#ifndef slic3r_Channel_hpp_ #define slic3r_Channel_hpp_ #include #include #include #include #include #include namespace Slic3r { template class Channel { public: using UniqueLock = std::unique_lock; template class Unlocker { public: Unlocker(UniqueLock lock) : m_lock(std::move(lock)) {} Unlocker(const Unlocker &other) noexcept : m_lock(std::move(other.m_lock)) {} // XXX: done beacuse of MSVC 2013 not supporting init of deleter by move Unlocker(Unlocker &&other) noexcept : m_lock(std::move(other.m_lock)) {} Unlocker& operator=(const Unlocker &other) = delete; Unlocker& operator=(Unlocker &&other) { m_lock = std::move(other.m_lock); } void operator()(Ptr*) { m_lock.unlock(); } private: mutable UniqueLock m_lock; // XXX: mutable: see above }; using Queue = std::deque; using LockedConstPtr = std::unique_ptr>; using LockedPtr = std::unique_ptr>; Channel() {} ~Channel() {} void push(const T& item, bool silent = false) { { UniqueLock lock(m_mutex); m_queue.push_back(item); } if (! silent) { m_condition.notify_one(); } } void push(T &&item, bool silent = false) { { UniqueLock lock(m_mutex); m_queue.push_back(std::forward(item)); } if (! silent) { m_condition.notify_one(); } } T pop() { UniqueLock lock(m_mutex); m_condition.wait(lock, [this]() { return !m_queue.empty(); }); auto item = std::move(m_queue.front()); m_queue.pop_front(); return item; } boost::optional try_pop() { UniqueLock lock(m_mutex); if (m_queue.empty()) { return boost::none; } else { auto item = std::move(m_queue.front()); m_queue.pop(); return item; } } // Unlocked observers/hints // Thread unsafe! Keep in mind you need to re-verify the result after locking! size_t size_hint() const noexcept { return m_queue.size(); } LockedConstPtr lock_read() const { return LockedConstPtr(&m_queue, Unlocker(UniqueLock(m_mutex))); } LockedPtr lock_rw() { return LockedPtr(&m_queue, Unlocker(UniqueLock(m_mutex))); } private: Queue m_queue; mutable std::mutex m_mutex; std::condition_variable m_condition; }; } // namespace Slic3r #endif // slic3r_Channel_hpp_