src/atomic.cc - platform/art - Gitiles

 /*
  * Copyright (C) 2010 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.
  */

 #include "atomic.h"

 #include <sched.h>

 namespace art {

 /*
  * Quasi-atomic 64-bit operations, for platforms that lack the real thing.
  *
  * TODO: unify ARMv6/x86/sh implementations using the to-be-written
  * spin lock implementation.  We don't want to rely on mutex innards,
  * and it would be great if all platforms were running the same code.
  */

 #if defined(HAVE_MACOSX_IPC)

 #include <libkern/OSAtomic.h>

 #if defined(__ppc__)        \
     || defined(__PPC__)     \
     || defined(__powerpc__) \
     || defined(__powerpc)   \
     || defined(__POWERPC__) \
     || defined(_M_PPC)      \
     || defined(__PPC)
 #define NEED_QUASIATOMICS 1
 #else

 int QuasiAtomicCas64(int64_t old_value, int64_t new_value, volatile int64_t* addr) {
   return OSAtomicCompareAndSwap64Barrier(old_value, new_value, (int64_t*)addr) == 0;
 }

 static inline int64_t QuasiAtomicSwap64Impl(int64_t value, volatile int64_t* addr) {
   int64_t old_value;
   do {
     old_value = *addr;
   } while (QuasiAtomicCas64(old_value, value, addr));
   return old_value;
 }

 int64_t QuasiAtomicSwap64(int64_t value, volatile int64_t* addr) {
   return QuasiAtomicSwap64Impl(value, addr);
 }

 int64_t QuasiAtomicSwap64Sync(int64_t value, volatile int64_t* addr) {
   ANDROID_MEMBAR_STORE();
   int64_t old_value = QuasiAtomicSwap64Impl(value, addr);
   /* TUNING: barriers can be avoided on some architectures */
   ANDROID_MEMBAR_FULL();
   return old_value;
 }

 int64_t QuasiAtomicRead64(volatile const int64_t* addr) {
   return OSAtomicAdd64Barrier(0, addr);
 }
 #endif

 #elif defined(__i386__) || defined(__x86_64__)
 #define NEED_QUASIATOMICS 1

 #elif __arm__
 #include <machine/cpu-features.h>

 #ifdef __ARM_HAVE_LDREXD
 static inline int64_t QuasiAtomicSwap64Impl(int64_t new_value, volatile int64_t* addr) {
   int64_t prev;
   int status;
   do {
     __asm__ __volatile__ ("@ QuasiAtomicSwap64\n"
         "ldrexd     %0, %H0, [%3]\n"
         "strexd     %1, %4, %H4, [%3]"
         : "=&r" (prev), "=&r" (status), "+m"(*addr)
         : "r" (addr), "r" (new_value)
         : "cc");
   } while (__builtin_expect(status != 0, 0));
   return prev;
 }

 int64_t QuasiAtomicSwap64(int64_t new_value, volatile int64_t* addr) {
   return QuasiAtomicSwap64Impl(new_value, addr);
 }

 int64_t QuasiAtomicSwap64Sync(int64_t new_value, volatile int64_t* addr) {
   ANDROID_MEMBAR_STORE();
   int64_t old_value = QuasiAtomicSwap64Impl(new_value, addr);
   ANDROID_MEMBAR_FULL();
   return old_value;
 }

 int QuasiAtomicCas64(int64_t old_value, int64_t new_value, volatile int64_t* addr) {
   int64_t prev;
   int status;
   do {
     __asm__ __volatile__ ("@ QuasiAtomicCas64\n"
         "ldrexd     %0, %H0, [%3]\n"
         "mov        %1, #0\n"
         "teq        %0, %4\n"
         "teqeq      %H0, %H4\n"
         "strexdeq   %1, %5, %H5, [%3]"
         : "=&r" (prev), "=&r" (status), "+m"(*addr)
         : "r" (addr), "Ir" (old_value), "r" (new_value)
         : "cc");
   } while (__builtin_expect(status != 0, 0));
   return prev != old_value;
 }

 int64_t QuasiAtomicRead64(volatile const int64_t* addr) {
   int64_t value;
   __asm__ __volatile__ ("@ QuasiAtomicRead64\n"
       "ldrexd     %0, %H0, [%1]"
       : "=&r" (value)
       : "r" (addr));
   return value;
 }

 #else

 // on the device, we implement the 64-bit atomic operations through
 // mutex locking. normally, this is bad because we must initialize
 // a pthread_mutex_t before being able to use it, and this means
 // having to do an initialization check on each function call, and
 // that's where really ugly things begin...
 //
 // BUT, as a special twist, we take advantage of the fact that in our
 // pthread library, a mutex is simply a volatile word whose value is always
 // initialized to 0. In other words, simply declaring a static mutex
 // object initializes it !
 //
 // another twist is that we use a small array of mutexes to dispatch
 // the contention locks from different memory addresses
 //

