/* * Copyright (C) 2008 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 ART_RUNTIME_ATOMIC_H_ #define ART_RUNTIME_ATOMIC_H_ #include <stdint.h> #include <atomic> #include <limits> #include <vector> #include "arch/instruction_set.h" #include "base/logging.h" #include "base/macros.h" namespace art { class Mutex; // QuasiAtomic encapsulates two separate facilities that we are // trying to move away from: "quasiatomic" 64 bit operations // and custom memory fences. For the time being, they remain // exposed. Clients should be converted to use either class Atomic // below whenever possible, and should eventually use C++11 atomics. // The two facilities that do not have a good C++11 analog are // ThreadFenceForConstructor and Atomic::*JavaData. // // NOTE: Two "quasiatomic" operations on the exact same memory address // are guaranteed to operate atomically with respect to each other, // but no guarantees are made about quasiatomic operations mixed with // non-quasiatomic operations on the same address, nor about // quasiatomic operations that are performed on partially-overlapping // memory. class QuasiAtomic { static constexpr bool NeedSwapMutexes(InstructionSet isa) { // TODO - mips64 still need this for Cas64 ??? return (isa == kMips) || (isa == kMips64); } public: static void Startup(); static void Shutdown(); // Reads the 64-bit value at "addr" without tearing. static int64_t Read64(volatile const int64_t* addr) { if (!NeedSwapMutexes(kRuntimeISA)) { int64_t value; #if defined(__LP64__) value = *addr; #else #if defined(__arm__) #if defined(__ARM_FEATURE_LPAE) // With LPAE support (such as Cortex-A15) then ldrd is defined not to tear. __asm__ __volatile__("@ QuasiAtomic::Read64\n" "ldrd %0, %H0, %1" : "=r" (value) : "m" (*addr)); #else // Exclusive loads are defined not to tear, clearing the exclusive state isn't necessary. __asm__ __volatile__("@ QuasiAtomic::Read64\n" "ldrexd %0, %H0, %1" : "=r" (value) : "Q" (*addr)); #endif #elif defined(__i386__) __asm__ __volatile__( "movq %1, %0\n" : "=x" (value) : "m" (*addr)); #else LOG(FATAL) << "Unsupported architecture"; #endif #endif // defined(__LP64__) return value; } else { return SwapMutexRead64(addr); } } // Writes to the 64-bit value at "addr" without tearing. static void Write64(volatile int64_t* addr, int64_t value) { if (!NeedSwapMutexes(kRuntimeISA)) { #if defined(__LP64__) *addr = value; #else #if defined(__arm__) #if defined(__ARM_FEATURE_LPAE) // If we know that ARM architecture has LPAE (such as Cortex-A15) strd is defined not to tear. __asm__ __volatile__("@ QuasiAtomic::Write64\n" "strd %1, %H1, %0" : "=m"(*addr) : "r" (value)); #else // The write is done as a swap so that the cache-line is in the exclusive state for the store. int64_t prev; int status; do { __asm__ __volatile__("@ QuasiAtomic::Write64\n" "ldrexd %0, %H0, %2\n" "strexd %1, %3, %H3, %2" : "=&r" (prev), "=&r" (status), "+Q"(*addr) : "r" (value) : "cc"); } while (UNLIKELY(status != 0)); #endif #elif defined(__i386__) __asm__ __volatile__( "movq %1, %0" : "=m" (*addr) : "x" (value)); #else LOG(FATAL) << "Unsupported architecture"; #endif #endif // defined(__LP64__) } else { SwapMutexWrite64(addr, value); } } // Atomically compare the value at "addr" to "old_value", if equal replace it with "new_value" // and return true. Otherwise, don't swap, and return false. // This is fully ordered, i.e. it has C++11 memory_order_seq_cst // semantics (assuming all other accesses use a mutex if this one does). // This has "strong" semantics; if it fails then it is guaranteed that // at some point during the execution of Cas64, *addr was not equal to // old_value. static bool Cas64(int64_t old_value, int64_t new_value, volatile int64_t* addr) { if (!NeedSwapMutexes(kRuntimeISA)) { return __sync_bool_compare_and_swap(addr, old_value, new_value); } else { return SwapMutexCas64(old_value, new_value, addr); } } // Does the architecture provide reasonable atomic long operations or do we fall back on mutexes? static bool LongAtomicsUseMutexes(InstructionSet isa) { return NeedSwapMutexes(isa); } static void ThreadFenceAcquire() { std::atomic_thread_fence(std::memory_order_acquire); } static void ThreadFenceRelease() { std::atomic_thread_fence(std::memory_order_release); } static void ThreadFenceForConstructor() { #if defined(__aarch64__) __asm__ __volatile__("dmb ishst" : : : "memory"); #else std::atomic_thread_fence(std::memory_order_release); #endif } static void ThreadFenceSequentiallyConsistent() { std::atomic_thread_fence(std::memory_order_seq_cst); } private: static Mutex* GetSwapMutex(const volatile int64_t* addr); static int64_t SwapMutexRead64(volatile const int64_t* addr); static void SwapMutexWrite64(volatile int64_t* addr, int64_t val); static bool SwapMutexCas64(int64_t old_value, int64_t new_value, volatile int64_t* addr); // We stripe across a bunch of