/* * Copyright © 2016 Advanced Micro Devices, Inc. * All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sub license, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES * OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NON-INFRINGEMENT. IN NO EVENT SHALL THE COPYRIGHT HOLDERS, AUTHORS * AND/OR ITS SUPPLIERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE * USE OR OTHER DEALINGS IN THE SOFTWARE. * * The above copyright notice and this permission notice (including the * next paragraph) shall be included in all copies or substantial portions * of the Software. */ #include "u_queue.h" #include "u_memory.h" #include "u_string.h" #include "os/os_time.h" static void util_queue_killall_and_wait(struct util_queue *queue); /**************************************************************************** * Wait for all queues to assert idle when exit() is called. * * Otherwise, C++ static variable destructors can be called while threads * are using the static variables. */ static once_flag atexit_once_flag = ONCE_FLAG_INIT; static struct list_head queue_list; static mtx_t exit_mutex = _MTX_INITIALIZER_NP; static void atexit_handler(void) { struct util_queue *iter; pipe_mutex_lock(exit_mutex); /* Wait for all queues to assert idle. */ LIST_FOR_EACH_ENTRY(iter, &queue_list, head) { util_queue_killall_and_wait(iter); } pipe_mutex_unlock(exit_mutex); } static void global_init(void) { LIST_INITHEAD(&queue_list); atexit(atexit_handler); } static void add_to_atexit_list(struct util_queue *queue) { call_once(&atexit_once_flag, global_init); pipe_mutex_lock(exit_mutex); LIST_ADD(&queue->head, &queue_list); pipe_mutex_unlock(exit_mutex); } static void remove_from_atexit_list(struct util_queue *queue) { struct util_queue *iter, *tmp; pipe_mutex_lock(exit_mutex); LIST_FOR_EACH_ENTRY_SAFE(iter, tmp, &queue_list, head) { if (iter == queue) { LIST_DEL(&iter->head); break; } } pipe_mutex_unlock(exit_mutex); } /**************************************************************************** * util_queue_fence */ static void util_queue_fence_signal(struct util_queue_fence *fence) { pipe_mutex_lock(fence->mutex); fence->signalled = true; cnd_broadcast(&fence->cond); pipe_mutex_unlock(fence->mutex); } void util_queue_fence_wait(struct util_queue_fence *fence) { pipe_mutex_lock(fence->mutex); while (!fence->signalled) cnd_wait(&fence->cond, &fence->mutex); pipe_mutex_unlock(fence->mutex); } void util_queue_fence_init(struct util_queue_fence *fence) { memset(fence, 0, sizeof(*fence)); pipe_mutex_init(fence->mutex); cnd_init(&fence->cond); fence->signalled = true; } void util_queue_fence_destroy(struct util_queue_fence *fence) { assert(fence->signalled); cnd_destroy(&fence->cond); pipe_mutex_destroy(fence->mutex); } /**************************************************************************** * util_queue implementation */ struct thread_input { struct util_queue *queue; int thread_index; }; static PIPE_THREAD_ROUTINE(util_queue_thread_func, input) { struct util_queue *queue = ((struct thread_input*)input)->queue; int thread_index = ((struct thread_input*)input)->thread_index; FREE(input); if (queue->name) { char name[16]; util_snprintf(name, sizeof(name), "%s:%i", queue->name, thread_index); pipe_thread_setname(name); } while (1) { struct util_queue_job job; pipe_mutex_lock(queue->lock); assert(queue->num_queued >= 0 && queue->num_queued <= queue->max_jobs); /* wait if the queue is empty */ while (!queue->kill_threads && queue->num_queued == 0) cnd_wait(&queue->has_queued_cond, &queue->lock); if (queue->kill_threads) { pipe_mutex_unlock(queue->lock); break; } job = queue->jobs[queue->read_idx]; memset(&queue->jobs[queue->read_idx], 0, sizeof(struct