/* * Copyright 2009, 2010 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. */ #ifndef _CK_PR_SPARCV9_H #define _CK_PR_SPARCV9_H #ifndef _CK_PR_H #error Do not include this file directly, use ck_pr.h #endif #include #include /* * The following represent supported atomic operations. * These operations may be emulated. */ #include "ck_f_pr.h" /* * Minimum interface requirement met. */ #define CK_F_PR /* * Order loads at the least. */ CK_CC_INLINE static void ck_pr_stall(void) { __asm__ __volatile__("membar #LoadLoad" ::: "memory"); return; } #define CK_PR_FENCE(T, I) \ CK_CC_INLINE static void \ ck_pr_fence_strict_##T(void) \ { \ __asm__ __volatile__(I ::: "memory"); \ } /* * Atomic operations are treated as both load and store * operations on SPARCv9. */ CK_PR_FENCE(atomic, "membar #StoreStore") CK_PR_FENCE(atomic_store, "membar #StoreStore") CK_PR_FENCE(atomic_load, "membar #StoreLoad") CK_PR_FENCE(store_atomic, "membar #StoreStore") CK_PR_FENCE(load_atomic, "membar #LoadStore") CK_PR_FENCE(store, "membar #StoreStore") CK_PR_FENCE(store_load, "membar #StoreLoad") CK_PR_FENCE(load, "membar #LoadLoad") CK_PR_FENCE(load_store, "membar #LoadStore") CK_PR_FENCE(memory, "membar #LoadLoad | #LoadStore | #StoreStore | #StoreLoad") CK_PR_FENCE(acquire, "membar #LoadLoad | #LoadStore") CK_PR_FENCE(release, "membar #LoadStore | #StoreStore") #undef CK_PR_FENCE #define CK_PR_LOAD(S, M, T, C, I) \ CK_CC_INLINE static T \ ck_pr_load_##S(const M *target) \ { \ T r; \ __asm__ __volatile__(I " [%1], %0" \ : "=&r" (r) \ : "r" (target) \ : "memory"); \ return (r); \ } CK_PR_LOAD(ptr, void, void *, uint64_t, "ldx") #define CK_PR_LOAD_S(S, T, I) CK_PR_LOAD(S, T, T, T, I) CK_PR_LOAD_S(64, uint64_t, "ldx") CK_PR_LOAD_S(32, uint32_t, "lduw") CK_PR_LOAD_S(uint, unsigned int, "lduw") CK_PR_LOAD_S(double, double, "ldx") CK_PR_LOAD_S(int, int, "ldsw") #undef CK_PR_LOAD_S #undef CK_PR_LOAD #define CK_PR_STORE(S, M, T, C, I) \ CK_CC_INLINE static void \ ck_pr_store_##S(M *target, T v) \ { \ __asm__ __volatile__(I " %0, [%1]" \ : \ : "r" (v), \ "r" (target) \ : "memory"); \ return; \ } CK_PR_STORE(ptr, void, const void *, uint64_t, "stx") #define CK_PR_STORE_S(S, T, I) CK_PR_STORE(S, T, T, T, I) CK_PR_STORE_S(8, uint8_t, "stub") CK_PR_STORE_S(64, uint64_t, "stx") CK_PR_STORE_S(32, uint32_t, "stuw") CK_PR_STORE_S(uint, unsigned int, "stuw") CK_PR_STORE_S(double, double, "stx") CK_PR_STORE_S(int, int, "stsw") #undef CK_PR_STORE_S #undef CK_PR_STORE CK_CC_INLINE static bool ck_pr_cas_64_value(uint64_t *target, uint64_t compare, uint64_t set, uint64_t *value) { __asm__ __volatile__("casx [%1], %2, %0" : "+&r" (set) : "r" (target), "r" (compare) : "memory"); *value = set; return (compare == set); } CK_CC_INLINE static bool ck_pr_cas_64(uint64_t *target, uint64_t compare, uint64_t set) { __asm__ __volatile__("casx [%1], %2, %0" : "+&r" (set) : "r" (target), "r" (compare) : "memory"); return (compare == set); } CK_CC_INLINE static bool ck_pr_cas_ptr(void *target, void *compare, void *set) { return ck_pr_cas_64(target, (uint64_t)compare, (uint64_t)set); } CK_CC_INLINE static bool ck_pr_cas_ptr_value(void *target, void *compare, void *set, void *previous) { return ck_pr_cas_64_value(target, (uint64_t)compare, (uint64_t)set, previous); } #define CK_PR_CAS(N, T) \ CK_CC_INLINE static bool \ ck_pr_cas_##N##_value(T *target, T compare, T set, T *value) \ { \ __asm__ __volatile__("cas [%1], %2, %0" \ : "+&r" (set) \ : "r" (target), \ "r" (compare) \ : "memory"); \ *value = set; \ return (compare == set); \ } \ CK_CC_INLINE static bool \ ck_pr_cas_##N(T *target, T compare, T set) \ { \ __asm__ __volatile__("cas [%1], %2, %0" \ : "+&r" (set) \ : "r" (target), \ "r" (compare) \ : "memory"); \ return (compare == set); \ } CK_PR_CAS(32, uint32_t) CK_PR_CAS(uint, unsigned int) CK_PR_CAS(int, int) #undef CK_PR_CAS #define CK_PR_FAS(N, T) \ CK_CC_INLINE static T \ ck_pr_fas_##N(T *target, T update) \ { \ \ __asm__ __volatile__("swap [%1], %0" \ : "+&r" (update) \ : "r" (target) \ : "memory"); \ return (update); \ } CK_PR_FAS(int, int) CK_PR_FAS(uint, unsigned int) CK_PR_FAS(32, uint32_t) #undef CK_PR_FAS #endif /* _CK_PR_SPARCV9_H */