PerformanceTests/StitchMarker/ck/include/gcc/ck_pr.h - WebKit - Git at Google

 /*
  * Copyright 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_GCC_H
 #define CK_PR_GCC_H

 #ifndef CK_PR_H
 #error Do not include this file directly, use ck_pr.h
 #endif

 #include <ck_cc.h>

 CK_CC_INLINE static void
 ck_pr_barrier(void)
 {

 	__asm__ __volatile__("" ::: "memory");
 	return;
 }

 #ifndef CK_F_PR
 #define CK_F_PR

 #include <ck_stdbool.h>
 #include <ck_stdint.h>

 /*
  * The following represent supported atomic operations.
  * These operations may be emulated.
  */
 #include "ck_f_pr.h"

 #define CK_PR_ACCESS(x) (*(volatile __typeof__(x) *)&(x))

 #define CK_PR_LOAD(S, M, T)		 			\
 	CK_CC_INLINE static T					\
 	ck_pr_md_load_##S(const M *target)			\
 	{							\
 		T r;						\
 		ck_pr_barrier();				\
 		r = CK_PR_ACCESS(*(const T *)target);		\
 		ck_pr_barrier();				\
 		return (r);					\
 	}							\
 	CK_CC_INLINE static void				\
 	ck_pr_md_store_##S(M *target, T v)			\
 	{							\
 		ck_pr_barrier();				\
 		CK_PR_ACCESS(*(T *)target) = v;			\
 		ck_pr_barrier();				\
 		return;						\
 	}

 CK_CC_INLINE static void *
 ck_pr_md_load_ptr(const void *target)
 {
 	void *r;

 	ck_pr_barrier();
 	r = CK_CC_DECONST_PTR(CK_PR_ACCESS(target));
 	ck_pr_barrier();

 	return r;
 }

 CK_CC_INLINE static void
 ck_pr_md_store_ptr(void *target, const void *v)
 {

 	ck_pr_barrier();
 	CK_PR_ACCESS(target) = CK_CC_DECONST_PTR(v);
 	ck_pr_barrier();
 	return;
 }

 #define CK_PR_LOAD_S(S, T) CK_PR_LOAD(S, T, T)

 CK_PR_LOAD_S(char, char)
 CK_PR_LOAD_S(uint, unsigned int)
 CK_PR_LOAD_S(int, int)
 #ifndef CK_PR_DISABLE_DOUBLE
 CK_PR_LOAD_S(double, double)
 #endif
 CK_PR_LOAD_S(64, uint64_t)
 CK_PR_LOAD_S(32, uint32_t)
 CK_PR_LOAD_S(16, uint16_t)
 CK_PR_LOAD_S(8,  uint8_t)

 #undef CK_PR_LOAD_S
 #undef CK_PR_LOAD

 CK_CC_INLINE static void
 ck_pr_stall(void)
 {

 	ck_pr_barrier();
 }

 /*
  * Load and store fences are equivalent to full fences in the GCC port.
  */
 #define CK_PR_FENCE(T)					\
 	CK_CC_INLINE static void			\
 	ck_pr_fence_strict_##T(void)			\
 	{						\
 		__sync_synchronize();			\
 	}

 CK_PR_FENCE(atomic)
 CK_PR_FENCE(atomic_atomic)
 CK_PR_FENCE(atomic_load)
 CK_PR_FENCE(atomic_store)
 CK_PR_FENCE(store_atomic)
 CK_PR_FENCE(load_atomic)
 CK_PR_FENCE(load)
 CK_PR_FENCE(load_load)
 CK_PR_FENCE(load_store)
 CK_PR_FENCE(store)
 CK_PR_FENCE(store_store)
 CK_PR_FENCE(store_load)
 CK_PR_FENCE(memory)
 CK_PR_FENCE(acquire)
 CK_PR_FENCE(release)
 CK_PR_FENCE(acqrel)
 CK_PR_FENCE(lock)
 CK_PR_FENCE(unlock)

 #undef CK_PR_FENCE

 /*
  * Atomic compare and swap.
  */
 #define CK_PR_CAS(S, M, T)							\
 	CK_CC_INLINE static bool						\
 	ck_pr_cas_##S(M *target, T compare, T set)				\
 	{									\
 		bool z;								\
 		z = __sync_bool_compare_and_swap((T *)target, compare, set);	\
 		return z;							\
 	}

 CK_PR_CAS(ptr, void, void *)

 #define CK_PR_CAS_S(S, T) CK_PR_CAS(S, T, T)

