELEASE, 0, 0, -1); m_add_id(p_queue, relay->id); m_add_int(p_queue, 0); m_close(p_queue); } } return (task); } static void mta_handle_envelope(struct envelope *evp, const char *smarthost) { struct mta_relay *relay; struct mta_task *task; struct mta_envelope *e; struct dispatcher *dispatcher; struct mailaddr maddr; struct relayhost relayh; char buf[LINE_MAX]; dispatcher = dict_xget(env->sc_dispatchers, evp->dispatcher); if (dispatcher->u.remote.smarthost && smarthost == NULL) { mta_query_smarthost(evp); return; } memset(&relayh, 0, sizeof(relayh)); if (smarthost && !text_to_relayhost(&relayh, smarthost)) { log_warnx("warn: Failed to parse smarthost %s", smarthost); m_create(p_queue, IMSG_MTA_DELIVERY_TEMPFAIL, 0, 0, -1); m_add_evpid(p_queue, evp->id); m_add_string(p_queue, "Cannot parse smarthost"); m_add_int(p_queue, ESC_OTHER_STATUS); m_close(p_queue); return; } relay = mta_relay(evp, &relayh); /* ignore if we don't know the limits yet */ if (relay->limits && relay->ntask >= (size_t)relay->limits->task_hiwat) { if (!(relay->state & RELAY_ONHOLD)) { log_info("smtp-out: hiwat reached on %s: holding envelopes", mta_relay_to_text(relay)); relay->state |= RELAY_ONHOLD; } } /* * If the relay has too many pending tasks, tell the * scheduler to hold it until further notice */ if (relay->state & RELAY_ONHOLD) { relay->state |= RELAY_HOLDQ; m_create(p_queue, IMSG_MTA_DELIVERY_HOLD, 0, 0, -1); m_add_evpid(p_queue, evp->id); m_add_id(p_queue, relay->id); m_close(p_queue); mta_relay_unref(relay); /* from here */ return; } task = NULL; TAILQ_FOREACH(task, &relay->tasks, entry) if (task->msgid == evpid_to_msgid(evp->id)) break; if (task == NULL) { task = xmalloc(sizeof *task); TAILQ_INIT(&task->envelopes); task->relay = relay; relay->ntask += 1; TAILQ_INSERT_TAIL(&relay->tasks, task, entry); task->msgid = evpid_to_msgid(evp->id); if (evp->sender.user[0] || evp->sender.domain[0]) (void)snprintf(buf, sizeof buf, "%s@%s", evp->sender.user, evp->sender.domain); else buf[0] = '\0'; if (dispatcher->u.remote.mail_from && evp->sender.user[0]) { memset(&maddr, 0, sizeof (maddr)); if (text_to_mailaddr(&maddr, dispatcher->u.remote.mail_from)) { (void)snprintf(buf, sizeof buf, "%s@%s", maddr.user[0] ? maddr.user : evp->sender.user, maddr.domain[0] ? maddr.domain : evp->sender.domain); } } task->sender = xstrdup(buf); stat_increment("mta.task", 1); } e = xcalloc(1, sizeof *e); e->id = evp->id; e->creation = evp->creation; e->smtpname = xstrdup(evp->smtpname); (void)snprintf(buf, sizeof buf, "%s@%s", evp->dest.user, evp->dest.domain); e->dest = xstrdup(buf); (void)snprintf(buf, sizeof buf, "%s@%s", evp->rcpt.user, evp->rcpt.domain); if (strcmp(buf, e->dest)) e->rcpt = xstrdup(buf); e->task = task; if (evp->dsn_orcpt.user[0] && evp->dsn_orcpt.domain[0]) { (void)snprintf(buf, sizeof buf, "%s@%s", evp->dsn_orcpt.user, evp->dsn_orcpt.domain); e->dsn_orcpt = xstrdup(buf); } (void)strlcpy(e->dsn_envid, evp->dsn_envid, sizeof e->dsn_envid); e->dsn_notify = evp->dsn_notify; e->dsn_ret = evp->dsn_ret; TAILQ_INSERT_TAIL(&task->envelopes, e, entry); log_debug("debug: mta: received evp:%016" PRIx64 " for <%s>", e->id, e->dest); stat_increment("mta.envelope", 1); mta_drain(relay); mta_relay_unref(relay); /* from here */ } static void mta_delivery_flush_event(int fd, short event, void *arg) { struct mta_envelope *e; struct timeval tv; if (tree_poproot(&flush_evp, NULL, (void**)(&e))) { if (e->delivery == IMSG_MTA_DELIVERY_OK) { m_create(p_queue, IMSG_MTA_DELIVERY_OK, 0, 0, -1); m_add_evpid(p_queue, e->id); m_add_int(p_queue, e->ext); m_close(p_queue); } else if (e->delivery == IMSG_MTA_DELIVERY_TEMPFAIL) { m_create(p_queue, IMSG_MTA_DELIVERY_TEMPFAIL, 0, 0, -1); m_add_evpid(p_queue, e->id); m_add_string(p_queue, e->status); m_add_int(p_queue, ESC_OTHER_STATUS); m_close(p_queue); } else if (e->delivery == IMSG_MTA_DELIVERY_PERMFAIL) { m_create(p_queue, IMSG_MTA_DELIVERY_PERMFAIL, 0, 0, -1); m_add_evpid(p_queue, e->id); m_add_string(p_queue, e->status); m_add_int(p_queue, ESC_OTHER_STATUS); m_close(p_queue); } else if (e->delivery == IMSG_MTA_DELIVERY_LOOP) { m_create(p_queue, IMSG_MTA_DELIVERY_LOOP, 0, 0, -1); m_add_evpid(p_queue, e->id); m_close(p_queue); } else { log_warnx("warn: bad delivery type %d for %016" PRIx64, e->delivery, e->id); fatalx("aborting"); } log_debug("debug: mta: flush for %016"PRIx64" (-> %s)", e->id, e->dest); free(e->smtpname); free(e->dest); free(e->rcpt); free(e->dsn_orcpt); free(e); tv.tv_sec = 0; tv.tv_usec = 0; evtimer_add(&ev_flush_evp, &tv); } } void mta_delivery_log(struct mta_envelope *e, const char *source, const char *relay, int delivery, const char *status) { if (delivery == IMSG_MTA_DELIVERY_OK) mta_log(e, "Ok", source, relay, status); else if (delivery == IMSG_MTA_DELIVERY_TEMPFAIL) mta_log(e, "TempFail", source, relay, status); else if (delivery == IMSG_MTA_DELIVERY_PERMFAIL) mta_log(e, "PermFail", source, relay, status); else if (delivery == IMSG_MTA_DELIVERY_LOOP) mta_log(e, "PermFail", source, relay, "Loop detected"); else { log_warnx("warn: bad delivery type %d for %016" PRIx64, delivery, e->id); fatalx("aborting"); } e->delivery = delivery; if (status) (void)strlcpy(e->status, status, sizeof(e->status)); } void mta_delivery_notify(struct mta_envelope *e) { struct timeval tv; tree_xset(&flush_evp, e->id, e); if (tree_count(&flush_evp) == 1) { tv.tv_sec = 0; tv.tv_usec = 0; evtimer_add(&ev_flush_evp, &tv); } } static void mta_query_mx(struct mta_relay *relay) { uint64_t id; if (relay->status & RELAY_WAIT_MX) return; log_debug("debug: mta: querying MX for %s...", mta_relay_to_text(relay)); if (waitq_wait(&relay->domain->mxs, mta_on_mx, relay)) { id = generate_uid(); tree_xset(&wait_mx, id, relay->domain); if (relay->domain->flags) m_create(p_lka, IMSG_MTA_DNS_HOST, 0, 0, -1); else