libcutils/include/cutils/atomic.h - third_party/android/platform/system/core - Git at Google

 /*
  * Copyright (C) 2007 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #ifndef ANDROID_CUTILS_ATOMIC_H
 #define ANDROID_CUTILS_ATOMIC_H

 #include <stdint.h>
 #include <sys/types.h>
 #include <stdatomic.h>

 #ifndef ANDROID_ATOMIC_INLINE
 #define ANDROID_ATOMIC_INLINE static inline
 #endif

 /*
  * A handful of basic atomic operations.
  * THESE ARE HERE FOR LEGACY REASONS ONLY.  AVOID.
  *
  * PREFERRED ALTERNATIVES:
  * - Use C++/C/pthread locks/mutexes whenever there is not a
  *   convincing reason to do otherwise.  Note that very clever and
  *   complicated, but correct, lock-free code is often slower than
  *   using locks, especially where nontrivial data structures
  *   are involved.
  * - C11 stdatomic.h.
  * - Where supported, C++11 std::atomic<T> .
  *
  * PLEASE STOP READING HERE UNLESS YOU ARE TRYING TO UNDERSTAND
  * OR UPDATE OLD CODE.
  *
  * The "acquire" and "release" terms can be defined intuitively in terms
  * of the placement of memory barriers in a simple lock implementation:
  *   - wait until compare-and-swap(lock-is-free --> lock-is-held) succeeds
  *   - barrier
  *   - [do work]
  *   - barrier
  *   - store(lock-is-free)
  * In very crude terms, the initial (acquire) barrier prevents any of the
  * "work" from happening before the lock is held, and the later (release)
  * barrier ensures that all of the work happens before the lock is released.
  * (Think of cached writes, cache read-ahead, and instruction reordering
  * around the CAS and store instructions.)
  *
  * The barriers must apply to both the compiler and the CPU.  Note it is
  * legal for instructions that occur before an "acquire" barrier to be
  * moved down below it, and for instructions that occur after a "release"
  * barrier to be moved up above it.
  *
  * The ARM-driven implementation we use here is short on subtlety,
  * and actually requests a full barrier from the compiler and the CPU.
  * The only difference between acquire and release is in whether they
  * are issued before or after the atomic operation with which they
  * are associated.  To ease the transition to C/C++ atomic intrinsics,
  * you should not rely on this, and instead assume that only the minimal
  * acquire/release protection is provided.
  *
  * NOTE: all int32_t* values are expected to be aligned on 32-bit boundaries.
  * If they are not, atomicity is not guaranteed.
  */

 ANDROID_ATOMIC_INLINE
 volatile atomic_int_least32_t* to_atomic_int_least32_t(volatile const int32_t* addr) {
 #ifdef __cplusplus
     return reinterpret_cast<volatile atomic_int_least32_t*>(const_cast<volatile int32_t*>(addr));
 #else
     return (volatile atomic_int_least32_t*)addr;
 #endif
 }

 /*
  * Basic arithmetic and bitwise operations.  These all provide a
  * barrier with "release" ordering, and return the previous value.
  *
  * These have the same characteristics (e.g. what happens on overflow)
  * as the equivalent non-atomic C operations.
  */
 ANDROID_ATOMIC_INLINE
 int32_t android_atomic_inc(volatile int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
         /* Int32_t, if it exists, is the same as int_least32_t. */
     return atomic_fetch_add_explicit(a, 1, memory_order_release);
 }

 ANDROID_ATOMIC_INLINE
 int32_t android_atomic_dec(volatile int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     return atomic_fetch_sub_explicit(a, 1, memory_order_release);
 }

 ANDROID_ATOMIC_INLINE
 int32_t android_atomic_add(int32_t value, volatile int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     return atomic_fetch_add_explicit(a, value, memory_order_release);
 }

 ANDROID_ATOMIC_INLINE
 int32_t android_atomic_and(int32_t value, volatile int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     return atomic_fetch_and_explicit(a, value, memory_order_release);
 }

 ANDROID_ATOMIC_INLINE
 int32_t android_atomic_or(int32_t value, volatile int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     return atomic_fetch_or_explicit(a, value, memory_order_release);
 }

