Include/pyatomic.h - platform/external/python/cpython3 - Gitiles

 #ifndef Py_ATOMIC_H
 #define Py_ATOMIC_H
 #ifdef Py_BUILD_CORE

 #include "dynamic_annotations.h"

 #include "pyconfig.h"

 #if defined(HAVE_STD_ATOMIC)
 #include <stdatomic.h>
 #endif

 /* This is modeled after the atomics interface from C1x, according to
  * the draft at
  * http://www.open-std.org/JTC1/SC22/wg14/www/docs/n1425.pdf.
  * Operations and types are named the same except with a _Py_ prefix
  * and have the same semantics.
  *
  * Beware, the implementations here are deep magic.
  */

 #if defined(HAVE_STD_ATOMIC)

 typedef enum _Py_memory_order {
     _Py_memory_order_relaxed = memory_order_relaxed,
     _Py_memory_order_acquire = memory_order_acquire,
     _Py_memory_order_release = memory_order_release,
     _Py_memory_order_acq_rel = memory_order_acq_rel,
     _Py_memory_order_seq_cst = memory_order_seq_cst
 } _Py_memory_order;

 typedef struct _Py_atomic_address {
     atomic_uintptr_t _value;
 } _Py_atomic_address;

 typedef struct _Py_atomic_int {
     atomic_int _value;
 } _Py_atomic_int;

 #define _Py_atomic_signal_fence(/*memory_order*/ ORDER) \
     atomic_signal_fence(ORDER)

 #define _Py_atomic_thread_fence(/*memory_order*/ ORDER) \
     atomic_thread_fence(ORDER)

 #define _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, ORDER) \
     atomic_store_explicit(&(ATOMIC_VAL)->_value, NEW_VAL, ORDER)

 #define _Py_atomic_load_explicit(ATOMIC_VAL, ORDER) \
     atomic_load_explicit(&(ATOMIC_VAL)->_value, ORDER)

 /* Use builtin atomic operations in GCC >= 4.7 */
 #elif defined(HAVE_BUILTIN_ATOMIC)

 typedef enum _Py_memory_order {
     _Py_memory_order_relaxed = __ATOMIC_RELAXED,
     _Py_memory_order_acquire = __ATOMIC_ACQUIRE,
     _Py_memory_order_release = __ATOMIC_RELEASE,
     _Py_memory_order_acq_rel = __ATOMIC_ACQ_REL,
     _Py_memory_order_seq_cst = __ATOMIC_SEQ_CST
 } _Py_memory_order;

 typedef struct _Py_atomic_address {
     Py_uintptr_t _value;
 } _Py_atomic_address;

 typedef struct _Py_atomic_int {
     int _value;
 } _Py_atomic_int;

 #define _Py_atomic_signal_fence(/*memory_order*/ ORDER) \
     __atomic_signal_fence(ORDER)

 #define _Py_atomic_thread_fence(/*memory_order*/ ORDER) \
     __atomic_thread_fence(ORDER)

 #define _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, ORDER) \
     (assert((ORDER) == __ATOMIC_RELAXED                       \
             || (ORDER) == __ATOMIC_SEQ_CST                    \
             || (ORDER) == __ATOMIC_RELEASE),                  \
      __atomic_store_n(&(ATOMIC_VAL)->_value, NEW_VAL, ORDER))

 #define _Py_atomic_load_explicit(ATOMIC_VAL, ORDER)           \
     (assert((ORDER) == __ATOMIC_RELAXED                       \
             || (ORDER) == __ATOMIC_SEQ_CST                    \
             || (ORDER) == __ATOMIC_ACQUIRE                    \
             || (ORDER) == __ATOMIC_CONSUME),                  \
      __atomic_load_n(&(ATOMIC_VAL)->_value, ORDER))

