/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Kernel task queues: general-purpose asynchronous task scheduling. * * A common problem in kernel programming is the need to schedule tasks * to be performed later, by another thread. There are several reasons * you may want or need to do this: * * (1) The task isn't time-critical, but your current code path is. * * (2) The task may require grabbing locks that you already hold. * * (3) The task may need to block (e.g. to wait for memory), but you * cannot block in your current context. * * (4) Your code path can't complete because of some condition, but you can't * sleep or fail, so you queue the task for later execution when condition * disappears. * * (5) You just want a simple way to launch multiple tasks in parallel. * * Task queues provide such a facility. In its simplest form (used when * performance is not a critical consideration) a task queue consists of a * single list of tasks, together with one or more threads to service the * list. There are some cases when this simple queue is not sufficient: * * (1) The task queues are very hot and there is a need to avoid data and lock * contention over global resources. * * (2) Some tasks may depend on other tasks to complete, so they can't be put in * the same list managed by the same thread. * * (3) Some tasks may block for a long time, and this should not block other * tasks in the queue. * * To provide useful service in such cases we define a "dynamic task queue" * which has an individual thread for each of the tasks. These threads are * dynamically created as they are needed and destroyed when they are not in * use. The API for managing task pools is the same as for managing task queues * with the exception of a taskq creation flag TASKQ_DYNAMIC which tells that * dynamic task pool behavior is desired. * * Dynamic task queues may also place tasks in the normal queue (called "backing * queue") when task pool runs out of resources. Users of task queues may * disallow such queued scheduling by specifying TQ_NOQUEUE in the dispatch * flags. * * The backing task queue is also used for scheduling internal tasks needed for * dynamic task queue maintenance. * * INTERFACES: * * taskq_t *taskq_create(name, nthreads, pri_t pri, minalloc, maxall, flags); * * Create a taskq with specified properties. * Possible 'flags': * * TASKQ_DYNAMIC: Create task pool for task management. If this flag is * specified, 'nthreads' specifies the maximum number of threads in * the task queue. Task execution order for dynamic task queues is * not predictable. * * If this flag is not specified (default case) a * single-list task queue is created with 'nthreads' threads * servicing it. Entries in this queue are managed by * taskq_ent_alloc() and taskq_ent_free() which try to keep the * task population between 'minalloc' and 'maxalloc', but the * latter limit is only advisory for TQ_SLEEP dispatches and the * former limit is only advisory for TQ_NOALLOC dispatches. If * TASKQ_PREPOPULATE is set in 'flags', the taskq will be * prepopulated with 'minalloc' task structures. * * Since non-DYNAMIC taskqs are queues, tasks are guaranteed to be * executed in the order they are scheduled if nthreads == 1. * If nthreads > 1, task execution order is not predictable. * * TASKQ_PREPOPULATE: Prepopulate task queue with threads. * Also prepopulate the task queue with 'minalloc' task structures. * * TASKQ_CPR_SAFE: This flag specifies that users of the task queue will * use their own protocol for handling CPR issues. This flag is not * supported for DYNAMIC task queues. * * The 'pri' field specifies the default priority for the threads that * service