/** * @file annotate_rwlock.c * * @brief Multithreaded test program that triggers various access patterns * without triggering any race conditions using a reader-writer lock * implemented via busy-waiting. Annotations are used to tell DRD * which higher-level rwlock operations are being performed. */ #define _GNU_SOURCE 1 #include <assert.h> #include <pthread.h> #include <stdio.h> #include <unistd.h> /* usleep() */ #include "../../config.h" #include "../../drd/drd.h" #ifndef HAVE_BUILTIN_ATOMIC #error Sorry, but this test program can only be compiled by a compiler that\ has built-in functions for atomic memory access. #endif typedef struct { volatile int locked; int writer_count; int reader_count; } rwlock_t; static rwlock_t s_rwlock; static int s_counter; static void rwlock_init(rwlock_t* p) { DRD_IGNORE_VAR(*p); p->locked = 0; p->writer_count = 0; p->reader_count = 0; ANNOTATE_RWLOCK_CREATE(p); } static void rwlock_destroy(rwlock_t* p) { ANNOTATE_RWLOCK_DESTROY(p); assert(p->locked == 0); assert(p->writer_count == 0); assert(p->reader_count == 0); } static void rwlock_rdlock(rwlock_t* p) { while (1) { while (__sync_val_compare_and_swap(&p->locked, 0, 1) == 1) ; if (p->writer_count == 0) break; #ifndef HAVE_PTHREAD_YIELD /* Darwin doesn't have an implementation of pthread_yield(). */ usleep(100 * 1000); #else pthread_yield(); #endif (void) __sync_fetch_and_sub(&p->locked, 1); } p->reader_count++; assert(p->reader_count >= 0); assert(p->writer_count >= 0); assert(p->reader_count == 0 || p->writer_count == 0); (void) __sync_fetch_and_sub(&p->locked, 1); ANNOTATE_READERLOCK_ACQUIRED(p); } static void rwlock_wrlock(rwlock_t* p) { while (1) { while (__sync_val_compare_and_swap(&p->locked, 0, 1) == 1) ; if (p->reader_count == 0) break; #ifndef HAVE_PTHREAD_YIELD /* Darwin doesn't have an implementation of pthread_yield(). */ usleep(100 * 1000); #else pthread_yield(); #endif (void) __sync_fetch_and_sub(&p->locked, 1); } p->writer_count++; assert(p->reader_count >= 0); assert(p->writer_count >= 0); assert(p->reader_count == 0 || p->writer_count == 0); (void) __sync_fetch_and_sub(&p->locked, 1); ANNOTATE_WRITERLOCK_ACQUIRED(p); } static void rwlock_unlock(rwlock_t* p) { while (__sync_val_compare_and_swap(&p->locked, 0, 1) == 1) ; if (p->reader_count > 0) { p->reader_count--; ANNOTATE_READERLOCK_RELEASED(p); } else { p->writer_count--; ANNOTATE_WRITERLOCK_RELEASED(p); } assert(p->reader_count >= 0); assert(p->writer_count >= 0); assert(p->reader_count == 0 || p->writer_count == 0); (void) __sync_fetch_and_sub(&p->locked, 1); } static void* thread_func(void* arg) { int i; int sum = 0; for (i = 0; i < 1000; i++) { rwlock_rdlock(&s_rwlock); sum += s_counter; rwlock_unlock(&s_rwlock); rwlock_wrlock(&s_rwlock); s_counter++; rwlock_unlock(&s_rwlock); } return 0; } int main(int argc, char** argv) { const int thread_count = 10; pthread_t tid[thread_count]; int i; rwlock_init(&s_rwlock); for (i = 0; i < thread_count; i++) { pthread_create(&tid[i], 0, thread_func, 0); } for (i = 0; i < thread_count; i++) { pthread_join(tid[i], 0); } rwlock_destroy(&s_rwlock); fprintf(stderr, "Finished.\n"); return 0; }