 #else

 typedef enum _Py_memory_order {
     _Py_memory_order_relaxed,
     _Py_memory_order_acquire,
     _Py_memory_order_release,
     _Py_memory_order_acq_rel,
     _Py_memory_order_seq_cst
 } _Py_memory_order;

 typedef struct _Py_atomic_address {
     Py_uintptr_t _value;
 } _Py_atomic_address;

 typedef struct _Py_atomic_int {
     int _value;
 } _Py_atomic_int;

 /* Only support GCC (for expression statements) and x86 (for simple
  * atomic semantics) for now */
 #if defined(__GNUC__) && (defined(__i386__) || defined(__amd64))

 static __inline__ void
 _Py_atomic_signal_fence(_Py_memory_order order)
 {
     if (order != _Py_memory_order_relaxed)
         __asm__ volatile("":::"memory");
 }

 static __inline__ void
 _Py_atomic_thread_fence(_Py_memory_order order)
 {
     if (order != _Py_memory_order_relaxed)
         __asm__ volatile("mfence":::"memory");
 }

 /* Tell the race checker about this operation's effects. */
 static __inline__ void
 _Py_ANNOTATE_MEMORY_ORDER(const volatile void *address, _Py_memory_order order)
 {
     (void)address;		/* shut up -Wunused-parameter */
     switch(order) {
     case _Py_memory_order_release:
     case _Py_memory_order_acq_rel:
     case _Py_memory_order_seq_cst:
         _Py_ANNOTATE_HAPPENS_BEFORE(address);
         break;
     case _Py_memory_order_relaxed:
     case _Py_memory_order_acquire:
         break;
     }
     switch(order) {
     case _Py_memory_order_acquire:
     case _Py_memory_order_acq_rel:
     case _Py_memory_order_seq_cst:
         _Py_ANNOTATE_HAPPENS_AFTER(address);
         break;
     case _Py_memory_order_relaxed:
     case _Py_memory_order_release:
         break;
     }
 }

 #define _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, ORDER) \
     __extension__ ({ \
         __typeof__(ATOMIC_VAL) atomic_val = ATOMIC_VAL; \
         __typeof__(atomic_val->_value) new_val = NEW_VAL;\
         volatile __typeof__(new_val) *volatile_data = &atomic_val->_value; \
         _Py_memory_order order = ORDER; \
         _Py_ANNOTATE_MEMORY_ORDER(atomic_val, order); \
         \
         /* Perform the operation. */ \
         _Py_ANNOTATE_IGNORE_WRITES_BEGIN(); \
         switch(order) { \
         case _Py_memory_order_release: \
             _Py_atomic_signal_fence(_Py_memory_order_release); \
             /* fallthrough */ \
         case _Py_memory_order_relaxed: \
             *volatile_data = new_val; \
             break; \
         \
         case _Py_memory_order_acquire: \
         case _Py_memory_order_acq_rel: \
         case _Py_memory_order_seq_cst: \
             __asm__ volatile("xchg %0, %1" \
                          : "+r"(new_val) \
                          : "m"(atomic_val->_value) \
                          : "memory"); \
             break; \
         } \
         _Py_ANNOTATE_IGNORE_WRITES_END(); \
     })

 #define _Py_atomic_load_explicit(ATOMIC_VAL, ORDER) \
     __extension__ ({  \
         __typeof__(ATOMIC_VAL) atomic_val = ATOMIC_VAL; \
         __typeof__(atomic_val->_value) result; \
         volatile __typeof__(result) *volatile_data = &atomic_val->_value; \
         _Py_memory_order order = ORDER; \
         _Py_ANNOTATE_MEMORY_ORDER(atomic_val, order); \
         \
         /* Perform the operation. */ \
         _Py_ANNOTATE_IGNORE_READS_BEGIN(); \
         switch(order) { \
         case _Py_memory_order_release: \
         case _Py_memory_order_acq_rel: \
         case _Py_memory_order_seq_cst: \
             /* Loads on x86 are not releases by default, so need a */ \
             /* thread fence. */ \
             _Py_atomic_thread_fence(_Py_memory_order_release); \
             break; \
         default: \
             /* No fence */ \
             break; \
         } \
         result = *volatile_data; \
         switch(order) { \
         case _Py_memory_order_acquire: \
         case _Py_memory_order_acq_rel: \
         case _Py_memory_order_seq_cst: \
             /* Loads on x86 are automatically acquire operations so */ \
             /* can get by with just a compiler fence. */ \
             _Py_atomic_signal_fence(_Py_memory_order_acquire); \
             break; \
         default: \
             /* No fence */ \
             break; \
         } \
         _Py_ANNOTATE_IGNORE_READS_END(); \
         result; \
     })

