#pragma once #include #include #include #include #include "base_sink.h" #include "../logger.h" #include "../details/blocking_queue.h" #include "../details/log_msg.h" #include namespace c11log { namespace sinks { static void msg_deleter(details::log_msg* msg_to_delete) { delete []msg_to_delete->msg_buf.first; delete msg_to_delete; } class async_sink : public base_sink { public: using queue_type = c11log::details::blocking_queue>>; explicit async_sink(const queue_type::size_type max_queue_size); //Stop logging and join the back thread // TODO: limit with timeout of the join and kill it afterwards? ~async_sink(); void add_sink(logger::sink_ptr sink); void remove_sink(logger::sink_ptr sink_ptr); queue_type& q(); //Wait to remaining items (if any) in the queue to be written and shutdown void shutdown(const std::chrono::milliseconds& timeout); protected: void _sink_it(const details::log_msg& msg) override; void _thread_loop(); private: c11log::logger::sinks_vector_t _sinks; std::atomic _active; queue_type _q; std::thread _back_thread; //Clear all remaining messages(if any), stop the _back_thread and join it void _shutdown(); std::mutex _shutdown_mutex; }; } } /////////////////////////////////////////////////////////////////////////////// // async_sink class implementation /////////////////////////////////////////////////////////////////////////////// inline c11log::sinks::async_sink::async_sink(const queue_type::size_type max_queue_size) :_sinks(), _active(true), _q(max_queue_size), _back_thread(&async_sink::_thread_loop, this) {} inline c11log::sinks::async_sink::~async_sink() { _shutdown(); } inline void c11log::sinks::async_sink::_sink_it(const details::log_msg& msg) { auto msg_size = msg.msg_buf.second; if(!_active || !msg_size) return; //re allocate on the heap the (stack based) message auto new_msg = new details::log_msg(msg); char *buf = new char[msg_size]; std::memcpy(buf, msg.msg_buf.first, msg_size); new_msg->msg_buf = bufpair_t(buf, msg_size); // Create unique_ptr with custom deleter and push it queue_type::item_type new_shared_msg(new_msg, msg_deleter); _q.push(std::move(new_shared_msg)); } inline void c11log::sinks::async_sink::_thread_loop() { static std::chrono::seconds pop_timeout { 1 }; while (_active) { queue_type::item_type msg; if (_q.pop(msg, pop_timeout)) { for (auto &sink : _sinks) { sink->log(*msg); if(!_active) break; } } } } inline void c11log::sinks::async_sink::add_sink(logger::sink_ptr sink) { _sinks.push_back(sink); } inline void c11log::sinks::async_sink::remove_sink(logger::sink_ptr sink_ptr) { _sinks.erase(std::remove(_sinks.begin(), _sinks.end(), sink_ptr), _sinks.end()); } inline c11log::sinks::async_sink::queue_type& c11log::sinks::async_sink::q() { return _q; } inline void c11log::sinks::async_sink::shutdown(const std::chrono::milliseconds& timeout) { if(timeout > std::chrono::milliseconds::zero()) { auto until = log_clock::now() + timeout; while (_q.size() > 0 && log_clock::now() < until) { std::this_thread::sleep_for(std::chrono::milliseconds(2)); } } _shutdown(); } inline void c11log::sinks::async_sink::_shutdown() { std::lock_guard guard(_shutdown_mutex); if(_active) { _active = false; if (_back_thread.joinable()) _back_thread.join(); } }