/* $NetBSD: task.c,v 1.16.2.2 2024/02/25 15:47:18 martin Exp $ */ /* * Copyright (C) Internet Systems Consortium, Inc. ("ISC") * * SPDX-License-Identifier: MPL-2.0 * * 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 https://mozilla.org/MPL/2.0/. * * See the COPYRIGHT file distributed with this work for additional * information regarding copyright ownership. */ /*! \file */ /* * XXXRTH Need to document the states a task can be in, and the rules * for changing states. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef HAVE_LIBXML2 #include #define ISC_XMLCHAR (const xmlChar *) #endif /* HAVE_LIBXML2 */ #ifdef HAVE_JSON_C #include #endif /* HAVE_JSON_C */ #include "task_p.h" /* * Task manager is built around 'as little locking as possible' concept. * Each thread has his own queue of tasks to be run, if a task is in running * state it will stay on the runner it's currently on, if a task is in idle * state it can be woken up on a specific runner with isc_task_sendto - that * helps with data locality on CPU. * * To make load even some tasks (from task pools) are bound to specific * queues using isc_task_create_bound. This way load balancing between * CPUs/queues happens on the higher layer. */ #ifdef ISC_TASK_TRACE #define XTRACE(m) \ fprintf(stderr, "task %p thread %zu: %s\n", task, isc_tid_v, (m)) #define XTTRACE(t, m) \ fprintf(stderr, "task %p thread %zu: %s\n", (t), isc_tid_v, (m)) #define XTHREADTRACE(m) fprintf(stderr, "thread %zu: %s\n", isc_tid_v, (m)) #else /* ifdef ISC_TASK_TRACE */ #define XTRACE(m) #define XTTRACE(t, m) #define XTHREADTRACE(m) #endif /* ifdef ISC_TASK_TRACE */ /*** *** Types. ***/ typedef enum { task_state_idle, /* not doing anything, events queue empty */ task_state_ready, /* waiting in worker's queue */ task_state_running, /* actively processing events */ task_state_done /* shutting down, no events or references */ } task_state_t; #if defined(HAVE_LIBXML2) || defined(HAVE_JSON_C) static const char *statenames[] = { "idle", "ready", "running", "done", }; #endif /* if defined(HAVE_LIBXML2) || defined(HAVE_JSON_C) */ #define TASK_MAGIC ISC_MAGIC('T', 'A', 'S', 'K') #define VALID_TASK(t) ISC_MAGIC_VALID(t, TASK_MAGIC) struct isc_task { /* Not locked. */ unsigned int magic; isc_taskmgr_t *manager; isc_mutex_t lock; /* Locked by task lock. */ int threadid; task_state_t state; isc_refcount_t references; isc_refcount_t running; isc_eventlist_t events; isc_eventlist_t on_shutdown; unsigned int nevents; unsigned int quantum; isc_stdtime_t now; isc_time_t tnow; char name[16]; void *tag; bool bound; /* Protected by atomics */ atomic_bool shuttingdown; atomic_bool privileged; /* Locked by task manager lock. */ LINK(isc_task_t) link; }; #define TASK_SHUTTINGDOWN(t) (atomic_load_acquire(&(t)->shuttingdown)) #define TASK_PRIVILEGED(t) (atomic_load_acquire(&(t)->privileged)) #define TASK_MANAGER_MAGIC ISC_MAGIC('T', 'S', 'K', 'M') #define VALID_MANAGER(m) ISC_MAGIC_VALID(m, TASK_MANAGER_MAGIC) struct isc_taskmgr { /* Not locked. */ unsigned int magic; isc_refcount_t references; isc_mem_t *mctx; isc_mutex_t lock; atomic_uint_fast32_t tasks_count; isc_nm_t *netmgr; /* Locked by task manager lock. */ unsigned int default_quantum; LIST(isc_task_t) tasks; atomic_uint_fast32_t mode; atomic_bool exclusive_req; bool exiting; isc_task_t *excl; }; #define DEFAULT_DEFAULT_QUANTUM 25 /*% * The following are intended for internal use (indicated by "isc__" * prefix) but are not declared as static, allowing direct access from * unit tests etc. */ bool isc_task_purgeevent(isc_task_t *task, isc_event_t *event); void isc_taskmgr_setexcltask(isc_taskmgr_t *mgr, isc_task_t *task); isc_result_t isc_taskmgr_excltask(isc_taskmgr_t *mgr, isc_task_t **taskp); /*** *** Tasks. ***/ static void task_finished(isc_task_t *task) { isc_taskmgr_t *manager = task->manager; isc_mem_t *mctx = manager->mctx; REQUIRE(EMPTY(task->events)); REQUIRE(task->nevents == 0); REQUIRE(EMPTY(task->on_shutdown)); REQUIRE(task->state == task_state_done); XTRACE("task_finished"); isc_refcount_destroy(&task->running); isc_refcount_destroy(&task->references); LOCK(&manager->lock); UNLINK(manager->tasks, task, link); atomic_fetch_sub(&manager->tasks_count, 1); UNLOCK(&manager->lock); isc_mutex_destroy(&task->lock); task->magic = 0; isc_mem_put(mctx, task, sizeof(*task)); isc_taskmgr_detach(&manager); } isc_result_t isc_task_create(isc_taskmgr_t *manager, unsigned int quantum, isc_task_t **taskp) { return (isc_task_create_bound(manager, quantum, taskp, -1)); } isc_result_t isc_task_create_bound(isc_taskmgr_t *manager, unsigned int quantum, isc_task_t **taskp, int threadid) { isc_task_t *task = NULL; bool exiting; REQUIRE(VALID_MANAGER(manager)); REQUIRE(taskp != NULL && *taskp == NULL); XTRACE("isc_task_create"); task = isc_mem_get(manager->mctx, sizeof(*task)); *task = (isc_task_t){ 0 }; isc_taskmgr_attach(manager, &task->manager); if (threadid == -1) { /* * Task is not pinned to a queue, it's threadid will be * chosen when first task will be sent to it - either * randomly or specified by isc_task_sendto. */ task->bound = false; task->threadid = -1; } else { /* * Task is pinned to a queue, it'll always be run * by a specific thread. */ task->bound = true; task->threadid = threadid; } isc_mutex_init(&task->lock); task->state = task_state_idle; isc_refcount_init(&task->references, 1); isc_refcount_init(&task->running, 0); INIT_LIST(task->events); INIT_LIST(task->on_shutdown); task->nevents = 0; task->quantum = (quantum > 0) ? quantum : manager->default_quantum; atomic_init(&task->shuttingdown, false); atomic_init(&task->privileged, false); task->now = 0; isc_time_settoepoch(&task->tnow); memset(task->name, 0, sizeof(task->name)); task->tag = NULL; INIT_LINK(task, link); task->magic = TASK_MAGIC; LOCK(&manager->lock); exiting = manager->exiting; if (!exiting) { APPEND(manager->tasks, task, link); atomic_fetch_add(&manager->tasks_count, 1); } UNLOCK(&manager->lock); if (exiting) { isc_refcount_destroy(&task->running); isc_refcount_decrement(&task->references); isc_refcount_destroy(&task->references); isc_mutex_destroy(&task->lock); isc_taskmgr_detach(&task->manager); isc_mem_put(manager->mctx, task, sizeof(*task)); return (ISC_R_SHUTTINGDOWN); } *taskp = task; return (ISC_R_SUCCESS); } void isc_task_attach(isc_task_t *source, isc_task_t **targetp) { /* * Attach *targetp to source. */ REQUIRE(VALID_TASK(source)); REQUIRE(targetp != NULL && *targetp == NULL); XTTRACE(source, "isc_task_attach"); isc_refcount_increment(&source->references); *targetp = source; } static bool task_shutdown(isc_task_t *task) { bool was_idle = false; isc_event_t *event, *prev; /* * Caller must be holding the task's lock. */ XTRACE("task_shutdown"); if (atomic_compare_exchange_strong(&task->shuttingdown, &(bool){ false }, true)) { XTRACE("shutting down"); if (task->state == task_state_idle) { INSIST(EMPTY(task->events)); task->state = task_state_ready; was_idle = true; } INSIST(task->state == task_state_ready || task->state == task_state_running); /* * Note that we post shutdown events LIFO. */ for (event = TAIL(task->on_shutdown); event != NULL; event = prev) { prev = PREV(event, ev_link); DEQUEUE(task->on_shutdown, event, ev_link); ENQUEUE(task->events, event, ev_link); task->nevents++; } } return (was_idle); } /* * Moves