m_create(p_lka, IMSG_MTA_DNS_MX, 0, 0, -1); m_add_id(p_lka, id); m_add_string(p_lka, relay->domain->name); m_close(p_lka); } relay->status |= RELAY_WAIT_MX; mta_relay_ref(relay); } static void mta_query_limits(struct mta_relay *relay) { if (relay->status & RELAY_WAIT_LIMITS) return; relay->limits = dict_get(env->sc_limits_dict, relay->domain->name); if (relay->limits == NULL) relay->limits = dict_get(env->sc_limits_dict, "default"); if (max_seen_conndelay_route < relay->limits->conndelay_route) max_seen_conndelay_route = relay->limits->conndelay_route; if (max_seen_discdelay_route < relay->limits->discdelay_route) max_seen_discdelay_route = relay->limits->discdelay_route; } static void mta_query_secret(struct mta_relay *relay) { if (relay->status & RELAY_WAIT_SECRET) return; log_debug("debug: mta: querying secret for %s...", mta_relay_to_text(relay)); tree_xset(&wait_secret, relay->id, relay); relay->status |= RELAY_WAIT_SECRET; m_create(p_lka, IMSG_MTA_LOOKUP_CREDENTIALS, 0, 0, -1); m_add_id(p_lka, relay->id); m_add_string(p_lka, relay->authtable); m_add_string(p_lka, relay->authlabel); m_close(p_lka); mta_relay_ref(relay); } static void mta_query_smarthost(struct envelope *evp0) { struct dispatcher *dispatcher; struct envelope *evp; evp = malloc(sizeof(*evp)); memmove(evp, evp0, sizeof(*evp)); dispatcher = dict_xget(env->sc_dispatchers, evp->dispatcher); log_debug("debug: mta: querying smarthost for %s:%s...", evp->dispatcher, dispatcher->u.remote.smarthost); tree_xset(&wait_smarthost, evp->id, evp); m_create(p_lka, IMSG_MTA_LOOKUP_SMARTHOST, 0, 0, -1); m_add_id(p_lka, evp->id); m_add_string(p_lka, dispatcher->u.remote.smarthost); m_close(p_lka); log_debug("debug: mta: querying smarthost"); } static void mta_query_preference(struct mta_relay *relay) { if (relay->status & RELAY_WAIT_PREFERENCE) return; log_debug("debug: mta: querying preference for %s...", mta_relay_to_text(relay)); tree_xset(&wait_preference, relay->id, relay); relay->status |= RELAY_WAIT_PREFERENCE; m_create(p_lka, IMSG_MTA_DNS_MX_PREFERENCE, 0, 0, -1); m_add_id(p_lka, relay->id); m_add_string(p_lka, relay->domain->name); m_add_string(p_lka, relay->backupname); m_close(p_lka); mta_relay_ref(relay); } static void mta_query_source(struct mta_relay *relay) { log_debug("debug: mta: querying source for %s...", mta_relay_to_text(relay)); relay->sourceloop += 1; if (relay->sourcetable == NULL) { /* * This is a recursive call, but it only happens once, since * another source will not be queried immediately. */ mta_relay_ref(relay); mta_on_source(relay, mta_source(NULL)); return; } m_create(p_lka, IMSG_MTA_LOOKUP_SOURCE, 0, 0, -1); m_add_id(p_lka, relay->id); m_add_string(p_lka, relay->sourcetable); m_close(p_lka); tree_xset(&wait_source, relay->id, relay); relay->status |= RELAY_WAIT_SOURCE; mta_relay_ref(relay); } static void mta_on_mx(void *tag, void *arg, void *data) { struct mta_domain *domain = data; struct mta_relay *relay = arg; log_debug("debug: mta: ... got mx (%p, %s, %s)", tag, domain->name, mta_relay_to_text(relay)); switch (domain->mxstatus) { case DNS_OK: break; case DNS_RETRY: relay->fail = IMSG_MTA_DELIVERY_TEMPFAIL; relay->failstr = "Temporary failure in MX lookup"; break; case DNS_EINVAL: relay->fail = IMSG_MTA_DELIVERY_PERMFAIL; relay->failstr = "Invalid domain name"; break; case DNS_ENONAME: relay->fail = IMSG_MTA_DELIVERY_PERMFAIL; relay->failstr = "Domain does not exist"; break; case DNS_ENOTFOUND: relay->fail = IMSG_MTA_DELIVERY_TEMPFAIL; relay->failstr = "No MX found for domain"; break; default: fatalx("bad DNS lookup error code"); break; } if (domain->mxstatus) log_info("smtp-out: Failed to resolve MX for %s: %s", mta_relay_to_text(relay), relay->failstr); relay->status &= ~RELAY_WAIT_MX; mta_drain(relay); mta_relay_unref(relay); /* from mta_drain() */ } static void mta_on_secret(struct mta_relay *relay, const char *secret) { log_debug("debug: mta: ... got secret for %s: %s", mta_relay_to_text(relay), secret); if (secret) relay->secret = strdup(secret); if (relay->secret == NULL) { log_warnx("warn: Failed to retrieve secret " "for %s", mta_relay_to_text(relay)); relay->fail = IMSG_MTA_DELIVERY_TEMPFAIL; relay->failstr = "Could not retrieve credentials"; } relay->status &= ~RELAY_WAIT_SECRET; mta_drain(relay); mta_relay_unref(relay); /* from mta_query_secret() */ } static void mta_on_smarthost(struct envelope *evp, const char *smarthost) { if (smarthost == NULL) { log_warnx("warn: Failed to retrieve smarthost " "for envelope %"PRIx64, evp->id); m_create(p_queue, IMSG_MTA_DELIVERY_TEMPFAIL, 0, 0, -1); m_add_evpid(p_queue, evp->id); m_add_string(p_queue, "Cannot retrieve smarthost"); m_add_int(p_queue, ESC_OTHER_STATUS); m_close(p_queue); return; } log_debug("debug: mta: ... got smarthost for %016"PRIx64": %s", evp->id, smarthost); mta_handle_envelope(evp, smarthost); free(evp); } static void mta_on_preference(struct mta_relay *relay, int preference) { log_debug("debug: mta: ... got preference for %s: %d", mta_relay_to_text(relay), preference); relay->backuppref = preference; relay->status &= ~RELAY_WAIT_PREFERENCE; mta_drain(relay); mta_relay_unref(relay); /* from mta_query_preference() */ } static void mta_on_source(struct mta_relay *relay, struct mta_source *source) { struct mta_connector *c; void *iter; int delay, errmask; log_debug("debug: mta: ... got source for %s: %s", mta_relay_to_text(relay), source ? mta_source_to_text(source) : "NULL"); relay->lastsource = time(NULL); delay = DELAY_CHECK_SOURCE_SLOW; if (source) { c = mta_connector(relay, source); if (c->flags & CONNECTOR_NEW) { c->flags &= ~CONNECTOR_NEW; delay = DELAY_CHECK_SOURCE; } mta_connect(c); if ((c->flags & CONNECTOR_ERROR) == 0) relay->sourceloop = 0; else delay = DELAY_CHECK_SOURCE_FAST; mta_source_unref(source); /* from constructor */ } else { log_warnx("warn: Failed to get source address for %s", mta_relay_to_text(relay)); } if (tree_count(&relay->connectors) == 0) { relay->fail = IMSG_MTA_DELIVERY_TEMPFAIL; relay->failstr = "Could not retrieve source address"; } if (tree_count(&relay->connectors) < relay->sourceloop) { relay->fail = IMSG_MTA_DELIVERY_TEMPFAIL; relay->failstr = "No valid route to remote MX"; errmask = 0; iter = NULL; while (tree_iter(&relay->connectors, &iter, NULL, (void **)&c)) errmask |= c->flags; if (errmask & CONNECTOR_ERROR_ROUTE_SMTP) relay->failstr = "Destination seem to reject all mails"; else if (errmask & CONNECTOR_ERROR_ROUTE_NET) relay->failstr = "Network error on destination MXs"; else if (errmask & CONNECTOR_ERROR_MX) relay->failstr = "No MX found for destination"; else if (errmask & CONNECTOR_ERROR_FAMILY) relay->failstr = "Address family mismatch on destination MXs"; else if (errmask & CONNECTOR_ERROR_BLOCKED) relay->failstr = "All routes to destination blocked"; else relay->failstr = "No valid route to destination"; } relay->nextsource = relay->lastsource + delay; relay->status &= ~RELAY_WAIT_SOURCE; mta_drain(relay); mta_relay_unref(relay); /* from mta_query_source() */ } static void mta_connect(struct mta_connector *c) { struct mta_route *route; struct mta_limits *l = c->relay->limits; int limits; time_t nextconn, now; /* toggle the block flag */ if (mta_is_blocked(c->source, c->relay->domain->name)) c->flags |= CONNECTOR_ERROR_BLOCKED; else c->flags &= ~CONNECTOR_ERROR_BLOCKED; again: log_debug("debug: mta: connecting with %s", mta_connector_to_text(c)); /* Do not connect if this connector has an error. */ if (c->flags & CONNECTOR_ERROR) { log_debug("debug: mta: connector error"); return; } if (c->flags & CONNECTOR_WAIT) { log_debug("debug: mta: cancelling connector timeout"); runq_cancel(runq_connector, NULL, c); c->flags &= ~CONNECTOR_WAIT; } /* No job. */ if (c->relay->ntask == 0) { log_debug("debug: mta: no task for connector"); return; } /* Do not create more connections than necessary */ if ((c->relay->nconn_ready >= c->relay->ntask) || (c->relay->nconn > 2 && c->relay->nconn >= c->relay->ntask / 2)) { log_debug("debug: mta: enough connections already"); return; } limits = 0; nextconn = now = time(NULL); if (c->relay->domain->lastconn + l->conndelay_domain > nextconn) { log_debug("debug: mta: cannot use domain %s before %llus", c->relay->domain->name, (unsigned long long) c->relay->domain->lastconn + l->conndelay_domain - now); nextconn = c->relay->domain->lastconn + l->conndelay_domain; } if (c->relay->domain->nconn >= l->maxconn_per_domain) { log_debug("debug: mta: hit domain limit"); limits |= CONNECTOR_LIMIT_DOMAIN; } if (c->source->lastconn + l->conndelay_source > nextconn) { log_debug("debug: mta: cannot use source %s before %llus", mta_source_to_text(c->source), (unsigned long long) c->source->lastconn + l->conndelay_source - now); nextconn = c->source->lastconn + l->conndelay_source; } if (c->source->nconn >= l->maxconn_per_source) { log_debug("debug: mta: hit source limit"); limits |= CONNECTOR_LIMIT_SOURCE; } if (c->lastconn + l->conndelay_connector > nextconn) { log_debug("debug: mta: cannot use %s before %llus", mta_connector_to_text(c), (unsigned long long) c->lastconn + l->conndelay_connector - now); nextconn = c->lastconn + l->conndelay_connector; } if (c->nconn >= l->maxconn_per_connector) { log_debug("debug: mta: hit connector limit"); limits |= CONNECTOR_LIMIT_CONN; } if (c->relay->lastconn + l->conndelay_relay > nextconn) { log_debug("debug: mta: cannot use %s before %llus", mta_relay_to_text(c->relay), (unsigned long long) c->relay->lastconn + l->conndelay_relay - now); nextconn = c->relay->lastconn + l->conndelay_relay; } if (c->relay->nconn >= l->maxconn_per_relay) { log_debug("debug: mta: hit relay limit"); limits |= CONNECTOR_LIMIT_RELAY; } /* We can connect now, find a route */ if (!limits && nextconn <= now) route = mta_find_route(c, now, &limits, &nextconn); else route = NULL; /* No route */ if (route == NULL) { if (c->flags & CONNECTOR_ERROR) { /* XXX we might want to clear this flag later */ log_debug("debug: mta-routing: no route available for %s: errors on connector", mta_connector_to_text(c)); return; } else if (limits) { log_debug("debug: mta-routing: no route available for %s: limits reached", mta_connector_to_text(c)); nextconn = now + DELAY_CHECK_LIMIT; } else { log_debug("debug: mta-routing: no route available for %s: must wait a bit", mta_connector_to_text(c)); } log_debug("debug: mta: retrying to connect on %s in %llus...", mta_connector_to_text(c), (unsigned long long) nextconn - time(NULL)); c->flags |= CONNECTOR_WAIT; runq_schedule(runq_connector, nextconn, NULL, c); return; } log_debug("debug: mta-routing: spawning new connection on %s", mta_route_to_text(route)); c->nconn += 1; c->lastconn = time(NULL); c->relay->nconn += 1; c->relay->lastconn = c->lastconn; c->relay->domain->nconn += 1; c->relay->domain->lastconn = c->lastconn; route->nconn += 1; route->lastconn = c->lastconn; route->src->nconn += 1; route->src->lastconn = c->lastconn; route->dst->nconn += 1; route->dst->lastconn = c->lastconn; mta_session(c->relay, route); /* this never fails synchronously */ mta_relay_ref(c->relay); goto again; } static void mta_on_timeout(struct runq *runq, void *arg) { struct mta_connector *connector = arg; struct mta_relay *relay = arg; struct mta_route *route = arg; struct hoststat *hs = arg; if (runq == runq_relay) { log_debug("debug: mta: ... timeout for %s", mta_relay_to_text(relay)); relay->status &= ~RELAY_WAIT_CONNECTOR; mta_drain(relay); mta_relay_unref(relay); /* from mta_drain() */ } else if (runq == runq_connector) { log_debug("debug: mta: ... timeout for %s", mta_connector_to_text(connector)); connector->flags &= ~CONNECTOR_WAIT; mta_connect(connector); } else if (runq == runq_route) { route->flags &= ~ROUTE_RUNQ; mta_route_enable(route); mta_route_unref(route); } else if (runq == runq_hoststat) { log_debug("debug: mta: ... timeout for hoststat %s", hs->name); mta_hoststat_remove_entry(hs); free(hs); } } static void mta_route_disable(struct mta_route *route, int penalty, int reason) { unsigned long long delay; route->penalty += penalty; route->lastpenalty = time(NULL); delay = (unsigned long long)DELAY_ROUTE_BASE * route->penalty * route->penalty; if (delay > DELAY_ROUTE_MAX) delay = DELAY_ROUTE_MAX; #if 0 delay = 60; #endif log_info("smtp-out: Disabling route %s for %llus", mta_route_to_text(route), delay); if (route->flags & ROUTE_DISABLED) runq_cancel(runq_route, NULL, route); else mta_route_ref(route); route->flags |= reason & ROUTE_DISABLED; runq_schedule(runq_route, time(NULL) + delay, NULL, route); } static void mta_route_enable(struct mta_route *route) { if (route->flags & ROUTE_DISABLED) { log_info("smtp-out: Enabling route %s", mta_route_to_text(route)); route->flags &= ~ROUTE_DISABLED; route->flags |= ROUTE_NEW; route->nerror = 0; } if (route->penalty) { #if DELAY_QUADRATIC route->penalty -= 1; route->lastpenalty = time(NULL); #else route->penalty = 0; #endif } } static void mta_drain(struct mta_relay *r) { char buf[64]; log_debug("debug: mta: draining %s " "refcount=%d, ntask=%zu, nconnector=%zu, nconn=%zu", mta_relay_to_text(r), r->refcount, r->ntask, tree_count(&r->connectors), r->nconn); /* * All done. */ if (r->ntask == 0) { log_debug("debug: mta: all done for %s", mta_relay_to_text(r)); return; } /* * If we know that this relay is failing flush the tasks. */ if (r->fail) { mta_flush(r, r->fail, r->failstr); return; } /* Query secret if needed. */ if (r->flags & RELAY_AUTH && r->secret == NULL) mta_query_secret(r); /* Query our preference if needed. */ if (r->backupname && r->backuppref == -1) mta_query_preference(r); /* Query the domain MXs if needed. */ if (r->domain->lastmxquery == 0) mta_query_mx(r); /* Query the limits if needed. */ if (r->limits == NULL) mta_query_limits(r); /* Wait until we are ready to proceed. */ if (r->status & RELAY_WAITMASK) { buf[0] = '\0'; if (r->status & RELAY_WAIT_MX) (void)strlcat(buf, " MX", sizeof buf); if (r->status & RELAY_WAIT_PREFERENCE) (void)strlcat(buf, " preference", sizeof buf); if (r->status & RELAY_WAIT_SECRET) (void)strlcat(buf, " secret", sizeof buf); if (r->status & RELAY_WAIT_SOURCE) (void)strlcat(buf, " source", sizeof buf); if (r->status & RELAY_WAIT_CONNECTOR) (void)strlcat(buf, " connector", sizeof buf); log_debug("debug: mta: %s waiting for%s", mta_relay_to_text(r), buf); return; } /* * We have pending task, and it's maybe time too try a new source. */ if (r->nextsource <= time(NULL)) mta_query_source(r); else { log_debug("debug: mta: scheduling relay %s in %llus...", mta_relay_to_text(r), (unsigned long long) r->nextsource - time(NULL)); runq_schedule(runq_relay, r->nextsource, NULL, r); r->status |= RELAY_WAIT_CONNECTOR; mta_relay_ref(r); } } static void mta_flush(struct mta_relay *relay, int fail, const char *error) { struct mta_envelope *e; struct mta_task *task; const char *domain; void *iter; struct mta_connector *c; size_t n, r; log_debug("debug: mta_flush(%s, %d, \"%s\")", mta_relay_to_text(relay), fail, error); if (fail != IMSG_MTA_DELIVERY_TEMPFAIL && fail != IMSG_MTA_DELIVERY_PERMFAIL) errx(1, "unexpected delivery status %d", fail); n = 0; while ((task = TAILQ_FIRST(&relay->tasks))) { TAILQ_REMOVE(&relay->tasks, task, entry); while ((e = TAILQ_FIRST(&task->envelopes))) { TAILQ_REMOVE(&task->envelopes, e, entry); /* * host was suspended, cache envelope id in hoststat tree * so that it can be retried when a delivery succeeds for * that domain. */ domain = strchr(e->dest, '@'); if (fail == IMSG_MTA_DELIVERY_TEMPFAIL && domain) { r = 0; iter = NULL; while (tree_iter(&relay->connectors, &iter, NULL, (void **)&c)) { if (c->flags & CONNECTOR_ERROR_ROUTE) r++; } if (tree_count(&relay->connectors) == r) mta_hoststat_cache(domain+1, e->id); } mta_delivery_log(e, NULL, relay->domain->name, fail, error); mta_delivery_notify(e); n++; } free(task->sender); free(task); } stat_decrement("mta.task", relay->ntask); stat_decrement("mta.envelope", n); relay->ntask = 0; /* release all waiting envelopes for the relay */ if (relay->state & RELAY_HOLDQ) { m_create(p_queue, IMSG_MTA_HOLDQ_RELEASE, 0, 0, -1); m_add_id(p_queue, relay->id); m_add_int(p_queue, -1); m_close(p_queue); } } /* * Find a route to use for this connector */ static struct mta_route * mta_find_route(struct mta_connector *c, time_t now, int *limits, time_t *nextconn) { struct mta_route *route, *best; struct mta_limits *l = c->relay->limits; struct mta_mx *mx; int level, limit_host, limit_route; int family_mismatch, seen, suspended_route; time_t tm; log_debug("debug: mta-routing: searching new route for %s...", mta_connector_to_text(c)); tm = 0; limit_host = 0; limit_route = 0; suspended_route = 0; family_mismatch = 0; level = -1; best = NULL; seen = 0; TAILQ_FOREACH(mx, &c->relay->domain->mxs, entry) { /* * New preference level */ if (mx->preference > level) { #ifndef IGNORE_MX_PREFERENCE /* * Use the current best MX if found. */ if (best) break; /* * No candidate found. There are valid MXs at this * preference level but they reached their limit, or * we can't connect yet. */ if (limit_host || limit_route || tm) break; /* * If we are a backup MX, do not relay to MXs with * a greater preference value. */ if (c->relay->backuppref >= 0 && mx->preference >= c->relay->backuppref) break; /* * Start looking at MXs on this preference level. */ #endif level = mx->preference; } if (mx->host->flags & HOST_IGNORE) continue; /* Found a possibly valid mx */ seen++; if ((c->source->sa && c->source->sa->sa_family != mx->host->sa->sa_family) || (l->family && l->family != mx->host->sa->sa_family)) { log_debug("debug: mta-routing: skipping host %s: AF mismatch", mta_host_to_text(mx->host)); family_mismatch = 1; continue; } if (mx->host->nconn >= l->maxconn_per_host) { log_debug("debug: mta-routing: skipping host %s: too many connections", mta_host_to_text(mx->host)); limit_host = 1; continue; } if (mx->host->lastconn + l->conndelay_host > now) { log_debug("debug: mta-routing: skipping host %s: cannot use before %llus", mta_host_to_text(mx->host), (unsigned long long) mx->host->lastconn + l->conndelay_host - now); if (tm == 0 || mx->host->lastconn + l->conndelay_host < tm) tm = mx->host->lastconn + l->conndelay_host; continue; } route = mta_route(c->source, mx->host); if (route->flags & ROUTE_DISABLED) { log_debug("debug: mta-routing: skipping route %s: suspend", mta_route_to_text(route)); suspended_route |= route->flags & ROUTE_DISABLED; mta_route_unref(route); /* from here */ continue; } if (route->nconn && (route->flags & ROUTE_NEW)) { log_debug("debug: mta-routing: skipping route %s: not validated yet", mta_route_to_text(route)); limit_route = 1; mta_route_unref(route); /* from here */ continue; } if (route->nconn >= l->maxconn_per_route) { log_debug("debug: mta-routing: skipping route %s: too many connections", mta_route_to_text(route)); limit_route = 1; mta_route_unref(route); /* from here */ continue; } if (route->lastconn + l->conndelay_route > now) { log_debug("debug: mta-routing: skipping route %s: cannot use before %llus (delay after connect)", mta_route_to_text(route), (unsigned long long) route->lastconn + l->conndelay_route - now); if (tm == 0 || route->lastconn + l->conndelay_route < tm) tm = route->lastconn + l->conndelay_route; mta_route_unref(route); /* from here */ continue; } if (route->lastdisc + l->discdelay_route > now) { log_debug("debug: mta-routing: skipping route %s: cannot use before %llus (delay after disconnect)", mta_route_to_text(route), (unsigned long long) route->lastdisc + l->discdelay_route - now); if (tm == 0 || route->lastdisc + l->discdelay_route < tm) tm = route->lastdisc + l->discdelay_route; mta_route_unref(route); /* from here */ continue; } /* Use the route with the lowest number of connections. */ if (best && route->nconn >= best->nconn) { log_debug("debug: mta-routing: skipping route %s: current one is better", mta_route_to_text(route)); mta_route_unref(route); /* from here */ continue; } if (best) mta_route_unref(best); /* from here */ best = route; log_debug("debug: mta-routing: selecting candidate route %s", mta_route_to_text(route)); } if (best) return (best); /* Order is important */ if (seen == 0) { log_info("smtp-out: No MX found for %s", mta_connector_to_text(c)); c->flags |= CONNECTOR_ERROR_MX; } else if (limit_route) { log_debug("debug: mta: hit route limit"); *limits |= CONNECTOR_LIMIT_ROUTE; } else if (limit_host) { log_debug("debug: mta: hit host limit"); *limits |= CONNECTOR_LIMIT_HOST; } else if (tm) { if (tm > *nextconn) *nextconn = tm; } else if (family_mismatch) { log_info("smtp-out: Address family mismatch on %s", mta_connector_to_text(c)); c->flags |= CONNECTOR_ERROR_FAMILY; } else if (suspended_route) { log_info("smtp-out: No valid route for %s", mta_connector_to_text(c)); if (suspended_route & ROUTE_DISABLED_NET) c->flags |= CONNECTOR_ERROR_ROUTE_NET; if (suspended_route & ROUTE_DISABLED_SMTP) c->flags |= CONNECTOR_ERROR_ROUTE_SMTP; } return (NULL); } static void mta_log(const struct mta_envelope *evp, const char *prefix, const char *source, const char *relay, const char *status) { log_info("%016"PRIx64" mta delivery evpid=%016"PRIx64" " "from=<%s> to=<%s> rcpt=<%s> source=\"%s\" " "relay=\"%s\" delay=%s result=\"%s\" stat=\"%s\"", evp->session, evp->id, evp->task->sender, evp->dest, evp->rcpt ? evp->rcpt : "-", source ? source : "-", relay, duration_to_text(time(NULL) - evp->creation), prefix, status); } static struct mta_relay * mta_relay(struct envelope *e, struct relayhost *relayh) { struct dispatcher *dispatcher; struct mta_relay key, *r; dispatcher = dict_xget(env->sc_dispatchers, e->dispatcher); memset(&key, 0, sizeof key); key.pki_name = dispatcher->u.remote.pki; key.ca_name = dispatcher->u.remote.ca; key.authtable = dispatcher->u.remote.auth; key.sourcetable = dispatcher->u.remote.source; key.helotable = dispatcher->u.remote.helo_source; key.heloname = dispatcher->u.remote.helo; if (dispatcher->u.remote.backup) { key.backupname = dispatcher->u.remote.backupmx; if (key.backupname == NULL) key.backupname = e->smtpname; key.domain = mta_domain(e->dest.domain, 0); key.flags |= RELAY_BACKUP; } else if (relayh->hostname[0]) { key.domain = mta_domain(relayh->hostname, 1); key.flags |= RELAY_MX; } else { key.domain = mta_domain(e->dest.domain, 0); if (!(relayh->flags & RELAY_STARTTLS)) key.flags |= RELAY_TLS_OPTIONAL; } key.flags |= relayh->flags; key.port = relayh->port; key.authlabel = relayh->authlabel; if (!key.authlabel[0]) key.authlabel = NULL; if (dispatcher->u.remote.smarthost && dispatcher->u.remote.tls_noverify == 0) key.flags |= RELAY_TLS_VERIFY; if ((r = SPLAY_FIND(mta_relay_tree, &relays, &key)) == NULL) { r = xcalloc(1, sizeof *r); TAILQ_INIT(&r->tasks); r->id = generate_uid(); r->flags = key.flags; r->domain = key.domain; r->backupname = key.backupname ? xstrdup(key.backupname) : NULL; r->backuppref = -1; r->port = key.port; r->pki_name = key.pki_name ? xstrdup(key.pki_name) : NULL; r->ca_name = key.ca_name ? xstrdup(key.ca_name) : NULL; if (key.authtable) r->authtable = xstrdup(key.authtable); if (key.authlabel) r->authlabel = xstrdup(key.authlabel); if (key.sourcetable) r->sourcetable = xstrdup(key.sourcetable); if (key.helotable) r->helotable = xstrdup(key.helotable); if (key.heloname) r->heloname = xstrdup(key.heloname); SPLAY_INSERT(mta_relay_tree, &relays, r); stat_increment("mta.relay", 1); } else { mta_domain_unref(key.domain); /* from here */ } r->refcount++; return (r); } static void mta_relay_ref(struct mta_relay *r) { r->refcount++; } static void mta_relay_unref(struct mta_relay *relay) { struct mta_connector *c; if (--relay->refcount) return; /* Make sure they are no envelopes held for this relay */ if (relay->state & RELAY_HOLDQ) { m_create(p_queue, IMSG_MTA_HOLDQ_RELEASE, 0, 0, -1); m_add_id(p_queue, relay->id); m_add_int(p_queue, 0); m_close(p_queue); } log_debug("debug: mta: freeing %s", mta_relay_to_text(relay)); SPLAY_REMOVE(mta_relay_tree, &relays, relay); while ((tree_poproot(&relay->connectors, NULL, (void**)&c))) mta_connector_free(c); free(relay->authlabel); free(relay->authtable); free(relay->backupname); free(relay->pki_name); free(relay->ca_name); free(relay->helotable); free(relay->heloname); free(relay->secret); free(relay->sourcetable); mta_domain_unref(relay->domain); /* from constructor */ free(relay); stat_decrement("mta.relay", 1); } const char * mta_relay_to_text(struct mta_relay *relay) { static char buf[1024]; char tmp[32]; const char *sep = ","; (void)snprintf(buf, sizeof buf, "[relay:%s", relay->domain->name); if (relay->port) { (void)strlcat(buf, sep, sizeof buf); (void)snprintf(tmp, sizeof tmp, "port=%d", (int)relay->port); (void)strlcat(buf, tmp, sizeof buf); } if (relay->flags & RELAY_STARTTLS) { (void)strlcat(buf, sep, sizeof buf); (void)strlcat(buf, "starttls", sizeof buf); } if (relay->flags & RELAY_SMTPS) { (void)strlcat(buf, sep, sizeof buf); (void)strlcat(buf, "smtps", sizeof buf); } if (relay->flags & RELAY_AUTH) { (void)strlcat(buf, sep, sizeof buf); (void)strlcat(buf, "auth=", sizeof buf); (void)strlcat(buf, relay->authtable, sizeof buf); (void)strlcat(buf, ":", sizeof buf); (void)strlcat(buf, relay->authlabel, sizeof buf); } if (relay->pki_name) { (void)strlcat(buf, sep, sizeof buf); (void)strlcat(buf, "pki_name=", sizeof buf); (void)strlcat(buf, relay->pki_name, sizeof buf); } if (relay->flags & RELAY_MX) { (void)strlcat(buf, sep, sizeof buf); (void)strlcat(buf, "mx", sizeof buf); } if (relay->backupname) { (void)strlcat(buf, sep, sizeof buf); (void)strlcat(buf, "backup=", sizeof buf); (void)strlcat(buf, relay->backupname, sizeof buf); } if (relay->sourcetable) { (void)strlcat(buf, sep, sizeof buf); (void)strlcat(buf, "sourcetable=", sizeof buf); (void)strlcat(buf, relay->sourcetable, sizeof buf); } if (relay->helotable) { (void)strlcat(buf, sep, sizeof buf); (void)strlcat(buf, "helotable=", sizeof buf); (void)strlcat(buf, relay->helotable, sizeof buf); } if (relay->heloname) { (void)strlcat(buf, sep, sizeof buf); (void)strlcat(buf, "heloname=", sizeof buf); (void)strlcat(buf, relay->heloname, sizeof buf); } (void)strlcat(buf, "]", sizeof buf); return (buf); } static void mta_relay_show(struct mta_relay *r, struct mproc *p, uint32_t id, time_t t) { struct mta_connector *c; void *iter; char buf[1024], flags[1024], dur[64]; time_t to; flags[0] = '\0'; #define SHOWSTATUS(f, n) do { \ if (r->status & (f)) { \ if (flags[0]) \ (void)strlcat(flags, ",", sizeof(flags)); \ (void)strlcat(flags, (n), sizeof(flags)); \ } \ } while(0) SHOWSTATUS(RELAY_WAIT_MX, "MX"); SHOWSTATUS(RELAY_WAIT_PREFERENCE, "preference"); SHOWSTATUS(RELAY_WAIT_SECRET, "secret"); SHOWSTATUS(RELAY_WAIT_LIMITS, "limits"); SHOWSTATUS(RELAY_WAIT_SOURCE, "source"); SHOWSTATUS(RELAY_WAIT_CONNECTOR, "connector"); #undef SHOWSTATUS if (runq_pending(runq_relay, NULL, r, &to)) (void)snprintf(dur, sizeof(dur), "%s", duration_to_text(to - t)); else (void)strlcpy(dur, "-", sizeof(dur)); (void)snprintf(buf, sizeof(buf), "%s refcount=%d ntask=%zu nconn=%zu lastconn=%s timeout=%s wait=%s%s", mta_relay_to_text(r), r->refcount, r->ntask, r->nconn, r->lastconn ? duration_to_text(t - r->lastconn) : "-", dur, flags, (r->state & RELAY_ONHOLD) ? "ONHOLD" : ""); m_compose(p, IMSG_CTL_MTA_SHOW_RELAYS, id, 0, -1, buf, strlen(buf) + 1); iter = NULL; while (tree_iter(&r->connectors, &iter, NULL, (void **)&c)) { if (runq_pending(runq_connector, NULL, c, &to)) (void)snprintf(dur, sizeof(dur), "%s", duration_to_text(to - t)); else (void)strlcpy(dur, "-", sizeof(dur)); flags[0] = '\0'; #define SHOWFLAG(f, n) do { \ if (c->flags & (f)) { \ if (flags[0]) \ (void)strlcat(flags, ",", sizeof(flags)); \ (void)strlcat(flags, (n), sizeof(flags)); \ } \ } while(0) SHOWFLAG(CONNECTOR_NEW, "NEW"); SHOWFLAG(CONNECTOR_WAIT, "WAIT"); SHOWFLAG(CONNECTOR_ERROR_FAMILY, "ERROR_FAMILY"); SHOWFLAG(CONNECTOR_ERROR_SOURCE, "ERROR_SOURCE"); SHOWFLAG(CONNECTOR_ERROR_MX, "ERROR_MX"); SHOWFLAG(CONNECTOR_ERROR_ROUTE_NET, "ERROR_ROUTE_NET"); SHOWFLAG(CONNECTOR_ERROR_ROUTE_SMTP, "ERROR_ROUTE_SMTP"); SHOWFLAG(CONNECTOR_ERROR_BLOCKED, "ERROR_BLOCKED"); SHOWFLAG(CONNECTOR_LIMIT_HOST, "LIMIT_HOST"); SHOWFLAG(CONNECTOR_LIMIT_ROUTE, "LIMIT_ROUTE"); SHOWFLAG(CONNECTOR_LIMIT_SOURCE, "LIMIT_SOURCE"); SHOWFLAG(CONNECTOR_LIMIT_RELAY, "LIMIT_RELAY"); SHOWFLAG(CONNECTOR_LIMIT_CONN, "LIMIT_CONN"); SHOWFLAG(CONNECTOR_LIMIT_DOMAIN, "LIMIT_DOMAIN"); #undef SHOWFLAG (void)snprintf(buf, sizeof(buf), " connector %s refcount=%d nconn=%zu lastconn=%s timeout=%s flags=%s", mta_source_to_text(c->source), c->refcount, c->nconn, c->lastconn ? duration_to_text(t - c->lastconn) : "-", dur, flags); m_compose(p, IMSG_CTL_MTA_SHOW_RELAYS, id, 0, -1, buf, strlen(buf) + 1); } } static int mta_relay_cmp(const struct mta_relay *a, const struct mta_relay *b) { int r; if (a->domain < b->domain) return (-1); if (a->domain > b->domain) return (1); if (a->flags < b->flags) return (-1); if (a->flags > b->flags) return (1); if (a->port < b->port) return (-1); if (a->port > b->port) return (1); if (a->authtable == NULL && b->authtable) return (-1); if (a->authtable && b->authtable == NULL) return (1); if (a->authtable && ((r = strcmp(a->authtable, b->authtable)))) return (r); if (a->authlabel && ((r = strcmp(a->authlabel, b->authlabel)))) return (r); if (a->sourcetable == NULL && b->sourcetable) return (-1); if (a->sourcetable && b->sourcetable == NULL) return (1); if (a->sourcetable && ((r = strcmp(a->sourcetable, b->sourcetable)))) return (r); if (a->helotable == NULL && b->helotable) return (-1); if (a->helotable && b->helotable == NULL) return (1); if (a->helotable && ((r = strcmp(a->helotable, b->helotable)))) return (r); if (a->heloname == NULL && b->heloname) return (-1); if (a->heloname && b->heloname == NULL) return (1); if (a->heloname && ((r = strcmp(a->heloname, b->heloname)))) return (r); if (a->pki_name == NULL && b->pki_name) return (-1); if (a->pki_name && b->pki_name == NULL) return (1); if (a->pki_name && ((r = strcmp(a->pki_name, b->pki_name)))) return (r); if (a->ca_name == NULL && b->ca_name) return (-1); if (a->ca_name && b->ca_name == NULL) return (1); if (a->ca_name && ((r = strcmp(a->ca_name, b->ca_name)))) return (r); if (a->backupname && ((r = strcmp(a->backupname, b->backupname)))) return (r); return (0); } SPLAY_GENERATE(mta_relay_tree, mta_relay, entry, mta_relay_cmp); static struct mta_host * mta_host(const struct sockaddr *sa) { struct mta_host key, *h; struct sockaddr_storage ss; memmove(&ss, sa, sa->sa_len); key.sa = (struct sockaddr*)&ss; h = SPLAY_FIND(mta_host_tree, &hosts, &key); if (h == NULL) { h = xcalloc(1, sizeof(*h)); h->sa = xmemdup(sa, sa->sa_len); SPLAY_INSERT(mta_host_tree, &hosts, h); stat_increment("mta.host", 1); } h->refcount++; return (h); } static void mta_host_ref(struct mta_host *h) { h->refcount++; } static void mta_host_unref(struct mta_host *h) { if (--h->refcount) return; SPLAY_REMOVE(mta_host_tree, &hosts, h); free(h->sa); free(h->ptrname); free(h); stat_decrement("mta.host", 1); } const char * mta_host_to_text(struct mta_host *h) { static char buf[1024]; if (h->ptrname) (void)snprintf(buf, sizeof buf, "%s (%s)", sa_to_text(h->sa), h->ptrname); else (void)snprintf(buf, sizeof buf, "%s", sa_to_text(h->sa)); return (buf); } static int mta_host_cmp(const struct mta_host *a, const struct mta_host *b) { if (a->sa->sa_len < b->sa->sa_len) return (-1); if (a->sa->sa_len > b->sa->sa_len) return (1); return (memcmp(a->sa, b->sa, a->sa->sa_len)); } SPLAY_GENERATE(mta_host_tree, mta_host, entry, mta_host_cmp); static struct mta_domain * mta_domain(char *name, int flags) { struct mta_domain key, *d; key.name = name; key.flags = flags; d = SPLAY_FIND(mta_domain_tree, &domains, &key); if (d == NULL) { d = xcalloc(1, sizeof(*d)); d->name = xstrdup(name); d->flags = flags; TAILQ_INIT(&d->mxs); SPLAY_INSERT(mta_domain_tree, &domains, d); stat_increment("mta.domain", 1); } d->refcount++; return (d); } #if 0 static void mta_domain_ref(struct mta_domain *d) { d->refcount++; } #endif static void mta_domain_unref(struct mta_domain *d) { struct mta_mx *mx; if (--d->refcount) return; while ((mx = TAILQ_FIRST(&d->mxs))) { TAILQ_REMOVE(&d->mxs, mx, entry); mta_host_unref(mx->host); /* from IMSG_DNS_HOST */ free(mx); } SPLAY_REMOVE(mta_domain_tree, &domains, d); free(d->name); free(d); stat_decrement("mta.domain", 1); } static int mta_domain_cmp(const struct mta_domain *a, const struct mta_domain *b) { if (a->flags < b->flags) return (-1); if (a->flags > b->flags) return (1); return (strcasecmp(a->name, b->name)); } SPLAY_GENERATE(mta_domain_tree, mta_domain, entry, mta_domain_cmp); static struct mta_source * mta_source(const struct sockaddr *sa) { struct mta_source key, *s; struct sockaddr_storage ss; if (sa) { memmove(&ss, sa, sa->sa_len); key.sa = (struct sockaddr*)&ss; } else key.sa = NULL; s = SPLAY_FIND(mta_source_tree, &sources, &key); if (s == NULL) { s = xcalloc(1, sizeof(*s)); if (sa) s->sa = xmemdup(sa, sa->sa_len); SPLAY_INSERT(mta_source_tree, &sources, s); stat_increment("mta.source", 1); } s->refcount++; return (s); } static void mta_source_ref(struct mta_source *s) { s->refcount++; } static void mta_source_unref(struct mta_source *s) { if (--s->refcount) return; SPLAY_REMOVE(mta_source_tree, &sources, s); free(s->sa); free(s); stat_decrement("mta.source", 1); } static const char * mta_source_to_text(struct mta_source *s) { static char buf[1024]; if (s->sa == NULL) return "[]"; (void)snprintf(buf, sizeof buf, "%s", sa_to_text(s->sa)); return (buf); } static int mta_source_cmp(const struct mta_source *a, const struct mta_source *b) { if (a->sa == NULL) return ((b->sa == NULL) ? 0 : -1); if (b->sa == NULL) return (1); if (a->sa->sa_len < b->sa->sa_len) return (-1); if (a->sa->sa_len > b->sa->sa_len) return (1); return (memcmp(a->sa, b->sa, a->sa->sa_len)); } SPLAY_GENERATE(mta_source_tree, mta_source, entry, mta_source_cmp); static struct mta_connector * mta_connector(struct mta_relay *relay, struct mta_source *source) { struct mta_connector *c; c = tree_get(&relay->connectors, (uintptr_t)(source)); if (c == NULL) { c = xcalloc(1, sizeof(*c)); c->relay = relay; c->source = source; c->flags |= CONNECTOR_NEW; mta_source_ref(source); tree_xset(&relay->connectors, (uintptr_t)(source), c); stat_increment("mta.connector", 1); log_debug("debug: mta: new %s", mta_connector_to_text(c)); } return (c); } static void mta_connector_free(struct mta_connector *c) { log_debug("debug: mta: freeing %s", mta_connector_to_text(c)); if (c->flags & CONNECTOR_WAIT) { log_debug("debug: mta: cancelling timeout for %s", mta_connector_to_text(c)); runq_cancel(runq_connector, NULL, c); } mta_source_unref(c->source); /* from constructor */ free(c); stat_decrement("mta.connector", 1); } static const char * mta_connector_to_text(struct mta_connector *c) { static char buf[1024]; (void)snprintf(buf, sizeof