/* * Copyright (c) 2003 by Hewlett-Packard Company. 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, sublicense, 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 above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * 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 NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS 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 following is useful primarily for debugging and documentation. */ /* We define various atomic operations by acquiring a global pthread */ /* lock. The resulting implementation will perform poorly, but should */ /* be correct unless it is used from signal handlers. */ /* We assume that all pthread operations act like full memory barriers. */ /* (We believe that is the intent of the specification.) */ #include #include "test_and_set_t_is_ao_t.h" /* This is not necessarily compatible with the native */ /* implementation. But those can't be safely mixed anyway. */ #ifdef __cplusplus extern "C" { #endif /* We define only the full barrier variants, and count on the */ /* generalization section below to fill in the rest. */ extern pthread_mutex_t AO_pt_lock; #ifdef __cplusplus } /* extern "C" */ #endif AO_INLINE void AO_nop_full(void) { pthread_mutex_lock(&AO_pt_lock); pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_nop_full AO_INLINE AO_t AO_load_full(const volatile AO_t *addr) { AO_t result; pthread_mutex_lock(&AO_pt_lock); result = *addr; pthread_mutex_unlock(&AO_pt_lock); return result; } #define AO_HAVE_load_full AO_INLINE void AO_store_full(volatile AO_t *addr, AO_t val) { pthread_mutex_lock(&AO_pt_lock); *addr = val; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_store_full AO_INLINE unsigned char AO_char_load_full(const volatile unsigned char *addr) { unsigned char result; pthread_mutex_lock(&AO_pt_lock); result = *addr; pthread_mutex_unlock(&AO_pt_lock); return result; } #define AO_HAVE_char_load_full AO_INLINE void AO_char_store_full(volatile unsigned char *addr, unsigned char val) { pthread_mutex_lock(&AO_pt_lock); *addr = val; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_char_store_full AO_INLINE unsigned short AO_short_load_full(const volatile unsigned short *addr) { unsigned short result; pthread_mutex_lock(&AO_pt_lock); result = *addr; pthread_mutex_unlock(&AO_pt_lock); return result; } #define AO_HAVE_short_load_full AO_INLINE void AO_short_store_full(volatile unsigned short *addr, unsigned short val) { pthread_mutex_lock(&AO_pt_lock); *addr = val; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_short_store_full AO_INLINE unsigned int AO_int_load_full(const volatile unsigned int *addr) { unsigned int result; pthread_mutex_lock(&AO_pt_lock); result = *addr; pthread_mutex_unlock(&AO_pt_lock); return result; } #define AO_HAVE_int_load_full AO_INLINE void AO_int_store_full(volatile unsigned int *addr, unsigned int val) { pthread_mutex_lock(&AO_pt_lock); *addr = val; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_int_store_full AO_INLINE AO_TS_VAL_t AO_test_and_set_full(volatile AO_TS_t *addr) { AO_TS_VAL_t result; pthread_mutex_lock(&AO_pt_lock); result = (AO_TS_VAL_t)(*addr); *addr = AO_TS_SET; pthread_mutex_unlock(&AO_pt_lock); assert(result == AO_TS_SET || result == AO_TS_CLEAR); return result; } #define AO_HAVE_test_and_set_full AO_INLINE AO_t AO_fetch_and_add_full(volatile AO_t *p, AO_t incr) { AO_t old_val; pthread_mutex_lock(&AO_pt_lock); old_val = *p; *p = old_val + incr; pthread_mutex_unlock(&AO_pt_lock); return old_val; } #define AO_HAVE_fetch_and_add_full AO_INLINE unsigned char AO_char_fetch_and_add_full(volatile unsigned char *p, unsigned char incr) { unsigned char old_val; pthread_mutex_lock(&AO_pt_lock); old_val = *p; *p = old_val + incr; pthread_mutex_unlock(&AO_pt_lock); return old_val; } #define AO_HAVE_char_fetch_and_add_full AO_INLINE unsigned short AO_short_fetch_and_add_full(volatile unsigned short *p, unsigned short incr) { unsigned short old_val; pthread_mutex_lock(&AO_pt_lock); old_val = *p; *p = old_val + incr; pthread_mutex_unlock(&AO_pt_lock); return old_val; } #define AO_HAVE_short_fetch_and_add_full AO_INLINE unsigned int AO_int_fetch_and_add_full(volatile unsigned int *p, unsigned int incr) { unsigned int old_val; pthread_mutex_lock(&AO_pt_lock); old_val = *p; *p = old_val + incr; pthread_mutex_unlock(&AO_pt_lock); return old_val; } #define AO_HAVE_int_fetch_and_add_full AO_INLINE void AO_and_full(volatile AO_t *p, AO_t value) { pthread_mutex_lock(&AO_pt_lock); *p &= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_and_full AO_INLINE void AO_or_full(volatile AO_t *p, AO_t value) { pthread_mutex_lock(&AO_pt_lock); *p |= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_or_full AO_INLINE void AO_xor_full(volatile AO_t *p, AO_t