Sunshine/sunshine/thread_safe.h

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//
// Created by loki on 6/10/19.
//
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#ifndef SUNSHINE_THREAD_SAFE_H
#define SUNSHINE_THREAD_SAFE_H
#include <vector>
#include <mutex>
#include <condition_variable>
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#include <atomic>
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#include <functional>
#include "utility.h"
namespace safe {
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template<class T>
class event_t {
using status_t = util::optional_t<T>;
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public:
template<class...Args>
void raise(Args &&...args) {
std::lock_guard lg { _lock };
if(!_continue) {
return;
}
if constexpr (std::is_same_v<std::optional<T>, status_t>) {
_status = std::make_optional<T>(std::forward<Args>(args)...);
}
else {
_status = status_t { std::forward<Args>(args)... };
}
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_cv.notify_all();
}
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// pop and view shoud not be used interchangebly
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status_t pop() {
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std::unique_lock ul{ _lock };
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if (!_continue) {
return util::false_v<status_t>;
}
while (!_status) {
_cv.wait(ul);
if (!_continue) {
return util::false_v<status_t>;
}
}
auto val = std::move(_status);
_status = util::false_v<status_t>;
return val;
}
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// pop and view shoud not be used interchangebly
template<class Rep, class Period>
status_t pop(std::chrono::duration<Rep, Period> delay) {
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std::unique_lock ul{ _lock };
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if (!_continue) {
return util::false_v<status_t>;
}
while (!_status) {
if (!_continue || _cv.wait_for(ul, delay) == std::cv_status::timeout) {
return util::false_v<status_t>;
}
}
auto val = std::move(_status);
_status = util::false_v<status_t>;
return val;
}
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// pop and view shoud not be used interchangebly
const status_t &view() {
std::unique_lock ul { _lock };
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if (!_continue) {
return util::false_v<status_t>;
}
while (!_status) {
_cv.wait(ul);
if (!_continue) {
return util::false_v<status_t>;
}
}
return _status;
}
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bool peek() {
std::lock_guard lg { _lock };
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return _continue && (bool)_status;
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}
void stop() {
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std::lock_guard lg{ _lock };
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_continue = false;
_cv.notify_all();
}
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void reset() {
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std::lock_guard lg{ _lock };
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_continue = true;
_status = util::false_v<status_t>;
}
[[nodiscard]] bool running() const {
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return _continue;
}
private:
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bool _continue { true };
status_t _status { util::false_v<status_t> };
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std::condition_variable _cv;
std::mutex _lock;
};
template<class T>
class queue_t {
using status_t = util::optional_t<T>;
public:
queue_t(std::uint32_t max_elements) : _max_elements { max_elements } {}
template<class ...Args>
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void raise(Args &&... args) {
std::lock_guard ul { _lock };
if(!_continue) {
return;
}
if(_queue.size() == _max_elements) {
_queue.clear();
}
_queue.emplace_back(std::forward<Args>(args)...);
_cv.notify_all();
}
bool peek() {
std::lock_guard lg { _lock };
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return _continue && !_queue.empty();
}
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template<class Rep, class Period>
status_t pop(std::chrono::duration<Rep, Period> delay) {
std::unique_lock ul { _lock };
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if (!_continue) {
return util::false_v<status_t>;
}
while (_queue.empty()) {
if (!_continue || _cv.wait_for(ul, delay) == std::cv_status::timeout) {
return util::false_v<status_t>;
}
}
auto val = std::move(_queue.front());
_queue.erase(std::begin(_queue));
return val;
}
status_t pop() {
std::unique_lock ul { _lock };
if (!_continue) {
return util::false_v<status_t>;
}
while (_queue.empty()) {
_cv.wait(ul);
if (!_continue) {
return util::false_v<status_t>;
}
}
auto val = std::move(_queue.front());
_queue.erase(std::begin(_queue));
return val;
}
std::vector<T> &unsafe() {
std::lock_guard { _lock };
return _queue;
}
void stop() {
std::lock_guard lg { _lock };
_continue = false;
_cv.notify_all();
}
[[nodiscard]] bool running() const {
return _continue;
}
private:
bool _continue { true };
std::uint32_t _max_elements;
std::mutex _lock;
std::condition_variable _cv;
std::vector<T> _queue;
};
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template<class T>
class shared_t {
public:
using element_type = T;
using construct_f = std::function<int(element_type &)>;
using destruct_f = std::function<void(element_type &)>;
struct ptr_t {
shared_t *owner;
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ptr_t() : owner { nullptr } {}
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explicit ptr_t(shared_t *owner) : owner { owner } {}
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ptr_t(ptr_t &&ptr) noexcept : owner { ptr.owner } {
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ptr.owner = nullptr;
}
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ptr_t(const ptr_t &ptr) noexcept : owner { ptr.owner } {
if(!owner) {
return;
}
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auto tmp = ptr.owner->ref();
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tmp.owner = nullptr;
}
ptr_t &operator=(const ptr_t &ptr) noexcept {
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if(!ptr.owner) {
release();
return *this;
}
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return *this = std::move(*ptr.owner->ref());
}
ptr_t &operator=(ptr_t &&ptr) noexcept {
if(owner) {
release();
}
std::swap(owner, ptr.owner);
return *this;
}
~ptr_t() {
if(owner) {
release();
}
}
operator bool () const {
return owner != nullptr;
}
void release() {
std::lock_guard lg { owner->_lock };
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if(!--owner->_count) {
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owner->_destruct(*get());
(*this)->~element_type();
}
owner = nullptr;
}
element_type *get() const {
return reinterpret_cast<element_type*>(owner->_object_buf.data());
}
element_type *operator->() {
return reinterpret_cast<element_type*>(owner->_object_buf.data());
}
};
template<class FC, class FD>
shared_t(FC && fc, FD &&fd) : _construct { std::forward<FC>(fc) }, _destruct { std::forward<FD>(fd) } {}
[[nodiscard]] ptr_t ref() {
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std::lock_guard lg { _lock };
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if(!_count++) {
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new(_object_buf.data()) element_type;
if(_construct(*reinterpret_cast<element_type*>(_object_buf.data()))) {
return ptr_t { nullptr };
}
}
return ptr_t { this };
}
private:
construct_f _construct;
destruct_f _destruct;
std::array<std::uint8_t, sizeof(element_type)> _object_buf;
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std::uint32_t _count;
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std::mutex _lock;
};
template<class T, class F_Construct, class F_Destruct>
auto make_shared(F_Construct &&fc, F_Destruct &&fd) {
return shared_t<T> {
std::forward<F_Construct>(fc), std::forward<F_Destruct>(fd)
};
}
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using signal_t = event_t<bool>;
}
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#endif //SUNSHINE_THREAD_SAFE_H