util_queue_job)); queue->read_idx = (queue->read_idx + 1) % queue->max_jobs; queue->num_queued--; cnd_signal(&queue->has_space_cond); pipe_mutex_unlock(queue->lock); if (job.job) { job.execute(job.job, thread_index); util_queue_fence_signal(job.fence); if (job.cleanup) job.cleanup(job.job, thread_index); } } /* signal remaining jobs before terminating */ pipe_mutex_lock(queue->lock); while (queue->jobs[queue->read_idx].job) { util_queue_fence_signal(queue->jobs[queue->read_idx].fence); queue->jobs[queue->read_idx].job = NULL; queue->read_idx = (queue->read_idx + 1) % queue->max_jobs; } queue->num_queued = 0; /* reset this when exiting the thread */ pipe_mutex_unlock(queue->lock); return 0; } bool util_queue_init(struct util_queue *queue, const char *name, unsigned max_jobs, unsigned num_threads) { unsigned i; memset(queue, 0, sizeof(*queue)); queue->name = name; queue->num_threads = num_threads; queue->max_jobs = max_jobs; queue->jobs = (struct util_queue_job*) CALLOC(max_jobs, sizeof(struct util_queue_job)); if (!queue->jobs) goto fail; pipe_mutex_init(queue->lock); queue->num_queued = 0; cnd_init(&queue->has_queued_cond); cnd_init(&queue->has_space_cond); queue->threads = (pipe_thread*)CALLOC(num_threads, sizeof(pipe_thread)); if (!queue->threads) goto fail; /* start threads */ for (i = 0; i < num_threads; i++) { struct thread_input *input = MALLOC_STRUCT(thread_input); input->queue = queue; input->thread_index = i; queue->threads[i] = pipe_thread_create(util_queue_thread_func, input); if (!queue->threads[i]) { FREE(input); if (i == 0) { /* no threads created, fail */ goto fail; } else { /* at least one thread created, so use it */ queue->num_threads = i; break; } } } add_to_atexit_list(queue); return true; fail: FREE(queue->threads); if (queue->jobs) { cnd_destroy(&queue->has_space_cond); cnd_destroy(&queue->has_queued_cond); pipe_mutex_destroy(queue->lock); FREE(queue->jobs); } /* also util_queue_is_initialized can be used to check for success */ memset(queue, 0, sizeof(*queue)); return false; } static void util_queue_killall_and_wait(struct util_queue *queue) { unsigned i; /* Signal all threads to terminate. */ pipe_mutex_lock(queue->lock); queue->kill_threads = 1; cnd_broadcast(&queue->has_queued_cond); pipe_mutex_unlock(queue->lock); for (i = 0; i < queue->num_threads; i++) pipe_thread_wait(queue->threads[i]); queue->num_threads = 0; } void util_queue_destroy(struct util_queue *queue) { util_queue_killall_and_wait(queue); remove_from_atexit_list(queue); cnd_destroy(&queue->has_space_cond); cnd_destroy(&queue->has_queued_cond); pipe_mutex_destroy(queue->lock); FREE(queue->jobs); FREE(queue->threads); } void util_queue_add_job(struct util_queue *queue, void *job, struct util_queue_fence *fence, util_queue_execute_func execute, util_queue_execute_func cleanup) { struct util_queue_job *ptr; assert(fence->signalled); fence->signalled = false; pipe_mutex_lock(queue->lock); assert(queue->num_queued >= 0 && queue->num_queued <= queue->max_jobs); /* if the queue is full, wait until there is space */ while (queue->num_queued == queue->max_jobs) cnd_wait(&queue->has_space_cond, &queue->lock); ptr = &queue->jobs[queue->write_idx]; assert(ptr->job == NULL); ptr->job = job; ptr->fence = fence; ptr->execute = execute; ptr->cleanup = cleanup; queue->write_idx = (queue->write_idx + 1) % queue->max_jobs; queue->num_queued++; cnd_signal(&queue->has_queued_cond); pipe_mutex_unlock(queue->lock); } int64_t util_queue_get_thread_time_nano(struct util_queue *queue, unsigned thread_index) { /* Allow some flexibility by not raising an error. */ if (thread_index >= queue->num_threads) return 0; return pipe_thread_get_time_nano(queue->threads[thread_index]); }