all scheduled tasks. * * void taskq_destroy(tap): * * Waits for any scheduled tasks to complete, then destroys the taskq. * Caller should guarantee that no new tasks are scheduled in the closing * taskq. * * taskqid_t taskq_dispatch(tq, func, arg, flags): * * Dispatches the task "func(arg)" to taskq. The 'flags' indicates whether * the caller is willing to block for memory. The function returns an * opaque value which is zero iff dispatch fails. If flags is TQ_NOSLEEP * or TQ_NOALLOC and the task can't be dispatched, taskq_dispatch() fails * and returns (taskqid_t)0. * * ASSUMES: func != NULL. * * Possible flags: * TQ_NOSLEEP: Do not wait for resources; may fail. * * TQ_NOALLOC: Do not allocate memory; may fail. May only be used with * non-dynamic task queues. * * TQ_NOQUEUE: Do not enqueue a task if it can't dispatch it due to * lack of available resources and fail. If this flag is not * set, and the task pool is exhausted, the task may be scheduled * in the backing queue. This flag may ONLY be used with dynamic * task queues. * * NOTE: This flag should always be used when a task queue is used * for tasks that may depend on each other for completion. * Enqueueing dependent tasks may create deadlocks. * * TQ_SLEEP: May block waiting for resources. May still fail for * dynamic task queues if TQ_NOQUEUE is also specified, otherwise * always succeed. * * NOTE: Dynamic task queues are much more likely to fail in * taskq_dispatch() (especially if TQ_NOQUEUE was specified), so it * is important to have backup strategies handling such failures. * * void taskq_wait(tq): * * Waits for all previously scheduled tasks to complete. * * NOTE: It does not stop any new task dispatches. * Do NOT call taskq_wait() from a task: it will cause deadlock. * * void taskq_suspend(tq) * * Suspend all task execution. Tasks already scheduled for a dynamic task * queue will still be executed, but all new scheduled tasks will be * suspended until taskq_resume() is called. * * int taskq_suspended(tq) * * Returns 1 if taskq is suspended and 0 otherwise. It is intended to * ASSERT that the task queue is suspended. * * void taskq_resume(tq) * * Resume task queue execution. * * int taskq_member(tq, thread) * * Returns 1 if 'thread' belongs to taskq 'tq' and 0 otherwise. The * intended use is to ASSERT that a given function is called in taskq * context only. * * system_taskq * * Global system-wide dynamic task queue for common uses. It may be used by * any subsystem that needs to schedule tasks and does not need to manage * its own task queues. It is initialized quite early during system boot. * * IMPLEMENTATION. * * This is schematic representation of the task queue structures. * * taskq: * +-------------+ * |tq_lock | +---< taskq_ent_free() * +-------------+ | * |... | | tqent: tqent: * +-------------+ | +------------+ +------------+ * | tq_freelist |-->| tqent_next |--> ... ->| tqent_next | * +-------------+ +------------+ +------------+ * |... | | ... | | ... | * +-------------+ +------------+ +------------+ * | tq_task | | * | | +-------------->taskq_ent_alloc() * +--------------------------------------------------------------------------+ * | | | tqent tqent | * | +---------------------+ +--> +------------+ +--> +------------+ | * | | ... | | | func, arg | | | func, arg | | * +>+---------------------+ <---|-+ +------------+ <---|-+ +------------+ | * | tq_taskq.tqent_next | ----+ | | tqent_next | --->+ | | tqent_next |--+ * +---------------------+ | +------------+ ^ | +------------+ * +-| tq_task.tqent_prev | +--| tqent_prev | | +--| tqent_prev | ^ * | +---------------------+ +------------+ | +------------+ | * | |... | | ... | | | ... | | * | +---------------------+ +------------+ | +------------+ | * | ^ | | * | | | | * +--------------------------------------+--------------+ TQ_APPEND() -+ * | | | * |... | taskq_thread()-----+ * +-------------+ * | tq_buckets |--+-------> [ NULL ] (for regular task queues) * +-------------+ | * | DYNAMIC TASK QUEUES: * | * +-> taskq_bucket[nCPU] taskq_bucket_dispatch() * +-------------------+ ^ * +--->| tqbucket_lock | | * | +-------------------+ +--------+ +--------+ * | | tqbucket_freelist |-->| tqent |-->...