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view ezBAMQC/src/htslib/cram/thread_pool.c @ 4:50a9d8992e65
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author | cshl-bsr |
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date | Tue, 29 Mar 2016 15:33:36 -0400 |
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/* Copyright (c) 2013 Genome Research Ltd. Author: James Bonfield <jkb@sanger.ac.uk> Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. Neither the names Genome Research Ltd and Wellcome Trust Sanger Institute nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY GENOME RESEARCH LTD AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL GENOME RESEARCH LTD OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include <stdlib.h> #include <signal.h> #include <errno.h> #include <stdio.h> #include <string.h> #include <sys/time.h> #include <assert.h> #include "cram/thread_pool.h" //#define DEBUG //#define DEBUG_TIME #define IN_ORDER #ifdef DEBUG static int worker_id(t_pool *p) { int i; pthread_t s = pthread_self(); for (i = 0; i < p->tsize; i++) { if (pthread_equal(s, p->t[i].tid)) return i; } return -1; } #endif /* ---------------------------------------------------------------------------- * A queue to hold results from the thread pool. * * Each thread pool may have jobs of multiple types being queued up and * interleaved, so we allow several results queue per pool. * * The jobs themselves are expected to push their results onto their * appropriate results queue. */ /* * Adds a result to the end of the result queue. * * Returns 0 on success; * -1 on failure */ static int t_pool_add_result(t_pool_job *j, void *data) { t_results_queue *q = j->q; t_pool_result *r; #ifdef DEBUG fprintf(stderr, "%d: Adding resulting to queue %p, serial %d\n", worker_id(j->p), q, j->serial); #endif /* No results queue is fine if we don't want any results back */ if (!q) return 0; if (!(r = malloc(sizeof(*r)))) return -1; r->next = NULL; r->data = data; r->serial = j->serial; pthread_mutex_lock(&q->result_m); if (q->result_tail) { q->result_tail->next = r; q->result_tail = r; } else { q->result_head = q->result_tail = r; } q->queue_len++; q->pending--; #ifdef DEBUG fprintf(stderr, "%d: Broadcasting result_avail (id %d)\n", worker_id(j->p), r->serial); #endif pthread_cond_signal(&q->result_avail_c); #ifdef DEBUG fprintf(stderr, "%d: Broadcast complete\n", worker_id(j->p)); #endif pthread_mutex_unlock(&q->result_m); return 0; } /* Core of t_pool_next_result() */ static t_pool_result *t_pool_next_result_locked(t_results_queue *q) { t_pool_result *r, *last; for (last = NULL, r = q->result_head; r; last = r, r = r->next) { if (r->serial == q->next_serial) break; } if (r) { if (q->result_head == r) q->result_head = r->next; else last->next = r->next; if (q->result_tail == r) q->result_tail = last; if (!q->result_head) q->result_tail = NULL; q->next_serial++; q->queue_len--; } return r; } /* * Pulls a result off the head of the result queue. Caller should * free it (and any internals as appropriate) after use. This doesn't * wait for a result to be present. * * Results will be returned in strict order. * * Returns t_pool_result pointer if a result is ready. * NULL if not. */ t_pool_result *t_pool_next_result(t_results_queue *q) { t_pool_result *r; #ifdef DEBUG fprintf(stderr, "Requesting next result on queue %p\n", q); #endif pthread_mutex_lock(&q->result_m); r = t_pool_next_result_locked(q); pthread_mutex_unlock(&q->result_m); #ifdef DEBUG fprintf(stderr, "(q=%p) Found %p\n", q, r); #endif return r; } t_pool_result *t_pool_next_result_wait(t_results_queue *q) { t_pool_result *r; #ifdef DEBUG fprintf(stderr, "Waiting for result %d...