yuzu/src/common/atomic_helpers.h

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chore: make yuzu REUSE compliant [REUSE] is a specification that aims at making file copyright information consistent, so that it can be both human and machine readable. It basically requires that all files have a header containing copyright and licensing information. When this isn't possible, like when dealing with binary assets, generated files or embedded third-party dependencies, it is permitted to insert copyright information in the `.reuse/dep5` file. Oh, and it also requires that all the licenses used in the project are present in the `LICENSES` folder, that's why the diff is so huge. This can be done automatically with `reuse download --all`. The `reuse` tool also contains a handy subcommand that analyzes the project and tells whether or not the project is (still) compliant, `reuse lint`. Following REUSE has a few advantages over the current approach: - Copyright information is easy to access for users / downstream - Files like `dist/license.md` do not need to exist anymore, as `.reuse/dep5` is used instead - `reuse lint` makes it easy to ensure that copyright information of files like binary assets / images is always accurate and up to date To add copyright information of files that didn't have it I looked up who committed what and when, for each file. As yuzu contributors do not have to sign a CLA or similar I couldn't assume that copyright ownership was of the "yuzu Emulator Project", so I used the name and/or email of the commit author instead. [REUSE]: https://reuse.software Follow-up to 01cf05bc75b1e47beb08937439f3ed9339e7b254
2022-05-15 00:06:02 +00:00
// SPDX-FileCopyrightText: 2013-2016 Cameron Desrochers
// SPDX-FileCopyrightText: 2015 Jeff Preshing
// SPDX-License-Identifier: BSD-2-Clause AND Zlib
2022-07-16 22:48:45 +00:00
// Distributed under the simplified BSD license (see the license file that
// should have come with this header).
// Uses Jeff Preshing's semaphore implementation (under the terms of its
// separate zlib license, embedded below).
#pragma once
// Provides portable (VC++2010+, Intel ICC 13, GCC 4.7+, and anything C++11 compliant)
// implementation of low-level memory barriers, plus a few semi-portable utility macros (for
// inlining and alignment). Also has a basic atomic type (limited to hardware-supported atomics with
// no memory ordering guarantees). Uses the AE_* prefix for macros (historical reasons), and the
// "moodycamel" namespace for symbols.
#include <cassert>
#include <cerrno>
#include <cstdint>
#include <ctime>
#include <type_traits>
// Platform detection
#if defined(__INTEL_COMPILER)
#define AE_ICC
#elif defined(_MSC_VER)
#define AE_VCPP
#elif defined(__GNUC__)
#define AE_GCC
#endif
#if defined(_M_IA64) || defined(__ia64__)
#define AE_ARCH_IA64
#elif defined(_WIN64) || defined(__amd64__) || defined(_M_X64) || defined(__x86_64__)
#define AE_ARCH_X64
#elif defined(_M_IX86) || defined(__i386__)
#define AE_ARCH_X86
#elif defined(_M_PPC) || defined(__powerpc__)
#define AE_ARCH_PPC
#else
#define AE_ARCH_UNKNOWN
#endif
// AE_UNUSED
#define AE_UNUSED(x) ((void)x)
// AE_NO_TSAN/AE_TSAN_ANNOTATE_*
#if defined(__has_feature)
#if __has_feature(thread_sanitizer)
#if __cplusplus >= 201703L // inline variables require C++17
namespace Common {
inline int ae_tsan_global;
}
#define AE_TSAN_ANNOTATE_RELEASE() \
AnnotateHappensBefore(__FILE__, __LINE__, (void*)(&::moodycamel::ae_tsan_global))
#define AE_TSAN_ANNOTATE_ACQUIRE() \
AnnotateHappensAfter(__FILE__, __LINE__, (void*)(&::moodycamel::ae_tsan_global))
extern "C" void AnnotateHappensBefore(const char*, int, void*);
extern "C" void AnnotateHappensAfter(const char*, int, void*);
#else // when we can't work with tsan, attempt to disable its warnings
#define AE_NO_TSAN __attribute__((no_sanitize("thread")))
#endif
#endif
#endif
#ifndef AE_NO_TSAN
#define AE_NO_TSAN
#endif
#ifndef AE_TSAN_ANNOTATE_RELEASE
#define AE_TSAN_ANNOTATE_RELEASE()
#define AE_TSAN_ANNOTATE_ACQUIRE()
#endif
// AE_FORCEINLINE
#if defined(AE_VCPP) || defined(AE_ICC)
#define AE_FORCEINLINE __forceinline
#elif defined(AE_GCC)
//#define AE_FORCEINLINE __attribute__((always_inline))
#define AE_FORCEINLINE inline
#else
#define AE_FORCEINLINE inline
#endif
// AE_ALIGN
#if defined(AE_VCPP) || defined(AE_ICC)
#define AE_ALIGN(x) __declspec(align(x))
#elif defined(AE_GCC)
#define AE_ALIGN(x) __attribute__((aligned(x)))
#else
// Assume GCC compliant syntax...
