/* * daemon/daemon.c - collection of workers that handles requests. * * Copyright (c) 2007, NLnet Labs. All rights reserved. * * This software is open source. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * Neither the name of the NLNET LABS nor the names of its contributors may * be used to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED * TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /** * \file * * The daemon consists of global settings and a number of workers. */ #include "config.h" #ifdef HAVE_OPENSSL_ERR_H #include #endif #ifdef HAVE_OPENSSL_RAND_H #include #endif #ifdef HAVE_OPENSSL_CONF_H #include #endif #ifdef HAVE_OPENSSL_ENGINE_H #include #endif #ifdef HAVE_TIME_H #include #endif #include #ifdef HAVE_NSS /* nss3 */ #include "nss.h" #endif #include "daemon/daemon.h" #include "daemon/worker.h" #include "daemon/remote.h" #include "daemon/acl_list.h" #include "util/log.h" #include "util/config_file.h" #include "util/data/msgreply.h" #include "util/shm_side/shm_main.h" #include "util/storage/lookup3.h" #include "util/storage/slabhash.h" #include "util/tcp_conn_limit.h" #include "util/edns.h" #include "services/listen_dnsport.h" #include "services/cache/rrset.h" #include "services/cache/infra.h" #include "services/localzone.h" #include "services/view.h" #include "services/modstack.h" #include "services/authzone.h" #include "util/module.h" #include "util/random.h" #include "util/tube.h" #include "util/net_help.h" #include "sldns/keyraw.h" #include "respip/respip.h" #include "iterator/iter_fwd.h" #include "iterator/iter_hints.h" #include #ifdef HAVE_SYSTEMD #include #endif #ifdef HAVE_NETDB_H #include #endif #ifdef USE_CACHEDB #include "cachedb/cachedb.h" #endif /** How many quit requests happened. */ static int sig_record_quit = 0; /** How many reload requests happened. */ static int sig_record_reload = 0; #if HAVE_DECL_SSL_COMP_GET_COMPRESSION_METHODS /** cleaner ssl memory freeup */ static void* comp_meth = NULL; #endif /** remove buffers for parsing and init */ int ub_c_lex_destroy(void); /** used when no other sighandling happens, so we don't die * when multiple signals in quick succession are sent to us. * @param sig: signal number. * @return signal handler return type (void or int). */ static RETSIGTYPE record_sigh(int sig) { #ifdef LIBEVENT_SIGNAL_PROBLEM /* cannot log, verbose here because locks may be held */ /* quit on signal, no cleanup and statistics, because installed libevent version is not threadsafe */ exit(0); #endif switch(sig) { case SIGTERM: #ifdef SIGQUIT case SIGQUIT: #endif #ifdef SIGBREAK case SIGBREAK: #endif case SIGINT: sig_record_quit++; break; #ifdef SIGHUP case SIGHUP: sig_record_reload++; break; #endif #ifdef SIGPIPE case SIGPIPE: break; #endif default: /* ignoring signal */ break; } } /** * Signal handling during the time when netevent is disabled. * Stores signals to replay later. */ static void signal_handling_record(void) { if( signal(SIGTERM, record_sigh) == SIG_ERR || #ifdef SIGQUIT signal(SIGQUIT, record_sigh) == SIG_ERR || #endif #ifdef SIGBREAK signal(SIGBREAK, record_sigh) == SIG_ERR || #endif #ifdef SIGHUP signal(SIGHUP, record_sigh) == SIG_ERR || #endif #ifdef SIGPIPE signal(SIGPIPE, SIG_IGN) == SIG_ERR || #endif signal(SIGINT, record_sigh) == SIG_ERR ) log_err("install sighandler: %s", strerror(errno)); } /** * Replay old signals. * @param wrk: worker that handles signals. */ static void signal_handling_playback(struct worker* wrk) { #ifdef SIGHUP if(sig_record_reload) worker_sighandler(SIGHUP, wrk); #endif if(sig_record_quit) worker_sighandler(SIGTERM, wrk); sig_record_quit = 0; sig_record_reload = 0; } struct daemon* daemon_init(void) { struct daemon* daemon = (struct daemon*)calloc(1, sizeof(struct daemon)); #ifdef USE_WINSOCK int r; WSADATA wsa_data; #endif if(!daemon) return NULL; #ifdef USE_WINSOCK r = WSAStartup(MAKEWORD(2,2), &wsa_data); if(r != 0) { fatal_exit("could not init winsock. WSAStartup: %s", wsa_strerror(r)); } #endif /* USE_WINSOCK */ signal_handling_record(); #ifdef HAVE_SSL # ifdef HAVE_ERR_LOAD_CRYPTO_STRINGS ERR_load_crypto_strings(); # endif #if OPENSSL_VERSION_NUMBER < 0x10100000 || !defined(HAVE_OPENSSL_INIT_SSL) ERR_load_SSL_strings(); #endif # ifdef USE_GOST (void)sldns_key_EVP_load_gost_id(); # endif # if OPENSSL_VERSION_NUMBER < 0x10100000 || !defined(HAVE_OPENSSL_INIT_CRYPTO) # ifndef S_SPLINT_S OpenSSL_add_all_algorithms(); # endif # else OPENSSL_init_crypto(OPENSSL_INIT_ADD_ALL_CIPHERS | OPENSSL_INIT_ADD_ALL_DIGESTS | OPENSSL_INIT_LOAD_CRYPTO_STRINGS, NULL); # endif # if HAVE_DECL_SSL_COMP_GET_COMPRESSION_METHODS /* grab the COMP method ptr because openssl leaks it */ comp_meth = (void*)SSL_COMP_get_compression_methods(); # endif # if OPENSSL_VERSION_NUMBER < 0x10100000 || !defined(HAVE_OPENSSL_INIT_SSL) (void)SSL_library_init(); # else (void)OPENSSL_init_ssl(OPENSSL_INIT_LOAD_SSL_STRINGS, NULL); # endif # if defined(HAVE_SSL) && defined(OPENSSL_THREADS) && !defined(THREADS_DISABLED) if(!ub_openssl_lock_init()) fatal_exit("could not init openssl locks"); # endif #elif defined(HAVE_NSS) if(NSS_NoDB_Init(NULL) != SECSuccess) fatal_exit("could not init NSS"); #endif /* HAVE_SSL or HAVE_NSS */ #ifdef HAVE_TZSET /* init timezone info while we are not chrooted yet */ tzset(); #endif daemon->need_to_exit = 0; modstack_init(&daemon->mods); if(!(daemon->env = (struct module_env*)calloc(1, sizeof(*daemon->env)))) { free(daemon); return NULL; } daemon->env->modstack = &daemon->mods; /* init edns_known_options */ if(!edns_known_options_init(daemon->env)) { free(daemon->env); free(daemon); return NULL; } alloc_init(&daemon->superalloc, NULL, 0); daemon->acl = acl_list_create(); if(!daemon->acl) { edns_known_options_delete(daemon->env); free(daemon->env); free(daemon); return NULL; } daemon->acl_interface = acl_list_create(); if(!daemon->acl_interface) { acl_list_delete(daemon->acl); edns_known_options_delete(daemon->env); free(daemon->env); free(daemon); return NULL; } daemon->tcl = tcl_list_create(); if(!daemon->tcl) { acl_list_delete(daemon->acl_interface); acl_list_delete(daemon->acl); edns_known_options_delete(daemon->env); free(daemon->env); free(daemon); return NULL; } listen_setup_locks(); if(gettimeofday(&daemon->time_boot, NULL) < 0) log_err("gettimeofday: %s", strerror(errno)); daemon->time_last_stat = daemon->time_boot; if((daemon->env->auth_zones = auth_zones_create()) == 0) { acl_list_delete(daemon->acl_interface); acl_list_delete(daemon->acl); tcl_list_delete(daemon->tcl); edns_known_options_delete(daemon->env); free(daemon->env); free(daemon); return NULL; } if(!(daemon->env->edns_strings = edns_strings_create())) { auth_zones_delete(daemon->env->auth_zones); acl_list_delete(daemon->acl_interface); acl_list_delete(daemon->acl); tcl_list_delete(daemon->tcl); edns_known_options_delete(daemon->env); free(daemon->env); free(daemon); return NULL; } return daemon; } static int setup_acl_for_ports(struct acl_list* list, struct listen_port* port_list) { struct acl_addr* acl_node; for(; port_list; port_list=port_list->next) { if(!port_list->socket) { /* This is mainly for testbound where port_list is * empty. */ continue; } if(!