\n", q->next_serial); #endif pthread_mutex_lock(&q->result_m); while (!(r = t_pool_next_result_locked(q))) { /* Possible race here now avoided via _locked() call, but incase... */ struct timeval now; struct timespec timeout; gettimeofday(&now, NULL); timeout.tv_sec = now.tv_sec + 10; timeout.tv_nsec = now.tv_usec * 1000; pthread_cond_timedwait(&q->result_avail_c, &q->result_m, &timeout); } pthread_mutex_unlock(&q->result_m); return r; } /* * Returns true if there are no items on the finished results queue and * also none still pending. */ int t_pool_results_queue_empty(t_results_queue *q) { int empty; pthread_mutex_lock(&q->result_m); empty = q->queue_len == 0 && q->pending == 0; pthread_mutex_unlock(&q->result_m); return empty; } /* * Returns the number of completed jobs on the results queue. */ int t_pool_results_queue_len(t_results_queue *q) { int len; pthread_mutex_lock(&q->result_m); len = q->queue_len; pthread_mutex_unlock(&q->result_m); return len; } int t_pool_results_queue_sz(t_results_queue *q) { int len; pthread_mutex_lock(&q->result_m); len = q->queue_len + q->pending; pthread_mutex_unlock(&q->result_m); return len; } /* * Frees a result 'r' and if free_data is true also frees * the internal r->data result too. */ void t_pool_delete_result(t_pool_result *r, int free_data) { if (!r) return; if (free_data && r->data) free(r->data); free(r); } /* * Initialises a results queue. * * Results queue pointer on success; * NULL on failure */ t_results_queue *t_results_queue_init(void) { t_results_queue *q = malloc(sizeof(*q)); pthread_mutex_init(&q->result_m, NULL); pthread_cond_init(&q->result_avail_c, NULL); q->result_head = NULL; q->result_tail = NULL; q->next_serial = 0; q->curr_serial = 0; q->queue_len = 0; q->pending = 0; return q; } /* Deallocates memory for a results queue */ void t_results_queue_destroy(t_results_queue *q) { #ifdef DEBUG fprintf(stderr, "Destroying results queue %p\n", q); #endif if (!q) return; pthread_mutex_destroy(&q->result_m); pthread_cond_destroy(&q->result_avail_c); memset(q, 0xbb, sizeof(*q)); free(q); #ifdef DEBUG fprintf(stderr, "Destroyed results queue %p\n", q); #endif } /* ---------------------------------------------------------------------------- * The thread pool. */ #define TDIFF(t2,t1) ((t2.tv_sec-t1.tv_sec)*1000000 + t2.tv_usec-t1.tv_usec) /* * A worker thread. * * Each thread waits for the pool to be non-empty. * As soon as this applies, one of them succeeds in getting the lock * and then executes the job. */ static void *t_pool_worker(void *arg) { t_pool_worker_t *w = (t_pool_worker_t *)arg; t_pool *p = w->p; t_pool_job *j; #ifdef DEBUG_TIME struct timeval t1, t2, t3; #endif for (;;) { // Pop an item off the pool queue #ifdef DEBUG_TIME gettimeofday(&t1, NULL); #endif pthread_mutex_lock(&p->pool_m); #ifdef DEBUG_TIME gettimeofday(&t2, NULL); p->wait_time += TDIFF(t2,t1); w->wait_time += TDIFF(t2,t1); #endif // If there is something on the job