#define AE_ALIGN(x) __attribute__((aligned(x)))
#endif
// Portable atomic fences implemented below:
namespace Common {
enum memory_order {
memory_order_relaxed,
memory_order_acquire,
memory_order_release,
memory_order_acq_rel,
memory_order_seq_cst,
// memory_order_sync: Forces a full sync:
// #LoadLoad, #LoadStore, #StoreStore, and most significantly, #StoreLoad
memory_order_sync = memory_order_seq_cst
};
} // namespace Common
#if (defined(AE_VCPP) && (_MSC_VER < 1700 || defined(__cplusplus_cli))) || \
(defined(AE_ICC) && __INTEL_COMPILER < 1600)
// VS2010 and ICC13 don't support std::atomic_*_fence, implement our own fences
#include <intrin.h>
#if defined(AE_ARCH_X64) || defined(AE_ARCH_X86)
#define AeFullSync _mm_mfence
#define AeLiteSync _mm_mfence
#elif defined(AE_ARCH_IA64)
#define AeFullSync __mf
#define AeLiteSync __mf
#elif defined(AE_ARCH_PPC)
#include <ppcintrinsics.h>
#define AeFullSync __sync
#define AeLiteSync __lwsync
#endif
#ifdef AE_VCPP
#pragma warning(push)
#pragma warning(disable : 4365) // Disable erroneous 'conversion from long to unsigned int,
// signed/unsigned mismatch' error when using `assert`
#ifdef __cplusplus_cli
#pragma managed(push, off)
#endif
#endif
namespace Common {
AE_FORCEINLINE void compiler_fence(memory_order order) AE_NO_TSAN {
switch (order) {
case memory_order_relaxed:
break;
case memory_order_acquire:
_ReadBarrier();
break;
case memory_order_release:
_WriteBarrier();
break;
case memory_order_acq_rel:
_ReadWriteBarrier();
break;
case memory_order_seq_cst:
_ReadWriteBarrier();
break;
default:
assert(false);
break;
2022-07-16 22:48:45 +00:00
}
}
// x86/x64 have a strong memory model -- all loads and stores have
// acquire and release semantics automatically (so only need compiler
// barriers for those).