 #else  /* !gcc x86 */
 /* Fall back to other compilers and processors by assuming that simple
    volatile accesses are atomic.  This is false, so people should port
    this. */
 #define _Py_atomic_signal_fence(/*memory_order*/ ORDER) ((void)0)
 #define _Py_atomic_thread_fence(/*memory_order*/ ORDER) ((void)0)
 #define _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, ORDER) \
     ((ATOMIC_VAL)->_value = NEW_VAL)
 #define _Py_atomic_load_explicit(ATOMIC_VAL, ORDER) \
     ((ATOMIC_VAL)->_value)

 #endif  /* !gcc x86 */
 #endif

 /* Standardized shortcuts. */
 #define _Py_atomic_store(ATOMIC_VAL, NEW_VAL) \
     _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, _Py_memory_order_seq_cst)
 #define _Py_atomic_load(ATOMIC_VAL) \
     _Py_atomic_load_explicit(ATOMIC_VAL, _Py_memory_order_seq_cst)

 /* Python-local extensions */

 #define _Py_atomic_store_relaxed(ATOMIC_VAL, NEW_VAL) \
     _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, _Py_memory_order_relaxed)
 #define _Py_atomic_load_relaxed(ATOMIC_VAL) \
     _Py_atomic_load_explicit(ATOMIC_VAL, _Py_memory_order_relaxed)

 #endif  /* Py_BUILD_CORE */
 #endif  /* Py_ATOMIC_H */
	#ifndef Py_ATOMIC_H
	#define Py_ATOMIC_H
	#ifdef Py_BUILD_CORE

	#include "dynamic_annotations.h"

	#include "pyconfig.h"

	#if defined(HAVE_STD_ATOMIC)
	#include <stdatomic.h>
	#endif

	/* This is modeled after the atomics interface from C1x, according to
	* the draft at
	* http://www.open-std.org/JTC1/SC22/wg14/www/docs/n1425.pdf.
	* Operations and types are named the same except with a _Py_ prefix
	* and have the same semantics.
	*
	* Beware, the implementations here are deep magic.
	*/

	#if defined(HAVE_STD_ATOMIC)

	typedef enum _Py_memory_order {
	_Py_memory_order_relaxed = memory_order_relaxed,
	_Py_memory_order_acquire = memory_order_acquire,
	_Py_memory_order_release = memory_order_release,
	_Py_memory_order_acq_rel = memory_order_acq_rel,
	_Py_memory_order_seq_cst = memory_order_seq_cst
	} _Py_memory_order;

	typedef struct _Py_atomic_address {
	atomic_uintptr_t _value;
	} _Py_atomic_address;

	typedef struct _Py_atomic_int {
	atomic_int _value;
	} _Py_atomic_int;

	#define _Py_atomic_signal_fence(/memory_order/ ORDER) \
	atomic_signal_fence(ORDER)

	#define _Py_atomic_thread_fence(/memory_order/ ORDER) \
	atomic_thread_fence(ORDER)

	#define _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, ORDER) \
	atomic_store_explicit(&(ATOMIC_VAL)->_value, NEW_VAL, ORDER)

	#define _Py_atomic_load_explicit(ATOMIC_VAL, ORDER) \
	atomic_load_explicit(&(ATOMIC_VAL)->_value, ORDER)

