STL/stl/inc/shared_mutex

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C++

// shared_mutex standard header
// Copyright (c) Microsoft Corporation.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
#pragma once
#ifndef _SHARED_MUTEX_
#define _SHARED_MUTEX_
#include <yvals_core.h>
#if _STL_COMPILER_PREPROCESSOR
#ifdef _M_CEE_PURE
#error <shared_mutex> is not supported when compiling with /clr:pure.
#endif // _M_CEE_PURE
#include <mutex>
#include <xthreads.h>
#ifndef _M_CEE
#include <condition_variable>
#endif // _M_CEE
#pragma pack(push, _CRT_PACKING)
#pragma warning(push, _STL_WARNING_LEVEL)
#pragma warning(disable : _STL_DISABLED_WARNINGS)
_STL_DISABLE_CLANG_WARNINGS
#pragma push_macro("new")
#undef new
_STD_BEGIN
// CLASS shared_mutex
class shared_mutex { // class for mutual exclusion shared across threads
public:
using native_handle_type = _Smtx_t*;
shared_mutex() noexcept // strengthened
: _Myhandle(nullptr) {}
~shared_mutex() noexcept {}
void lock() noexcept /* strengthened */ { // lock exclusive
_Smtx_lock_exclusive(&_Myhandle);
}
_NODISCARD bool try_lock() noexcept /* strengthened */ { // try to lock exclusive
return _Smtx_try_lock_exclusive(&_Myhandle) != 0;
}
void unlock() noexcept /* strengthened */ { // unlock exclusive
_Smtx_unlock_exclusive(&_Myhandle);
}
void lock_shared() noexcept /* strengthened */ { // lock non-exclusive
_Smtx_lock_shared(&_Myhandle);
}
_NODISCARD bool try_lock_shared() noexcept /* strengthened */ { // try to lock non-exclusive
return _Smtx_try_lock_shared(&_Myhandle) != 0;
}
void unlock_shared() noexcept /* strengthened */ { // unlock non-exclusive
_Smtx_unlock_shared(&_Myhandle);
}
_NODISCARD native_handle_type native_handle() noexcept /* strengthened */ { // get native handle
return &_Myhandle;
}
shared_mutex(const shared_mutex&) = delete;
shared_mutex& operator=(const shared_mutex&) = delete;
private:
_Smtx_t _Myhandle;
};
// shared_timed_mutex is not supported under /clr
#ifndef _M_CEE
// CLASS shared_timed_mutex
class shared_timed_mutex { // class for mutual exclusion shared across threads
using _Read_cnt_t = unsigned int;
static constexpr _Read_cnt_t _Max_readers = static_cast<_Read_cnt_t>(-1);
public:
shared_timed_mutex() noexcept // strengthened
: _Mymtx(), _Read_queue(), _Write_queue(), _Readers(0), _Writing(false) {}
~shared_timed_mutex() noexcept {}
void lock() { // lock exclusive
unique_lock<mutex> _Lock(_Mymtx);
while (_Writing) {
_Write_queue.wait(_Lock);
}
_Writing = true;
while (0 < _Readers) {
_Read_queue.wait(_Lock); // wait for writing, no readers
}
}
_NODISCARD bool try_lock() { // try to lock exclusive
lock_guard<mutex> _Lock(_Mymtx);
if (_Writing || 0 < _Readers) {
return false;
} else { // set writing, no readers
_Writing = true;
return true;
}
}
template <class _Rep, class _Period>
_NODISCARD bool try_lock_for(const chrono::duration<_Rep, _Period>& _Rel_time) { // try to lock for duration
return try_lock_until(chrono::steady_clock::now() + _Rel_time);
}
template <class _Clock, class _Duration>
_NODISCARD bool try_lock_until(
const chrono::time_point<_Clock, _Duration>& _Abs_time) { // try to lock until time point