 #include <pthread.h>

 #define  SWAP_LOCK_COUNT  32U
 static pthread_mutex_t  _swap_locks[SWAP_LOCK_COUNT];

 #define  SWAP_LOCK(addr) &_swap_locks[((unsigned)(void*)(addr) >> 3U) % SWAP_LOCK_COUNT]

 int64_t QuasiAtomicSwap64(int64_t value, volatile int64_t* addr) {
   pthread_mutex_t*  lock = SWAP_LOCK(addr);

   pthread_mutex_lock(lock);

   int64_t old_value = *addr;
   *addr = value;

   pthread_mutex_unlock(lock);
   return old_value;
 }

 int64_t QuasiAtomicSwap64Sync(int64_t value, volatile int64_t* addr) {
   // Same as QuasiAtomicSwap64 - mutex handles barrier.
   return QuasiAtomicSwap64(value, addr);
 }

 int QuasiAtomicCas64(int64_t old_value, int64_t new_value, volatile int64_t* addr) {
   int result;
   pthread_mutex_t*  lock = SWAP_LOCK(addr);

   pthread_mutex_lock(lock);

   if (*addr == old_value) {
     *addr  = new_value;
     result = 0;
   } else {
     result = 1;
   }
   pthread_mutex_unlock(lock);
   return result;
 }

 int64_t QuasiAtomicRead64(volatile const int64_t* addr) {
   int64_t result;
   pthread_mutex_t*  lock = SWAP_LOCK(addr);

   pthread_mutex_lock(lock);
   result = *addr;
   pthread_mutex_unlock(lock);
   return result;
 }

 #endif /*__ARM_HAVE_LDREXD*/

 /*****************************************************************************/
 #elif __sh__
 #define NEED_QUASIATOMICS 1

 #else
 #error "Unsupported atomic operations for this platform"
 #endif


 #if NEED_QUASIATOMICS

 /* Note that a spinlock is *not* a good idea in general
  * since they can introduce subtle issues. For example,
  * a real-time thread trying to acquire a spinlock already
  * acquired by another thread will never yeld, making the
  * CPU loop endlessly!
  *
  * However, this code is only used on the Linux simulator
  * so it's probably ok for us.
  *
  * The alternative is to use a pthread mutex, but
  * these must be initialized before being used, and
  * then you have the problem of lazily initializing
  * a mutex without any other synchronization primitive.
  *
  * TODO: these currently use sched_yield(), which is not guaranteed to
  * do anything at all.  We need to use dvmIterativeSleep or a wait /
  * notify mechanism if the initial attempt fails.
  */

 /* global spinlock for all 64-bit quasiatomic operations */
 static int32_t quasiatomic_spinlock = 0;

 int QuasiAtomicCas64(int64_t old_value, int64_t new_value, volatile int64_t* addr) {
   int result;

   while (android_atomic_acquire_cas(0, 1, &quasiatomic_spinlock)) {
 #ifdef HAVE_WIN32_THREADS
     Sleep(0);
 #else
     sched_yield();
 #endif
   }

   if (*addr == old_value) {
     *addr = new_value;
     result = 0;
   } else {
     result = 1;
   }

   android_atomic_release_store(0, &quasiatomic_spinlock);

   return result;
 }

 int64_t QuasiAtomicRead64(volatile const int64_t* addr) {
   int64_t result;

   while (android_atomic_acquire_cas(0, 1, &quasiatomic_spinlock)) {
 #ifdef HAVE_WIN32_THREADS
     Sleep(0);
 #else
     sched_yield();
 #endif
   }

   result = *addr;
   android_atomic_release_store(0, &quasiatomic_spinlock);

   return result;
 }

 int64_t QuasiAtomicSwap64(int64_t value, volatile int64_t* addr) {
   int64_t result;

   while (android_atomic_acquire_cas(0, 1, &quasiatomic_spinlock)) {
 #ifdef HAVE_WIN32_THREADS
     Sleep(0);
 #else
     sched_yield();
 #endif
   }

   result = *addr;
   *addr = value;
   android_atomic_release_store(0, &quasiatomic_spinlock);

   return result;
 }

 int64_t QuasiAtomicSwap64Sync(int64_t value, volatile int64_t* addr) {
   // Same as QuasiAtomicSwap64 - syscall handles barrier.
   return QuasiAtomicSwap64(value, addr);
 }

