/* * Copyright (C) Internet Systems Consortium, Inc. ("ISC") * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * See the COPYRIGHT file distributed with this work for additional * information regarding copyright ownership. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "netmgr-int.h" #include "uv-compat.h" /*% * How many isc_nmhandles and isc_nm_uvreqs will we be * caching for reuse in a socket. */ #define ISC_NM_HANDLES_STACK_SIZE 600 #define ISC_NM_REQS_STACK_SIZE 600 /*% * Shortcut index arrays to get access to statistics counters. */ static const isc_statscounter_t udp4statsindex[] = { isc_sockstatscounter_udp4open, isc_sockstatscounter_udp4openfail, isc_sockstatscounter_udp4close, isc_sockstatscounter_udp4bindfail, isc_sockstatscounter_udp4connectfail, isc_sockstatscounter_udp4connect, -1, -1, isc_sockstatscounter_udp4sendfail, isc_sockstatscounter_udp4recvfail, isc_sockstatscounter_udp4active }; static const isc_statscounter_t udp6statsindex[] = { isc_sockstatscounter_udp6open, isc_sockstatscounter_udp6openfail, isc_sockstatscounter_udp6close, isc_sockstatscounter_udp6bindfail, isc_sockstatscounter_udp6connectfail, isc_sockstatscounter_udp6connect, -1, -1, isc_sockstatscounter_udp6sendfail, isc_sockstatscounter_udp6recvfail, isc_sockstatscounter_udp6active }; static const isc_statscounter_t tcp4statsindex[] = { isc_sockstatscounter_tcp4open, isc_sockstatscounter_tcp4openfail, isc_sockstatscounter_tcp4close, isc_sockstatscounter_tcp4bindfail, isc_sockstatscounter_tcp4connectfail, isc_sockstatscounter_tcp4connect, isc_sockstatscounter_tcp4acceptfail, isc_sockstatscounter_tcp4accept, isc_sockstatscounter_tcp4sendfail, isc_sockstatscounter_tcp4recvfail, isc_sockstatscounter_tcp4active }; static const isc_statscounter_t tcp6statsindex[] = { isc_sockstatscounter_tcp6open, isc_sockstatscounter_tcp6openfail, isc_sockstatscounter_tcp6close, isc_sockstatscounter_tcp6bindfail, isc_sockstatscounter_tcp6connectfail, isc_sockstatscounter_tcp6connect, isc_sockstatscounter_tcp6acceptfail, isc_sockstatscounter_tcp6accept, isc_sockstatscounter_tcp6sendfail, isc_sockstatscounter_tcp6recvfail, isc_sockstatscounter_tcp6active }; #if 0 /* XXX: not currently used */ static const isc_statscounter_t unixstatsindex[] = { isc_sockstatscounter_unixopen, isc_sockstatscounter_unixopenfail, isc_sockstatscounter_unixclose, isc_sockstatscounter_unixbindfail, isc_sockstatscounter_unixconnectfail, isc_sockstatscounter_unixconnect, isc_sockstatscounter_unixacceptfail, isc_sockstatscounter_unixaccept, isc_sockstatscounter_unixsendfail, isc_sockstatscounter_unixrecvfail, isc_sockstatscounter_unixactive }; #endif /* if 0 */ /* * libuv is not thread safe, but has mechanisms to pass messages * between threads. Each socket is owned by a thread. For UDP * sockets we have a set of sockets for each interface and we can * choose a sibling and send the message directly. For TCP, or if * we're calling from a non-networking thread, we need to pass the * request using async_cb. */ static thread_local int isc__nm_tid_v = ISC_NETMGR_TID_UNKNOWN; static void nmsocket_maybe_destroy(isc_nmsocket_t *sock); static void nmhandle_free(isc_nmsocket_t *sock, isc_nmhandle_t *handle); static isc_threadresult_t nm_thread(isc_threadarg_t worker0); static void async_cb(uv_async_t *handle); static void process_queue(isc__networker_t *worker, isc_queue_t *queue); int isc_nm_tid(void) { return (isc__nm_tid_v); } bool isc__nm_in_netthread(void) { return (isc__nm_tid_v >= 0); } isc_nm_t * isc_nm_start(isc_mem_t *mctx, uint32_t workers) { isc_nm_t *mgr = NULL; char name[32]; mgr = isc_mem_get(mctx, sizeof(*mgr)); *mgr = (isc_nm_t){ .nworkers = workers }; isc_mem_attach(mctx, &mgr->mctx); isc_mutex_init(&mgr->lock); isc_condition_init(&mgr->wkstatecond); isc_refcount_init(&mgr->references, 1); atomic_init(&mgr->workers_running, 0); atomic_init(&mgr->workers_paused, 0); atomic_init(&mgr->maxudp, 0); atomic_init(&mgr->paused, false); atomic_init(&mgr->interlocked, false); /* * Default TCP timeout values. * May be updated by isc_nm_tcptimeouts(). */ mgr->init = 30000; mgr->idle = 30000; mgr->keepalive = 30000; mgr->advertised = 