/* * Copyright 2011-2013 Samy Al Bahra. * All rights reserved. * * 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. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 THE AUTHOR 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 #include #include #include #include #include #include #include #include #include #include #include #include "../../common.h" #ifndef ITERATE #define ITERATE 1000000 #endif static struct affinity a; static unsigned int locked; static unsigned int tid = 2; static int nthr; static ck_rwlock_t lock = CK_RWLOCK_INITIALIZER; static ck_rwlock_recursive_t r_lock = CK_RWLOCK_RECURSIVE_INITIALIZER; static void * thread_recursive(void *null CK_CC_UNUSED) { int i = ITERATE; unsigned int l; unsigned int t = ck_pr_faa_uint(&tid, 1); if (aff_iterate(&a)) { perror("ERROR: Could not affine thread"); exit(EXIT_FAILURE); } while (i--) { while (ck_rwlock_recursive_write_trylock(&r_lock, t) == false) ck_pr_stall(); ck_rwlock_recursive_write_lock(&r_lock, t); ck_rwlock_recursive_write_lock(&r_lock, t); ck_rwlock_recursive_write_lock(&r_lock, t); { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 8) { ck_error("ERROR [WR:%d]: %u != 2\n", __LINE__, l); } ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } } ck_rwlock_recursive_write_unlock(&r_lock); ck_rwlock_recursive_write_unlock(&r_lock); ck_rwlock_recursive_write_unlock(&r_lock); ck_rwlock_recursive_write_unlock(&r_lock); ck_rwlock_recursive_read_lock(&r_lock); { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [RD:%d]: %u != 0\n", __LINE__, l); } } ck_rwlock_recursive_read_unlock(&r_lock); } return (NULL); } #ifdef CK_F_PR_RTM static void * thread_rtm_adaptive(void *null CK_CC_UNUSED) { unsigned int i = ITERATE; unsigned int l; struct ck_elide_config config = CK_ELIDE_CONFIG_DEFAULT_INITIALIZER; struct ck_elide_stat st = CK_ELIDE_STAT_INITIALIZER; if (aff_iterate(&a)) { perror("ERROR: Could not affine thread"); exit(EXIT_FAILURE); } while (i--) { CK_ELIDE_LOCK_ADAPTIVE(ck_rwlock_write, &st, &config, &lock); { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 8) { ck_error("ERROR [WR:%d]: %u != 2\n", __LINE__, l); } ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } } CK_ELIDE_UNLOCK_ADAPTIVE(ck_rwlock_write, &st, &lock); CK_ELIDE_LOCK(ck_rwlock_read, &lock); { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [RD:%d]: %u != 0\n", __LINE__, l); } } CK_ELIDE_UNLOCK(ck_rwlock_read, &lock); } return NULL; } static void * thread_rtm_mix(void *null CK_CC_UNUSED) { unsigned int i = ITERATE; unsigned int l; if (aff_iterate(&a)) { perror("ERROR: Could not affine thread"); exit(EXIT_FAILURE); } while (i--) { if (i & 1) { CK_ELIDE_LOCK(ck_rwlock_write, &lock); } else { ck_rwlock_write_lock(&lock); } { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 8) { ck_error("ERROR [WR:%d]: %u != 2\n", __LINE__, l); } ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } } if (i & 1) { CK_ELIDE_UNLOCK(ck_rwlock_write, &lock); } else { ck_rwlock_write_unlock(&lock); } if (i & 1) { CK_ELIDE_LOCK(ck_rwlock_read, &lock); } else { ck_rwlock_read_lock(&lock); } { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [RD:%d]: %u != 0\n", __LINE__, l); } } if (i & 1) { CK_ELIDE_UNLOCK(ck_rwlock_read, &lock); } else { ck_rwlock_read_unlock(&lock); } } return (NULL); } static void * thread_rtm(void *null CK_CC_UNUSED) { unsigned int i = ITERATE; unsigned int l; if (aff_iterate(&a)) { perror("ERROR: Could not affine thread"); exit(EXIT_FAILURE); } while (i--) { CK_ELIDE_LOCK(ck_rwlock_write, &lock); { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 8) { ck_error("ERROR [WR:%d]: %u != 2\n", __LINE__, l); } ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } } CK_ELIDE_UNLOCK(ck_rwlock_write, &lock); CK_ELIDE_LOCK(ck_rwlock_read, &lock); { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [RD:%d]: %u != 0\n", __LINE__, l); } } CK_ELIDE_UNLOCK(ck_rwlock_read, &lock); } return (NULL); } #endif /* CK_F_PR_RTM */ static void * thread(void *null CK_CC_UNUSED) { unsigned int i = ITERATE; unsigned int l; if (aff_iterate(&a)) { perror("ERROR: Could not affine thread"); exit(EXIT_FAILURE); } while (i--) { ck_rwlock_write_lock(&lock); { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); ck_pr_inc_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 8) { ck_error("ERROR [WR:%d]: %u != 2\n", __LINE__, l); } ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); ck_pr_dec_uint(&locked); l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [WR:%d]: %u != 0\n", __LINE__, l); } } ck_rwlock_write_unlock(&lock); ck_rwlock_read_lock(&lock); { l = ck_pr_load_uint(&locked); if (l != 0) { ck_error("ERROR [RD:%d]: %u != 0\n", __LINE__, l); } } ck_rwlock_read_unlock(&lock); } return (NULL); } static void rwlock_test(pthread_t *threads, void *(*f)(void *), const char *test) { int i; fprintf(stderr, "Creating threads (%s)...", test); for (i = 0; i < nthr; i++) { if (pthread_create(&threads[i], NULL, f, NULL)) { ck_error("ERROR: Could not create thread %d\n", i); } } fprintf(stderr, "."); for (i = 0; i < nthr; i++) pthread_join(threads[i], NULL); fprintf(stderr, "done (passed)\n"); return; } int main(int argc, char *argv[]) { pthread_t *threads; if (argc != 3) { ck_error("Usage: validate \n"); } nthr = atoi(argv[1]); if (nthr <= 0) { ck_error("ERROR: Number of threads must be greater than 0\n"); } threads = malloc(sizeof(pthread_t) * nthr); if (threads == NULL) { ck_error("ERROR: Could not allocate thread structures\n"); } a.delta = atoi(argv[2]); rwlock_test(threads, thread, "regular"); #ifdef CK_F_PR_RTM rwlock_test(threads, thread_rtm, "rtm"); rwlock_test(threads, thread_rtm_mix, "rtm-mix"); rwlock_test(threads, thread_rtm_adaptive, "rtm-adaptive"); #endif rwlock_test(threads, thread_recursive, "recursive"); return 0; }