stm32f103-template/rt-thread/components/libc/cplusplus/cpp11/gcc/condition_variable

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#pragma once
#if __cplusplus < 201103L
#error "C++ version lower than C++11"
#endif
#include <pthread.h>
#include <system_error>
#include <chrono>
#include <utility>
#include <functional>
#include <memory>
#include "__utils.h"
#include "mutex"
#define rt_cpp_cond_var pthread_cond_t
namespace std
{
enum class cv_status
{
no_timeout,
timeout
};
class condition_variable
{
public:
typedef rt_cpp_cond_var *native_handle_type;
condition_variable(const condition_variable &) = delete;
condition_variable &operator=(const condition_variable &) = delete;
condition_variable() = default;
~condition_variable()
{
pthread_cond_destroy(&_m_cond);
}
void wait(unique_lock<mutex> &lock);
void notify_one() noexcept
{
pthread_cond_signal(&_m_cond);
}
void notify_all() noexcept
{
pthread_cond_broadcast(&_m_cond);
}
template <class Predicate>
void wait(unique_lock<mutex> &lock, Predicate pred)
{
while (!pred())
wait(lock);
}
template <class Clock, class Duration>
cv_status wait_until(unique_lock<mutex> &lock,
const chrono::time_point<Clock, Duration> &abs_time)
{
if (!lock.owns_lock())
throw_system_error((int)errc::operation_not_permitted,
"condition_variable::wailt_until: waiting on unlocked lock");
auto secs = chrono::time_point_cast<chrono::seconds>(abs_time);
auto nano_secs = chrono::duration_cast<chrono::nanoseconds>(abs_time - secs);
struct timespec c_abs_time = {static_cast<time_t>(secs.time_since_epoch().count()),
static_cast<long>(nano_secs.count())};
pthread_cond_timedwait(&_m_cond, lock.mutex()->native_handle(), &c_abs_time);
return (Clock::now() < abs_time) ? cv_status::no_timeout : cv_status::timeout;
}
template <class Clock, class Duration, class Predicate>
bool wait_until(unique_lock<mutex> &lock,
const chrono::time_point<Clock, Duration> &abs_time,
Predicate pred)
{
while (!pred())
if (wait_until(lock, abs_time) == cv_status::timeout)
return pred();
return true;
}
template <class Rep, class Period>
cv_status wait_for(unique_lock<mutex> &lock,
const chrono::duration<Rep, Period> &rel_time)
{
return wait_until(lock, real_time_clock::now() + rel_time);
}
template <class Rep, class Period, class Predicate>
bool wait_for(unique_lock<mutex> &lock,
const chrono::duration<Rep, Period> &rel_time,
Predicate pred)
{
return wait_until(lock, real_time_clock::now() + rel_time, std::move(pred));
}
native_handle_type native_handle()
{
return &_m_cond;
}
private:
rt_cpp_cond_var _m_cond = PTHREAD_COND_INITIALIZER;
};
// Lockable is only required to have `lock()` and `unlock()`
class condition_variable_any
{
private:
condition_variable _m_cond;
shared_ptr<mutex> _m_mtx;
// so that Lockable automatically unlocks when waiting and locks after waiting
template <class Lockable>
struct unlocker
{
Lockable &_m_lock;
explicit unlocker(Lockable &lk)
: _m_lock(lk)
{
_m_lock.unlock();
}
~unlocker()
{
_m_lock.lock();
}
unlocker(const unlocker &) = delete;
unlocker &operator=(const unlocker &) = delete;
};
public:
condition_variable_any() : _m_mtx(std::make_shared<mutex>()) {}
~condition_variable_any() = default;
condition_variable_any(const condition_variable_any &) = delete;
condition_variable_any &operator=(const condition_variable_any &) = delete;
void notify_one() noexcept
{
lock_guard<mutex> lk(*_m_mtx);
_m_cond.notify_one();
}
void notify_all() noexcept
{
lock_guard<mutex> lk(*_m_mtx);
_m_cond.notify_all();
}
template <class Lock>
void wait(Lock &lock)
{
shared_ptr<mutex> mut = _m_mtx;
unique_lock<mutex> lk(*mut);
unlocker<Lock> auto_lk(lock); // unlock here
unique_lock<mutex> lk2(std::move(lk));
_m_cond.wait(lk2);
} // mut.unlock(); lock.lock();
template <class Lock, class Predicate>
void wait(Lock &lock, Predicate pred)
{
while (!pred())
wait(lock);
}
template <class Lock, class Clock, class Duration>
cv_status wait_until(Lock &lock,
const chrono::time_point<Clock, Duration> &abs_time)
{
shared_ptr<mutex> mut = _m_mtx;
unique_lock<mutex> lk(*mut);
unlocker<Lock> auto_lk(lock); // unlock here
unique_lock<mutex> lk2(std::move(lk));
return _m_cond.wait_until(lk2, abs_time);
}
template <class Lock, class Clock, class Duration, class Predicate>
bool wait_until(Lock &lock,
const chrono::time_point<Clock, Duration> &abs_time,
Predicate pred)
{
while (!pred())
if (wait_until(lock, abs_time) == cv_status::timeout)
return pred();
return true;
}
template <class Lock, class Rep, class Period>
cv_status wait_for(Lock &lock,
const chrono::duration<Rep, Period> &rel_time)
{
return wait_until(lock, real_time_clock::now() + rel_time);
}
template <class Lock, class Rep, class Period, class Predicate>
bool wait_for(Lock &lock,
const chrono::duration<Rep, Period> &rel_time,
Predicate pred)
{
return wait_until(lock, real_time_clock::now() + rel_time, std::move(pred));
}
};
void notify_all_at_thread_exit(condition_variable &cond, unique_lock<mutex> lk);
} // namespace std