a task onto the appropriate run queue. * * Caller must NOT hold queue lock. */ static void task_ready(isc_task_t *task) { isc_taskmgr_t *manager = task->manager; REQUIRE(VALID_MANAGER(manager)); XTRACE("task_ready"); isc_refcount_increment0(&task->running); LOCK(&task->lock); isc_nm_task_enqueue(manager->netmgr, task, task->threadid); UNLOCK(&task->lock); } void isc_task_ready(isc_task_t *task) { task_ready(task); } static bool task_detach(isc_task_t *task) { /* * Caller must be holding the task lock. */ XTRACE("detach"); if (isc_refcount_decrement(&task->references) == 1 && task->state == task_state_idle) { INSIST(EMPTY(task->events)); /* * There are no references to this task, and no * pending events. We could try to optimize and * either initiate shutdown or clean up the task, * depending on its state, but it's easier to just * make the task ready and allow run() or the event * loop to deal with shutting down and termination. */ task->state = task_state_ready; return (true); } return (false); } void isc_task_detach(isc_task_t **taskp) { isc_task_t *task; bool was_idle; /* * Detach *taskp from its task. */ REQUIRE(taskp != NULL); task = *taskp; REQUIRE(VALID_TASK(task)); XTRACE("isc_task_detach"); LOCK(&task->lock); was_idle = task_detach(task); UNLOCK(&task->lock); if (was_idle) { task_ready(task); } *taskp = NULL; } static bool task_send(isc_task_t *task, isc_event_t **eventp, int c) { bool was_idle = false; isc_event_t *event; /* * Caller must be holding the task lock. */ REQUIRE(eventp != NULL); event = *eventp; *eventp = NULL; REQUIRE(event != NULL); REQUIRE(event->ev_type > 0); REQUIRE(task->state != task_state_done); REQUIRE(!ISC_LINK_LINKED(event, ev_ratelink)); XTRACE("task_send"); if (task->bound) { c = task->threadid; } else if (c < 0) { c = -1; } if (task->state == task_state_idle) { was_idle = true; task->threadid = c; INSIST(EMPTY(task->events)); task->state = task_state_ready; } INSIST(task->state == task_state_ready || task->state == task_state_running); ENQUEUE(task->events, event, ev_link); task->nevents++; return (was_idle); } void isc_task_send(isc_task_t *task, isc_event_t **eventp) { isc_task_sendto(task, eventp, -1); } void isc_task_sendanddetach(isc_task_t **taskp, isc_event_t **eventp) { isc_task_sendtoanddetach(taskp, eventp, -1); } void isc_task_sendto(isc_task_t *task, isc_event_t **eventp, int c) { bool was_idle; /* * Send '*event' to 'task'. */ REQUIRE(VALID_TASK(task)); XTRACE("isc_task_send"); /* * We're trying hard to hold locks for as short a time as possible. * We're also trying to hold as few locks as possible. This is why * some processing is deferred until after the lock is released. */ LOCK(&task->lock); was_idle = task_send(task, eventp, c); UNLOCK(&task->lock); if (was_idle) { /* * We need to add this task to the ready queue. * * We've waited until now to do it because making a task * ready requires locking the manager. If we tried to do * this while holding the task lock, we could deadlock. * * We've changed the state to ready, so no one else will * be trying to add this task to the ready queue. The * only way to leave the ready state is by executing the * task. It thus doesn't matter if events are added, * removed, or a shutdown is started in the interval * between the time we released the task lock, and the time * we add the task to the ready queue. */ task_ready(task); } } void isc_task_sendtoanddetach(isc_task_t **taskp, isc_event_t **eventp, int c) { bool idle1, idle2; isc_task_t *task; /* * Send '*event' to '*taskp' and then detach '*taskp' from its * task. */ REQUIRE(taskp != NULL); task = *taskp; REQUIRE(VALID_TASK(task)); XTRACE("isc_task_sendanddetach"); LOCK(&task->lock); idle1 = task_send(task, eventp, c); idle2 = task_detach(task); UNLOCK(&task->lock); /* * If idle1, then idle2 shouldn't be true as well since we're holding * the task lock, and thus the task cannot switch from ready back to * idle. */ INSIST(!