| tqent | ^ * | +-------------------+<--+--------+<--...+--------+ | * | | ... | | thread | | thread | | * | +-------------------+ +--------+ +--------+ | * | +-------------------+ | * taskq_dispatch()--+--->| tqbucket_lock | TQ_APPEND()------+ * TQ_HASH() | +-------------------+ +--------+ +--------+ * | | tqbucket_freelist |-->| tqent |-->...| tqent | * | +-------------------+<--+--------+<--...+--------+ * | | ... | | thread | | thread | * | +-------------------+ +--------+ +--------+ * +---> ... * * * Task queues use tq_task field to link new entry in the queue. The queue is a * circular doubly-linked list. Entries are put in the end of the list with * TQ_APPEND() and processed from the front of the list by taskq_thread() in * FIFO order. Task queue entries are cached in the free list managed by * taskq_ent_alloc() and taskq_ent_free() functions. * * All threads used by task queues mark t_taskq field of the thread to * point to the task queue. * * Dynamic Task Queues Implementation. * * For a dynamic task queues there is a 1-to-1 mapping between a thread and * taskq_ent_structure. Each entry is serviced by its own thread and each thread * is controlled by a single entry. * * Entries are distributed over a set of buckets. To avoid using modulo * arithmetics the number of buckets is 2^n and is determined as the nearest * power of two roundown of the number of CPUs in the system. Tunable * variable 'taskq_maxbuckets' limits the maximum number of buckets. Each entry * is attached to a bucket for its lifetime and can't migrate to other buckets. * * Entries that have scheduled tasks are not placed in any list. The dispatch * function sets their "func" and "arg" fields and signals the corresponding * thread to execute the task. Once the thread executes the task it clears the * "func" field and places an entry on the bucket cache of free entries pointed * by "tqbucket_freelist" field. ALL entries on the free list should have "func" * field equal to NULL. The free list is a circular doubly-linked list identical * in structure to the tq_task list above, but entries are taken from it in LIFO * order - the last freed entry is the first to be allocated. The * taskq_bucket_dispatch() function gets the most recently used entry from the * free list, sets its "func" and "arg" fields and signals a worker thread. * * After executing each task a per-entry thread taskq_d_thread() places its * entry on the bucket free list and goes to a timed sleep. If it wakes up * without getting new task it removes the entry from the free list and destroys * itself. The thread sleep time is controlled by a tunable variable * `taskq_thread_timeout'. * * There is various statistics kept in the bucket which allows for later * analysis of taskq usage patterns. Also, a global copy of taskq creation and * death statistics is kept in the global taskq data structure. Since thread * creation and death happen rarely, updating such global data does not present * a performance problem. * * NOTE: Threads are not bound to any CPU and there is absolutely no association * between the bucket and actual thread CPU, so buckets are used only to * split resources and reduce resource contention. Having threads attached * to the CPU denoted by a bucket may reduce number of times the job * switches between CPUs. * * Current algorithm creates a thread whenever a bucket has no free * entries. It would be nice to know how many threads are in the running * state and don't create threads if all CPUs are busy with existing * tasks, but it is unclear how such strategy can be implemented. * * Currently buckets are created statically as an array attached to task * queue. On some system with nCPUs < max_ncpus it may waste system * memory. One solution may be allocation of buckets when they are first * touched, but it is not clear how useful it is. * * SUSPEND/RESUME implementation. * * Before executing a task taskq_thread() (executing non-dynamic task * queues) obtains taskq's thread lock as a reader. The taskq_suspend() * function gets the same lock as a writer blocking all non-dynamic task * execution. The taskq_resume() function releases the lock allowing * taskq_thread to continue execution. * * For dynamic task queues, each bucket is marked as TQBUCKET_SUSPEND by * taskq_suspend() function. After that taskq_bucket_dispatch() always * fails, so that taskq_dispatch() will either enqueue tasks for a * suspended backing queue or fail if TQ_NOQUEUE is specified in dispatch * flags. * * NOTE: taskq_suspend() does not immediately block any tasks already * scheduled for dynamic task queues. It only suspends new tasks * scheduled after taskq_suspend() was called. * * taskq_member() function works by comparing a thread t_taskq pointer with * the passed thread pointer. * * LOCKS and LOCK Hierarchy: * * There are two locks used in task queues. * * 1) Task queue structure has a lock, protecting global task queue state. * * 2) Each per-CPU bucket has a lock for bucket management. * * If both locks are needed, task queue lock should be taken only after bucket * lock. * * DEBUG FACILITIES. * * For DEBUG kernels it is possible to induce random failures to * taskq_dispatch() function when it is given TQ_NOSLEEP argument. The value of * taskq_dmtbf and taskq_smtbf tunables control the mean time between induced * failures for dynamic and static task queues respectively. * * Setting TASKQ_STATISTIC to 0 will disable per-bucket statistics. * * TUNABLES * * system_taskq_size - Size of the global system_taskq. * This value is multiplied by nCPUs to determine * actual size. * Default value: 64 * * taskq_thread_timeout - Maximum idle time for taskq_d_thread() * Default value: 5 minutes * * taskq_maxbuckets - Maximum number of buckets in any task queue * Default value: 128 * * taskq_search_depth - Maximum # of buckets searched for a free entry * Default value: 4 * * taskq_dmtbf - Mean time between induced dispatch failures * for dynamic task queues. * Default value: UINT_MAX (no induced failures) * * taskq_smtbf - Mean time between induced dispatch failures * for static task queues. * Default value: UINT_MAX (no induced failures) * * CONDITIONAL compilation. * * TASKQ_STATISTIC - If set will enable bucket statistic (default). * */ #include #include #include #include #include #include #include #include #include #include #include #include static kmem_cache_t *taskq_ent_cache, *taskq_cache; /* Global system task queue for common use */ taskq_t *system_taskq; /* * Maxmimum number of entries in global system taskq is * system_taskq_size * max_ncpus */ #define SYSTEM_TASKQ_SIZE 1 int system_taskq_size = SYSTEM_TASKQ_SIZE; /* * Dynamic task queue threads that don't get any work within * taskq_thread_timeout destroy themselves */ #define TASKQ_THREAD_TIMEOUT (60 * 5) int taskq_thread_timeout = TASKQ_THREAD_TIMEOUT; #define TASKQ_MAXBUCKETS 128 int taskq_maxbuckets = TASKQ_MAXBUCKETS; /* * When a bucket has no available entries another buckets are tried. * taskq_search_depth parameter limits the amount of buckets that we search * before failing. This is mostly useful in systems with many CPUs where we may * spend too much time scanning busy buckets. */ #define TASKQ_SEARCH_DEPTH 4 int taskq_search_depth = TASKQ_SEARCH_DEPTH; /* * Hashing function: mix various bits of x. May be pretty much anything. */ #define TQ_HASH(x) ((x) ^ ((x) >> 11) ^ ((x) >> 17) ^ ((x) ^ 27)) /* * We do not create any new threads when the system is low on memory and start * throttling memory allocations. The following macro tries to estimate such * condition. */ #define ENOUGH_MEMORY() (freemem > throttlefree) /* * Static functions. */ static taskq_t *taskq_create_common(const char *, int, int, pri_t, int, int, uint_t); static void taskq_thread(void *); static int taskq_constructor(void *, void *, int); static void taskq_destructor(void *, void *); static int taskq_ent_constructor(void *, void *, int); static void taskq_ent_destructor(void *, void *); static taskq_ent_t *taskq_ent_alloc(taskq_t *, int); static void taskq_ent_free(taskq_t *, taskq_ent_t *); /* * Collect per-bucket statistic when TASKQ_STATISTIC is defined. */ #define TASKQ_STATISTIC 1 #if TASKQ_STATISTIC #define TQ_STAT(b, x) b->tqbucket_stat.x++ #else #define TQ_STAT(b, x) #endif /* * Random fault injection. */ uint_t taskq_random; uint_t taskq_dmtbf = UINT_MAX; /* mean time between injected failures */ uint_t taskq_smtbf = UINT_MAX; /* mean time between injected failures */ /* * TQ_NOSLEEP dispatches on dynamic task queues are always allowed to fail. * * TQ_NOSLEEP dispatches on static task queues can't arbitrarily fail because * they could prepopulate the cache and make sure that they do not use more * then minalloc entries. So, fault injection in this case insures that * either TASKQ_PREPOPULATE is not set or there are more entries allocated * than is specified by minalloc. TQ_NOALLOC dispatches are always allowed * to fail, but for simplicity we treat them identically to TQ_NOSLEEP * dispatches. */ #ifdef DEBUG #define TASKQ_D_RANDOM_DISPATCH_FAILURE(tq, flag) \ taskq_random = (taskq_random * 2416 + 374441) % 1771875;\ if ((flag & TQ_NOSLEEP) && \ taskq_random < 1771875 / taskq_dmtbf) { \ return (NULL); \ } #define TASKQ_S_RANDOM_DISPATCH_FAILURE(tq, flag) \ taskq_random = (taskq_random * 2416 + 374441) % 1771875;\ if ((flag & (TQ_NOSLEEP | TQ_NOALLOC)) && \ (!(tq->tq_flags & TASKQ_PREPOPULATE) || \ (tq->tq_nalloc > tq->tq_minalloc)) && \ (taskq_random < (1771875 / taskq_smtbf))) { \ mutex_exit(&tq->tq_lock); \ return ((taskqid_t)0); \ } #else #define TASKQ_S_RANDOM_DISPATCH_FAILURE(tq, flag) #define TASKQ_D_RANDOM_DISPATCH_FAILURE(tq, flag) #endif #define IS_EMPTY(l) (((l).tqent_prev == (l).tqent_next) && \ ((l).tqent_prev == &(l))) /* * Append `tqe' in the end of the doubly-linked list denoted by l. */ #define TQ_APPEND(l, tqe) { \ tqe->tqent_next = &l; \ tqe->tqent_prev = l.tqent_prev; \ tqe->tqent_next->tqent_prev = tqe; \ tqe->tqent_prev->tqent_next = tqe; \ } /* * Schedule a task specified by func and arg into the task queue entry tqe. */ #define TQ_ENQUEUE(tq, tqe, func, arg) { \ ASSERT(MUTEX_HELD(&tq->tq_lock)); \ TQ_APPEND(tq->tq_task, tqe); \ tqe->tqent_func = (func); \ tqe->tqent_arg = (arg); \ tq->tq_tasks++; \ if (tq->tq_tasks - tq->tq_executed > tq->tq_maxtasks) \ tq->tq_maxtasks = tq->tq_tasks - tq->tq_executed; \ cv_signal(&tq->tq_dispatch_cv); \ DTRACE_PROBE2(taskq__enqueue, taskq_t *, tq, taskq_ent_t *, tqe); \ } /* * Do-nothing