 CK_PR_CAS_S(char, char)
 CK_PR_CAS_S(int, int)
 CK_PR_CAS_S(uint, unsigned int)
 CK_PR_CAS_S(64, uint64_t)
 CK_PR_CAS_S(32, uint32_t)
 CK_PR_CAS_S(16, uint16_t)
 CK_PR_CAS_S(8,  uint8_t)

 #undef CK_PR_CAS_S
 #undef CK_PR_CAS

 /*
  * Compare and swap, set *v to old value of target.
  */
 CK_CC_INLINE static bool
 ck_pr_cas_ptr_value(void *target, void *compare, void *set, void *v)
 {
 	set = __sync_val_compare_and_swap((void **)target, compare, set);
 	*(void **)v = set;
 	return (set == compare);
 }

 #define CK_PR_CAS_O(S, T)						\
 	CK_CC_INLINE static bool					\
 	ck_pr_cas_##S##_value(T *target, T compare, T set, T *v)	\
 	{								\
 		set = __sync_val_compare_and_swap(target, compare, set);\
 		*v = set;						\
 		return (set == compare);				\
 	}

 CK_PR_CAS_O(char, char)
 CK_PR_CAS_O(int, int)
 CK_PR_CAS_O(uint, unsigned int)
 CK_PR_CAS_O(64, uint64_t)
 CK_PR_CAS_O(32, uint32_t)
 CK_PR_CAS_O(16, uint16_t)
 CK_PR_CAS_O(8,  uint8_t)

 #undef CK_PR_CAS_O

 /*
  * Atomic fetch-and-add operations.
  */
 #define CK_PR_FAA(S, M, T)					\
 	CK_CC_INLINE static T					\
 	ck_pr_faa_##S(M *target, T d)				\
 	{							\
 		d = __sync_fetch_and_add((T *)target, d);	\
 		return (d);					\
 	}

 CK_PR_FAA(ptr, void, void *)

 #define CK_PR_FAA_S(S, T) CK_PR_FAA(S, T, T)

 CK_PR_FAA_S(char, char)
 CK_PR_FAA_S(uint, unsigned int)
 CK_PR_FAA_S(int, int)
 CK_PR_FAA_S(64, uint64_t)
 CK_PR_FAA_S(32, uint32_t)
 CK_PR_FAA_S(16, uint16_t)
 CK_PR_FAA_S(8,  uint8_t)

 #undef CK_PR_FAA_S
 #undef CK_PR_FAA

 /*
  * Atomic store-only binary operations.
  */
 #define CK_PR_BINARY(K, S, M, T)				\
 	CK_CC_INLINE static void				\
 	ck_pr_##K##_##S(M *target, T d)				\
 	{							\
 		d = __sync_fetch_and_##K((T *)target, d);	\
 		return;						\
 	}

 #define CK_PR_BINARY_S(K, S, T) CK_PR_BINARY(K, S, T, T)

 #define CK_PR_GENERATE(K)			\
 	CK_PR_BINARY(K, ptr, void, void *)	\
 	CK_PR_BINARY_S(K, char, char)		\
 	CK_PR_BINARY_S(K, int, int)		\
 	CK_PR_BINARY_S(K, uint, unsigned int)	\
 	CK_PR_BINARY_S(K, 64, uint64_t)		\
 	CK_PR_BINARY_S(K, 32, uint32_t)		\
 	CK_PR_BINARY_S(K, 16, uint16_t)		\
 	CK_PR_BINARY_S(K, 8, uint8_t)

 CK_PR_GENERATE(add)
 CK_PR_GENERATE(sub)
 CK_PR_GENERATE(and)
 CK_PR_GENERATE(or)
 CK_PR_GENERATE(xor)

 #undef CK_PR_GENERATE
 #undef CK_PR_BINARY_S
 #undef CK_PR_BINARY

 #define CK_PR_UNARY(S, M, T)			\
 	CK_CC_INLINE static void		\
 	ck_pr_inc_##S(M *target)		\
 	{					\
 		ck_pr_add_##S(target, (T)1);	\
 		return;				\
 	}					\
 	CK_CC_INLINE static void		\
 	ck_pr_dec_##S(M *target)		\
 	{					\
 		ck_pr_sub_##S(target, (T)1);	\
 		return;				\
 	}

 #define CK_PR_UNARY_S(S, M) CK_PR_UNARY(S, M, M)

 CK_PR_UNARY(ptr, void, void *)
 CK_PR_UNARY_S(char, char)
 CK_PR_UNARY_S(int, int)
 CK_PR_UNARY_S(uint, unsigned int)
 CK_PR_UNARY_S(64, uint64_t)
 CK_PR_UNARY_S(32, uint32_t)
 CK_PR_UNARY_S(16, uint16_t)
 CK_PR_UNARY_S(8, uint8_t)