#if defined(AE_ARCH_X86) || defined(AE_ARCH_X64)
AE_FORCEINLINE void fence(memory_order order) AE_NO_TSAN {
switch (order) {
case memory_order_relaxed:
break;
case memory_order_acquire:
_ReadBarrier();
break;
case memory_order_release:
_WriteBarrier();
break;
case memory_order_acq_rel:
_ReadWriteBarrier();
break;
case memory_order_seq_cst:
_ReadWriteBarrier();
AeFullSync();
_ReadWriteBarrier();
break;
default:
assert(false);
}
}
#else
AE_FORCEINLINE void fence(memory_order order) AE_NO_TSAN {
// Non-specialized arch, use heavier memory barriers everywhere just in case :-(
switch (order) {
case memory_order_relaxed:
break;
case memory_order_acquire:
_ReadBarrier();
AeLiteSync();
_ReadBarrier();
break;
case memory_order_release:
_WriteBarrier();
AeLiteSync();
_WriteBarrier();
break;
case memory_order_acq_rel:
_ReadWriteBarrier();
AeLiteSync();
_ReadWriteBarrier();
break;
case memory_order_seq_cst:
_ReadWriteBarrier();
AeFullSync();
_ReadWriteBarrier();
break;
default:
assert(false);
}
}
#endif
} // namespace Common
#else
// Use standard library of atomics
#include <atomic>
namespace Common {
AE_FORCEINLINE void compiler_fence(memory_order order) AE_NO_TSAN {
switch (order) {
case memory_order_relaxed:
break;
case memory_order_acquire:
std::atomic_signal_fence(std::memory_order_acquire);
break;
case memory_order_release:
std::atomic_signal_fence(std::memory_order_release);
break;
case memory_order_acq_rel:
std::atomic_signal_fence(std::memory_order_acq_rel);
break;
case memory_order_seq_cst:
std::atomic_signal_fence(std::memory_order_seq_cst);
break;
default:
assert(false);
}
}
AE_FORCEINLINE void fence(memory_order order) AE_NO_TSAN {
switch (order) {
case memory_order_relaxed:
break;
case memory_order_acquire:
AE_TSAN_ANNOTATE_ACQUIRE();
std::atomic_thread_fence(std::memory_order_acquire);
break;
case memory_order_release:
AE_TSAN_ANNOTATE_RELEASE();
std::atomic_thread_fence(std::memory_order_release);
break;
case memory_order_acq_rel:
AE_TSAN_ANNOTATE_ACQUIRE();
AE_TSAN_ANNOTATE_RELEASE();
std::atomic_thread_fence(std::memory_order_acq_rel);
break;
case memory_order_seq_cst:
AE_TSAN_ANNOTATE_ACQUIRE();
AE_TSAN_ANNOTATE_RELEASE();
std::atomic_thread_fence(std::memory_order_seq_cst);
break;
default:
assert(false);
}
}
} // namespace Common
#endif
#if !defined(AE_VCPP) || (_MSC_VER >= 1700 && !defined(__cplusplus_cli))
#define AE_USE_STD_ATOMIC_FOR_WEAK_ATOMIC
#endif
#ifdef AE_USE_STD_ATOMIC_FOR_WEAK_ATOMIC
#include <atomic>
#endif
#include <utility>
// WARNING: *NOT* A REPLACEMENT FOR std::atomic. READ CAREFULLY:
// Provides basic support for atomic variables -- no memory ordering guarantees are provided.
// The guarantee of atomicity is only made for types that already have atomic load and store
// guarantees at the hardware level -- on most platforms this generally means aligned pointers and
// integers (only).