(idle1 && idle2)); if (idle1 || idle2) { task_ready(task); } *taskp = NULL; } #define PURGE_OK(event) (((event)->ev_attributes & ISC_EVENTATTR_NOPURGE) == 0) static unsigned int dequeue_events(isc_task_t *task, void *sender, isc_eventtype_t first, isc_eventtype_t last, void *tag, isc_eventlist_t *events, bool purging) { isc_event_t *event, *next_event; unsigned int count = 0; REQUIRE(VALID_TASK(task)); REQUIRE(last >= first); XTRACE("dequeue_events"); /* * Events matching 'sender', whose type is >= first and <= last, and * whose tag is 'tag' will be dequeued. If 'purging', matching events * which are marked as unpurgable will not be dequeued. * * sender == NULL means "any sender", and tag == NULL means "any tag". */ LOCK(&task->lock); for (event = HEAD(task->events); event != NULL; event = next_event) { next_event = NEXT(event, ev_link); if (event->ev_type >= first && event->ev_type <= last && (sender == NULL || event->ev_sender == sender) && (tag == NULL || event->ev_tag == tag) && (!purging || PURGE_OK(event))) { DEQUEUE(task->events, event, ev_link); task->nevents--; ENQUEUE(*events, event, ev_link); count++; } } UNLOCK(&task->lock); return (count); } unsigned int isc_task_purgerange(isc_task_t *task, void *sender, isc_eventtype_t first, isc_eventtype_t last, void *tag) { unsigned int count; isc_eventlist_t events; isc_event_t *event, *next_event; REQUIRE(VALID_TASK(task)); /* * Purge events from a task's event queue. */ XTRACE("isc_task_purgerange"); ISC_LIST_INIT(events); count = dequeue_events(task, sender, first, last, tag, &events, true); for (event = HEAD(events); event != NULL; event = next_event) { next_event = NEXT(event, ev_link); ISC_LIST_UNLINK(events, event, ev_link); isc_event_free(&event); } /* * Note that purging never changes the state of the task. */ return (count); } unsigned int isc_task_purge(isc_task_t *task, void *sender, isc_eventtype_t type, void *tag) { /* * Purge events from a task's event queue. */ REQUIRE(VALID_TASK(task)); XTRACE("isc_task_purge"); return (isc_task_purgerange(task, sender, type, type, tag)); } bool isc_task_purgeevent(isc_task_t *task, isc_event_t *event) { bool found = false; /* * Purge 'event' from a task's event queue. */ REQUIRE(VALID_TASK(task)); /* * If 'event' is on the task's event queue, it will be purged, * unless it is marked as unpurgeable. 'event' does not have to be * on the task's event queue; in fact, it can even be an invalid * pointer. Purging only occurs if the event is actually on the task's * event queue. * * Purging never changes the state of the task. */ LOCK(&task->lock); if (ISC_LINK_LINKED(event, ev_link)) { DEQUEUE(task->events, event, ev_link); task->nevents--; found = true; } UNLOCK(&task->lock); if (!found) { return (false); } isc_event_free(&event); return (true); } unsigned int isc_task_unsend(isc_task_t *task, void *sender, isc_eventtype_t type, void *tag, isc_eventlist_t *events) { /* * Remove events from a task's event queue. */ XTRACE("isc_task_unsend"); return (dequeue_events(task, sender, type, type, tag, events, false)); } isc_result_t isc_task_onshutdown(isc_task_t *task, isc_taskaction_t action, void *arg) { bool disallowed = false; isc_result_t result = ISC_R_SUCCESS; isc_event_t *event; /* * Send a shutdown event with action 'action' and argument 'arg' when * 'task' is shutdown. */ REQUIRE(VALID_TASK(task)); REQUIRE(action != NULL); event = isc_event_allocate(task->manager->mctx, NULL, ISC_TASKEVENT_SHUTDOWN, action, arg, sizeof(*event)); if (TASK_SHUTTINGDOWN(task)) { disallowed = true; result = ISC_R_SHUTTINGDOWN; } else { LOCK(&task->lock); ENQUEUE(task->on_shutdown, event, ev_link); UNLOCK(&task->lock); } if (disallowed) { isc_mem_put(task->manager->mctx, event, sizeof(*event)); } return (result); } void isc_task_shutdown(isc_task_t *task) { bool was_idle; /* * Shutdown 'task'. */ REQUIRE(VALID_TASK(task)); LOCK(&task->lock); was_idle = task_shutdown(task); UNLOCK(&task->lock); if (was_idle) { task_ready(task); } } void isc_task_destroy(isc_task_t **taskp) { /* * Destroy '*taskp'. */ REQUIRE(taskp != NULL); isc_task_shutdown(*taskp); isc_task_detach(taskp); } void isc_task_setname(isc_task_t *task, const char *name, void *tag) { /* * Name 'task'. */ REQUIRE(VALID_TASK(task)); LOCK(&task->lock); strlcpy(task->name, name, sizeof(task->name)); task->tag = tag; UNLOCK(&task->lock); } const char * isc_task_getname(isc_task_t *task) { REQUIRE(VALID_TASK(task)); return (task->name); } void * isc_task_gettag(isc_task_t *task) { REQUIRE(VALID_TASK(task)); return (task->tag); } isc_nm_t * isc_task_getnetmgr(isc_task_t *task) { REQUIRE(VALID_TASK(task)); return (task->manager->netmgr); } void isc_task_setquantum(isc_task_t *task, unsigned int quantum) { REQUIRE(VALID_TASK(task)); LOCK(&task->lock); task->quantum = (quantum > 0) ? quantum : task->manager->default_quantum; UNLOCK(&task->lock); } /*** *** Task Manager. ***/ static isc_result_t task_run(isc_task_t *task) { unsigned int dispatch_count = 0; bool finished = false; isc_event_t *event = NULL; isc_result_t result = ISC_R_SUCCESS; uint32_t quantum; REQUIRE(VALID_TASK(task)); LOCK(&task->lock); quantum = task->quantum; if (task->state != task_state_ready) { goto done; } INSIST(task->state == task_state_ready); task->state = task_state_running; XTRACE("running"); XTRACE(task->name); TIME_NOW(&task->tnow); task->now = isc_time_seconds(&task->tnow); while (true) { if (!EMPTY(task->events)) { event = HEAD(task->events); DEQUEUE(task->events, event, ev_link); task->nevents--; /* * Execute the event action. */ XTRACE("execute action"); XTRACE(task->name); if (event->ev_action != NULL) { UNLOCK(&task->lock); (event->ev_action)(task, event); LOCK(&task->lock); } XTRACE("execution complete"); dispatch_count++; } if (isc_refcount_current(&task->references) == 0 && EMPTY(task->events) && !TASK_SHUTTINGDOWN(task)) { /* * There are no references and no pending events for * this task, which means it will not become runnable * again via an external action (such as sending an * event or detaching). * * We initiate shutdown to prevent it from becoming a * zombie. * * We do this here instead of in the "if * EMPTY(task->events)" block below because: * * If we post no shutdown events, we want the task * to finish. * * If we did post shutdown events, will still want * the task's quantum to be applied. */ INSIST(!task_shutdown(task)); } if (EMPTY(task->events)) { /* * Nothing else to do for this task right now. */ XTRACE("empty"); if (isc_refcount_current(&task->references) == 0 && TASK_SHUTTINGDOWN(task)) { /* * The task is done. */ XTRACE("done"); task->state = task_state_done; } else if (task->state == task_state_running) { XTRACE("idling"); task->state = task_state_idle; } break; } else if (dispatch_count >= quantum) { /* * Our quantum has expired, but there is more work to be * done. We'll requeue it to the ready queue later. * * We don't check quantum until dispatching at least one * event, so the minimum quantum is one. */ XTRACE("quantum"); task->state = task_state_ready; result = ISC_R_QUOTA; break; } } done: if (isc_refcount_decrement(&task->running) == 1 && task->state == task_state_done) { finished = true; } UNLOCK(&task->lock); if (finished) { task_finished(task); } return (result); } isc_result_t isc_task_run(isc_task_t *task) { return (task_run(task)); } static void manager_free(isc_taskmgr_t *manager) { isc_refcount_destroy(&manager->references); isc_nm_detach(&manager->netmgr); isc_mutex_destroy(&manager->lock); manager->magic = 0; isc_mem_putanddetach(&manager->mctx, manager, sizeof(*manager)); } void isc_taskmgr_attach(isc_taskmgr_t *source, isc_taskmgr_t **targetp) { REQUIRE(VALID_MANAGER(source)); REQUIRE(targetp != NULL && *targetp == NULL); isc_refcount_increment(&source->references); *targetp = source; } void isc_taskmgr_detach(isc_taskmgr_t **managerp) { REQUIRE(managerp != NULL); REQUIRE(VALID_MANAGER(*managerp)); isc_taskmgr_t *manager = *managerp; *managerp = NULL; if (isc_refcount_decrement(&manager->references) == 1) { manager_free(manager); } } isc_result_t isc__taskmgr_create(isc_mem_t *mctx, unsigned int default_quantum, isc_nm_t *nm, isc_taskmgr_t **managerp) { isc_taskmgr_t *manager; /* * Create a new task manager. */ REQUIRE(managerp != NULL && *managerp == NULL); REQUIRE(nm != NULL); manager = isc_mem_get(mctx, sizeof(*manager)); *manager = (isc_taskmgr_t){ .magic = TASK_MANAGER_MAGIC }; isc_mutex_init(&manager->lock); if (default_quantum == 0) { default_quantum = DEFAULT_DEFAULT_QUANTUM; } manager->default_quantum = default_quantum; if (nm != NULL) { isc_nm_attach(nm, &manager->netmgr); } INIT_LIST(manager->tasks); atomic_init(&manager->mode, isc_taskmgrmode_normal); atomic_init(&manager->exclusive_req, false); atomic_init(&manager->tasks_count, 0); isc_mem_attach(mctx, &manager->mctx); isc_refcount_init(&manager->references, 1); *managerp = manager; return (ISC_R_SUCCESS); } void isc__taskmgr_shutdown(isc_taskmgr_t *manager) { isc_task_t *task; REQUIRE(VALID_MANAGER(manager)); XTHREADTRACE("isc_taskmgr_shutdown"); /* * Only one non-worker thread may ever call this routine. * If a worker thread wants to initiate shutdown of the * task manager, it should ask some non-worker thread to call * isc_taskmgr_destroy(), e.g. by signalling a condition variable * that the startup thread is sleeping on. */ /* * Unlike elsewhere, we're going to hold this lock a long time. * We need to do so, because otherwise the list of tasks could * change while we were traversing it. * * This is also the only function where we will hold both the * task manager lock and a task lock at the same time. */ LOCK(&manager->lock); if (manager->excl != NULL) { isc_task_detach((isc_task_t **)&manager->excl); } /* * Make sure we only get called once. */ INSIST(manager->exiting == false); manager->exiting = true; /* * Post shutdown event(s) to every task (if they haven't already been * posted). */ for (task = HEAD(manager->tasks); task != NULL; task = NEXT(task, link)) { bool was_idle; LOCK(&task->lock); was_idle = task_shutdown(task); UNLOCK(&task->lock); if (was_idle) { task_ready(task); } } UNLOCK(&manager->lock); } void isc__taskmgr_destroy(isc_taskmgr_t **managerp) { REQUIRE(managerp != NULL && VALID_MANAGER(*managerp)); XTHREADTRACE("isc_taskmgr_destroy"); #ifdef ISC_TASK_TRACE int counter = 0; while (isc_refcount_current(&(*managerp)->references) > 1 && counter++ < 1000) { usleep(10 * 1000); } INSIST(counter < 1000); #else while (isc_refcount_current(&(*managerp)->references) > 1) { usleep(10 * 1000); } #endif isc_taskmgr_detach(managerp); } void isc_taskmgr_setexcltask(isc_taskmgr_t *mgr, isc_task_t *task) { REQUIRE(VALID_MANAGER(mgr)); REQUIRE(VALID_TASK(task)); LOCK(&task->lock); REQUIRE(task->threadid == 0); UNLOCK(&task->lock); LOCK(&mgr->lock); if (mgr->excl != NULL) { isc_task_detach(&mgr->excl); } isc_task_attach(task, &mgr->excl); UNLOCK(&mgr->lock); } isc_result_t isc_taskmgr_excltask(isc_taskmgr_t *mgr, isc_task_t **taskp) { isc_result_t result; REQUIRE(VALID_MANAGER(mgr)); REQUIRE(taskp != NULL && *taskp == NULL); LOCK(&mgr->lock); if (mgr->excl != NULL) { isc_task_attach(mgr->excl, taskp); result = ISC_R_SUCCESS; } else if (mgr->exiting) { result = ISC_R_SHUTTINGDOWN; } else { result = ISC_R_NOTFOUND; } UNLOCK(&mgr->lock); return (result); } isc_result_t isc_task_beginexclusive(isc_task_t *task) { isc_taskmgr_t *manager; REQUIRE(VALID_TASK(task)); manager = task->manager; REQUIRE(task->state == task_state_running); LOCK(&manager->lock); REQUIRE(task == manager->excl || (manager->exiting && manager->excl == NULL)); UNLOCK(&manager->lock); if (!atomic_compare_exchange_strong(&manager->exclusive_req, &(bool){ false }, true)) { return (ISC_R_LOCKBUSY); } if (isc_log_wouldlog(isc_lctx, ISC_LOG_DEBUG(1))) { isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_OTHER, ISC_LOG_DEBUG(1), "exclusive task mode: %s", "starting"); } isc_nm_pause(manager->netmgr); if (isc_log_wouldlog(isc_lctx, ISC_LOG_DEBUG(1))) { isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_OTHER, ISC_LOG_DEBUG(1), "exclusive task mode: %s", "started"); } return (ISC_R_SUCCESS); } void isc_task_endexclusive(isc_task_t *task) { isc_taskmgr_t *manager = NULL; REQUIRE(VALID_TASK(task)); REQUIRE(task->state == task_state_running); manager = task->manager; if (isc_log_wouldlog(isc_lctx, ISC_LOG_DEBUG(1))) { isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_OTHER, ISC_LOG_DEBUG(1), "exclusive task mode: %s", "ending"); } isc_nm_resume(manager->netmgr); if (isc_log_wouldlog(isc_lctx, ISC_LOG_DEBUG(1))) { isc_log_write(isc_lctx, ISC_LOGCATEGORY_GENERAL, ISC_LOGMODULE_OTHER, ISC_LOG_DEBUG(1), "exclusive task mode: %s", "ended"); } atomic_compare_exchange_enforced(&manager->exclusive_req, &(bool){ true }, false); } void isc_taskmgr_setmode(isc_taskmgr_t *manager, isc_taskmgrmode_t mode) { atomic_store(&manager->mode, mode); } isc_taskmgrmode_t isc_taskmgr_mode(isc_taskmgr_t *manager) { return (atomic_load(&manager->mode)); } void isc_task_setprivilege(isc_task_t *task, bool priv) { REQUIRE(VALID_TASK(task)); atomic_store_release(&task->privileged, priv); } bool isc_task_getprivilege(isc_task_t *task) { REQUIRE(VALID_TASK(task)); return (TASK_PRIVILEGED(task)); } bool isc_task_privileged(isc_task_t *task) { REQUIRE(VALID_TASK(task)); return (isc_taskmgr_mode(task->manager) && TASK_PRIVILEGED(task)); } bool isc_task_exiting(isc_task_t *task) { REQUIRE(VALID_TASK(task)); return (TASK_SHUTTINGDOWN(task)); } #ifdef HAVE_LIBXML2 #define TRY0(a) \ do { \ xmlrc = (a); \ if (xmlrc < 0) \ goto error; \ } while (0) int isc_taskmgr_renderxml(isc_taskmgr_t *mgr, void *writer0) { isc_task_t *task = NULL; int xmlrc; xmlTextWriterPtr writer = (xmlTextWriterPtr)writer0; LOCK(&mgr->lock); /* * Write out the thread-model, and some details about each depending * on which type is enabled. */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "thread-model")); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "type")); TRY0(xmlTextWriterWriteString(writer, ISC_XMLCHAR "threaded")); TRY0(xmlTextWriterEndElement(writer)); /* type */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "default-quantum")); TRY0(xmlTextWriterWriteFormatString(writer, "%d", mgr->default_quantum)); TRY0(xmlTextWriterEndElement(writer)); /* default-quantum */ TRY0(xmlTextWriterEndElement(writer)); /* thread-model */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "tasks")); task = ISC_LIST_HEAD(mgr->tasks); while (task != NULL) { LOCK(&task->lock); TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "task")); if (task->name[0] != 0) { TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "name")); TRY0(xmlTextWriterWriteFormatString(writer, "%s", task->name)); TRY0(xmlTextWriterEndElement(writer)); /* name */ } TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "reference" "s")); TRY0(xmlTextWriterWriteFormatString( writer, "%" PRIuFAST32, isc_refcount_current(&task->references))); TRY0(xmlTextWriterEndElement(writer)); /* references */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "id")); TRY0(xmlTextWriterWriteFormatString(writer, "%p", task)); TRY0(xmlTextWriterEndElement(writer)); /* id */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "state")); TRY0(xmlTextWriterWriteFormatString(writer, "%s", statenames[task->state])); TRY0(xmlTextWriterEndElement(writer)); /* state */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "quantum")); TRY0(xmlTextWriterWriteFormatString(writer, "%d", task->quantum)); TRY0(xmlTextWriterEndElement(writer)); /* quantum */ TRY0(xmlTextWriterStartElement(writer, ISC_XMLCHAR "events")); TRY0(xmlTextWriterWriteFormatString(writer, "%d", task->nevents)); TRY0(xmlTextWriterEndElement(writer)); /* events */ TRY0(xmlTextWriterEndElement(writer)); UNLOCK(&task->lock); task = ISC_LIST_NEXT(task, link); } TRY0(xmlTextWriterEndElement(writer)); /* tasks */ error: if (task != NULL) { UNLOCK(&task->lock); } UNLOCK(&mgr->lock); return (xmlrc); } #endif /* HAVE_LIBXML2 */ #ifdef HAVE_JSON_C #define CHECKMEM(m) \ do { \ if (m == NULL) { \ result = ISC_R_NOMEMORY; \ goto error; \ } \ } while (0) isc_result_t isc_taskmgr_renderjson(isc_taskmgr_t *mgr, void *tasks0) { isc_result_t result = ISC_R_SUCCESS; isc_task_t *task = NULL; json_object *obj = NULL, *array = NULL, *taskobj = NULL; json_object *tasks = (json_object *)tasks0; LOCK(&mgr->lock); /* * Write out the thread-model, and some details about each depending * on which type is enabled. */ obj = json_object_new_string("threaded"); CHECKMEM(obj); json_object_object_add(tasks, "thread-model", obj); obj = json_object_new_int(mgr->default_quantum); CHECKMEM(obj); json_object_object_add(tasks, "default-quantum", obj); array = json_object_new_array(); CHECKMEM(array); for (task = ISC_LIST_HEAD(mgr->tasks); task != NULL; task = ISC_LIST_NEXT(task, link)) { char buf[255]; LOCK(&task->lock); taskobj = json_object_new_object(); CHECKMEM(taskobj); json_object_array_add(array, taskobj); snprintf(buf, sizeof(buf), "%p", task); obj = json_object_new_string(buf); CHECKMEM(obj); json_object_object_add(taskobj, "id", obj); if (task->name[0] != 0) { obj = json_object_new_string(task->name); CHECKMEM(obj); json_object_object_add(taskobj, "name", obj); } obj = json_object_new_int( isc_refcount_current(&task->references)); CHECKMEM(obj); json_object_object_add(taskobj, "references", obj); obj = json_object_new_string(statenames[task->state]); CHECKMEM(obj); json_object_object_add(taskobj, "state", obj); obj = json_object_new_int(task->quantum); CHECKMEM(obj); json_object_object_add(taskobj, "quantum", obj); obj = json_object_new_int(task->nevents); CHECKMEM(obj); json_object_object_add(taskobj, "events", obj); UNLOCK(&task->lock); } json_object_object_add(tasks, "tasks", array); array = NULL; result = ISC_R_SUCCESS; error: if (array != NULL) { json_object_put(array); } if (task != NULL) { UNLOCK(&task->lock); } UNLOCK(&mgr->lock); return (result); } #endif /* ifdef HAVE_JSON_C */