 #undef CK_PR_UNARY_S
 #undef CK_PR_UNARY
 #endif /* !CK_F_PR */
 #endif /* CK_PR_GCC_H */
	/*
	* Copyright 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_GCC_H
	#define CK_PR_GCC_H

	#ifndef CK_PR_H
	#error Do not include this file directly, use ck_pr.h
	#endif

	#include <ck_cc.h>

	CK_CC_INLINE static void
	ck_pr_barrier(void)
	{

	__asm__ __volatile__("" ::: "memory");
	return;
	}

	#ifndef CK_F_PR
	#define CK_F_PR

	#include <ck_stdbool.h>
	#include <ck_stdint.h>

	/*
	* The following represent supported atomic operations.
	* These operations may be emulated.
	*/
	#include "ck_f_pr.h"

	#define CK_PR_ACCESS(x) ((volatile __typeof__(x) )&(x))

	#define CK_PR_LOAD(S, M, T) \
	CK_CC_INLINE static T \
	ck_pr_md_load_##S(const M *target) \
	{ \
	T r; \
	ck_pr_barrier(); \
	r = CK_PR_ACCESS((const T )target); \
	ck_pr_barrier(); \
	return (r); \
	} \
	CK_CC_INLINE static void \
	ck_pr_md_store_##S(M *target, T v) \
	{ \
	ck_pr_barrier(); \
	CK_PR_ACCESS((T )target) = v; \
	ck_pr_barrier(); \
	return; \
	}

	CK_CC_INLINE static void *
	ck_pr_md_load_ptr(const void *target)
	{
	void *r;

	ck_pr_barrier();
	r = CK_CC_DECONST_PTR(CK_PR_ACCESS(target));
	ck_pr_barrier();

	return r;
	}

	CK_CC_INLINE static void
	ck_pr_md_store_ptr(void target, const void v)
	{

	ck_pr_barrier();
	CK_PR_ACCESS(target) = CK_CC_DECONST_PTR(v);
	ck_pr_barrier();
	return;
	}

	#define CK_PR_LOAD_S(S, T) CK_PR_LOAD(S, T, T)

	CK_PR_LOAD_S(char, char)
	CK_PR_LOAD_S(uint, unsigned int)
	CK_PR_LOAD_S(int, int)
	#ifndef CK_PR_DISABLE_DOUBLE
	CK_PR_LOAD_S(double, double)
	#endif
	CK_PR_LOAD_S(64, uint64_t)
	CK_PR_LOAD_S(32, uint32_t)
	CK_PR_LOAD_S(16, uint16_t)
	CK_PR_LOAD_S(8, uint8_t)

	#undef CK_PR_LOAD_S
	#undef CK_PR_LOAD

	CK_CC_INLINE static void
	ck_pr_stall(void)
	{

	ck_pr_barrier();
	}

	/*
	* Load and store fences are equivalent to full fences in the GCC port.
	*/
	#define CK_PR_FENCE(T) \
	CK_CC_INLINE static void \
	ck_pr_fence_strict_##T(void) \
	{ \
	__sync_synchronize(); \
	}

	CK_PR_FENCE(atomic)
	CK_PR_FENCE(atomic_atomic)
	CK_PR_FENCE(atomic_load)
	CK_PR_FENCE(atomic_store)
	CK_PR_FENCE(store_atomic)
	CK_PR_FENCE(load_atomic)
	CK_PR_FENCE(load)
	CK_PR_FENCE(load_load)
	CK_PR_FENCE(load_store)
	CK_PR_FENCE(store)
	CK_PR_FENCE(store_store)
	CK_PR_FENCE(store_load)
	CK_PR_FENCE(memory)
	CK_PR_FENCE(acquire)
	CK_PR_FENCE(release)
	CK_PR_FENCE(acqrel)
	CK_PR_FENCE(lock)
	CK_PR_FENCE(unlock)

	#undef CK_PR_FENCE

	/*
	* Atomic compare and swap.
	*/
	#define CK_PR_CAS(S, M, T) \
	CK_CC_INLINE static bool \
	ck_pr_cas_##S(M *target, T compare, T set) \
	{ \
	bool z; \
	z = __sync_bool_compare_and_swap((T *)target, compare, set); \
	return z; \
	}

	CK_PR_CAS(ptr, void, void *)

	#define CK_PR_CAS_S(S, T) CK_PR_CAS(S, T, T)