30000; isc_mutex_init(&mgr->reqlock); isc_mempool_create(mgr->mctx, sizeof(isc__nm_uvreq_t), &mgr->reqpool); isc_mempool_setname(mgr->reqpool, "nm_reqpool"); isc_mempool_setfreemax(mgr->reqpool, 4096); isc_mempool_associatelock(mgr->reqpool, &mgr->reqlock); isc_mempool_setfillcount(mgr->reqpool, 32); isc_mutex_init(&mgr->evlock); isc_mempool_create(mgr->mctx, sizeof(isc__netievent_storage_t), &mgr->evpool); isc_mempool_setname(mgr->evpool, "nm_evpool"); isc_mempool_setfreemax(mgr->evpool, 4096); isc_mempool_associatelock(mgr->evpool, &mgr->evlock); isc_mempool_setfillcount(mgr->evpool, 32); mgr->workers = isc_mem_get(mctx, workers * sizeof(isc__networker_t)); for (size_t i = 0; i < workers; i++) { int r; isc__networker_t *worker = &mgr->workers[i]; *worker = (isc__networker_t){ .mgr = mgr, .id = i, }; r = uv_loop_init(&worker->loop); RUNTIME_CHECK(r == 0); worker->loop.data = &mgr->workers[i]; r = uv_async_init(&worker->loop, &worker->async, async_cb); RUNTIME_CHECK(r == 0); isc_mutex_init(&worker->lock); isc_condition_init(&worker->cond); worker->ievents = isc_queue_new(mgr->mctx, 128); worker->ievents_prio = isc_queue_new(mgr->mctx, 128); worker->recvbuf = isc_mem_get(mctx, ISC_NETMGR_RECVBUF_SIZE); /* * We need to do this here and not in nm_thread to avoid a * race - we could exit isc_nm_start, launch nm_destroy, * and nm_thread would still not be up. */ atomic_fetch_add_explicit(&mgr->workers_running, 1, memory_order_relaxed); isc_thread_create(nm_thread, &mgr->workers[i], &worker->thread); snprintf(name, sizeof(name), "isc-net-%04zu", i); isc_thread_setname(worker->thread, name); } mgr->magic = NM_MAGIC; return (mgr); } /* * Free the resources of the network manager. */ static void nm_destroy(isc_nm_t **mgr0) { REQUIRE(VALID_NM(*mgr0)); REQUIRE(!isc__nm_in_netthread()); isc_nm_t *mgr = *mgr0; *mgr0 = NULL; isc_refcount_destroy(&mgr->references); mgr->magic = 0; for (size_t i = 0; i < mgr->nworkers; i++) { isc__netievent_t *event = NULL; LOCK(&mgr->workers[i].lock); mgr->workers[i].finished = true; UNLOCK(&mgr->workers[i].lock); event = isc__nm_get_ievent(mgr, netievent_stop); isc__nm_enqueue_ievent(&mgr->workers[i], event); } LOCK(&mgr->lock); while (atomic_load(&mgr->workers_running) > 0) { WAIT(&mgr->wkstatecond, &mgr->lock); } UNLOCK(&mgr->lock); for (size_t i = 0; i < mgr->nworkers; i++) { isc__networker_t *worker = &mgr->workers[i]; isc__netievent_t *ievent = NULL; int r; /* Empty the async event queues */ while ((ievent = (isc__netievent_t *)isc_queue_dequeue( worker->ievents)) != NULL) { isc_mempool_put(mgr->evpool, ievent); } while ((ievent = (isc__netievent_t *)isc_queue_dequeue( worker->ievents_prio)) != NULL) { isc_mempool_put(mgr->evpool, ievent); } r = uv_loop_close(&worker->loop); INSIST(r == 0); isc_queue_destroy(worker->ievents); isc_queue_destroy(worker->ievents_prio); isc_mutex_destroy(&worker->lock); isc_condition_destroy(&worker->cond); isc_mem_put(mgr->mctx, worker->recvbuf, ISC_NETMGR_RECVBUF_SIZE); isc_thread_join(worker->thread, NULL); } if (mgr->stats != NULL) { isc_stats_detach(&mgr->stats); } isc_condition_destroy(&mgr->wkstatecond); isc_mutex_destroy(&mgr->lock); isc_mempool_destroy(&mgr->evpool); isc_mutex_destroy(&mgr->evlock); isc_mempool_destroy(&mgr->reqpool); isc_mutex_destroy(&mgr->reqlock); isc_mem_put(mgr->mctx, mgr->workers, mgr->nworkers * sizeof(isc__networker_t)); isc_mem_putanddetach(&mgr->mctx, mgr, sizeof(*mgr)); } void isc_nm_pause(isc_nm_t *mgr) { REQUIRE(VALID_NM(mgr)); REQUIRE(!isc__nm_in_netthread()); atomic_store(&mgr->paused, true); isc__nm_acquire_interlocked_force(mgr); for (size_t i = 0; i < mgr->nworkers; i++) { isc__netievent_t *event = NULL; LOCK(&mgr->workers[i].lock); mgr->workers[i].paused = true; UNLOCK(&mgr->workers[i].lock); /* * We have to issue a stop, otherwise the uv_run loop will * run indefinitely! */ event = isc__nm_get_ievent(mgr, netievent_stop); isc__nm_enqueue_ievent(&mgr->workers[i], event); } LOCK(&mgr->lock); while (atomic_load_relaxed(&mgr->workers_paused) != atomic_load_relaxed(&mgr->workers_running)) { WAIT(&mgr->wkstatecond, &mgr->lock); } UNLOCK(&mgr->lock); } void isc_nm_resume(isc_nm_t *mgr) { REQUIRE(VALID_NM(mgr)); REQUIRE(!isc__nm_in_netthread()); for (size_t i = 0; i < mgr->nworkers; i++) { LOCK(&mgr->workers[i].lock); mgr->workers[i].paused = false; SIGNAL(&mgr->workers[i].cond); UNLOCK(&mgr->workers[i].lock); } isc__nm_drop_interlocked(mgr); /* * We're not waiting for all the workers to come back to life; * they eventually will, we don't care. */ } void isc_nm_attach(isc_nm_t *mgr, isc_nm_t **dst) { REQUIRE(VALID_NM(mgr)); REQUIRE(dst != NULL && *dst == NULL); isc_refcount_increment(&mgr->references); *dst = mgr; } void isc_nm_detach(isc_nm_t **mgr0) { isc_nm_t *mgr = NULL; REQUIRE(mgr0 != NULL); REQUIRE(VALID_NM(*mgr0)); mgr = *mgr0; *mgr0 = NULL; if (isc_refcount_decrement(&mgr->references) == 1) { nm_destroy(&mgr); } } void isc_nm_closedown(isc_nm_t *mgr) { REQUIRE(VALID_NM(mgr)); atomic_store(&mgr->closing, true); for (size_t i = 0; i < mgr->nworkers; i++) { isc__netievent_t *event = NULL; event = isc__nm_get_ievent(mgr, netievent_shutdown); isc__nm_enqueue_ievent(&mgr->workers[i], event); } } void isc_nm_destroy(isc_nm_t **mgr0) { isc_nm_t *mgr = NULL; REQUIRE(mgr0 != NULL); REQUIRE(VALID_NM(*mgr0)); mgr = *mgr0; /* * Close active connections. */ isc_nm_closedown(mgr); /* * Wait for the manager to be dereferenced elsewhere. */ while (isc_refcount_current(&mgr->references) > 1) { /* * Sometimes libuv gets stuck, pausing and unpausing * netmgr goes over all events in async queue for all * the workers, and since it's done only on shutdown it * doesn't cost us anything. */ isc_nm_pause(mgr); isc_nm_resume(mgr); #ifdef WIN32 _sleep(1000); #else /* ifdef WIN32 */ usleep(1000000); #endif /* ifdef WIN32 */ } /* * Detach final reference. */ isc_nm_detach(mgr0); } void isc_nm_maxudp(isc_nm_t *mgr, uint32_t maxudp) { REQUIRE(VALID_NM(mgr)); atomic_store(&mgr->maxudp, maxudp); } void isc_nm_tcp_settimeouts(isc_nm_t *mgr, uint32_t init, uint32_t idle, uint32_t keepalive, uint32_t advertised) { REQUIRE(VALID_NM(mgr)); mgr->init = init * 100; mgr->idle = idle * 100; mgr->keepalive = keepalive * 100; mgr->advertised = advertised * 100; } void isc_nm_tcp_gettimeouts(isc_nm_t *mgr, uint32_t *initial, uint32_t *idle, uint32_t *keepalive, uint32_t *advertised) { REQUIRE(VALID_NM(mgr)); if (initial != NULL) { *initial = mgr->init / 100; } if (idle != NULL) { *idle = mgr->idle / 100; } if (keepalive != NULL) { *keepalive = mgr->keepalive / 100; } if (advertised != NULL) { *advertised = mgr->advertised / 100; } } /* * nm_thread is a single worker thread, that runs uv_run event loop * until asked to stop. */ static isc_threadresult_t nm_thread(isc_threadarg_t worker0) { isc__networker_t *worker = (isc__networker_t *)worker0; isc__nm_tid_v = worker->id; isc_thread_setaffinity(isc__nm_tid_v); while (true) { int r = uv_run(&worker->loop, UV_RUN_DEFAULT); bool pausing = false; /* * or there's nothing to do. In the first case - wait * for condition. In the latter - timedwait */ LOCK(&worker->lock); while (worker->paused) { LOCK(&worker->mgr->lock); if (!pausing) { atomic_fetch_add_explicit( &worker->mgr->workers_paused, 1, memory_order_acquire); pausing = true; } SIGNAL(&worker->mgr->wkstatecond); UNLOCK(&worker->mgr->lock); WAIT(&worker->cond, &worker->lock); /* Process priority events */ process_queue(worker, worker->ievents_prio); } if (pausing) { uint32_t wp = atomic_fetch_sub_explicit( &worker->mgr->workers_paused, 1, memory_order_release); if (wp == 1) { atomic_store(&worker->mgr->paused, false); } } bool finished = worker->finished; UNLOCK(&worker->lock); if (finished) { /* * We need to launch the loop one more time * in UV_RUN_NOWAIT mode to make sure that * worker->async is closed, so that we can * close the loop cleanly. We don't care * about the callback, as in this case we can * be certain that uv_run() will eat the event. * * XXX: We may need to take steps here to ensure * that all netmgr handles are freed. */ uv_close((uv_handle_t *)&worker->async, NULL); uv_run(&worker->loop, UV_RUN_NOWAIT); break; } if (r == 0) { /* * XXX: uv_run() in UV_RUN_DEFAULT mode returns * zero if there are still active uv_handles. * This shouldn't happen, but if it does, we just * keep checking