namespace Common {
template <typename T>
class weak_atomic {
public:
AE_NO_TSAN weak_atomic() : value() {}
#ifdef AE_VCPP
#pragma warning(push)
#pragma warning(disable : 4100) // Get rid of (erroneous) 'unreferenced formal parameter' warning
#endif
template <typename U>
AE_NO_TSAN weak_atomic(U&& x) : value(std::forward<U>(x)) {}
#ifdef __cplusplus_cli
// Work around bug with universal reference/nullptr combination that only appears when /clr is
// on
AE_NO_TSAN weak_atomic(nullptr_t) : value(nullptr) {}
#endif
AE_NO_TSAN weak_atomic(weak_atomic const& other) : value(other.load()) {}
AE_NO_TSAN weak_atomic(weak_atomic&& other) : value(std::move(other.load())) {}
#ifdef AE_VCPP
#pragma warning(pop)
#endif
AE_FORCEINLINE operator T() const AE_NO_TSAN {
return load();
}
#ifndef AE_USE_STD_ATOMIC_FOR_WEAK_ATOMIC
template <typename U>
AE_FORCEINLINE weak_atomic const& operator=(U&& x) AE_NO_TSAN {
value = std::forward<U>(x);
return *this;
}
AE_FORCEINLINE weak_atomic const& operator=(weak_atomic const& other) AE_NO_TSAN {
value = other.value;
return *this;
}
AE_FORCEINLINE T load() const AE_NO_TSAN {
return value;
}
AE_FORCEINLINE T fetch_add_acquire(T increment) AE_NO_TSAN {
#if defined(AE_ARCH_X64) || defined(AE_ARCH_X86)
if (sizeof(T) == 4)
return _InterlockedExchangeAdd((long volatile*)&value, (long)increment);
#if defined(_M_AMD64)
else if (sizeof(T) == 8)
return _InterlockedExchangeAdd64((long long volatile*)&value, (long long)increment);
#endif
#else
#error Unsupported platform
#endif
assert(false && "T must be either a 32 or 64 bit type");
return value;
}
AE_FORCEINLINE T fetch_add_release(T increment) AE_NO_TSAN {
#if defined(AE_ARCH_X64) || defined(AE_ARCH_X86)
if (sizeof(T) == 4)
return _InterlockedExchangeAdd((long volatile*)&value, (long)increment);
#if defined(_M_AMD64)
else if (sizeof(T) == 8)
return _InterlockedExchangeAdd64((long long volatile*)&value, (long long)increment);
#endif
#else
#error Unsupported platform
#endif
assert(false && "T must be either a 32 or 64 bit type");
return value;
}
#else
template <typename U>
AE_FORCEINLINE weak_atomic const& operator=(U&& x) AE_NO_TSAN {
value.store(std::forward<U>(x), std::memory_order_relaxed);
return *this;
}
AE_FORCEINLINE weak_atomic const& operator=(weak_atomic const& other) AE_NO_TSAN {
value.store(other.value.load(std::memory_order_relaxed), std::memory_order_relaxed);
return *this;
}
AE_FORCEINLINE T load() const AE_NO_TSAN {
return value.load(std::memory_order_relaxed);
}
AE_FORCEINLINE T fetch_add_acquire(T increment) AE_NO_TSAN {
return value.fetch_add(increment, std::memory_order_acquire);
}
AE_FORCEINLINE T fetch_add_release(T increment) AE_NO_TSAN {
return value.fetch_add(increment, std::memory_order_release);
}
#endif
private:
#ifndef AE_USE_STD_ATOMIC_FOR_WEAK_ATOMIC
// No std::atomic support, but still need to circumvent compiler optimizations.
// `volatile` will make memory access slow, but is guaranteed to be reliable.
volatile T value;
#else
std::atomic<T> value;
#endif
};
} // namespace Common
// Portable single-producer, single-consumer semaphore below:
#if defined(_WIN32)
// Avoid including windows.h in a header; we only need a handful of
// items, so we'll redeclare them here (this is relatively safe since
// the API generally has to remain stable between Windows versions).
// I know this is an ugly hack but it still beats polluting the global
// namespace with thousands of generic names or adding a .cpp for nothing.