(acl_node = acl_interface_insert(list, (struct sockaddr_storage*)port_list->socket->addr, port_list->socket->addrlen, acl_refuse))) { return 0; } port_list->socket->acl = acl_node; } return 1; } int daemon_open_shared_ports(struct daemon* daemon) { log_assert(daemon); if(daemon->cfg->port != daemon->listening_port) { char** resif = NULL; int num_resif = 0; size_t i; struct listen_port* p0; daemon->reuseport = 0; /* free and close old ports */ if(daemon->ports != NULL) { for(i=0; inum_ports; i++) listening_ports_free(daemon->ports[i]); free(daemon->ports); daemon->ports = NULL; } /* clean acl_interface */ acl_interface_init(daemon->acl_interface); if(!resolve_interface_names(daemon->cfg->ifs, daemon->cfg->num_ifs, NULL, &resif, &num_resif)) return 0; /* see if we want to reuseport */ #ifdef SO_REUSEPORT if(daemon->cfg->so_reuseport && daemon->cfg->num_threads > 0) daemon->reuseport = 1; #endif /* try to use reuseport */ p0 = listening_ports_open(daemon->cfg, resif, num_resif, &daemon->reuseport); if(!p0) { listening_ports_free(p0); config_del_strarray(resif, num_resif); return 0; } if(daemon->reuseport) { /* reuseport was successful, allocate for it */ daemon->num_ports = (size_t)daemon->cfg->num_threads; } else { /* do the normal, singleportslist thing, * reuseport not enabled or did not work */ daemon->num_ports = 1; } if(!(daemon->ports = (struct listen_port**)calloc( daemon->num_ports, sizeof(*daemon->ports)))) { listening_ports_free(p0); config_del_strarray(resif, num_resif); return 0; } daemon->ports[0] = p0; if(!setup_acl_for_ports(daemon->acl_interface, daemon->ports[0])) { listening_ports_free(p0); config_del_strarray(resif, num_resif); return 0; } if(daemon->reuseport) { /* continue to use reuseport */ for(i=1; inum_ports; i++) { if(!(daemon->ports[i]= listening_ports_open(daemon->cfg, resif, num_resif, &daemon->reuseport)) || !daemon->reuseport ) { for(i=0; inum_ports; i++) listening_ports_free(daemon->ports[i]); free(daemon->ports); daemon->ports = NULL; config_del_strarray(resif, num_resif); return 0; } if(!setup_acl_for_ports(daemon->acl_interface, daemon->ports[i])) { for(i=0; inum_ports; i++) listening_ports_free(daemon->ports[i]); free(daemon->ports); daemon->ports = NULL; config_del_strarray(resif, num_resif); return 0; } } } config_del_strarray(resif, num_resif); daemon->listening_port = daemon->cfg->port; } if(!daemon->cfg->remote_control_enable && daemon->rc_port) { listening_ports_free(daemon->rc_ports); daemon->rc_ports = NULL; daemon->rc_port = 0; } if(daemon->cfg->remote_control_enable && daemon->cfg->control_port != daemon->rc_port) { listening_ports_free(daemon->rc_ports); if(!(daemon->rc_ports=daemon_remote_open_ports(daemon->cfg))) return 0; daemon->rc_port = daemon->cfg->control_port; } return 1; } int daemon_privileged(struct daemon* daemon) { daemon->env->cfg = daemon->cfg; daemon->env->alloc = &daemon->superalloc; daemon->env->worker = NULL; if(!modstack_call_startup(&daemon->mods, daemon->cfg->module_conf, daemon->env)) { fatal_exit("failed to startup modules"); } return 1; } /** * Setup modules. setup module stack. * @param daemon: the daemon */ static void daemon_setup_modules(struct daemon* daemon) { daemon->env->cfg = daemon->cfg; daemon->env->alloc = &daemon->superalloc; daemon->env->worker = NULL; if(daemon->mods_inited) { modstack_call_deinit(&daemon->mods, daemon->env); } daemon->env->need_to_validate = 0; /* set by module init below */ if(!modstack_call_init(&daemon->mods, daemon->cfg->module_conf, daemon->env)) { fatal_exit("failed to init modules"); } daemon->mods_inited = 1; log_edns_known_options(VERB_ALGO, daemon->env); } /** * Obtain allowed port numbers, concatenate the list, and shuffle them * (ready