	/* Use builtin atomic operations in GCC >= 4.7 */
	#elif defined(HAVE_BUILTIN_ATOMIC)

	typedef enum _Py_memory_order {
	_Py_memory_order_relaxed = __ATOMIC_RELAXED,
	_Py_memory_order_acquire = __ATOMIC_ACQUIRE,
	_Py_memory_order_release = __ATOMIC_RELEASE,
	_Py_memory_order_acq_rel = __ATOMIC_ACQ_REL,
	_Py_memory_order_seq_cst = __ATOMIC_SEQ_CST
	} _Py_memory_order;

	typedef struct _Py_atomic_address {
	Py_uintptr_t _value;
	} _Py_atomic_address;

	typedef struct _Py_atomic_int {
	int _value;
	} _Py_atomic_int;

	#define _Py_atomic_signal_fence(/memory_order/ ORDER) \
	__atomic_signal_fence(ORDER)

	#define _Py_atomic_thread_fence(/memory_order/ ORDER) \
	__atomic_thread_fence(ORDER)

	#define _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, ORDER) \
	(assert((ORDER) == __ATOMIC_RELAXED \
	\|\| (ORDER) == __ATOMIC_SEQ_CST \
	\|\| (ORDER) == __ATOMIC_RELEASE), \
	__atomic_store_n(&(ATOMIC_VAL)->_value, NEW_VAL, ORDER))

	#define _Py_atomic_load_explicit(ATOMIC_VAL, ORDER) \
	(assert((ORDER) == __ATOMIC_RELAXED \
	\|\| (ORDER) == __ATOMIC_SEQ_CST \
	\|\| (ORDER) == __ATOMIC_ACQUIRE \
	\|\| (ORDER) == __ATOMIC_CONSUME), \
	__atomic_load_n(&(ATOMIC_VAL)->_value, ORDER))

	#else

	typedef enum _Py_memory_order {
	_Py_memory_order_relaxed,
	_Py_memory_order_acquire,
	_Py_memory_order_release,
	_Py_memory_order_acq_rel,
	_Py_memory_order_seq_cst
	} _Py_memory_order;

	typedef struct _Py_atomic_address {
	Py_uintptr_t _value;
	} _Py_atomic_address;

	typedef struct _Py_atomic_int {
	int _value;
	} _Py_atomic_int;

	/* Only support GCC (for expression statements) and x86 (for simple
	* atomic semantics) for now */
	#if defined(__GNUC__) && (defined(__i386__) \|\| defined(__amd64))

	static __inline__ void
	_Py_atomic_signal_fence(_Py_memory_order order)
	{
	if (order != _Py_memory_order_relaxed)
	__asm__ volatile("":::"memory");
	}

	static __inline__ void
	_Py_atomic_thread_fence(_Py_memory_order order)
	{
	if (order != _Py_memory_order_relaxed)
	__asm__ volatile("mfence":::"memory");
	}

	/* Tell the race checker about this operation's effects. */
	static __inline__ void
	_Py_ANNOTATE_MEMORY_ORDER(const volatile void *address, _Py_memory_order order)
	{
	(void)address; /* shut up -Wunused-parameter */
	switch(order) {
	case _Py_memory_order_release:
	case _Py_memory_order_acq_rel:
	case _Py_memory_order_seq_cst:
	_Py_ANNOTATE_HAPPENS_BEFORE(address);
	break;
	case _Py_memory_order_relaxed:
	case _Py_memory_order_acquire:
	break;
	}
	switch(order) {
	case _Py_memory_order_acquire:
	case _Py_memory_order_acq_rel:
	case _Py_memory_order_seq_cst:
	_Py_ANNOTATE_HAPPENS_AFTER(address);
	break;
	case _Py_memory_order_relaxed:
	case _Py_memory_order_release:
	break;
	}
	}