extern "C" {
struct _SECURITY_ATTRIBUTES;
__declspec(dllimport) void* __stdcall CreateSemaphoreW(_SECURITY_ATTRIBUTES* lpSemaphoreAttributes,
long lInitialCount, long lMaximumCount,
const wchar_t* lpName);
__declspec(dllimport) int __stdcall CloseHandle(void* hObject);
__declspec(dllimport) unsigned long __stdcall WaitForSingleObject(void* hHandle,
unsigned long dwMilliseconds);
__declspec(dllimport) int __stdcall ReleaseSemaphore(void* hSemaphore, long lReleaseCount,
long* lpPreviousCount);
}
#elif defined(__MACH__)
#include <mach/mach.h>
#elif defined(__unix__)
#include <semaphore.h>
#elif defined(FREERTOS)
#include <FreeRTOS.h>
#include <semphr.h>
#include <task.h>
#endif
namespace Common {
// Code in the spsc_sema namespace below is an adaptation of Jeff Preshing's
// portable + lightweight semaphore implementations, originally from
// https://github.com/preshing/cpp11-on-multicore/blob/master/common/sema.h
// LICENSE:
// Copyright (c) 2015 Jeff Preshing
//
// This software is provided 'as-is', without any express or implied
// warranty. In no event will the authors be held liable for any damages
// arising from the use of this software.
//
// Permission is granted to anyone to use this software for any purpose,
// including commercial applications, and to alter it and redistribute it
// freely, subject to the following restrictions:
//
// 1. The origin of this software must not be misrepresented; you must not
// claim that you wrote the original software. If you use this software
// in a product, an acknowledgement in the product documentation would be
// appreciated but is not required.
// 2. Altered source versions must be plainly marked as such, and must not be
// misrepresented as being the original software.
// 3. This notice may not be removed or altered from any source distribution.
namespace spsc_sema {
#if defined(_WIN32)
class Semaphore {
private:
void* m_hSema;
Semaphore(const Semaphore& other);
Semaphore& operator=(const Semaphore& other);
public:
AE_NO_TSAN Semaphore(int initialCount = 0) : m_hSema() {
assert(initialCount >= 0);
const long maxLong = 0x7fffffff;
m_hSema = CreateSemaphoreW(nullptr, initialCount, maxLong, nullptr);
assert(m_hSema);
}
AE_NO_TSAN ~Semaphore() {
CloseHandle(m_hSema);
}
bool wait() AE_NO_TSAN {
const unsigned long infinite = 0xffffffff;
return WaitForSingleObject(m_hSema, infinite) == 0;
}
bool try_wait() AE_NO_TSAN {
return WaitForSingleObject(m_hSema, 0) == 0;
}
bool timed_wait(std::uint64_t usecs) AE_NO_TSAN {
return WaitForSingleObject(m_hSema, (unsigned long)(usecs / 1000)) == 0;
}
void signal(int count = 1) AE_NO_TSAN {
while (!ReleaseSemaphore(m_hSema, count, nullptr))
;
}
};
#elif defined(__MACH__)
//---------------------------------------------------------
// Semaphore (Apple iOS and OSX)
// Can't use POSIX semaphores due to
// http://lists.apple.com/archives/darwin-kernel/2009/Apr/msg00010.html
//---------------------------------------------------------
class Semaphore {
private:
semaphore_t m_sema;
Semaphore(const Semaphore& other);
Semaphore& operator=(const Semaphore& other);
public:
AE_NO_TSAN Semaphore(int initialCount = 0) : m_sema() {
assert(initialCount >= 0);
kern_return_t rc =
semaphore_create(mach_task_self(), &m_sema, SYNC_POLICY_FIFO, initialCount);
assert(rc == KERN_SUCCESS);
AE_UNUSED(rc);
}