to be handed out to threads). * @param daemon: the daemon. Uses rand and cfg. * @param shufport: the portlist output. * @return number of ports available. */ static int daemon_get_shufport(struct daemon* daemon, int* shufport) { int i, n, k, temp; int avail = 0; for(i=0; i<65536; i++) { if(daemon->cfg->outgoing_avail_ports[i]) { shufport[avail++] = daemon->cfg-> outgoing_avail_ports[i]; } } if(avail == 0) fatal_exit("no ports are permitted for UDP, add " "with outgoing-port-permit"); /* Knuth shuffle */ n = avail; while(--n > 0) { k = ub_random_max(daemon->rand, n+1); /* 0<= k<= n */ temp = shufport[k]; shufport[k] = shufport[n]; shufport[n] = temp; } return avail; } /** * Clear and delete per-worker alloc caches, and free memory maintained in * superalloc. * The rrset and message caches must be empty at the time of call. * @param daemon: the daemon that maintains the alloc caches to be cleared. */ static void daemon_clear_allocs(struct daemon* daemon) { int i; /* daemon->num may be different during reloads (after configuration * read). Use old_num which has the correct value used to setup the * worker_allocs */ for(i=0; iold_num; i++) { alloc_clear(daemon->worker_allocs[i]); free(daemon->worker_allocs[i]); } free(daemon->worker_allocs); daemon->worker_allocs = NULL; alloc_clear_special(&daemon->superalloc); } /** * Allocate empty worker structures. With backptr and thread-number, * from 0..numthread initialised. Used as user arguments to new threads. * Creates the daemon random generator if it does not exist yet. * The random generator stays existing between reloads with a unique state. * @param daemon: the daemon with (new) config settings. */ static void daemon_create_workers(struct daemon* daemon) { int i, numport; int* shufport; log_assert(daemon && daemon->cfg); if(!daemon->rand) { daemon->rand = ub_initstate(NULL); if(!daemon->rand) fatal_exit("could not init random generator"); hash_set_raninit((uint32_t)ub_random(daemon->rand)); } shufport = (int*)calloc(65536, sizeof(int)); if(!shufport) fatal_exit("out of memory during daemon init"); numport = daemon_get_shufport(daemon, shufport); verbose(VERB_ALGO, "total of %d outgoing ports available", numport); #ifdef HAVE_NGTCP2 daemon->doq_table = doq_table_create(daemon->cfg, daemon->rand); if(!daemon->doq_table) fatal_exit("could not create doq_table: out of memory"); #endif daemon->num = (daemon->cfg->num_threads?daemon->cfg->num_threads:1); if(daemon->reuseport && (int)daemon->num < (int)daemon->num_ports) { log_warn("cannot reduce num-threads to %d because so-reuseport " "so continuing with %d threads.", (int)daemon->num, (int)daemon->num_ports); daemon->num = (int)daemon->num_ports; } daemon->workers = (struct worker**)calloc((size_t)daemon->num, sizeof(struct worker*)); if(!daemon->workers) fatal_exit("out of memory during daemon init"); if(daemon->cfg->dnstap) { #ifdef USE_DNSTAP daemon->dtenv = dt_create(daemon->cfg); if (!daemon->dtenv) fatal_exit("dt_create failed"); #else fatal_exit("dnstap enabled in config but not built with dnstap support"); #endif } for(i=0; inum; i++) { if(!(daemon->workers[i] = worker_create(daemon, i, shufport+numport*i/daemon->num, numport*(i+1)/daemon->num - numport*i/daemon->num))) /* the above is not ports/numthr, due to rounding */ fatal_exit("could not create worker"); } /* create per-worker alloc caches if not reusing existing ones. */ if(!daemon->worker_allocs) { daemon->worker_allocs = (struct alloc_cache**)calloc( (size_t)daemon->num, sizeof(struct alloc_cache*)); if(!daemon->worker_allocs) fatal_exit("could not allocate worker allocs"); for(i=0; inum; i++) { struct alloc_cache* alloc = calloc(1, sizeof(struct alloc_cache)); if (!alloc) fatal_exit("could not allocate worker alloc"); alloc_init(alloc, &daemon->superalloc, i); daemon->worker_allocs[i] = alloc; } } free(shufport); } #ifdef THREADS_DISABLED /** * Close all pipes except for the numbered thread. * @param daemon: daemon to close pipes in. * @param thr: thread number 0..num-1 of thread to skip. */ static void close_other_pipes(struct daemon* daemon, int thr) { int i; for(i=0; inum; i++) if(i!