doc/html/boost_asio/example/cpp03/timers/time_t_timer.cpp
// // time_t_timer.cpp // ~~~~~~~~~~~~~~~~ // // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com) // // 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) // #include <boost/asio.hpp> #include <ctime> #include <iostream> // A custom implementation of the Clock concept from the standard C++ library. struct time_t_clock { // The duration type. typedef boost::asio::chrono::steady_clock::duration duration; // The duration's underlying arithmetic representation. typedef duration::rep rep; // The ratio representing the duration's tick period. typedef duration::period period; // An absolute time point represented using the clock. typedef boost::asio::chrono::time_point<time_t_clock> time_point; // The clock is not monotonically increasing. static const bool is_steady = false; // Get the current time. static time_point now() { return time_point() + boost::asio::chrono::seconds(std::time(0)); } }; // The boost::asio::basic_waitable_timer template accepts an optional WaitTraits // template parameter. The underlying time_t clock has one-second granularity, // so these traits may be customised to reduce the latency between the clock // ticking over and a wait operation's completion. When the timeout is near // (less than one second away) we poll the clock more frequently to detect the // time change closer to when it occurs. The user can select the appropriate // trade off between accuracy and the increased CPU cost of polling. In extreme // cases, a zero duration may be returned to make the timers as accurate as // possible, albeit with 100% CPU usage. struct time_t_wait_traits { // Determine how long until the clock should be next polled to determine // whether the duration has elapsed. static time_t_clock::duration to_wait_duration( const time_t_clock::duration& d) { if (d > boost::asio::chrono::seconds(1)) return d - boost::asio::chrono::seconds(1); else if (d > boost::asio::chrono::seconds(0)) return boost::asio::chrono::milliseconds(10); else return boost::asio::chrono::seconds(0); } // Determine how long until the clock should be next polled to determine // whether the absoluate time has been reached. static time_t_clock::duration to_wait_duration( const time_t_clock::time_point& t) { return to_wait_duration(t - time_t_clock::now()); } }; typedef boost::asio::basic_waitable_timer< time_t_clock, time_t_wait_traits> time_t_timer; void handle_timeout(const boost::system::error_code&) { std::cout << "handle_timeout\n"; } int main() { try { boost::asio::io_context io_context; time_t_timer timer(io_context); timer.expires_after(boost::asio::chrono::seconds(5)); std::cout << "Starting synchronous wait\n"; timer.wait(); std::cout << "Finished synchronous wait\n"; timer.expires_after(boost::asio::chrono::seconds(5)); std::cout << "Starting asynchronous wait\n"; timer.async_wait(&handle_timeout); io_context.run(); std::cout << "Finished asynchronous wait\n"; } catch (std::exception& e) { std::cout << "Exception: " << e.what() << "\n"; } return 0; }