AE_NO_TSAN ~Semaphore() {
semaphore_destroy(mach_task_self(), m_sema);
}
bool wait() AE_NO_TSAN {
return semaphore_wait(m_sema) == KERN_SUCCESS;
}
bool try_wait() AE_NO_TSAN {
return timed_wait(0);
}
bool timed_wait(std::uint64_t timeout_usecs) AE_NO_TSAN {
mach_timespec_t ts;
ts.tv_sec = static_cast<unsigned int>(timeout_usecs / 1000000);
ts.tv_nsec = static_cast<int>((timeout_usecs % 1000000) * 1000);
// added in OSX 10.10:
// https://developer.apple.com/library/prerelease/mac/documentation/General/Reference/APIDiffsMacOSX10_10SeedDiff/modules/Darwin.html
kern_return_t rc = semaphore_timedwait(m_sema, ts);
return rc == KERN_SUCCESS;
}
void signal() AE_NO_TSAN {
while (semaphore_signal(m_sema) != KERN_SUCCESS)
;
}
void signal(int count) AE_NO_TSAN {
while (count-- > 0) {
while (semaphore_signal(m_sema) != KERN_SUCCESS)
;
}
}
};
#elif defined(__unix__)
//---------------------------------------------------------
// Semaphore (POSIX, Linux)
//---------------------------------------------------------
class Semaphore {
private:
sem_t m_sema;
Semaphore(const Semaphore& other);
Semaphore& operator=(const Semaphore& other);
public:
AE_NO_TSAN Semaphore(int initialCount = 0) : m_sema() {
assert(initialCount >= 0);
int rc = sem_init(&m_sema, 0, static_cast<unsigned int>(initialCount));
assert(rc == 0);
AE_UNUSED(rc);
}
AE_NO_TSAN ~Semaphore() {
sem_destroy(&m_sema);
}
bool wait() AE_NO_TSAN {
// http://stackoverflow.com/questions/2013181/gdb-causes-sem-wait-to-fail-with-eintr-error
int rc;
do {
rc = sem_wait(&m_sema);
} while (rc == -1 && errno == EINTR);
return rc == 0;
}
bool try_wait() AE_NO_TSAN {
int rc;
do {
rc = sem_trywait(&m_sema);
} while (rc == -1 && errno == EINTR);
return rc == 0;
}
bool timed_wait(std::uint64_t usecs) AE_NO_TSAN {
struct timespec ts;
const int usecs_in_1_sec = 1000000;
const int nsecs_in_1_sec = 1000000000;
clock_gettime(CLOCK_REALTIME, &ts);
ts.tv_sec += static_cast<time_t>(usecs / usecs_in_1_sec);
ts.tv_nsec += static_cast<long>(usecs % usecs_in_1_sec) * 1000;
// sem_timedwait bombs if you have more than 1e9 in tv_nsec
// so we have to clean things up before passing it in
if (ts.tv_nsec >= nsecs_in_1_sec) {
ts.tv_nsec -= nsecs_in_1_sec;
++ts.tv_sec;
}
int rc;
do {
rc = sem_timedwait(&m_sema, &ts);
} while (rc == -1 && errno == EINTR);
return rc == 0;
}
void signal() AE_NO_TSAN {
while (sem_post(&m_sema) == -1)
;
}
void signal(int count) AE_NO_TSAN {
while (count-- > 0) {
while (sem_post(&m_sema) == -1)
;
}
}
};
#elif defined(FREERTOS)
//---------------------------------------------------------
// Semaphore (FreeRTOS)
//---------------------------------------------------------
class Semaphore {
private:
SemaphoreHandle_t m_sema;
Semaphore(const Semaphore& other);
Semaphore& operator=(const Semaphore& other);
public:
AE_NO_TSAN Semaphore(int initialCount = 0) : m_sema() {
assert(initialCount >= 0);
m_sema = xSemaphoreCreateCounting(static_cast<UBaseType_t>(~0ull),
static_cast<UBaseType_t>(initialCount));
assert(m_sema);
}
AE_NO_TSAN ~Semaphore() {
vSemaphoreDelete(m_sema);
}
bool wait() AE_NO_TSAN {
return xSemaphoreTake(m_sema, portMAX_DELAY) == pdTRUE;
}
bool try_wait() AE_NO_TSAN {
// Note: In an ISR context, if this causes a task to unblock,
// the caller won't know about it
if (xPortIsInsideInterrupt())
return xSemaphoreTakeFromISR(m_sema, NULL) == pdTRUE;
