axmol/thirdparty/yasio/cxx17/shared_mutex.hpp

251 lines
6.3 KiB
C++

//////////////////////////////////////////////////////////////////////////////////////////
// A multi-platform support c++11 library with focus on asynchronous socket I/O for any
// client application.
//////////////////////////////////////////////////////////////////////////////////////////
//
// Copyright (c) 2021 halx99 (halx99 at live dot com)
// Copyright Vicente J. Botet Escriba 2012.
// Copyright Howard Hinnant 2007-2010.
//
// Distributed under the Boost Software License, Version 1.0. (See accompanying
// file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
//
// see also: https://github.com/boostorg/thread/blob/develop/include/boost/thread/v2/shared_mutex.hpp
//
#ifndef YASIO__SHARED_MUTEX_HPP
#define YASIO__SHARED_MUTEX_HPP
#include "yasio/compiler/feature_test.hpp"
#include <limits.h>
/// The shared_mutex workaround on c++11
#if YASIO__HAS_CXX17 && !defined(__APPLE__)
# include <shared_mutex>
#else
# include <mutex>
# include <condition_variable>
namespace cxx17
{
// CLASS TEMPLATE shared_mutex
class shared_mutex {
typedef std::mutex mutex_t;
typedef std::condition_variable cond_t;
typedef unsigned count_t;
mutex_t mut_;
cond_t gate1_;
// the gate2_ condition variable is only used by functions that
// have taken write_entered_ but are waiting for no_readers()
cond_t gate2_;
count_t state_;
static const count_t write_entered_ = 1U << (sizeof(count_t) * CHAR_BIT - 1);
static const count_t n_readers_ = ~write_entered_;
bool no_writer() const { return (state_ & write_entered_) == 0; }
bool one_writer() const { return (state_ & write_entered_) != 0; }
bool no_writer_no_readers() const
{
// return (state_ & write_entered_) == 0 &&
// (state_ & n_readers_) == 0;
return state_ == 0;
}
bool no_writer_no_max_readers() const { return (state_ & write_entered_) == 0 && (state_ & n_readers_) != n_readers_; }
bool no_readers() const { return (state_ & n_readers_) == 0; }
bool one_or_more_readers() const { return (state_ & n_readers_) > 0; }
shared_mutex(shared_mutex const&) = delete;
shared_mutex& operator=(shared_mutex const&) = delete;
public:
shared_mutex() : state_(0) {}
~shared_mutex() { std::lock_guard<mutex_t> _(mut_); }
// Exclusive ownership
void lock()
{
std::unique_lock<mutex_t> lk(mut_);
gate1_.wait(lk, std::bind(&shared_mutex::no_writer, std::ref(*this)));
state_ |= write_entered_;
gate2_.wait(lk, std::bind(&shared_mutex::no_readers, std::ref(*this)));
}
bool try_lock()
{
std::unique_lock<mutex_t> lk(mut_);
if (!no_writer_no_readers())
{
return false;
}
state_ = write_entered_;
return true;
}
void unlock()
{
std::lock_guard<mutex_t> _(mut_);
assert(one_writer());
assert(no_readers());
state_ = 0;
// notify all since multiple *lock_shared*() calls may be able
// to proceed in response to this notification
gate1_.notify_all();
}
// Shared ownership
void lock_shared()
{
std::unique_lock<mutex_t> lk(mut_);
gate1_.wait(lk, std::bind(&shared_mutex::no_writer_no_max_readers, std::ref(*this)));
count_t num_readers = (state_ & n_readers_) + 1;
state_ &= ~n_readers_;
state_ |= num_readers;
}
bool try_lock_shared()
{
std::unique_lock<mutex_t> lk(mut_);
if (!no_writer_no_max_readers())
{
return false;
}
count_t num_readers = (state_ & n_readers_) + 1;
state_ &= ~n_readers_;
state_ |= num_readers;
return true;
}
void unlock_shared()
{
std::lock_guard<mutex_t> _(mut_);
assert(one_or_more_readers());
count_t num_readers = (state_ & n_readers_) - 1;
state_ &= ~n_readers_;
state_ |= num_readers;
if (no_writer())
{
if (num_readers == n_readers_ - 1)
gate1_.notify_one();
}
else
{
if (num_readers == 0)
gate2_.notify_one();
}
}
};
// CLASS TEMPLATE shared_lock
template <class _Mutex>
class shared_lock {
public:
using mutex_type = _Mutex;
shared_lock() : _Pmtx(nullptr), _Owns(false) {}
explicit shared_lock(mutex_type& _Mtx) : _Pmtx(YASIO__STD addressof(_Mtx)), _Owns(true)
{ // construct with mutex and lock shared
_Mtx.lock_shared();
}
explicit shared_lock(mutex_type& _Mtx, YASIO__STD defer_lock_t) : _Pmtx(YASIO__STD addressof(_Mtx)), _Owns(false) {} // // construct with unlocked mutex
explicit shared_lock(mutex_type& _Mtx, YASIO__STD try_to_lock_t)
: _Pmtx(YASIO__STD addressof(_Mtx)), _Owns(_Mtx.try_lock_shared()) {} // construct with mutex and try to lock shared
explicit shared_lock(mutex_type& _Mtx, YASIO__STD adopt_lock_t) : _Pmtx(YASIO__STD addressof(_Mtx)), _Owns(true) {} // construct with mutex and adopt owership
~shared_lock()
{
if (_Owns)
_Pmtx->unlock_shared();
}
shared_lock(shared_lock&& _Other) : _Pmtx(_Other._Pmtx), _Owns(_Other._Owns)
{
_Other._Pmtx = nullptr;
_Other._Owns = false;
}
shared_lock& operator=(shared_lock&& _Right)
{
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;
}
bool try_lock()
{ // try to lock the mutex
_Validate();
_Owns = _Pmtx->try_lock_shared();
return _Owns;
}
void unlock()
{ // try to unlock the mutex
if (!_Pmtx || !_Owns)
yasio__throw_error0(std::errc::operation_not_permitted);
_Pmtx->unlock_shared();
_Owns = false;
}
// MUTATE
void swap(shared_lock& _Right)
{
YASIO__STD swap(_Pmtx, _Right._Pmtx);
YASIO__STD swap(_Owns, _Right._Owns);
}
mutex_type* release()
{
_Mutex* _Res = _Pmtx;
_Pmtx = nullptr;
_Owns = false;
return _Res;
}
// OBSERVE
bool owns_lock() const { return _Owns; }
explicit operator bool() const { return _Owns; }
mutex_type* mutex() const { return _Pmtx; }
private:
_Mutex* _Pmtx;
bool _Owns;
void _Validate() const
{ // check if the mutex can be locked
if (!_Pmtx)
yasio__throw_error0(std::errc::operation_not_permitted);
if (_Owns)
yasio__throw_error0(std::errc::resource_deadlock_would_occur);
}
};
} // namespace cxx17
#endif
#endif