until they're done. We nap for a * tenth of a second on each loop so as not to burn * CPU. (We do a conditional wait instead, but it * seems like overkill for this case.) */ #ifdef WIN32 _sleep(100); #else /* ifdef WIN32 */ usleep(100000); #endif /* ifdef WIN32 */ } /* * Empty the async queue. */ process_queue(worker, worker->ievents_prio); process_queue(worker, worker->ievents); } LOCK(&worker->mgr->lock); atomic_fetch_sub_explicit(&worker->mgr->workers_running, 1, memory_order_relaxed); SIGNAL(&worker->mgr->wkstatecond); UNLOCK(&worker->mgr->lock); return ((isc_threadresult_t)0); } /* * async_cb is a universal callback for 'async' events sent to event loop. * It's the only way to safely pass data to the libuv event loop. We use a * single async event and a lockless queue of 'isc__netievent_t' structures * passed from other threads. */ static void async_cb(uv_async_t *handle) { isc__networker_t *worker = (isc__networker_t *)handle->loop->data; process_queue(worker, worker->ievents_prio); process_queue(worker, worker->ievents); } static void process_queue(isc__networker_t *worker, isc_queue_t *queue) { isc__netievent_t *ievent = NULL; while ((ievent = (isc__netievent_t *)isc_queue_dequeue(queue)) != NULL) { switch (ievent->type) { case netievent_stop: uv_stop(&worker->loop); isc_mempool_put(worker->mgr->evpool, ievent); return; case netievent_udplisten: isc__nm_async_udplisten(worker, ievent); break; case netievent_udpstop: isc__nm_async_udpstop(worker, ievent); break; case netievent_udpsend: isc__nm_async_udpsend(worker, ievent); break; case netievent_tcpconnect: isc__nm_async_tcpconnect(worker, ievent); break; case netievent_tcplisten: isc__nm_async_tcplisten(worker, ievent); break; case netievent_tcpchildaccept: isc__nm_async_tcpchildaccept(worker, ievent); break; case netievent_tcpaccept: isc__nm_async_tcpaccept(worker, ievent); break; case netievent_tcpstartread: isc__nm_async_tcp_startread(worker, ievent); break; case netievent_tcppauseread: isc__nm_async_tcp_pauseread(worker, ievent); break; case netievent_tcpsend: isc__nm_async_tcpsend(worker, ievent); break; case netievent_tcpstop: isc__nm_async_tcpstop(worker, ievent); break; case netievent_tcpclose: isc__nm_async_tcpclose(worker, ievent); break; case netievent_tcpdnsclose: isc__nm_async_tcpdnsclose(worker, ievent); break; case netievent_closecb: isc__nm_async_closecb(worker, ievent); break; case netievent_shutdown: isc__nm_async_shutdown(worker, ievent); break; default: INSIST(0); ISC_UNREACHABLE(); } isc__nm_put_ievent(worker->mgr, ievent); } } void * isc__nm_get_ievent(isc_nm_t *mgr, isc__netievent_type type) { isc__netievent_storage_t *event = isc_mempool_get(mgr->evpool); *event = (isc__netievent_storage_t){ .ni.type = type }; return (event); } void isc__nm_put_ievent(isc_nm_t *mgr, void *ievent) { isc_mempool_put(mgr->evpool, ievent); } void isc__nm_enqueue_ievent(isc__networker_t *worker, isc__netievent_t *event) { if (event->type > netievent_prio) { /* * We need to make sure this signal will be delivered and * the queue will be processed. */ LOCK(&worker->lock); isc_queue_enqueue(worker->ievents_prio, (uintptr_t)event); SIGNAL(&worker->cond); UNLOCK(&worker->lock); } else { isc_queue_enqueue(worker->ievents, (uintptr_t)event); } uv_async_send(&worker->async); } bool isc__nmsocket_active(isc_nmsocket_t *sock) { REQUIRE(VALID_NMSOCK(sock)); if (sock->parent != NULL) { return (atomic_load(&sock->parent->active)); } return (atomic_load(&sock->active)); } void isc_nmsocket_attach(isc_nmsocket_t *sock, isc_nmsocket_t **target) { REQUIRE(VALID_NMSOCK(sock)); REQUIRE(target != NULL && *target == NULL); if (sock->parent != NULL) { INSIST(sock->parent->parent == NULL); /* sanity check */ isc_refcount_increment0(&sock->parent->references); } else { isc_refcount_increment0(&sock->references); } *target = sock; } /* * Free all resources inside a socket (including its children if any). */ static void nmsocket_cleanup(isc_nmsocket_t *sock, bool dofree) { isc_nmhandle_t *handle = NULL; isc__nm_uvreq_t *uvreq = NULL; REQUIRE(VALID_NMSOCK(sock)); REQUIRE(!isc__nmsocket_active(sock)); atomic_store(&sock->destroying, true); if (sock->parent == NULL && sock->children != NULL) { /* * We shouldn't be here unless there are no active handles, * so we can clean up and free the children. */ for (int i = 0; i < sock->nchildren; i++) { if (!atomic_load(&sock->children[i].destroying)) { nmsocket_cleanup(&sock->children[i], false); } } /* * This was a parent socket; free the children. */ isc_mem_put(sock->mgr->mctx, sock->children, sock->nchildren * sizeof(*sock)); sock->children = NULL; sock->nchildren = 0; } if (sock->statsindex != NULL) { isc__nm_decstats(sock->mgr, sock->statsindex[STATID_ACTIVE]); } if (sock->tcphandle != NULL) { isc_nmhandle_unref(sock->tcphandle); sock->tcphandle = NULL; } while ((handle = isc_astack_pop(sock->inactivehandles)) != NULL) { nmhandle_free(sock, handle); } if (sock->buf != NULL) { isc_mem_free(sock->mgr->mctx, sock->buf); } if (sock->quota != NULL) { isc_quota_detach(&sock->quota); } sock->pquota = NULL; if (sock->timer_initialized) { sock->timer_initialized = false; /* We might be in timer callback */ if (!uv_is_closing((uv_handle_t *)&sock->timer)) { uv_timer_stop(&sock->timer); uv_close((uv_handle_t *)&sock->timer, NULL); } } isc_astack_destroy(sock->inactivehandles); while ((uvreq = isc_astack_pop(sock->inactivereqs)) != NULL) { isc_mempool_put(sock->mgr->reqpool, uvreq); } isc_astack_destroy(sock->inactivereqs); sock->magic = 0; isc_mem_free(sock->mgr->mctx, sock->ah_frees); isc_mem_free(sock->mgr->mctx, sock->ah_handles); isc_mutex_destroy(&sock->lock); isc_condition_destroy(&sock->cond); if (dofree) { isc_nm_t *mgr = sock->mgr; isc_mem_put(mgr->mctx, sock, sizeof(*sock)); isc_nm_detach(&mgr); } else { isc_nm_detach(&sock->mgr); } } static void nmsocket_maybe_destroy(isc_nmsocket_t *sock) { int active_handles; bool destroy = false; if (sock->parent != NULL) { /* * This is a child socket and cannot be destroyed except * as a side effect of destroying the parent, so let's go * see if the parent is ready to be destroyed. */ nmsocket_maybe_destroy(sock->parent); return; } /* * This is a parent socket (or a standalone). See whether the * children have active handles before deciding whether to * accept destruction. */ LOCK(&sock->lock); if (atomic_load(&sock->active) || atomic_load(&sock->destroying) || !atomic_load(&sock->closed) || atomic_load(&sock->references) != 0) { UNLOCK(&sock->lock); return; } active_handles = atomic_load(&sock->ah); if (sock->children != NULL) { for (int i = 0; i < sock->nchildren; i++) { LOCK(&sock->children[i].lock); active_handles += atomic_load(&sock->children[i].ah); UNLOCK(&sock->children[i].lock); } } if (active_handles == 0 || sock->tcphandle != NULL) { destroy = true; } UNLOCK(&sock->lock); if (destroy) { nmsocket_cleanup(sock, true); } } void isc__nmsocket_prep_destroy(isc_nmsocket_t *sock) { REQUIRE(sock->parent == NULL); /* * The final external reference to the socket is gone. We can try * destroying the socket, but we have to wait for all the inflight * handles to finish first. */ atomic_store(&sock->active, false); /* * If the socket has children, they'll need to be marked inactive * so they can be cleaned up too. */ if (sock->children != NULL) { for (int i = 0; i < sock->nchildren; i++) { atomic_store(&sock->children[i].active, false); } } /* * If we're here then we already stopped listening; otherwise * we'd have a hanging reference from the listening process. * * If it's a regular socket we may need to close it. */ if (!atomic_load(&sock->closed)) { switch (sock->type) { case isc_nm_tcpsocket: isc__nm_tcp_close(sock); break; case isc_nm_tcpdnssocket: isc__nm_tcpdns_close(sock); break; default: break; } } nmsocket_maybe_destroy(sock); } void isc_nmsocket_detach(isc_nmsocket_t **sockp) { REQUIRE(sockp != NULL && *sockp != NULL); REQUIRE(VALID_NMSOCK(*sockp)); isc_nmsocket_t *sock = *sockp, *rsock = NULL; *sockp = NULL; /* * If the socket is a part of a set (a child socket) we are * counting references for the whole set at the parent. */ if (sock->parent != NULL) { rsock = sock->parent; INSIST(rsock->parent == NULL); /* Sanity check */ } else { rsock = sock; } if (isc_refcount_decrement(&rsock->references) == 