 #endif /*NEED_QUASIATOMICS*/

 }  // namespace art
	/*
	* Copyright (C) 2010 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.
	*/

	#include "atomic.h"

	#include <sched.h>

	namespace art {

	/*
	* Quasi-atomic 64-bit operations, for platforms that lack the real thing.
	*
	* TODO: unify ARMv6/x86/sh implementations using the to-be-written
	* spin lock implementation. We don't want to rely on mutex innards,
	* and it would be great if all platforms were running the same code.
	*/

	#if defined(HAVE_MACOSX_IPC)

	#include <libkern/OSAtomic.h>

	#if defined(__ppc__) \
	\|\| defined(__PPC__) \
	\|\| defined(__powerpc__) \
	\|\| defined(__powerpc) \
	\|\| defined(__POWERPC__) \
	\|\| defined(_M_PPC) \
	\|\| defined(__PPC)
	#define NEED_QUASIATOMICS 1
	#else

	int QuasiAtomicCas64(int64_t old_value, int64_t new_value, volatile int64_t* addr) {
	return OSAtomicCompareAndSwap64Barrier(old_value, new_value, (int64_t*)addr) == 0;
	}

	static inline int64_t QuasiAtomicSwap64Impl(int64_t value, volatile int64_t* addr) {
	int64_t old_value;
	do {
	old_value = *addr;
	} while (QuasiAtomicCas64(old_value, value, addr));
	return old_value;
	}

	int64_t QuasiAtomicSwap64(int64_t value, volatile int64_t* addr) {
	return QuasiAtomicSwap64Impl(value, addr);
	}

	int64_t QuasiAtomicSwap64Sync(int64_t value, volatile int64_t* addr) {
	ANDROID_MEMBAR_STORE();
	int64_t old_value = QuasiAtomicSwap64Impl(value, addr);
	/* TUNING: barriers can be avoided on some architectures */
	ANDROID_MEMBAR_FULL();
	return old_value;
	}

	int64_t QuasiAtomicRead64(volatile const int64_t* addr) {
	return OSAtomicAdd64Barrier(0, addr);
	}
	#endif

	#elif defined(__i386__) \|\| defined(__x86_64__)
	#define NEED_QUASIATOMICS 1

	#elif __arm__
	#include <machine/cpu-features.h>

	#ifdef __ARM_HAVE_LDREXD
	static inline int64_t QuasiAtomicSwap64Impl(int64_t new_value, volatile int64_t* addr) {
	int64_t prev;
	int status;
	do {
	__asm__ __volatile__ ("@ QuasiAtomicSwap64\n"
	"ldrexd %0, %H0, [%3]\n"
	"strexd %1, %4, %H4, [%3]"
	: "=&r" (prev), "=&r" (status), "+m"(*addr)
	: "r" (addr), "r" (new_value)
	: "cc");
	} while (__builtin_expect(status != 0, 0));
	return prev;
	}

	int64_t QuasiAtomicSwap64(int64_t new_value, volatile int64_t* addr) {
	return QuasiAtomicSwap64Impl(new_value, addr);
	}

	int64_t QuasiAtomicSwap64Sync(int64_t new_value, volatile int64_t* addr) {
	ANDROID_MEMBAR_STORE();
	int64_t old_value = QuasiAtomicSwap64Impl(new_value, addr);
	ANDROID_MEMBAR_FULL();
	return old_value;
	}

	int QuasiAtomicCas64(int64_t old_value, int64_t new_value, volatile int64_t* addr) {
	int64_t prev;
	int status;
	do {
	__asm__ __volatile__ ("@ QuasiAtomicCas64\n"
	"ldrexd %0, %H0, [%3]\n"
	"mov %1, #0\n"
	"teq %0, %4\n"
	"teqeq %H0, %H4\n"
	"strexdeq %1, %5, %H5, [%3]"
	: "=&r" (prev), "=&r" (status), "+m"(*addr)
	: "r" (addr), "Ir" (old_value), "r" (new_value)
	: "cc");
	} while (__builtin_expect(status != 0, 0));
	return prev != old_value;
	}

	int64_t QuasiAtomicRead64(volatile const int64_t* addr) {
	int64_t value;
	__asm__ __volatile__ ("@ QuasiAtomicRead64\n"
	"ldrexd %0, %H0, [%1]"
	: "=&r" (value)
	: "r" (addr));
	return value;
	}

	#else

	// on the device, we implement the 64-bit atomic operations through
	// mutex locking. normally, this is bad because we must initialize
	// a pthread_mutex_t before being able to use it, and this means
	// having to do an initialization check on each function call, and
	// that's where really ugly things begin...
	//
	// BUT, as a special twist, we take advantage of the fact that in our
	// pthread library, a mutex is simply a volatile word whose value is always
	// initialized to 0. In other words, simply declaring a static mutex
	// object initializes it !
	//
	// another twist is that we use a small array of mutexes to dispatch
	// the contention locks from different memory addresses
	//