	CK_PR_CAS_S(char, char)
	CK_PR_CAS_S(int, int)
	CK_PR_CAS_S(uint, unsigned int)
	CK_PR_CAS_S(64, uint64_t)
	CK_PR_CAS_S(32, uint32_t)
	CK_PR_CAS_S(16, uint16_t)
	CK_PR_CAS_S(8, uint8_t)

	#undef CK_PR_CAS_S
	#undef CK_PR_CAS

	/*
	* Compare and swap, set *v to old value of target.
	*/
	CK_CC_INLINE static bool
	ck_pr_cas_ptr_value(void target, void compare, void set, void v)
	{
	set = __sync_val_compare_and_swap((void **)target, compare, set);
	(void *)v = set;
	return (set == compare);
	}

	#define CK_PR_CAS_O(S, T) \
	CK_CC_INLINE static bool \
	ck_pr_cas_##S##_value(T target, T compare, T set, T v) \
	{ \
	set = __sync_val_compare_and_swap(target, compare, set);\
	*v = set; \
	return (set == compare); \
	}

	CK_PR_CAS_O(char, char)
	CK_PR_CAS_O(int, int)
	CK_PR_CAS_O(uint, unsigned int)
	CK_PR_CAS_O(64, uint64_t)
	CK_PR_CAS_O(32, uint32_t)
	CK_PR_CAS_O(16, uint16_t)
	CK_PR_CAS_O(8, uint8_t)

	#undef CK_PR_CAS_O

	/*
	* Atomic fetch-and-add operations.
	*/
	#define CK_PR_FAA(S, M, T) \
	CK_CC_INLINE static T \
	ck_pr_faa_##S(M *target, T d) \
	{ \
	d = __sync_fetch_and_add((T *)target, d); \
	return (d); \
	}

	CK_PR_FAA(ptr, void, void *)

	#define CK_PR_FAA_S(S, T) CK_PR_FAA(S, T, T)

	CK_PR_FAA_S(char, char)
	CK_PR_FAA_S(uint, unsigned int)
	CK_PR_FAA_S(int, int)
	CK_PR_FAA_S(64, uint64_t)
	CK_PR_FAA_S(32, uint32_t)
	CK_PR_FAA_S(16, uint16_t)
	CK_PR_FAA_S(8, uint8_t)

	#undef CK_PR_FAA_S
	#undef CK_PR_FAA

	/*
	* Atomic store-only binary operations.
	*/
	#define CK_PR_BINARY(K, S, M, T) \
	CK_CC_INLINE static void \
	ck_pr_##K##_##S(M *target, T d) \
	{ \
	d = __sync_fetch_and_##K((T *)target, d); \
	return; \
	}

	#define CK_PR_BINARY_S(K, S, T) CK_PR_BINARY(K, S, T, T)

	#define CK_PR_GENERATE(K) \
	CK_PR_BINARY(K, ptr, void, void *) \
	CK_PR_BINARY_S(K, char, char) \
	CK_PR_BINARY_S(K, int, int) \
	CK_PR_BINARY_S(K, uint, unsigned int) \
	CK_PR_BINARY_S(K, 64, uint64_t) \
	CK_PR_BINARY_S(K, 32, uint32_t) \
	CK_PR_BINARY_S(K, 16, uint16_t) \
	CK_PR_BINARY_S(K, 8, uint8_t)

	CK_PR_GENERATE(add)
	CK_PR_GENERATE(sub)
	CK_PR_GENERATE(and)
	CK_PR_GENERATE(or)
	CK_PR_GENERATE(xor)

	#undef CK_PR_GENERATE
	#undef CK_PR_BINARY_S
	#undef CK_PR_BINARY

	#define CK_PR_UNARY(S, M, T) \
	CK_CC_INLINE static void \
	ck_pr_inc_##S(M *target) \
	{ \
	ck_pr_add_##S(target, (T)1); \
	return; \
	} \
	CK_CC_INLINE static void \
	ck_pr_dec_##S(M *target) \
	{ \
	ck_pr_sub_##S(target, (T)1); \
	return; \
	}

	#define CK_PR_UNARY_S(S, M) CK_PR_UNARY(S, M, M)

	CK_PR_UNARY(ptr, void, void *)
	CK_PR_UNARY_S(char, char)
	CK_PR_UNARY_S(int, int)
	CK_PR_UNARY_S(uint, unsigned int)
	CK_PR_UNARY_S(64, uint64_t)
	CK_PR_UNARY_S(32, uint32_t)
	CK_PR_UNARY_S(16, uint16_t)
	CK_PR_UNARY_S(8, uint8_t)

	#undef CK_PR_UNARY_S
	#undef CK_PR_UNARY
	#endif /* !CK_F_PR */
	#endif /* CK_PR_GCC_H */