1) { isc__nmsocket_prep_destroy(rsock); } } void isc__nmsocket_init(isc_nmsocket_t *sock, isc_nm_t *mgr, isc_nmsocket_type type, isc_nmiface_t *iface) { uint16_t family; REQUIRE(sock != NULL); REQUIRE(mgr != NULL); REQUIRE(iface != NULL); family = iface->addr.type.sa.sa_family; *sock = (isc_nmsocket_t){ .type = type, .iface = iface, .fd = -1, .ah_size = 32, .inactivehandles = isc_astack_new( mgr->mctx, ISC_NM_HANDLES_STACK_SIZE), .inactivereqs = isc_astack_new( mgr->mctx, ISC_NM_REQS_STACK_SIZE) }; isc_nm_attach(mgr, &sock->mgr); sock->uv_handle.handle.data = sock; sock->ah_frees = isc_mem_allocate(mgr->mctx, sock->ah_size * sizeof(size_t)); sock->ah_handles = isc_mem_allocate( mgr->mctx, sock->ah_size * sizeof(isc_nmhandle_t *)); ISC_LINK_INIT(&sock->quotacb, link); for (size_t i = 0; i < 32; i++) { sock->ah_frees[i] = i; sock->ah_handles[i] = NULL; } switch (type) { case isc_nm_udpsocket: case isc_nm_udplistener: if (family == AF_INET) { sock->statsindex = udp4statsindex; } else { sock->statsindex = udp6statsindex; } isc__nm_incstats(sock->mgr, sock->statsindex[STATID_ACTIVE]); break; case isc_nm_tcpsocket: case isc_nm_tcplistener: if (family == AF_INET) { sock->statsindex = tcp4statsindex; } else { sock->statsindex = tcp6statsindex; } isc__nm_incstats(sock->mgr, sock->statsindex[STATID_ACTIVE]); break; default: break; } isc_mutex_init(&sock->lock); isc_condition_init(&sock->cond); isc_refcount_init(&sock->references, 1); atomic_init(&sock->active, true); atomic_init(&sock->sequential, false); atomic_init(&sock->overlimit, false); atomic_init(&sock->processing, false); atomic_init(&sock->readpaused, false); sock->magic = NMSOCK_MAGIC; } void isc__nm_alloc_cb(uv_handle_t *handle, size_t size, uv_buf_t *buf) { isc_nmsocket_t *sock = uv_handle_get_data(handle); isc__networker_t *worker = NULL; REQUIRE(VALID_NMSOCK(sock)); REQUIRE(isc__nm_in_netthread()); REQUIRE(size <= ISC_NETMGR_RECVBUF_SIZE); worker = &sock->mgr->workers[sock->tid]; INSIST(!worker->recvbuf_inuse); buf->base = worker->recvbuf; worker->recvbuf_inuse = true; buf->len = ISC_NETMGR_RECVBUF_SIZE; } void isc__nm_free_uvbuf(isc_nmsocket_t *sock, const uv_buf_t *buf) { isc__networker_t *worker = NULL; REQUIRE(VALID_NMSOCK(sock)); if (buf->base == NULL) { /* Empty buffer: might happen in case of error. */ return; } worker = &sock->mgr->workers[sock->tid]; REQUIRE(worker->recvbuf_inuse); if (buf->base > worker->recvbuf && buf->base <= worker->recvbuf + ISC_NETMGR_RECVBUF_SIZE) { /* Can happen in case of out-of-order recvmmsg in libuv1.36 */ return; } REQUIRE(buf->base == worker->recvbuf); worker->recvbuf_inuse = false; } static isc_nmhandle_t * alloc_handle(isc_nmsocket_t *sock) { isc_nmhandle_t *handle = isc_mem_get(sock->mgr->mctx, sizeof(isc_nmhandle_t) + sock->extrahandlesize); *handle = (isc_nmhandle_t){ .magic = NMHANDLE_MAGIC }; isc_refcount_init(&handle->references, 1); return (handle); } isc_nmhandle_t * isc__nmhandle_get(isc_nmsocket_t *sock, isc_sockaddr_t *peer, isc_sockaddr_t *local) { isc_nmhandle_t *handle = NULL; size_t handlenum; int pos; REQUIRE(VALID_NMSOCK(sock)); handle = isc_astack_pop(sock->inactivehandles); if (handle == NULL) { handle = alloc_handle(sock); } else { INSIST(VALID_NMHANDLE(handle)); isc_refcount_increment0(&handle->references); } handle->sock = sock; if (peer != NULL) { memcpy(&handle->peer, peer, sizeof(isc_sockaddr_t)); } else { memcpy(&handle->peer, &sock->peer, sizeof(isc_sockaddr_t)); } if (local != NULL) { memcpy(&handle->local, local, sizeof(isc_sockaddr_t)); } else if (sock->iface != NULL) { memcpy(&handle->local, &sock->iface->addr, sizeof(isc_sockaddr_t)); } else { INSIST(0); ISC_UNREACHABLE(); } LOCK(&sock->lock); /* We need to add this handle to the list of active handles */ if ((size_t)atomic_load(&sock->ah) == sock->ah_size) { sock->ah_frees = isc_mem_reallocate(sock->mgr->mctx, sock->ah_frees, sock->ah_size * 2 * sizeof(size_t)); sock->ah_handles = isc_mem_reallocate( sock->mgr->mctx, sock->ah_handles, sock->ah_size * 2 * sizeof(isc_nmhandle_t *)); for (size_t i = sock->ah_size; i < sock->ah_size * 2; i++) { sock->ah_frees[i] = i; sock->ah_handles[i] = NULL; } sock->ah_size *= 