task which may be used to prepopulate thread caches. */ /*ARGSUSED*/ void nulltask(void *unused) { } /*ARGSUSED*/ static int taskq_constructor(void *buf, void *cdrarg, int kmflags) { taskq_t *tq = buf; bzero(tq, sizeof (taskq_t)); mutex_init(&tq->tq_lock, NULL, MUTEX_DEFAULT, NULL); rw_init(&tq->tq_threadlock, NULL, RW_DEFAULT, NULL); cv_init(&tq->tq_dispatch_cv, NULL, CV_DEFAULT, NULL); cv_init(&tq->tq_wait_cv, NULL, CV_DEFAULT, NULL); tq->tq_task.tqent_next = &tq->tq_task; tq->tq_task.tqent_prev = &tq->tq_task; return (0); } /*ARGSUSED*/ static void taskq_destructor(void *buf, void *cdrarg) { taskq_t *tq = buf; mutex_destroy(&tq->tq_lock); rw_destroy(&tq->tq_threadlock); cv_destroy(&tq->tq_dispatch_cv); cv_destroy(&tq->tq_wait_cv); } /*ARGSUSED*/ static int taskq_ent_constructor(void *buf, void *cdrarg, int kmflags) { taskq_ent_t *tqe = buf; tqe->tqent_thread = NULL; cv_init(&tqe->tqent_cv, NULL, CV_DEFAULT, NULL); return (0); } /*ARGSUSED*/ static void taskq_ent_destructor(void *buf, void *cdrarg) { taskq_ent_t *tqe = buf; ASSERT(tqe->tqent_thread == NULL); cv_destroy(&tqe->tqent_cv); } /* * Create global system dynamic task queue. */ void system_taskq_init(void) { system_taskq = taskq_create_common("system_taskq", 0, system_taskq_size * max_ncpus, minclsyspri, 4, 512, TASKQ_PREPOPULATE); } void system_taskq_fini(void) { taskq_destroy(system_taskq); } static void taskq_init(void *dummy __unused) { taskq_ent_cache = kmem_cache_create("taskq_ent_cache", sizeof (taskq_ent_t), 0, taskq_ent_constructor, taskq_ent_destructor, NULL, NULL, NULL, 0); taskq_cache = kmem_cache_create("taskq_cache", sizeof (taskq_t), 0, taskq_constructor, taskq_destructor, NULL, NULL, NULL, 0); system_taskq_init(); } static void taskq_fini(void *dummy __unused) { system_taskq_fini(); kmem_cache_destroy(taskq_cache); kmem_cache_destroy(taskq_ent_cache); } /* * taskq_ent_alloc() * * Allocates a new taskq_ent_t structure either from the free list or from the * cache. Returns NULL if it can't be allocated. * * Assumes: tq->tq_lock is held. */ static taskq_ent_t * taskq_ent_alloc(taskq_t *tq, int flags) { int kmflags = (flags & TQ_NOSLEEP) ? KM_NOSLEEP : KM_SLEEP; taskq_ent_t *tqe; ASSERT(MUTEX_HELD(&tq->tq_lock)); /* * TQ_NOALLOC allocations are allowed to use the freelist, even if * we are below tq_minalloc. */ if ((tqe = tq->tq_freelist) != NULL && ((flags & TQ_NOALLOC) || tq->tq_nalloc >= tq->tq_minalloc)) { tq->tq_freelist = tqe->tqent_next; } else { if (flags & TQ_NOALLOC) return (NULL); mutex_exit(&tq->tq_lock); if (tq->tq_nalloc >= tq->tq_maxalloc) { if (kmflags & KM_NOSLEEP) { mutex_enter(&tq->tq_lock); return (NULL); } /* * We don't want to exceed tq_maxalloc, but we can't * wait for other tasks to complete (and thus free up * task structures) without risking deadlock with * the caller. So, we just delay for one second * to throttle the allocation rate. */ delay(hz); } tqe = kmem_cache_alloc(taskq_ent_cache, kmflags); mutex_enter(&tq->tq_lock); if (tqe != NULL) tq->tq_nalloc++; } return (tqe); } /* * taskq_ent_free() * * Free taskq_ent_t structure by either putting it on the free list or freeing * it to the cache. * * Assumes: tq->tq_lock is held. */ static void taskq_ent_free(taskq_t *tq, taskq_ent_t *tqe) { ASSERT(MUTEX_HELD(&tq->tq_lock)); if (tq->tq_nalloc <= tq->tq_minalloc) { tqe->tqent_next = tq->tq_freelist; tq->tq_freelist = tqe; } else { tq->tq_nalloc--; mutex_exit(&tq->tq_lock); kmem_cache_free(taskq_ent_cache, tqe); mutex_enter(&tq->tq_lock); } } /* * Dispatch a task. * * Assumes: func != NULL * * Returns: NULL if dispatch failed. * non-NULL if task dispatched successfully. * Actual return value is the pointer to taskq entry that was used to * dispatch a task. This is useful for debugging. */ /* ARGSUSED */ taskqid_t taskq_dispatch(taskq_t *tq, task_func_t func, void *arg, uint_t flags) { taskq_ent_t *tqe = NULL; ASSERT(tq != NULL); ASSERT(func != NULL); ASSERT(!