auto _Not_writing = [this] { return !_Writing; };
auto _Zero_readers = [this] { return _Readers == 0; };
unique_lock<mutex> _Lock(_Mymtx);
if (!_Write_queue.wait_until(_Lock, _Abs_time, _Not_writing)) {
return false;
}
_Writing = true;
if (!_Read_queue.wait_until(_Lock, _Abs_time, _Zero_readers)) { // timeout, leave writing state
_Writing = false;
_Lock.unlock(); // unlock before notifying, for efficiency
_Write_queue.notify_all();
return false;
}
return true;
}
void unlock() { // unlock exclusive
{ // unlock before notifying, for efficiency
lock_guard<mutex> _Lock(_Mymtx);
_Writing = false;
}
_Write_queue.notify_all();
}
void lock_shared() { // lock non-exclusive
unique_lock<mutex> _Lock(_Mymtx);
while (_Writing || _Readers == _Max_readers) {
_Write_queue.wait(_Lock);
}
++_Readers;
}
_NODISCARD bool try_lock_shared() { // try to lock non-exclusive
lock_guard<mutex> _Lock(_Mymtx);
if (_Writing || _Readers == _Max_readers) {
return false;
} else { // count another reader
++_Readers;
return true;
}
}
template <class _Rep, class _Period>
_NODISCARD bool try_lock_shared_for(
const chrono::duration<_Rep, _Period>& _Rel_time) { // try to lock non-exclusive for relative time
return try_lock_shared_until(_Rel_time + chrono::steady_clock::now());
}
template <class _Time>
bool _Try_lock_shared_until(_Time _Abs_time) { // try to lock non-exclusive until absolute time
const auto _Can_acquire = [this] { return !_Writing && _Readers < _Max_readers; };
unique_lock<mutex> _Lock(_Mymtx);
if (!_Write_queue.wait_until(_Lock, _Abs_time, _Can_acquire)) {
return false;
}
++_Readers;
return true;
}
template <class _Clock, class _Duration>
_NODISCARD bool try_lock_shared_until(
const chrono::time_point<_Clock, _Duration>& _Abs_time) { // try to lock non-exclusive until absolute time
return _Try_lock_shared_until(_Abs_time);
}
_NODISCARD bool try_lock_shared_until(const xtime* _Abs_time) { // try to lock non-exclusive until absolute time
return _Try_lock_shared_until(_Abs_time);
}
void unlock_shared() { // unlock non-exclusive
_Read_cnt_t _Local_readers;
bool _Local_writing;
{ // unlock before notifying, for efficiency
lock_guard<mutex> _Lock(_Mymtx);
--_Readers;
_Local_readers = _Readers;
_Local_writing = _Writing;
}
if (_Local_writing && _Local_readers == 0) {
_Read_queue.notify_one();
} else if (!_Local_writing && _Local_readers == _Max_readers - 1) {
_Write_queue.notify_all();
}
}
shared_timed_mutex(const shared_timed_mutex&) = delete;
shared_timed_mutex& operator=(const shared_timed_mutex&) = delete;
private:
mutex _Mymtx;
condition_variable _Read_queue;
condition_variable _Write_queue;
_Read_cnt_t _Readers;
bool _Writing;
};
#endif // _M_CEE
// CLASS TEMPLATE shared_lock
template <class _Mutex>
class shared_lock { // shareable lock
public:
using mutex_type = _Mutex;
shared_lock() noexcept : _Pmtx(nullptr), _Owns(false) {}
explicit shared_lock(mutex_type& _Mtx)
: _Pmtx(_STD addressof(_Mtx)), _Owns(true) { // construct with mutex and lock shared
_Mtx.lock_shared();
}
shared_lock(mutex_type& _Mtx, defer_lock_t) noexcept
: _Pmtx(_STD addressof(_Mtx)), _Owns(false) { // construct with unlocked mutex