list and a higher priority // thread waiting, let it handle this instead. // while (p->head && p->t_stack_top != -1 && p->t_stack_top < w->idx) { // pthread_mutex_unlock(&p->pool_m); // pthread_cond_signal(&p->t[p->t_stack_top].pending_c); // pthread_mutex_lock(&p->pool_m); // } while (!p->head && !p->shutdown) { p->nwaiting++; if (p->njobs == 0) pthread_cond_signal(&p->empty_c); #ifdef DEBUG_TIME gettimeofday(&t2, NULL); #endif #ifdef IN_ORDER // Push this thread to the top of the waiting stack if (p->t_stack_top == -1 || p->t_stack_top > w->idx) p->t_stack_top = w->idx; p->t_stack[w->idx] = 1; pthread_cond_wait(&w->pending_c, &p->pool_m); p->t_stack[w->idx] = 0; /* Find new t_stack_top */ { int i; p->t_stack_top = -1; for (i = 0; i < p->tsize; i++) { if (p->t_stack[i]) { p->t_stack_top = i; break; } } } #else pthread_cond_wait(&p->pending_c, &p->pool_m); #endif #ifdef DEBUG_TIME gettimeofday(&t3, NULL); p->wait_time += TDIFF(t3,t2); w->wait_time += TDIFF(t3,t2); #endif p->nwaiting--; } if (p->shutdown) { #ifdef DEBUG_TIME p->total_time += TDIFF(t3,t1); #endif #ifdef DEBUG fprintf(stderr, "%d: Shutting down\n", worker_id(p)); #endif pthread_mutex_unlock(&p->pool_m); pthread_exit(NULL); } j = p->head; if (!(p->head = j->next)) p->tail = NULL; if (p->njobs-- >= p->qsize) pthread_cond_signal(&p->full_c); if (p->njobs == 0) pthread_cond_signal(&p->empty_c); pthread_mutex_unlock(&p->pool_m); // We have job 'j' - now execute it. t_pool_add_result(j, j->func(j->arg)); #ifdef DEBUG_TIME pthread_mutex_lock(&p->pool_m); gettimeofday(&t3, NULL); p->total_time += TDIFF(t3,t1); pthread_mutex_unlock(&p->pool_m); #endif memset(j, 0xbb, sizeof(*j)); free(j); } return NULL; } /* * Creates a worker pool of length qsize with tsize worker threads. * * Returns pool pointer on success; * NULL on failure */ t_pool *t_pool_init(int qsize, int tsize) { int i; t_pool *p = malloc(sizeof(*p)); p->qsize = qsize; p->tsize = tsize; p->njobs = 0; p->nwaiting = 0; p->shutdown = 0; p->head = p->tail = NULL; p->t_stack = NULL; #ifdef DEBUG_TIME p->total_time = p->wait_time = 0; #endif p->t = malloc(tsize * sizeof(p->t[0])); pthread_mutex_init(&p->pool_m, NULL); pthread_cond_init(&p->empty_c, NULL); pthread_cond_init(&p->full_c, NULL); pthread_mutex_lock(&p->pool_m); #ifdef IN_ORDER if (!(p->t_stack = malloc(tsize * sizeof(*p->t_stack)))) return NULL; p->t_stack_top = -1; for (i = 0; i < tsize; i++) { t_pool_worker_t *w = &p->t[i]; p->t_stack[i] = 0; w->p = p; w->idx = i; w->wait_time = 0; pthread_cond_init(&w->pending_c, NULL); if (0 != pthread_create(&w->tid, NULL, t_pool_worker, w)) return NULL; } #else pthread_cond_init(&p->pending_c, NULL); for (i = 0; i < tsize; i++) { t_pool_worker_t *w = &p->t[i]; w->p = p; w->idx = i; pthread_cond_init(&w->pending_c, NULL); if (0 != pthread_create(&w->tid, NULL, t_pool_worker, w)) return NULL; } #endif pthread_mutex_unlock(&p->pool_m); return p; } /* * Adds an item to the work pool. * * FIXME: Maybe return 1,0,-1 and distinguish between job dispathed vs * result returned. Ie rather than blocking on full queue we're permitted * to return early on "result available" event too. * Caller would then have a while loop around t_pool_dispatch. * Or, return -1 and set errno to EAGAIN to indicate job not yet submitted. * * Returns 0 on success * -1 on failure */ int