	#include <pthread.h>

	#define SWAP_LOCK_COUNT 32U
	static pthread_mutex_t _swap_locks[SWAP_LOCK_COUNT];

	#define SWAP_LOCK(addr) &_swap_locks[((unsigned)(void*)(addr) >> 3U) % SWAP_LOCK_COUNT]

	int64_t QuasiAtomicSwap64(int64_t value, volatile int64_t* addr) {
	pthread_mutex_t* lock = SWAP_LOCK(addr);

	pthread_mutex_lock(lock);

	int64_t old_value = *addr;
	*addr = value;

	pthread_mutex_unlock(lock);
	return old_value;
	}

	int64_t QuasiAtomicSwap64Sync(int64_t value, volatile int64_t* addr) {
	// Same as QuasiAtomicSwap64 - mutex handles barrier.
	return QuasiAtomicSwap64(value, addr);
	}

	int QuasiAtomicCas64(int64_t old_value, int64_t new_value, volatile int64_t* addr) {
	int result;
	pthread_mutex_t* lock = SWAP_LOCK(addr);

	pthread_mutex_lock(lock);

	if (*addr == old_value) {
	*addr = new_value;
	result = 0;
	} else {
	result = 1;
	}
	pthread_mutex_unlock(lock);
	return result;
	}

	int64_t QuasiAtomicRead64(volatile const int64_t* addr) {
	int64_t result;
	pthread_mutex_t* lock = SWAP_LOCK(addr);

	pthread_mutex_lock(lock);
	result = *addr;
	pthread_mutex_unlock(lock);
	return result;
	}

	#endif /__ARM_HAVE_LDREXD/

	/*****************************************************************************/
	#elif __sh__
	#define NEED_QUASIATOMICS 1

	#else
	#error "Unsupported atomic operations for this platform"
	#endif


	#if NEED_QUASIATOMICS

	/* Note that a spinlock is not a good idea in general
	* since they can introduce subtle issues. For example,
	* a real-time thread trying to acquire a spinlock already
	* acquired by another thread will never yeld, making the
	* CPU loop endlessly!
	*
	* However, this code is only used on the Linux simulator
	* so it's probably ok for us.
	*
	* The alternative is to use a pthread mutex, but
	* these must be initialized before being used, and
	* then you have the problem of lazily initializing
	* a mutex without any other synchronization primitive.
	*
	* TODO: these currently use sched_yield(), which is not guaranteed to
	* do anything at all. We need to use dvmIterativeSleep or a wait /
	* notify mechanism if the initial attempt fails.
	*/

	/* global spinlock for all 64-bit quasiatomic operations */
	static int32_t quasiatomic_spinlock = 0;

	int QuasiAtomicCas64(int64_t old_value, int64_t new_value, volatile int64_t* addr) {
	int result;

	while (android_atomic_acquire_cas(0, 1, &quasiatomic_spinlock)) {
	#ifdef HAVE_WIN32_THREADS
	Sleep(0);
	#else
	sched_yield();
	#endif
	}

	if (*addr == old_value) {
	*addr = new_value;
	result = 0;
	} else {
	result = 1;
	}

	android_atomic_release_store(0, &quasiatomic_spinlock);

	return result;
	}

	int64_t QuasiAtomicRead64(volatile const int64_t* addr) {
	int64_t result;

	while (android_atomic_acquire_cas(0, 1, &quasiatomic_spinlock)) {
	#ifdef HAVE_WIN32_THREADS
	Sleep(0);
	#else
	sched_yield();
	#endif
	}

	result = *addr;
	android_atomic_release_store(0, &quasiatomic_spinlock);

	return result;
	}

	int64_t QuasiAtomicSwap64(int64_t value, volatile int64_t* addr) {
	int64_t result;

	while (android_atomic_acquire_cas(0, 1, &quasiatomic_spinlock)) {
	#ifdef HAVE_WIN32_THREADS
	Sleep(0);
	#else
	sched_yield();
	#endif
	}

	result = *addr;
	*addr = value;
	android_atomic_release_store(0, &quasiatomic_spinlock);

	return result;
	}

	int64_t QuasiAtomicSwap64Sync(int64_t value, volatile int64_t* addr) {
	// Same as QuasiAtomicSwap64 - syscall handles barrier.
	return QuasiAtomicSwap64(value, addr);
	}

	#endif /NEED_QUASIATOMICS/

	} // namespace art