value) { pthread_mutex_lock(&AO_pt_lock); *p ^= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_xor_full AO_INLINE void AO_char_and_full(volatile unsigned char *p, unsigned char value) { pthread_mutex_lock(&AO_pt_lock); *p &= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_char_and_full AO_INLINE void AO_char_or_full(volatile unsigned char *p, unsigned char value) { pthread_mutex_lock(&AO_pt_lock); *p |= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_char_or_full AO_INLINE void AO_char_xor_full(volatile unsigned char *p, unsigned char value) { pthread_mutex_lock(&AO_pt_lock); *p ^= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_char_xor_full AO_INLINE void AO_short_and_full(volatile unsigned short *p, unsigned short value) { pthread_mutex_lock(&AO_pt_lock); *p &= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_short_and_full AO_INLINE void AO_short_or_full(volatile unsigned short *p, unsigned short value) { pthread_mutex_lock(&AO_pt_lock); *p |= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_short_or_full AO_INLINE void AO_short_xor_full(volatile unsigned short *p, unsigned short value) { pthread_mutex_lock(&AO_pt_lock); *p ^= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_short_xor_full AO_INLINE void AO_int_and_full(volatile unsigned *p, unsigned value) { pthread_mutex_lock(&AO_pt_lock); *p &= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_int_and_full AO_INLINE void AO_int_or_full(volatile unsigned *p, unsigned value) { pthread_mutex_lock(&AO_pt_lock); *p |= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_int_or_full AO_INLINE void AO_int_xor_full(volatile unsigned *p, unsigned value) { pthread_mutex_lock(&AO_pt_lock); *p ^= value; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_int_xor_full AO_INLINE AO_t AO_fetch_compare_and_swap_full(volatile AO_t *addr, AO_t old_val, AO_t new_val) { AO_t fetched_val; pthread_mutex_lock(&AO_pt_lock); fetched_val = *addr; if (fetched_val == old_val) *addr = new_val; pthread_mutex_unlock(&AO_pt_lock); return fetched_val; } #define AO_HAVE_fetch_compare_and_swap_full AO_INLINE unsigned char AO_char_fetch_compare_and_swap_full(volatile unsigned char *addr, unsigned char old_val, unsigned char new_val) { unsigned char fetched_val; pthread_mutex_lock(&AO_pt_lock); fetched_val = *addr; if (fetched_val == old_val) *addr = new_val; pthread_mutex_unlock(&AO_pt_lock); return fetched_val; } #define AO_HAVE_char_fetch_compare_and_swap_full AO_INLINE unsigned short AO_short_fetch_compare_and_swap_full(volatile unsigned short *addr, unsigned short old_val, unsigned short new_val) { unsigned short fetched_val; pthread_mutex_lock(&AO_pt_lock); fetched_val = *addr; if (fetched_val == old_val) *addr = new_val; pthread_mutex_unlock(&AO_pt_lock); return fetched_val; } #define AO_HAVE_short_fetch_compare_and_swap_full AO_INLINE unsigned AO_int_fetch_compare_and_swap_full(volatile unsigned *addr, unsigned old_val, unsigned new_val) { unsigned fetched_val; pthread_mutex_lock(&AO_pt_lock); fetched_val = *addr; if (fetched_val == old_val) *addr = new_val; pthread_mutex_unlock(&AO_pt_lock); return fetched_val; } #define AO_HAVE_int_fetch_compare_and_swap_full /* Unlike real architectures, we define both double-width CAS variants. */ typedef struct { AO_t AO_val1; AO_t AO_val2; } AO_double_t; #define AO_HAVE_double_t #define AO_DOUBLE_T_INITIALIZER { (AO_t)0, (AO_t)0 } AO_INLINE AO_double_t AO_double_load_full(const volatile AO_double_t *addr) { AO_double_t result; pthread_mutex_lock(&AO_pt_lock); result.AO_val1 = addr->AO_val1; result.AO_val2 = addr->AO_val2; pthread_mutex_unlock(&AO_pt_lock); return result; } #define AO_HAVE_double_load_full AO_INLINE void AO_double_store_full(volatile AO_double_t *addr, AO_double_t value) { pthread_mutex_lock(&AO_pt_lock); addr->AO_val1 = value.AO_val1; addr->AO_val2 = value.AO_val2; pthread_mutex_unlock(&AO_pt_lock); } #define AO_HAVE_double_store_full AO_INLINE int AO_compare_double_and_swap_double_full(volatile AO_double_t *addr, AO_t old1, AO_t old2, AO_t new1, AO_t new2) { pthread_mutex_lock(&AO_pt_lock); if (addr -> AO_val1 == old1 && addr -> AO_val2 == old2) { addr -> AO_val1 = new1; addr -> AO_val2 = new2; pthread_mutex_unlock(&AO_pt_lock); return 1; } else pthread_mutex_unlock(&AO_pt_lock); return 0; } #define AO_HAVE_compare_double_and_swap_double_full AO_INLINE int AO_compare_and_swap_double_full(volatile AO_double_t *addr, AO_t old1, AO_t new1, AO_t new2) { pthread_mutex_lock(&AO_pt_lock); if (addr -> AO_val1 == old1) { addr -> AO_val1 = new1; addr -> AO_val2 = new2; pthread_mutex_unlock(&AO_pt_lock); return 1; } else pthread_mutex_unlock(&AO_pt_lock); return 0; } #define AO_HAVE_compare_and_swap_double_full /* We can't use hardware loads and stores, since they don't */ /* interact correctly with atomic updates. */