=thr) { if(i==0) { /* only close read part, need to write stats */ tube_close_read(daemon->workers[i]->cmd); } else { /* complete close channel to others */ tube_delete(daemon->workers[i]->cmd); daemon->workers[i]->cmd = NULL; } } } #endif /* THREADS_DISABLED */ /** * Function to start one thread. * @param arg: user argument. * @return: void* user return value could be used for thread_join results. */ static void* thread_start(void* arg) { struct worker* worker = (struct worker*)arg; int port_num = 0; log_thread_set(&worker->thread_num); ub_thread_blocksigs(); #ifdef THREADS_DISABLED /* close pipe ends used by main */ tube_close_write(worker->cmd); close_other_pipes(worker->daemon, worker->thread_num); #endif #ifdef SO_REUSEPORT if(worker->daemon->cfg->so_reuseport) port_num = worker->thread_num % worker->daemon->num_ports; else port_num = 0; #endif if(!worker_init(worker, worker->daemon->cfg, worker->daemon->ports[port_num], 0)) fatal_exit("Could not initialize thread"); worker_work(worker); return NULL; } /** * Fork and init the other threads. Main thread returns for special handling. * @param daemon: the daemon with other threads to fork. */ static void daemon_start_others(struct daemon* daemon) { int i; log_assert(daemon); verbose(VERB_ALGO, "start threads"); /* skip i=0, is this thread */ for(i=1; inum; i++) { ub_thread_create(&daemon->workers[i]->thr_id, thread_start, daemon->workers[i]); #ifdef THREADS_DISABLED /* close pipe end of child */ tube_close_read(daemon->workers[i]->cmd); #endif /* no threads */ } } /** * Stop the other threads. * @param daemon: the daemon with other threads. */ static void daemon_stop_others(struct daemon* daemon) { int i; log_assert(daemon); verbose(VERB_ALGO, "stop threads"); /* skip i=0, is this thread */ /* use i=0 buffer for sending cmds; because we are #0 */ for(i=1; inum; i++) { worker_send_cmd(daemon->workers[i], worker_cmd_quit); } /* wait for them to quit */ for(i=1; inum; i++) { /* join it to make sure its dead */ verbose(VERB_ALGO, "join %d", i); ub_thread_join(daemon->workers[i]->thr_id); verbose(VERB_ALGO, "join success %d", i); } } void daemon_fork(struct daemon* daemon) { int have_view_respip_cfg = 0; #ifdef HAVE_SYSTEMD int ret; #endif log_assert(daemon); if(!(daemon->views = views_create())) fatal_exit("Could not create views: out of memory"); /* create individual views and their localzone/data trees */ if(!views_apply_cfg(daemon->views, daemon->cfg)) fatal_exit("Could not set up views"); if(!acl_list_apply_cfg(daemon->acl, daemon->cfg, daemon->views)) fatal_exit("Could not setup access control list"); if(!acl_interface_apply_cfg(daemon->acl_interface, daemon->cfg, daemon->views)) fatal_exit("Could not setup interface control list"); if(!tcl_list_apply_cfg(daemon->tcl, daemon->cfg)) fatal_exit("Could not setup TCP connection limits"); if(daemon->cfg->dnscrypt) { #ifdef USE_DNSCRYPT daemon->dnscenv = dnsc_create(); if (!daemon->dnscenv) fatal_exit("dnsc_create failed"); dnsc_apply_cfg(daemon->dnscenv, daemon->cfg); #else fatal_exit("dnscrypt enabled in config but unbound was not built with " "dnscrypt support"); #endif } if(daemon->cfg->cookie_secret_file && daemon->cfg->cookie_secret_file[0]) { if(!