2; } handlenum = atomic_fetch_add(&sock->ah, 1); pos = sock->ah_frees[handlenum]; INSIST(sock->ah_handles[pos] == NULL); sock->ah_handles[pos] = handle; handle->ah_pos = pos; UNLOCK(&sock->lock); if (sock->type == isc_nm_tcpsocket) { INSIST(sock->tcphandle == NULL); sock->tcphandle = handle; } return (handle); } void isc_nmhandle_ref(isc_nmhandle_t *handle) { REQUIRE(VALID_NMHANDLE(handle)); isc_refcount_increment(&handle->references); } bool isc_nmhandle_is_stream(isc_nmhandle_t *handle) { REQUIRE(VALID_NMHANDLE(handle)); return (handle->sock->type == isc_nm_tcpsocket || handle->sock->type == isc_nm_tcpdnssocket); } static void nmhandle_free(isc_nmsocket_t *sock, isc_nmhandle_t *handle) { size_t extra = sock->extrahandlesize; isc_refcount_destroy(&handle->references); if (handle->dofree != NULL) { handle->dofree(handle->opaque); } *handle = (isc_nmhandle_t){ .magic = 0 }; isc_mem_put(sock->mgr->mctx, handle, sizeof(isc_nmhandle_t) + extra); } static void nmhandle_deactivate(isc_nmsocket_t *sock, isc_nmhandle_t *handle) { /* * We do all of this under lock to avoid races with socket * destruction. We have to do this now, because at this point the * socket is either unused or still attached to event->sock. */ LOCK(&sock->lock); INSIST(sock->ah_handles[handle->ah_pos] == handle); INSIST(sock->ah_size > handle->ah_pos); INSIST(atomic_load(&sock->ah) > 0); sock->ah_handles[handle->ah_pos] = NULL; size_t handlenum = atomic_fetch_sub(&sock->ah, 1) - 1; sock->ah_frees[handlenum] = handle->ah_pos; handle->ah_pos = 0; bool reuse = false; if (atomic_load(&sock->active)) { reuse = isc_astack_trypush(sock->inactivehandles, handle); } if (!reuse) { nmhandle_free(sock, handle); } UNLOCK(&sock->lock); } void isc_nmhandle_unref(isc_nmhandle_t *handle) { isc_nmsocket_t *sock = NULL, *tmp = NULL; REQUIRE(VALID_NMHANDLE(handle)); if (isc_refcount_decrement(&handle->references) > 1) { return; } /* We need an acquire memory barrier here */ (void)isc_refcount_current(&handle->references); sock = handle->sock; handle->sock = NULL; if (handle->doreset != NULL) { handle->doreset(handle->opaque); } /* * Temporarily reference the socket to ensure that it can't * be deleted by another thread while we're deactivating the * handle. */ isc_nmsocket_attach(sock, &tmp); nmhandle_deactivate(sock, handle); /* * The handle is gone now. If the socket has a callback configured * for that (e.g., to perform cleanup after request processing), * call it now, or schedule it to run asynchronously. */ if (sock->closehandle_cb != NULL) { if (sock->tid == isc_nm_tid()) { sock->closehandle_cb(sock); } else { isc__netievent_closecb_t *event = isc__nm_get_ievent( sock->mgr, netievent_closecb); /* * The socket will be finally detached by the closecb * event handler. */ isc_nmsocket_attach(sock, &event->sock); isc__nm_enqueue_ievent(&sock->mgr->workers[sock->tid], (isc__netievent_t *)event); } } isc_nmsocket_detach(&tmp); } void * isc_nmhandle_getdata(isc_nmhandle_t *handle) { REQUIRE(VALID_NMHANDLE(handle)); return (handle->opaque); } void isc_nmhandle_setdata(isc_nmhandle_t *handle, void *arg, isc_nm_opaquecb_t doreset, isc_nm_opaquecb_t dofree) { REQUIRE(VALID_NMHANDLE(handle)); handle->opaque = arg; handle->doreset = doreset; handle->dofree = dofree; } void * isc_nmhandle_getextra(isc_nmhandle_t *handle) { REQUIRE(VALID_NMHANDLE(handle)); return (handle->extra); } isc_sockaddr_t isc_nmhandle_peeraddr(isc_nmhandle_t *handle) { REQUIRE(VALID_NMHANDLE(handle)); return (handle->peer); } isc_sockaddr_t isc_nmhandle_localaddr(isc_nmhandle_t *handle) { REQUIRE(VALID_NMHANDLE(handle)); return (handle->local); } isc_nm_t * isc_nmhandle_netmgr(isc_nmhandle_t *handle) { REQUIRE(VALID_NMHANDLE(handle)); REQUIRE(VALID_NMSOCK(handle->sock)); return (handle->sock->mgr); } isc__nm_uvreq_t * isc__nm_uvreq_get(isc_nm_t *mgr, isc_nmsocket_t *sock) { isc__nm_uvreq_t *req = NULL; REQUIRE(VALID_NM(mgr)); REQUIRE(VALID_NMSOCK(sock)); if (sock != NULL && atomic_load(&sock->active)) { /* Try to reuse one */ req = isc_astack_pop(sock->inactivereqs); } if (req == NULL) { req = isc_mempool_get(mgr->reqpool); } *req = (isc__nm_uvreq_t){ .magic = 0 }; req->uv_req.req.data = req; isc_nmsocket_attach(sock, &req->sock); req->magic = UVREQ_MAGIC; return (req); } void isc__nm_uvreq_put(isc__nm_uvreq_t **req0, isc_nmsocket_t *sock) { isc__nm_uvreq_t *req = NULL; isc_nmhandle_t *handle = NULL; REQUIRE(req0 != NULL); REQUIRE(VALID_UVREQ(*req0)); req = *req0; *req0 = NULL; INSIST(sock == req->sock); req->magic = 0; /* * We need to save this first to make sure that handle, * sock, and the netmgr won't all disappear. */ handle = req->handle; req->handle = NULL; if (!atomic_load(&sock->active) || !isc_astack_trypush(sock->inactivereqs, req)) { isc_mempool_put(sock->mgr->reqpool, req); } if (handle != NULL) { isc_nmhandle_unref(handle); } isc_nmsocket_detach(&sock); } isc_result_t isc_nm_send(isc_nmhandle_t *handle, isc_region_t *region, isc_nm_cb_t cb, void *cbarg) { REQUIRE(VALID_NMHANDLE(handle)); switch (handle->sock->type) { case isc_nm_udpsocket: case isc_nm_udplistener: return (isc__nm_udp_send(handle, region, cb, cbarg)); case isc_nm_tcpsocket: return (isc__nm_tcp_send(handle, region, cb, cbarg)); case isc_nm_tcpdnssocket: return (isc__nm_tcpdns_send(handle, region, cb, cbarg)); default: INSIST(0); ISC_UNREACHABLE(); } } isc_result_t isc_nm_read(isc_nmhandle_t *handle, isc_nm_recv_cb_t cb, void *cbarg) { REQUIRE(VALID_NMHANDLE(handle)); switch (handle->sock->type) { case isc_nm_tcpsocket: return (isc__nm_tcp_read(handle, cb, cbarg)); default: INSIST(0); ISC_UNREACHABLE(); } } isc_result_t isc_nm_pauseread(isc_nmsocket_t *sock) { REQUIRE(VALID_NMSOCK(sock)); switch (sock->type) { case isc_nm_tcpsocket: return (isc__nm_tcp_pauseread(sock)); default: INSIST(0); ISC_UNREACHABLE(); } } isc_result_t isc_nm_resumeread(isc_nmsocket_t *sock) { REQUIRE(VALID_NMSOCK(sock)); switch (sock->type) { case isc_nm_tcpsocket: return (isc__nm_tcp_resumeread(sock)); default: INSIST(0); ISC_UNREACHABLE(); } } void isc_nm_stoplistening(isc_nmsocket_t *sock) { REQUIRE(VALID_NMSOCK(sock)); switch (sock->type) { case isc_nm_udplistener: isc__nm_udp_stoplistening(sock); break; case isc_nm_tcpdnslistener: isc__nm_tcpdns_stoplistening(sock); break; case isc_nm_tcplistener: isc__nm_tcp_stoplistening(sock); break; default: INSIST(0); ISC_UNREACHABLE(); } } void isc__nm_async_closecb(isc__networker_t *worker, isc__netievent_t *ev0) { isc__netievent_closecb_t *ievent = (isc__netievent_closecb_t *)ev0; REQUIRE(VALID_NMSOCK(ievent->sock)); REQUIRE(ievent->sock->tid == isc_nm_tid()); REQUIRE(ievent->sock->closehandle_cb != NULL); UNUSED(worker); ievent->sock->closehandle_cb(ievent->sock); isc_nmsocket_detach(&ievent->sock); } static void shutdown_walk_cb(uv_handle_t *handle, void *arg) { UNUSED(arg); switch (handle->type) { case UV_TCP: isc__nm_tcp_shutdown(uv_handle_get_data(handle)); break; default: break; } } void isc__nm_async_shutdown(isc__networker_t *worker, isc__netievent_t *ev0) { UNUSED(ev0); uv_walk(&worker->loop, shutdown_walk_cb, NULL); } bool isc__nm_acquire_interlocked(isc_nm_t *mgr) { LOCK(&mgr->lock); bool success = atomic_compare_exchange_strong(&mgr->interlocked, &(bool){ false }, true); UNLOCK(&mgr->lock); return (success); } void isc__nm_drop_interlocked(isc_nm_t *mgr) { LOCK(&mgr->lock); bool success = atomic_compare_exchange_strong(&mgr->interlocked, &(bool){ true }, false); INSIST(success); BROADCAST(&mgr->wkstatecond); UNLOCK(&mgr->lock); } void isc__nm_acquire_interlocked_force(isc_nm_t *mgr) { LOCK(&mgr->lock); while (!atomic_compare_exchange_strong(&mgr->interlocked, &(bool){ false }, true)) { WAIT(&mgr->wkstatecond, &mgr->lock); } UNLOCK(&mgr->lock); } void isc_nm_setstats(isc_nm_t *mgr, isc_stats_t *stats) { REQUIRE(VALID_NM(mgr)); REQUIRE(mgr->stats == NULL); REQUIRE(isc_stats_ncounters(stats) == isc_sockstatscounter_max); isc_stats_attach(stats, &mgr->stats); } void isc__nm_incstats(isc_nm_t *mgr, isc_statscounter_t counterid) { REQUIRE(VALID_NM(mgr)); REQUIRE(counterid != -1); if (mgr->stats != NULL) { isc_stats_increment(mgr->stats, counterid); } } void isc__nm_decstats(isc_nm_t *mgr, isc_statscounter_t counterid) { REQUIRE(VALID_NM(mgr)); REQUIRE(counterid != -1); if (mgr->stats != NULL) { isc_stats_decrement(mgr->stats, counterid); } }