}
shared_lock(mutex_type& _Mtx, try_to_lock_t)
: _Pmtx(_STD addressof(_Mtx)), _Owns(_Mtx.try_lock_shared()) { // construct with mutex and try to lock shared
}
shared_lock(mutex_type& _Mtx, adopt_lock_t)
: _Pmtx(_STD addressof(_Mtx)), _Owns(true) { // construct with mutex and adopt ownership
}
template <class _Rep, class _Period>
shared_lock(mutex_type& _Mtx, const chrono::duration<_Rep, _Period>& _Rel_time)
: _Pmtx(_STD addressof(_Mtx)),
_Owns(_Mtx.try_lock_shared_for(_Rel_time)) { // construct with mutex and try to lock for relative time
}
template <class _Clock, class _Duration>
shared_lock(mutex_type& _Mtx, const chrono::time_point<_Clock, _Duration>& _Abs_time)
: _Pmtx(_STD addressof(_Mtx)),
_Owns(_Mtx.try_lock_shared_until(_Abs_time)) { // construct with mutex and try to lock until absolute time
}
~shared_lock() noexcept {
if (_Owns) {
_Pmtx->unlock_shared();
}
}
shared_lock(shared_lock&& _Other) noexcept : _Pmtx(_Other._Pmtx), _Owns(_Other._Owns) {
_Other._Pmtx = nullptr;
_Other._Owns = false;
}
shared_lock& operator=(shared_lock&& _Right) noexcept {
if (_Owns) {
_Pmtx->unlock_shared();
}
_Pmtx = _Right._Pmtx;
_Owns = _Right._Owns;
_Right._Pmtx = nullptr;
_Right._Owns = false;
return *this;
}
shared_lock(const shared_lock&) = delete;
shared_lock& operator=(const shared_lock&) = delete;
void lock() { // lock the mutex
_Validate();
_Pmtx->lock_shared();
_Owns = true;
}
_NODISCARD bool try_lock() { // try to lock the mutex
_Validate();
_Owns = _Pmtx->try_lock_shared();
return _Owns;
}
template <class _Rep, class _Period>
_NODISCARD bool try_lock_for(
const chrono::duration<_Rep, _Period>& _Rel_time) { // try to lock the mutex for _Rel_time
_Validate();
_Owns = _Pmtx->try_lock_shared_for(_Rel_time);
return _Owns;
}
template <class _Clock, class _Duration>
_NODISCARD bool try_lock_until(
const chrono::time_point<_Clock, _Duration>& _Abs_time) { // try to lock the mutex until _Abs_time
_Validate();
_Owns = _Pmtx->try_lock_shared_until(_Abs_time);
return _Owns;
}
void unlock() { // try to unlock the mutex
if (!_Pmtx || !_Owns) {
_Throw_system_error(errc::operation_not_permitted);
}
_Pmtx->unlock_shared();
_Owns = false;
}
// MUTATE
void swap(shared_lock& _Right) noexcept {
_STD swap(_Pmtx, _Right._Pmtx);
_STD swap(_Owns, _Right._Owns);
}
mutex_type* release() noexcept {
_Mutex* _Res = _Pmtx;
_Pmtx = nullptr;
_Owns = false;
return _Res;
}
// OBSERVE
_NODISCARD bool owns_lock() const noexcept {
return _Owns;
}
explicit operator bool() const noexcept {
return _Owns;
}
_NODISCARD mutex_type* mutex() const noexcept {
return _Pmtx;
}
private:
_Mutex* _Pmtx;
bool _Owns;
void _Validate() const { // check if the mutex can be locked
if (!_Pmtx) {
_Throw_system_error(errc::operation_not_permitted);
}
if (_Owns) {
_Throw_system_error(errc::resource_deadlock_would_occur);
}
}
};
// SWAP
template <class _Mutex>
void swap(shared_lock<_Mutex>& _Left, shared_lock<_Mutex>& _Right) noexcept {
_Left.swap(_Right);
}
_STD_END
#pragma pop_macro("new")
_STL_RESTORE_CLANG_WARNINGS
#pragma warning(pop)
#pragma pack(pop)
#endif // _STL_COMPILER_PREPROCESSOR
#endif // _SHARED_MUTEX_