 /*
  * Perform an atomic load with "acquire" or "release" ordering.
  *
  * Note that the notion of a "release" ordering for a load does not
  * really fit into the C11 or C++11 memory model.  The extra ordering
  * is normally observable only by code using memory_order_relaxed
  * atomics, or data races.  In the rare cases in which such ordering
  * is called for, use memory_order_relaxed atomics and a leading
  * atomic_thread_fence (typically with memory_order_acquire,
  * not memory_order_release!) instead.  If you do not understand
  * this comment, you are in the vast majority, and should not be
  * using release loads or replacing them with anything other than
  * locks or default sequentially consistent atomics.
  */
 ANDROID_ATOMIC_INLINE
 int32_t android_atomic_acquire_load(volatile const int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     return atomic_load_explicit(a, memory_order_acquire);
 }

 ANDROID_ATOMIC_INLINE
 int32_t android_atomic_release_load(volatile const int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     atomic_thread_fence(memory_order_seq_cst);
     /* Any reasonable clients of this interface would probably prefer   */
     /* something weaker.  But some remaining clients seem to be         */
     /* abusing this API in strange ways, e.g. by using it as a fence.   */
     /* Thus we are conservative until we can get rid of remaining       */
     /* clients (and this function).                                     */
     return atomic_load_explicit(a, memory_order_relaxed);
 }

 /*
  * Perform an atomic store with "acquire" or "release" ordering.
  *
  * Note that the notion of an "acquire" ordering for a store does not
  * really fit into the C11 or C++11 memory model.  The extra ordering
  * is normally observable only by code using memory_order_relaxed
  * atomics, or data races.  In the rare cases in which such ordering
  * is called for, use memory_order_relaxed atomics and a trailing
  * atomic_thread_fence (typically with memory_order_release,
  * not memory_order_acquire!) instead.
  */
 ANDROID_ATOMIC_INLINE
 void android_atomic_acquire_store(int32_t value, volatile int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     atomic_store_explicit(a, value, memory_order_relaxed);
     atomic_thread_fence(memory_order_seq_cst);
     /* Again overly conservative to accomodate weird clients.   */
 }

 ANDROID_ATOMIC_INLINE
 void android_atomic_release_store(int32_t value, volatile int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     atomic_store_explicit(a, value, memory_order_release);
 }

 /*
  * Compare-and-set operation with "acquire" or "release" ordering.
  *
  * This returns zero if the new value was successfully stored, which will
  * only happen when *addr == oldvalue.
  *
  * (The return value is inverted from implementations on other platforms,
  * but matches the ARM ldrex/strex result.)
  *
  * Implementations that use the release CAS in a loop may be less efficient
  * than possible, because we re-issue the memory barrier on each iteration.
  */
 ANDROID_ATOMIC_INLINE
 int android_atomic_acquire_cas(int32_t oldvalue, int32_t newvalue,
                            volatile int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     return !atomic_compare_exchange_strong_explicit(
                                           a, &oldvalue, newvalue,
                                           memory_order_acquire,
                                           memory_order_acquire);
 }

 ANDROID_ATOMIC_INLINE
 int android_atomic_release_cas(int32_t oldvalue, int32_t newvalue,
                                volatile int32_t* addr)
 {
     volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
     return !atomic_compare_exchange_strong_explicit(
                                           a, &oldvalue, newvalue,
                                           memory_order_release,
                                           memory_order_relaxed);
 }

 /*
  * Fence primitives.
  */
 ANDROID_ATOMIC_INLINE
 void android_compiler_barrier(void)
 {
     __asm__ __volatile__ ("" : : : "memory");
     /* Could probably also be:                          */
     /* atomic_signal_fence(memory_order_seq_cst);       */
 }

 ANDROID_ATOMIC_INLINE
 void android_memory_barrier(void)
 {
     atomic_thread_fence(memory_order_seq_cst);
 }

 /*
  * Aliases for code using an older version of this header.  These are now
  * deprecated and should not be used.  The definitions will be removed
  * in a future release.
  */
 #define android_atomic_write android_atomic_release_store
 #define android_atomic_cmpxchg android_atomic_release_cas