	#define _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, ORDER) \
	__extension__ ({ \
	__typeof__(ATOMIC_VAL) atomic_val = ATOMIC_VAL; \
	__typeof__(atomic_val->_value) new_val = NEW_VAL;\
	volatile __typeof__(new_val) *volatile_data = &atomic_val->_value; \
	_Py_memory_order order = ORDER; \
	_Py_ANNOTATE_MEMORY_ORDER(atomic_val, order); \
	\
	/* Perform the operation. */ \
	_Py_ANNOTATE_IGNORE_WRITES_BEGIN(); \
	switch(order) { \
	case _Py_memory_order_release: \
	_Py_atomic_signal_fence(_Py_memory_order_release); \
	/* fallthrough */ \
	case _Py_memory_order_relaxed: \
	*volatile_data = new_val; \
	break; \
	\
	case _Py_memory_order_acquire: \
	case _Py_memory_order_acq_rel: \
	case _Py_memory_order_seq_cst: \
	__asm__ volatile("xchg %0, %1" \
	: "+r"(new_val) \
	: "m"(atomic_val->_value) \
	: "memory"); \
	break; \
	} \
	_Py_ANNOTATE_IGNORE_WRITES_END(); \
	})

	#define _Py_atomic_load_explicit(ATOMIC_VAL, ORDER) \
	__extension__ ({ \
	__typeof__(ATOMIC_VAL) atomic_val = ATOMIC_VAL; \
	__typeof__(atomic_val->_value) result; \
	volatile __typeof__(result) *volatile_data = &atomic_val->_value; \
	_Py_memory_order order = ORDER; \
	_Py_ANNOTATE_MEMORY_ORDER(atomic_val, order); \
	\
	/* Perform the operation. */ \
	_Py_ANNOTATE_IGNORE_READS_BEGIN(); \
	switch(order) { \
	case _Py_memory_order_release: \
	case _Py_memory_order_acq_rel: \
	case _Py_memory_order_seq_cst: \
	/* Loads on x86 are not releases by default, so need a */ \
	/* thread fence. */ \
	_Py_atomic_thread_fence(_Py_memory_order_release); \
	break; \
	default: \
	/* No fence */ \
	break; \
	} \
	result = *volatile_data; \
	switch(order) { \
	case _Py_memory_order_acquire: \
	case _Py_memory_order_acq_rel: \
	case _Py_memory_order_seq_cst: \
	/* Loads on x86 are automatically acquire operations so */ \
	/* can get by with just a compiler fence. */ \
	_Py_atomic_signal_fence(_Py_memory_order_acquire); \
	break; \
	default: \
	/* No fence */ \
	break; \
	} \
	_Py_ANNOTATE_IGNORE_READS_END(); \
	result; \
	})

	#else /* !gcc x86 */
	/* Fall back to other compilers and processors by assuming that simple
	volatile accesses are atomic. This is false, so people should port
	this. */
	#define _Py_atomic_signal_fence(/memory_order/ ORDER) ((void)0)
	#define _Py_atomic_thread_fence(/memory_order/ ORDER) ((void)0)
	#define _Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, ORDER) \
	((ATOMIC_VAL)->_value = NEW_VAL)
	#define _Py_atomic_load_explicit(ATOMIC_VAL, ORDER) \
	((ATOMIC_VAL)->_value)

	#endif /* !gcc x86 */
	#endif

	/* Standardized shortcuts. */
	#define _Py_atomic_store(ATOMIC_VAL, NEW_VAL) \
	_Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, _Py_memory_order_seq_cst)
	#define _Py_atomic_load(ATOMIC_VAL) \
	_Py_atomic_load_explicit(ATOMIC_VAL, _Py_memory_order_seq_cst)

	/* Python-local extensions */

	#define _Py_atomic_store_relaxed(ATOMIC_VAL, NEW_VAL) \
	_Py_atomic_store_explicit(ATOMIC_VAL, NEW_VAL, _Py_memory_order_relaxed)
	#define _Py_atomic_load_relaxed(ATOMIC_VAL) \
	_Py_atomic_load_explicit(ATOMIC_VAL, _Py_memory_order_relaxed)

	#endif /* Py_BUILD_CORE */
	#endif /* Py_ATOMIC_H */