(daemon->cookie_secrets = cookie_secrets_create())) fatal_exit("Could not create cookie_secrets: out of memory"); if(!cookie_secrets_apply_cfg(daemon->cookie_secrets, daemon->cfg->cookie_secret_file)) fatal_exit("Could not setup cookie_secrets"); } /* create global local_zones */ if(!(daemon->local_zones = local_zones_create())) fatal_exit("Could not create local zones: out of memory"); if(!local_zones_apply_cfg(daemon->local_zones, daemon->cfg)) fatal_exit("Could not set up local zones"); if(!(daemon->env->fwds = forwards_create()) || !forwards_apply_cfg(daemon->env->fwds, daemon->cfg)) fatal_exit("Could not set forward zones"); if(!(daemon->env->hints = hints_create()) || !hints_apply_cfg(daemon->env->hints, daemon->cfg)) fatal_exit("Could not set root or stub hints"); /* process raw response-ip configuration data */ if(!(daemon->respip_set = respip_set_create())) fatal_exit("Could not create response IP set"); if(!respip_global_apply_cfg(daemon->respip_set, daemon->cfg)) fatal_exit("Could not set up response IP set"); if(!respip_views_apply_cfg(daemon->views, daemon->cfg, &have_view_respip_cfg)) fatal_exit("Could not set up per-view response IP sets"); daemon->use_response_ip = !respip_set_is_empty(daemon->respip_set) || have_view_respip_cfg; /* setup modules */ daemon_setup_modules(daemon); /* read auth zonefiles */ if(!auth_zones_apply_cfg(daemon->env->auth_zones, daemon->cfg, 1, &daemon->use_rpz, daemon->env, &daemon->mods)) fatal_exit("auth_zones could not be setup"); /* Set-up EDNS strings */ if(!edns_strings_apply_cfg(daemon->env->edns_strings, daemon->cfg)) fatal_exit("Could not set up EDNS strings"); #ifdef USE_CACHEDB daemon->env->cachedb_enabled = cachedb_is_enabled(&daemon->mods, daemon->env); #endif /* response-ip-xxx options don't work as expected without the respip * module. To avoid run-time operational surprise we reject such * configuration. */ if(daemon->use_response_ip && modstack_find(&daemon->mods, "respip") < 0) fatal_exit("response-ip options require respip module"); /* RPZ response ip triggers don't work as expected without the respip * module. To avoid run-time operational surprise we reject such * configuration. */ if(daemon->use_rpz && modstack_find(&daemon->mods, "respip") < 0) fatal_exit("RPZ requires the respip module"); /* first create all the worker structures, so we can pass * them to the newly created threads. */ daemon_create_workers(daemon); #if defined(HAVE_EV_LOOP) || defined(HAVE_EV_DEFAULT_LOOP) /* in libev the first inited base gets signals */ if(!worker_init(daemon->workers[0], daemon->cfg, daemon->ports[0], 1)) fatal_exit("Could not initialize main thread"); #endif /* Now create the threads and init the workers. * By the way, this is thread #0 (the main thread). */ daemon_start_others(daemon); /* Special handling for the main thread. This is the thread * that handles signals and remote control. */ #if !(defined(HAVE_EV_LOOP) || defined(HAVE_EV_DEFAULT_LOOP)) /* libevent has the last inited base get signals (or any base) */ if(!worker_init(daemon->workers[0], daemon->cfg, daemon->ports[0], 1)) fatal_exit("Could not initialize main thread"); #endif signal_handling_playback(daemon->workers[0]); if (!shm_main_init(daemon)) log_warn("SHM has failed"); /* Start resolver service on main thread. */ #ifdef HAVE_SYSTEMD ret = sd_notify(0, "READY=1"); if(ret <= 0 && getenv("NOTIFY_SOCKET")) fatal_exit("sd_notify failed %s: %s. Make sure that unbound has " "access/permission to use the socket presented by systemd.", getenv("NOTIFY_SOCKET"), (ret==0?"no $NOTIFY_SOCKET": strerror(-ret))); #endif log_info("start of service (%s).", PACKAGE_STRING); worker_work(daemon->workers[0]); #ifdef HAVE_SYSTEMD if (daemon->workers[0]->need_to_exit) sd_notify(0, "STOPPING=1"); else sd_notify(0, "RELOADING=1"); #endif log_info("service stopped (%s).", PACKAGE_STRING); /* we exited! a signal happened! Stop other threads */ daemon_stop_others(daemon); /* Shutdown SHM */ shm_main_shutdown(daemon); daemon->reuse_cache = daemon->workers[0]->reuse_cache; daemon->need_to_exit = daemon->workers[0]->need_to_exit; } void daemon_cleanup(struct daemon* daemon) { int i; log_assert(daemon); /* before stopping main worker, handle signals ourselves, so we don't die on multiple reload signals for example. */ signal_handling_record(); log_thread_set(NULL); /* clean up caches because * a) RRset IDs will be recycled after a reload, causing collisions * b) validation config can change, thus rrset, msg, keycache clear * * If we are trying to keep the cache as long as possible, we should * defer the cleanup until we know whether the new configuration allows * the reuse. (If we're exiting, cleanup should be done here). */ if(!daemon->reuse_cache || daemon->need_to_exit) { slabhash_clear(&daemon->env->rrset_cache->table); slabhash_clear(daemon->env->msg_cache); } daemon->old_num = daemon->num; /* save the current num */ forwards_delete(daemon->env->fwds); daemon->env->fwds = NULL; hints_delete(daemon->env->hints); daemon->env->hints = NULL; local_zones_delete(daemon->local_zones); daemon->local_zones = NULL; respip_set_delete(daemon->respip_set); daemon->respip_set = NULL; views_delete(daemon->views); daemon->views = NULL; if(daemon->env->auth_zones) auth_zones_cleanup(daemon->env->auth_zones); /* key cache is cleared by module deinit during next daemon_fork() */ daemon_remote_clear(daemon->rc); for(i=0; inum; i++) worker_delete(daemon->workers[i]); free(daemon->workers); daemon->workers = NULL; /* Unless we're trying to keep the cache, worker alloc_caches should be * cleared and freed here. We do this after deleting workers to * guarantee that the alloc caches are valid throughout the lifetime * of workers. */ if(!daemon->reuse_cache || daemon->need_to_exit) daemon_clear_allocs(daemon); daemon->num = 0; #ifdef USE_DNSTAP dt_delete(daemon->dtenv); daemon->dtenv = NULL; #endif #ifdef USE_DNSCRYPT dnsc_delete(daemon->dnscenv); daemon->dnscenv = NULL; #endif #ifdef HAVE_NGTCP2 doq_table_delete(daemon->doq_table); daemon->doq_table = NULL; #endif daemon->cfg = NULL; } void daemon_delete(struct daemon* daemon) { size_t i; if(!daemon) return; modstack_call_deinit(&daemon->mods, daemon->env); modstack_call_destartup(&daemon->mods, daemon->env); modstack_free(&daemon->mods); daemon_remote_delete(daemon->rc); for(i = 0; i < daemon->num_ports; i++) listening_ports_free(daemon->ports[i]); free(daemon->ports); listening_ports_free(daemon->rc_ports); if(daemon->env) { slabhash_delete(daemon->env->msg_cache); rrset_cache_delete(daemon->env->rrset_cache); infra_delete(daemon->env->infra_cache); edns_known_options_delete(daemon->env); edns_strings_delete(daemon->env->edns_strings); auth_zones_delete(daemon->env->auth_zones); } ub_randfree(daemon->rand); alloc_clear(&daemon->superalloc); acl_list_delete(daemon->acl); acl_list_delete(daemon->acl_interface); tcl_list_delete(daemon->tcl); cookie_secrets_delete(daemon->cookie_secrets); listen_desetup_locks(); free(daemon->chroot); free(daemon->pidfile); free(daemon->env); #ifdef HAVE_SSL listen_sslctx_delete_ticket_keys(); SSL_CTX_free((SSL_CTX*)daemon->listen_sslctx); SSL_CTX_free((SSL_CTX*)daemon->connect_sslctx); #endif