t_pool_dispatch(t_pool *p, t_results_queue *q, void *(*func)(void *arg), void *arg) { t_pool_job *j = malloc(sizeof(*j)); if (!j) return -1; j->func = func; j->arg = arg; j->next = NULL; j->p = p; j->q = q; if (q) { pthread_mutex_lock(&q->result_m); j->serial = q->curr_serial++; q->pending++; pthread_mutex_unlock(&q->result_m); } else { j->serial = 0; } #ifdef DEBUG fprintf(stderr, "Dispatching job %p for queue %p, serial %d\n", j, q, j->serial); #endif pthread_mutex_lock(&p->pool_m); // Check if queue is full while (p->njobs >= p->qsize) pthread_cond_wait(&p->full_c, &p->pool_m); p->njobs++; if (p->tail) { p->tail->next = j; p->tail = j; } else { p->head = p->tail = j; } // Let a worker know we have data. #ifdef IN_ORDER if (p->t_stack_top >= 0 && p->njobs > p->tsize - p->nwaiting) pthread_cond_signal(&p->t[p->t_stack_top].pending_c); #else pthread_cond_signal(&p->pending_c); #endif pthread_mutex_unlock(&p->pool_m); #ifdef DEBUG fprintf(stderr, "Dispatched (serial %d)\n", j->serial); #endif return 0; } /* * As above but optional non-block flag. * * nonblock 0 => block if input queue is full * nonblock +1 => don't block if input queue is full, but do not add task * nonblock -1 => add task regardless of whether queue is full (over-size) */ int t_pool_dispatch2(t_pool *p, t_results_queue *q, void *(*func)(void *arg), void *arg, int nonblock) { t_pool_job *j; #ifdef DEBUG fprintf(stderr, "Dispatching job for queue %p, serial %d\n", q, q->curr_serial); #endif pthread_mutex_lock(&p->pool_m); if (p->njobs >= p->qsize && nonblock == 1) { pthread_mutex_unlock(&p->pool_m); errno = EAGAIN; return -1; } if (!(j = malloc(sizeof(*j)))) return -1; j->func = func; j->arg = arg; j->next = NULL; j->p = p; j->q = q; if (q) { pthread_mutex_lock(&q->result_m); j->serial = q->curr_serial; pthread_mutex_unlock(&q->result_m); } else { j->serial = 0; } if (q) { pthread_mutex_lock(&q->result_m); q->curr_serial++; q->pending++; pthread_mutex_unlock(&q->result_m); } // Check if queue is full if (nonblock == 0) while (p->njobs >= p->qsize) pthread_cond_wait(&p->full_c, &p->pool_m); p->njobs++; // if (q->curr_serial % 100 == 0) // fprintf(stderr, "p->njobs = %d p->qsize = %d\n", p->njobs, p->qsize); if (p->tail) { p->tail->next = j; p->tail = j; } else { p->head = p->tail = j; } #ifdef DEBUG fprintf(stderr, "Dispatched (serial %d)\n", j->serial); #endif // Let a worker know we have data. #ifdef IN_ORDER // Keep incoming queue at 1 per running thread, so there is always // something waiting when they end their current task. If we go above // this signal to start more threads (if available). This has the effect // of concentrating jobs to fewer cores when we are I/O bound, which in // turn benefits systems with auto CPU frequency scaling. if (p->t_stack_top >= 0 && p->njobs > p->tsize - p->nwaiting) pthread_cond_signal(&p->t[p->t_stack_top].pending_c); #else pthread_cond_signal(&p->pending_c); #endif pthread_mutex_unlock(&p->pool_m); return 0; } /* * Flushes the pool, but doesn't exit. This simply drains the queue and * ensures all worker threads have finished their current task. * * Returns 0 on success; * -1 on failure */ int t_pool_flush(t_pool *p) { int i; #ifdef DEBUG fprintf(stderr, "Flushing pool %p\n", p); #endif // Drains the queue pthread_mutex_lock(&p->pool_m); // Wake up everything