 #endif // ANDROID_CUTILS_ATOMIC_H
	/*
	* Copyright (C) 2007 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#ifndef ANDROID_CUTILS_ATOMIC_H
	#define ANDROID_CUTILS_ATOMIC_H

	#include <stdint.h>
	#include <sys/types.h>
	#include <stdatomic.h>

	#ifndef ANDROID_ATOMIC_INLINE
	#define ANDROID_ATOMIC_INLINE static inline
	#endif

	/*
	* A handful of basic atomic operations.
	* THESE ARE HERE FOR LEGACY REASONS ONLY. AVOID.
	*
	* PREFERRED ALTERNATIVES:
	* - Use C++/C/pthread locks/mutexes whenever there is not a
	* convincing reason to do otherwise. Note that very clever and
	* complicated, but correct, lock-free code is often slower than
	* using locks, especially where nontrivial data structures
	* are involved.
	* - C11 stdatomic.h.
	* - Where supported, C++11 std::atomic<T> .
	*
	* PLEASE STOP READING HERE UNLESS YOU ARE TRYING TO UNDERSTAND
	* OR UPDATE OLD CODE.
	*
	* The "acquire" and "release" terms can be defined intuitively in terms
	* of the placement of memory barriers in a simple lock implementation:
	* - wait until compare-and-swap(lock-is-free --> lock-is-held) succeeds
	* - barrier
	* - [do work]
	* - barrier
	* - store(lock-is-free)
	* In very crude terms, the initial (acquire) barrier prevents any of the
	* "work" from happening before the lock is held, and the later (release)
	* barrier ensures that all of the work happens before the lock is released.
	* (Think of cached writes, cache read-ahead, and instruction reordering
	* around the CAS and store instructions.)
	*
	* The barriers must apply to both the compiler and the CPU. Note it is
	* legal for instructions that occur before an "acquire" barrier to be
	* moved down below it, and for instructions that occur after a "release"
	* barrier to be moved up above it.
	*
	* The ARM-driven implementation we use here is short on subtlety,
	* and actually requests a full barrier from the compiler and the CPU.
	* The only difference between acquire and release is in whether they
	* are issued before or after the atomic operation with which they
	* are associated. To ease the transition to C/C++ atomic intrinsics,
	* you should not rely on this, and instead assume that only the minimal
	* acquire/release protection is provided.
	*
	* NOTE: all int32_t* values are expected to be aligned on 32-bit boundaries.
	* If they are not, atomicity is not guaranteed.
	*/

	ANDROID_ATOMIC_INLINE
	volatile atomic_int_least32_t* to_atomic_int_least32_t(volatile const int32_t* addr) {
	#ifdef __cplusplus
	return reinterpret_cast<volatile atomic_int_least32_t>(const_cast<volatile int32_t>(addr));
	#else
	return (volatile atomic_int_least32_t*)addr;
	#endif
	}

	/*
	* Basic arithmetic and bitwise operations. These all provide a
	* barrier with "release" ordering, and return the previous value.
	*
	* These have the same characteristics (e.g. what happens on overflow)
	* as the equivalent non-atomic C operations.
	*/
	ANDROID_ATOMIC_INLINE
	int32_t android_atomic_inc(volatile int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	/* Int32_t, if it exists, is the same as int_least32_t. */
	return atomic_fetch_add_explicit(a, 1, memory_order_release);
	}

	ANDROID_ATOMIC_INLINE
	int32_t android_atomic_dec(volatile int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	return atomic_fetch_sub_explicit(a, 1, memory_order_release);
	}

	ANDROID_ATOMIC_INLINE
	int32_t android_atomic_add(int32_t value, volatile int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	return atomic_fetch_add_explicit(a, value, memory_order_release);
	}

	ANDROID_ATOMIC_INLINE
	int32_t android_atomic_and(int32_t value, volatile int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	return atomic_fetch_and_explicit(a, value, memory_order_release);
	}

	ANDROID_ATOMIC_INLINE
	int32_t android_atomic_or(int32_t value, volatile int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	return atomic_fetch_or_explicit(a, value, memory_order_release);
	}