(tq->tq_flags & TASKQ_DYNAMIC)); /* * TQ_NOQUEUE flag can't be used with non-dynamic task queues. */ ASSERT(! (flags & TQ_NOQUEUE)); /* * Enqueue the task to the underlying queue. */ mutex_enter(&tq->tq_lock); TASKQ_S_RANDOM_DISPATCH_FAILURE(tq, flags); if ((tqe = taskq_ent_alloc(tq, flags)) == NULL) { mutex_exit(&tq->tq_lock); return ((taskqid_t)NULL); } TQ_ENQUEUE(tq, tqe, func, arg); mutex_exit(&tq->tq_lock); return ((taskqid_t)tqe); } /* * Wait for all pending tasks to complete. * Calling taskq_wait from a task will cause deadlock. */ void taskq_wait(taskq_t *tq) { mutex_enter(&tq->tq_lock); while (tq->tq_task.tqent_next != &tq->tq_task || tq->tq_active != 0) cv_wait(&tq->tq_wait_cv, &tq->tq_lock); mutex_exit(&tq->tq_lock); } /* * Suspend execution of tasks. * * Tasks in the queue part will be suspended immediately upon return from this * function. Pending tasks in the dynamic part will continue to execute, but all * new tasks will be suspended. */ void taskq_suspend(taskq_t *tq) { rw_enter(&tq->tq_threadlock, RW_WRITER); /* * Mark task queue as being suspended. Needed for taskq_suspended(). */ mutex_enter(&tq->tq_lock); ASSERT(!(tq->tq_flags & TASKQ_SUSPENDED)); tq->tq_flags |= TASKQ_SUSPENDED; mutex_exit(&tq->tq_lock); } /* * returns: 1 if tq is suspended, 0 otherwise. */ int taskq_suspended(taskq_t *tq) { return ((tq->tq_flags & TASKQ_SUSPENDED) != 0); } /* * Resume taskq execution. */ void taskq_resume(taskq_t *tq) { ASSERT(RW_WRITE_HELD(&tq->tq_threadlock)); mutex_enter(&tq->tq_lock); ASSERT(tq->tq_flags & TASKQ_SUSPENDED); tq->tq_flags &= ~TASKQ_SUSPENDED; mutex_exit(&tq->tq_lock); rw_exit(&tq->tq_threadlock); } /* * Worker thread for processing task queue. */ static void taskq_thread(void *arg) { taskq_t *tq = arg; taskq_ent_t *tqe; callb_cpr_t cprinfo; hrtime_t start, end; CALLB_CPR_INIT(&cprinfo, &tq->tq_lock, callb_generic_cpr, tq->tq_name); mutex_enter(&tq->tq_lock); while (tq->tq_flags & TASKQ_ACTIVE) { if ((tqe = tq->tq_task.tqent_next) == &tq->tq_task) { if (--tq->tq_active == 0) cv_broadcast(&tq->tq_wait_cv); if (tq->tq_flags & TASKQ_CPR_SAFE) { cv_wait(&tq->tq_dispatch_cv, &tq->tq_lock); } else { CALLB_CPR_SAFE_BEGIN(&cprinfo); cv_wait(&tq->tq_dispatch_cv, &tq->tq_lock); CALLB_CPR_SAFE_END(&cprinfo, &tq->tq_lock); } tq->tq_active++; continue; } tqe->tqent_prev->tqent_next = tqe->tqent_next; tqe->tqent_next->tqent_prev = tqe->tqent_prev; mutex_exit(&tq->tq_lock); rw_enter(&tq->tq_threadlock, RW_READER); start = gethrtime(); DTRACE_PROBE2(taskq__exec__start, taskq_t *, tq, taskq_ent_t *, tqe); tqe->tqent_func(tqe->tqent_arg); DTRACE_PROBE2(taskq__exec__end, taskq_t *, tq, taskq_ent_t *, tqe); end = gethrtime(); rw_exit(&tq->tq_threadlock); mutex_enter(&tq->tq_lock); tq->tq_totaltime += end - start; tq->tq_executed++; taskq_ent_free(tq, tqe); } tq->tq_nthreads--; cv_broadcast(&tq->tq_wait_cv); ASSERT(!