different mutexes to reduce contention. static constexpr size_t kSwapMutexCount = 32; static std::vector<Mutex*>* gSwapMutexes; DISALLOW_COPY_AND_ASSIGN(QuasiAtomic); }; template<typename T> class PACKED(sizeof(T)) Atomic : public std::atomic<T> { public: Atomic<T>() : std::atomic<T>(0) { } explicit Atomic<T>(T value) : std::atomic<T>(value) { } // Load from memory without ordering or synchronization constraints. T LoadRelaxed() const { return this->load(std::memory_order_relaxed); } // Load from memory with acquire ordering. T LoadAcquire() const { return this->load(std::memory_order_acquire); } // Word tearing allowed, but may race. // TODO: Optimize? // There has been some discussion of eventually disallowing word // tearing for Java data loads. T LoadJavaData() const { return this->load(std::memory_order_relaxed); } // Load from memory with a total ordering. // Corresponds exactly to a Java volatile load. T LoadSequentiallyConsistent() const { return this->load(std::memory_order_seq_cst); } // Store to memory without ordering or synchronization constraints. void StoreRelaxed(T desired) { this->store(desired, std::memory_order_relaxed); } // Word tearing allowed, but may race. void StoreJavaData(T desired) { this->store(desired, std::memory_order_relaxed); } // Store to memory with release ordering. void StoreRelease(T desired) { this->store(desired, std::memory_order_release); } // Store to memory with a total ordering. void StoreSequentiallyConsistent(T desired) { this->store(desired, std::memory_order_seq_cst); } // Atomically replace the value with desired value if it matches the expected value. // Participates in total ordering of atomic operations. bool CompareExchangeStrongSequentiallyConsistent(T expected_value, T desired_value) { return this->compare_exchange_strong(expected_value, desired_value, std::memory_order_seq_cst); } // The same, except it may fail spuriously. bool CompareExchangeWeakSequentiallyConsistent(T expected_value, T desired_value) { return this->compare_exchange_weak(expected_value, desired_value, std::memory_order_seq_cst); } // Atomically replace the value with desired value if it matches the expected value. Doesn't // imply ordering or synchronization constraints. bool CompareExchangeStrongRelaxed(T expected_value, T desired_value) { return this->compare_exchange_strong(expected_value, desired_value, std::memory_order_relaxed); } // The same, except it may fail spuriously. bool CompareExchangeWeakRelaxed(T expected_value, T desired_value) { return this->compare_exchange_weak(expected_value, desired_value, std::memory_order_relaxed); } // Atomically replace the value with desired value if it matches the expected value. Prior writes // made to other memory locations by the thread that did the release become visible in this // thread. bool CompareExchangeWeakAcquire(T expected_value, T desired_value) { return this->compare_exchange_weak(expected_value, desired_value, std::memory_order_acquire); } // Atomically replace the value with desired value if it matches the expected value. prior writes // to other memory locations become visible to the threads that do a consume or an acquire on the // same location. bool CompareExchangeWeakRelease(T expected_value, T desired_value) { return this->compare_exchange_weak(expected_value, desired_value, std::memory_order_release); } T FetchAndAddSequentiallyConsistent(const T value) { return this->fetch_add(value, std::memory_order_seq_cst); // Return old_value. } T FetchAndAddRelaxed(const T value) { return this->fetch_add(value, std::memory_order_relaxed); // Return old_value. } T FetchAndSubSequentiallyConsistent(const T value) { return this->fetch_sub(value, std::memory_order_seq_cst); // Return old value. } T FetchAndOrSequentiallyConsistent(const T value) { return this->fetch_or(value, std::memory_order_seq_cst); // Return old_value. } T FetchAndAndSequentiallyConsistent(const T value) { return this->fetch_and(value, std::memory_order_seq_cst); // Return old_value. } volatile T* Address() { return reinterpret_cast<T*>(this); } static T MaxValue() { return std::numeric_limits<T>::max(); } }; typedef Atomic<int32_t> AtomicInteger; static_assert(sizeof(AtomicInteger) == sizeof(int32_t), "Weird AtomicInteger size"); static_assert(alignof(AtomicInteger) == alignof(int32_t), "AtomicInteger alignment differs from that of underlyingtype"); static_assert(sizeof(Atomic<int64_t>) == sizeof(int64_t), "Weird Atomic<int64> size"); // Assert the alignment of 64-bit integers is 64-bit. This isn't true on certain 32-bit // architectures (e.g. x86-32) but we know that 64-bit integers here are arranged to be 8-byte // aligned. #if defined(__LP64__) static_assert(alignof(Atomic<int64_t>) == alignof(int64_t), "Atomic<int64> alignment differs from that of underlying type"); #endif } // namespace art #endif // ART_RUNTIME_ATOMIC_H_