free(daemon); /* lex cleanup */ ub_c_lex_destroy(); /* libcrypto cleanup */ #ifdef HAVE_SSL # if defined(USE_GOST) sldns_key_EVP_unload_gost(); # endif # if HAVE_DECL_SSL_COMP_GET_COMPRESSION_METHODS && HAVE_DECL_SK_SSL_COMP_POP_FREE # ifndef S_SPLINT_S # if OPENSSL_VERSION_NUMBER < 0x10100000 sk_SSL_COMP_pop_free(comp_meth, (void(*)())CRYPTO_free); # endif # endif # endif # ifdef HAVE_OPENSSL_CONFIG EVP_cleanup(); # if (OPENSSL_VERSION_NUMBER < 0x10100000) && !defined(OPENSSL_NO_ENGINE) && defined(HAVE_ENGINE_CLEANUP) ENGINE_cleanup(); # endif CONF_modules_free(); # endif # ifdef HAVE_CRYPTO_CLEANUP_ALL_EX_DATA CRYPTO_cleanup_all_ex_data(); /* safe, no more threads right now */ # endif # ifdef HAVE_ERR_FREE_STRINGS ERR_free_strings(); # endif # if OPENSSL_VERSION_NUMBER < 0x10100000 RAND_cleanup(); # endif # if defined(HAVE_SSL) && defined(OPENSSL_THREADS) && !defined(THREADS_DISABLED) ub_openssl_lock_delete(); # endif #ifndef HAVE_ARC4RANDOM _ARC4_LOCK_DESTROY(); #endif #elif defined(HAVE_NSS) NSS_Shutdown(); #endif /* HAVE_SSL or HAVE_NSS */ checklock_stop(); #ifdef USE_WINSOCK if(WSACleanup() != 0) { log_err("Could not WSACleanup: %s", wsa_strerror(WSAGetLastError())); } #endif } void daemon_apply_cfg(struct daemon* daemon, struct config_file* cfg) { int new_num = cfg->num_threads?cfg->num_threads:1; daemon->cfg = cfg; config_apply(cfg); /* If this is a reload and we deferred the decision on whether to * reuse the alloc, RRset, and message caches, then check to see if * it's safe to keep the caches: * - changing the number of threads is obviously incompatible with * keeping the per-thread alloc caches. It also means we have to * clear RRset and message caches. (note that 'new_num' may be * adjusted in daemon_create_workers, but for our purpose we can * simply compare it with 'old_num'; if they are equal here, * 'new_num' won't be adjusted to a different value than 'old_num'). * - changing RRset cache size effectively clears any remaining cache * entries. We could keep their keys in alloc caches, but it would * be more consistent with the sense of the change to clear allocs * and free memory. To do so we also have to clear message cache. * - only changing message cache size does not necessarily affect * RRset or alloc cache. But almost all new subsequent queries will * require recursive resolution anyway, so it doesn't help much to * just keep RRset and alloc caches. For simplicity we clear/free * the other two, too. */ if(daemon->worker_allocs && (new_num != daemon->old_num || !slabhash_is_size(daemon->env->msg_cache, cfg->msg_cache_size, cfg->msg_cache_slabs) || !slabhash_is_size(&daemon->env->rrset_cache->table, cfg->rrset_cache_size, cfg->rrset_cache_slabs))) { log_warn("cannot reuse caches due to critical config change"); slabhash_clear(&daemon->env->rrset_cache->table); slabhash_clear(daemon->env->msg_cache); daemon_clear_allocs(daemon); } if(!slabhash_is_size(daemon->env->msg_cache, cfg->msg_cache_size, cfg->msg_cache_slabs)) { slabhash_delete(daemon->env->msg_cache); daemon->env->msg_cache = slabhash_create(cfg->msg_cache_slabs, HASH_DEFAULT_STARTARRAY, cfg->msg_cache_size, msgreply_sizefunc, query_info_compare, query_entry_delete, reply_info_delete, NULL); if(!daemon->env->msg_cache) { fatal_exit("malloc failure updating config settings"); } } if((daemon->env->rrset_cache = rrset_cache_adjust( daemon->env->rrset_cache, cfg, &daemon->superalloc)) == 0) fatal_exit("malloc failure updating config settings"); if((daemon->env->infra_cache = infra_adjust(daemon->env->infra_cache, cfg))==0) fatal_exit("malloc failure updating config settings"); }