(tq->tq_flags & TASKQ_CPR_SAFE)); CALLB_CPR_EXIT(&cprinfo); thread_exit(); } /* * Taskq creation. May sleep for memory. * Always use automatically generated instances to avoid kstat name space * collisions. */ taskq_t * taskq_create(const char *name, int nthreads, pri_t pri, int minalloc, int maxalloc, uint_t flags) { return taskq_create_common(name, 0, nthreads, pri, minalloc, maxalloc, flags | TASKQ_NOINSTANCE); } static taskq_t * taskq_create_common(const char *name, int instance, int nthreads, pri_t pri, int minalloc, int maxalloc, uint_t flags) { taskq_t *tq = kmem_cache_alloc(taskq_cache, KM_SLEEP); uint_t ncpus = ((boot_max_ncpus == -1) ? max_ncpus : boot_max_ncpus); uint_t bsize; /* # of buckets - always power of 2 */ ASSERT(instance == 0); ASSERT(flags == TASKQ_PREPOPULATE | TASKQ_NOINSTANCE); /* * TASKQ_CPR_SAFE and TASKQ_DYNAMIC flags are mutually exclusive. */ ASSERT((flags & (TASKQ_DYNAMIC | TASKQ_CPR_SAFE)) != ((TASKQ_DYNAMIC | TASKQ_CPR_SAFE))); ASSERT(tq->tq_buckets == NULL); bsize = 1 << (highbit(ncpus) - 1); ASSERT(bsize >= 1); bsize = MIN(bsize, taskq_maxbuckets); tq->tq_maxsize = nthreads; (void) strncpy(tq->tq_name, name, TASKQ_NAMELEN + 1); tq->tq_name[TASKQ_NAMELEN] = '\0'; /* Make sure the name conforms to the rules for C indentifiers */ strident_canon(tq->tq_name, TASKQ_NAMELEN); tq->tq_flags = flags | TASKQ_ACTIVE; tq->tq_active = nthreads; tq->tq_nthreads = nthreads; tq->tq_minalloc = minalloc; tq->tq_maxalloc = maxalloc; tq->tq_nbuckets = bsize; tq->tq_pri = pri; if (flags & TASKQ_PREPOPULATE) { mutex_enter(&tq->tq_lock); while (minalloc-- > 0) taskq_ent_free(tq, taskq_ent_alloc(tq, TQ_SLEEP)); mutex_exit(&tq->tq_lock); } if (nthreads == 1) { tq->tq_thread = thread_create(NULL, 0, taskq_thread, tq, 0, NULL, TS_RUN, pri); } else { kthread_t **tpp = kmem_alloc(sizeof (kthread_t *) * nthreads, KM_SLEEP); tq->tq_threadlist = tpp; mutex_enter(&tq->tq_lock); while (nthreads-- > 0) { *tpp = thread_create(NULL, 0, taskq_thread, tq, 0, NULL, TS_RUN, pri); tpp++; } mutex_exit(&tq->tq_lock); } return (tq); } /* * taskq_destroy(). * * Assumes: by the time taskq_destroy is called no one will use this task queue * in any way and no one will try to dispatch entries in it. */ void taskq_destroy(taskq_t *tq) { taskq_bucket_t *b = tq->tq_buckets; int bid = 0; ASSERT(! (tq->tq_flags & TASKQ_CPR_SAFE)); /* * Wait for any pending entries to complete. */ taskq_wait(tq); mutex_enter(&tq->tq_lock); ASSERT((tq->tq_task.tqent_next == &tq->tq_task) && (tq->tq_active == 0)); if ((tq->tq_nthreads > 1) && (tq->tq_threadlist != NULL)) kmem_free(tq->tq_threadlist, sizeof (kthread_t *) * tq->tq_nthreads); tq->tq_flags &= ~TASKQ_ACTIVE; cv_broadcast(&tq->tq_dispatch_cv); while (tq->tq_nthreads != 0) cv_wait(&tq->tq_wait_cv, &tq->tq_lock); tq->tq_minalloc = 0; while (tq->tq_nalloc != 0) taskq_ent_free(tq, taskq_ent_alloc(tq, TQ_SLEEP)); mutex_exit(&tq->tq_lock); /* * Mark each bucket as closing and wakeup all sleeping threads. */ for (; (b != NULL) && (bid < tq->tq_nbuckets); b++, bid++) { taskq_ent_t *tqe; mutex_enter(&b->tqbucket_lock); b->tqbucket_flags |= TQBUCKET_CLOSE; /* Wakeup all sleeping threads */ for (tqe = b->tqbucket_freelist.tqent_next; tqe != &b->tqbucket_freelist; tqe = tqe->tqent_next) cv_signal(&tqe->tqent_cv); ASSERT(b->tqbucket_nalloc == 0); /* * At this point we waited for all pending jobs to complete (in * both the task queue and the bucket and no new jobs should * arrive. Wait for all threads to die. */ while (b->tqbucket_nfree > 0) cv_wait(&b->tqbucket_cv, &b->tqbucket_lock); mutex_exit(&b->tqbucket_lock); mutex_destroy(&b->tqbucket_lock); cv_destroy(&b->tqbucket_cv); } if (tq->tq_buckets != NULL) { ASSERT(tq->tq_flags & TASKQ_DYNAMIC); kmem_free(tq->tq_buckets, sizeof (taskq_bucket_t) * tq->tq_nbuckets); /* Cleanup fields before returning tq to the cache */ tq->tq_buckets = NULL; tq->tq_tcreates = 0; tq->tq_tdeaths = 0; } else { ASSERT(!(tq->tq_flags & TASKQ_DYNAMIC)); } tq->tq_totaltime = 0; tq->tq_tasks = 0; tq->tq_maxtasks = 0; tq->tq_executed = 0; kmem_cache_free(taskq_cache, tq); } SYSINIT(sol_taskq, SI_SUB_DRIVERS, SI_ORDER_MIDDLE, taskq_init, NULL); SYSUNINIT(sol_taskq, SI_SUB_DRIVERS, SI_ORDER_MIDDLE, taskq_fini, NULL);