return xSemaphoreTake(m_sema, 0) == pdTRUE;
}
bool timed_wait(std::uint64_t usecs) AE_NO_TSAN {
std::uint64_t msecs = usecs / 1000;
TickType_t ticks = static_cast<TickType_t>(msecs / portTICK_PERIOD_MS);
if (ticks == 0)
return try_wait();
return xSemaphoreTake(m_sema, ticks) == pdTRUE;
}
void signal() AE_NO_TSAN {
// Note: In an ISR context, if this causes a task to unblock,
// the caller won't know about it
BaseType_t rc;
if (xPortIsInsideInterrupt())
rc = xSemaphoreGiveFromISR(m_sema, NULL);
else
rc = xSemaphoreGive(m_sema);
assert(rc == pdTRUE);
AE_UNUSED(rc);
}
void signal(int count) AE_NO_TSAN {
while (count-- > 0)
signal();
}
};
#else
#error Unsupported platform! (No semaphore wrapper available)
#endif
//---------------------------------------------------------
// LightweightSemaphore
//---------------------------------------------------------
class LightweightSemaphore {
public:
typedef std::make_signed<std::size_t>::type ssize_t;
private:
weak_atomic<ssize_t> m_count;
Semaphore m_sema;
bool waitWithPartialSpinning(std::int64_t timeout_usecs = -1) AE_NO_TSAN {
ssize_t oldCount;
// Is there a better way to set the initial spin count?
// If we lower it to 1000, testBenaphore becomes 15x slower on my Core i7-5930K Windows PC,
// as threads start hitting the kernel semaphore.
int spin = 1024;
while (--spin >= 0) {
if (m_count.load() > 0) {
m_count.fetch_add_acquire(-1);
return true;
}
compiler_fence(memory_order_acquire); // Prevent the compiler from collapsing the loop.
}
oldCount = m_count.fetch_add_acquire(-1);
if (oldCount > 0)
return true;
if (timeout_usecs < 0) {
if (m_sema.wait())
return true;
}
if (timeout_usecs > 0 && m_sema.timed_wait(static_cast<uint64_t>(timeout_usecs)))
return true;
// At this point, we've timed out waiting for the semaphore, but the
// count is still decremented indicating we may still be waiting on
// it. So we have to re-adjust the count, but only if the semaphore
// wasn't signaled enough times for us too since then. If it was, we
// need to release the semaphore too.
while (true) {
oldCount = m_count.fetch_add_release(1);
if (oldCount < 0)
return false; // successfully restored things to the way they were
// Oh, the producer thread just signaled the semaphore after all. Try again:
oldCount = m_count.fetch_add_acquire(-1);
if (oldCount > 0 && m_sema.try_wait())
return true;
}
}
public:
AE_NO_TSAN LightweightSemaphore(ssize_t initialCount = 0) : m_count(initialCount), m_sema() {
assert(initialCount >= 0);
}
bool tryWait() AE_NO_TSAN {
if (m_count.load() > 0) {
m_count.fetch_add_acquire(-1);
return true;
}
return false;
}
bool wait() AE_NO_TSAN {
return tryWait() || waitWithPartialSpinning();
}
bool wait(std::int64_t timeout_usecs) AE_NO_TSAN {
return tryWait() || waitWithPartialSpinning(timeout_usecs);
}
void signal(ssize_t count = 1) AE_NO_TSAN {
assert(count >= 0);
ssize_t oldCount = m_count.fetch_add_release(count);
assert(oldCount >= -1);
if (oldCount < 0) {
m_sema.signal(1);
}
}
std::size_t availableApprox() const AE_NO_TSAN {
ssize_t count = m_count.load();
return count > 0 ? static_cast<std::size_t>(count) : 0;
}
};
} // namespace spsc_sema
} // namespace Common
#if defined(AE_VCPP) && (_MSC_VER < 1700 || defined(__cplusplus_cli))
#pragma warning(pop)
#ifdef __cplusplus_cli
#pragma managed(pop)
#endif
#endif