for the final sprint! for (i = 0; i < p->tsize; i++) if (p->t_stack[i]) pthread_cond_signal(&p->t[i].pending_c); while (p->njobs || p->nwaiting != p->tsize) pthread_cond_wait(&p->empty_c, &p->pool_m); pthread_mutex_unlock(&p->pool_m); #ifdef DEBUG fprintf(stderr, "Flushed complete for pool %p, njobs=%d, nwaiting=%d\n", p, p->njobs, p->nwaiting); #endif return 0; } /* * Destroys a thread pool. If 'kill' is true the threads are terminated now, * otherwise they are joined into the main thread so they will finish their * current work load. * * Use t_pool_destroy(p,0) after a t_pool_flush(p) on a normal shutdown or * t_pool_destroy(p,1) to quickly exit after a fatal error. */ void t_pool_destroy(t_pool *p, int kill) { int i; #ifdef DEBUG fprintf(stderr, "Destroying pool %p, kill=%d\n", p, kill); #endif /* Send shutdown message to worker threads */ if (!kill) { pthread_mutex_lock(&p->pool_m); p->shutdown = 1; #ifdef DEBUG fprintf(stderr, "Sending shutdown request\n"); #endif #ifdef IN_ORDER for (i = 0; i < p->tsize; i++) pthread_cond_signal(&p->t[i].pending_c); #else pthread_cond_broadcast(&p->pending_c); #endif pthread_mutex_unlock(&p->pool_m); #ifdef DEBUG fprintf(stderr, "Shutdown complete\n"); #endif for (i = 0; i < p->tsize; i++) pthread_join(p->t[i].tid, NULL); } else { for (i = 0; i < p->tsize; i++) pthread_kill(p->t[i].tid, SIGINT); } pthread_mutex_destroy(&p->pool_m); pthread_cond_destroy(&p->empty_c); pthread_cond_destroy(&p->full_c); #ifdef IN_ORDER for (i = 0; i < p->tsize; i++) pthread_cond_destroy(&p->t[i].pending_c); #else pthread_cond_destroy(&p->pending_c); #endif #ifdef DEBUG_TIME fprintf(stderr, "Total time=%f\n", p->total_time / 1000000.0); fprintf(stderr, "Wait time=%f\n", p->wait_time / 1000000.0); fprintf(stderr, "%d%% utilisation\n", (int)(100 - ((100.0 * p->wait_time) / p->total_time + 0.5))); for (i = 0; i < p->tsize; i++) fprintf(stderr, "%d: Wait time=%f\n", i, p->t[i].wait_time / 1000000.0); #endif if (p->t_stack) free(p->t_stack); free(p->t); free(p); #ifdef DEBUG fprintf(stderr, "Destroyed pool %p\n", p); #endif } /*----------------------------------------------------------------------------- * Test app. */ #ifdef TEST_MAIN #include <stdio.h> #include <math.h> void *doit(void *arg) { int i, k, x = 0; int job = *(int *)arg; int *res; printf("Worker: execute job %d\n", job); usleep(random() % 1000000); // to coerce job completion out of order if (0) { for (k = 0; k < 100; k++) { for (i = 0; i < 100000; i++) { x++; x += x * sin(i); x += x * cos(x); } } x *= 100; x += job; } else { x = job*job; } printf("Worker: job %d terminating, x=%d\n", job, x); free(arg); res = malloc(sizeof(*res)); *res = x; return res; } #define NTHREADS 8 int main(int argc, char **argv) { t_pool *p = t_pool_init(NTHREADS*2, NTHREADS); t_results_queue *q = t_results_queue_init(); int i; t_pool_result *r; // Dispatch jobs for (i = 0; i < 20; i++) { int *ip = malloc(sizeof(*ip)); *ip = i; printf("Submitting %d\n", i); t_pool_dispatch(p, q, doit, ip); // Check for results if ((r = t_pool_next_result(q))) { printf("RESULT: %d\n", *(int *)r->data); t_pool_delete_result(r, 1); } } t_pool_flush(p); while ((r = t_pool_next_result(q))) { printf("RESULT: %d\n", *(int *)r->data); t_pool_delete_result(r, 1); } t_pool_destroy(p, 0); t_results_queue_destroy(q); return 0; } #endif