	/*
	* Perform an atomic load with "acquire" or "release" ordering.
	*
	* Note that the notion of a "release" ordering for a load does not
	* really fit into the C11 or C++11 memory model. The extra ordering
	* is normally observable only by code using memory_order_relaxed
	* atomics, or data races. In the rare cases in which such ordering
	* is called for, use memory_order_relaxed atomics and a leading
	* atomic_thread_fence (typically with memory_order_acquire,
	* not memory_order_release!) instead. If you do not understand
	* this comment, you are in the vast majority, and should not be
	* using release loads or replacing them with anything other than
	* locks or default sequentially consistent atomics.
	*/
	ANDROID_ATOMIC_INLINE
	int32_t android_atomic_acquire_load(volatile const int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	return atomic_load_explicit(a, memory_order_acquire);
	}

	ANDROID_ATOMIC_INLINE
	int32_t android_atomic_release_load(volatile const int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	atomic_thread_fence(memory_order_seq_cst);
	/* Any reasonable clients of this interface would probably prefer */
	/* something weaker. But some remaining clients seem to be */
	/* abusing this API in strange ways, e.g. by using it as a fence. */
	/* Thus we are conservative until we can get rid of remaining */
	/* clients (and this function). */
	return atomic_load_explicit(a, memory_order_relaxed);
	}

	/*
	* Perform an atomic store with "acquire" or "release" ordering.
	*
	* Note that the notion of an "acquire" ordering for a store does not
	* really fit into the C11 or C++11 memory model. The extra ordering
	* is normally observable only by code using memory_order_relaxed
	* atomics, or data races. In the rare cases in which such ordering
	* is called for, use memory_order_relaxed atomics and a trailing
	* atomic_thread_fence (typically with memory_order_release,
	* not memory_order_acquire!) instead.
	*/
	ANDROID_ATOMIC_INLINE
	void android_atomic_acquire_store(int32_t value, volatile int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	atomic_store_explicit(a, value, memory_order_relaxed);
	atomic_thread_fence(memory_order_seq_cst);
	/* Again overly conservative to accomodate weird clients. */
	}

	ANDROID_ATOMIC_INLINE
	void android_atomic_release_store(int32_t value, volatile int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	atomic_store_explicit(a, value, memory_order_release);
	}

	/*
	* Compare-and-set operation with "acquire" or "release" ordering.
	*
	* This returns zero if the new value was successfully stored, which will
	* only happen when *addr == oldvalue.
	*
	* (The return value is inverted from implementations on other platforms,
	* but matches the ARM ldrex/strex result.)
	*
	* Implementations that use the release CAS in a loop may be less efficient
	* than possible, because we re-issue the memory barrier on each iteration.
	*/
	ANDROID_ATOMIC_INLINE
	int android_atomic_acquire_cas(int32_t oldvalue, int32_t newvalue,
	volatile int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	return !atomic_compare_exchange_strong_explicit(
	a, &oldvalue, newvalue,
	memory_order_acquire,
	memory_order_acquire);
	}

	ANDROID_ATOMIC_INLINE
	int android_atomic_release_cas(int32_t oldvalue, int32_t newvalue,
	volatile int32_t* addr)
	{
	volatile atomic_int_least32_t* a = to_atomic_int_least32_t(addr);
	return !atomic_compare_exchange_strong_explicit(
	a, &oldvalue, newvalue,
	memory_order_release,
	memory_order_relaxed);
	}

	/*
	* Fence primitives.
	*/
	ANDROID_ATOMIC_INLINE
	void android_compiler_barrier(void)
	{
	__asm__ __volatile__ ("" : : : "memory");
	/* Could probably also be: */
	/* atomic_signal_fence(memory_order_seq_cst); */
	}

	ANDROID_ATOMIC_INLINE
	void android_memory_barrier(void)
	{
	atomic_thread_fence(memory_order_seq_cst);
	}

	/*
	* Aliases for code using an older version of this header. These are now
	* deprecated and should not be used. The definitions will be removed
	* in a future release.
	*/
	#define android_atomic_write android_atomic_release_store
	#define android_atomic_cmpxchg android_atomic_release_cas

	#endif // ANDROID_CUTILS_ATOMIC_H