buf, "[connector:%s->%s,0x%x]", mta_source_to_text(c->source), mta_relay_to_text(c->relay), c->flags); return (buf); } static struct mta_route * mta_route(struct mta_source *src, struct mta_host *dst) { struct mta_route key, *r; static uint64_t rid = 0; key.src = src; key.dst = dst; r = SPLAY_FIND(mta_route_tree, &routes, &key); if (r == NULL) { r = xcalloc(1, sizeof(*r)); r->src = src; r->dst = dst; r->flags |= ROUTE_NEW; r->id = ++rid; SPLAY_INSERT(mta_route_tree, &routes, r); mta_source_ref(src); mta_host_ref(dst); stat_increment("mta.route", 1); } else if (r->flags & ROUTE_RUNQ) { log_debug("debug: mta: mta_route_ref(): cancelling runq for route %s", mta_route_to_text(r)); r->flags &= ~(ROUTE_RUNQ | ROUTE_KEEPALIVE); runq_cancel(runq_route, NULL, r); r->refcount--; /* from mta_route_unref() */ } r->refcount++; return (r); } static void mta_route_ref(struct mta_route *r) { r->refcount++; } static void mta_route_unref(struct mta_route *r) { time_t sched, now; int delay; if (--r->refcount) return; /* * Nothing references this route, but we might want to keep it alive * for a while. */ now = time(NULL); sched = 0; if (r->penalty) { #if DELAY_QUADRATIC delay = DELAY_ROUTE_BASE * r->penalty * r->penalty; #else delay = 15 * 60; #endif if (delay > DELAY_ROUTE_MAX) delay = DELAY_ROUTE_MAX; sched = r->lastpenalty + delay; log_debug("debug: mta: mta_route_unref(): keeping route %s alive for %llus (penalty %d)", mta_route_to_text(r), (unsigned long long) sched - now, r->penalty); } else if (!(r->flags & ROUTE_KEEPALIVE)) { if (r->lastconn + max_seen_conndelay_route > now) sched = r->lastconn + max_seen_conndelay_route; if (r->lastdisc + max_seen_discdelay_route > now && r->lastdisc + max_seen_discdelay_route < sched) sched = r->lastdisc + max_seen_discdelay_route; if (sched > now) log_debug("debug: mta: mta_route_unref(): keeping route %s alive for %llus (imposed delay)", mta_route_to_text(r), (unsigned long long) sched - now); } if (sched > now) { r->flags |= ROUTE_RUNQ; runq_schedule(runq_route, sched, NULL, r); r->refcount++; return; } log_debug("debug: mta: mta_route_unref(): really discarding route %s", mta_route_to_text(r)); SPLAY_REMOVE(mta_route_tree, &routes, r); mta_source_unref(r->src); /* from constructor */ mta_host_unref(r->dst); /* from constructor */ free(r); stat_decrement("mta.route", 1); } static const char * mta_route_to_text(struct mta_route *r) { static char buf[1024]; (void)snprintf(buf, sizeof buf, "%s <-> %s", mta_source_to_text(r->src), mta_host_to_text(r->dst)); return (buf); } static int mta_route_cmp(const struct mta_route *a, const struct mta_route *b) { if (a->src < b->src) return (-1); if (a->src > b->src) return (1); if (a->dst < b->dst) return (-1); if (a->dst > b->dst) return (1); return (0); } SPLAY_GENERATE(mta_route_tree, mta_route, entry, mta_route_cmp); void mta_block(struct mta_source *src, char *dom) { struct mta_block key, *b; key.source = src; key.domain = dom; b = SPLAY_FIND(mta_block_tree, &blocks, &key); if (b != NULL) return; b = xcalloc(1, sizeof(*b)); if (dom) b->domain = xstrdup(dom); b->source = src; mta_source_ref(src); SPLAY_INSERT(mta_block_tree, &blocks, b); } void mta_unblock(struct mta_source *src, char *dom) { struct mta_block key, *b; key.source = src; key.domain = dom; b = SPLAY_FIND(mta_block_tree, &blocks, &key); if (b == NULL) return; SPLAY_REMOVE(mta_block_tree, &blocks, b); mta_source_unref(b->source); free(b->domain); free(b); } int mta_is_blocked(struct mta_source *src, char *dom) { struct mta_block key; key.source = src; key.domain = dom; if (SPLAY_FIND(mta_block_tree, &blocks, &key)) return (1); return (0); } static int mta_block_cmp(const struct mta_block *a, const struct mta_block *b) { if (a->source < b->source) return (-1); if (a->source > b->source) return (1); if (!a->domain && b->domain) return (-1); if (a->domain && !b->domain) return (1); if (a->domain == b->domain) return (0); return (strcasecmp(a->domain, b->domain)); } SPLAY_GENERATE(mta_block_tree, mta_block, entry, mta_block_cmp); /* hoststat errors are not critical, we do best effort */ void mta_hoststat_update(const char *host, const char *error) { struct hoststat *hs = NULL; char buf[HOST_NAME_MAX+1]; time_t tm; if (!lowercase(buf, host, sizeof buf)) return; tm = time(NULL); hs = dict_get(&hoststat, buf); if (hs == NULL) { if ((hs = calloc(1, sizeof *hs)) == NULL) return; tree_init(&hs->deferred); runq_schedule(runq_hoststat, tm+HOSTSTAT_EXPIRE_DELAY, NULL, hs); } (void)strlcpy(hs->name, buf, sizeof hs->name); (void)strlcpy(hs->error, error, sizeof hs->error); hs->tm = time(NULL); dict_set(&hoststat, buf, hs); runq_cancel(runq_hoststat, NULL, hs); runq_schedule(runq_hoststat, tm+HOSTSTAT_EXPIRE_DELAY, NULL, hs); } void mta_hoststat_cache(const char *host, uint64_t evpid) { struct hoststat *hs = NULL; char buf[HOST_NAME_MAX+1]; if (!lowercase(buf, host, sizeof buf)) return; hs = dict_get(&hoststat, buf); if (hs == NULL) return; if (tree_count(&hs->deferred) >= env->sc_mta_max_deferred) return; tree_set(&hs->deferred, evpid, NULL); } void mta_hoststat_uncache(const char *host, uint64_t evpid) { struct hoststat *hs = NULL; char buf[HOST_NAME_MAX+1]; if (!lowercase(buf, host, sizeof buf)) return; hs = dict_get(&hoststat, buf); if (hs == NULL) return; tree_pop(&hs->deferred, evpid); } void mta_hoststat_reschedule(const char *host) { struct hoststat *hs = NULL; char buf[HOST_NAME_MAX+1]; uint64_t evpid; if (!lowercase(buf, host, sizeof buf)) return; hs = dict_get(&hoststat, buf); if (hs == NULL) return; while (tree_poproot(&hs->deferred, &evpid, NULL)) { m_compose(p_queue, IMSG_MTA_SCHEDULE, 0, 0, -1, &evpid, sizeof evpid); } } static void mta_hoststat_remove_entry(struct hoststat *hs) { while (tree_poproot(&hs->deferred, NULL, NULL)) ; dict_pop(&hoststat, hs->name); runq_cancel(runq_hoststat, NULL, hs); }