// // detail/deadline_timer_service.hpp // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ // // 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) // #ifndef ASIO_DETAIL_DEADLINE_TIMER_SERVICE_HPP #define ASIO_DETAIL_DEADLINE_TIMER_SERVICE_HPP #if defined(_MSC_VER) && (_MSC_VER >= 1200) # pragma once #endif // defined(_MSC_VER) && (_MSC_VER >= 1200) #include "asio/detail/config.hpp" #include #include "asio/error.hpp" #include "asio/execution_context.hpp" #include "asio/detail/bind_handler.hpp" #include "asio/detail/fenced_block.hpp" #include "asio/detail/memory.hpp" #include "asio/detail/noncopyable.hpp" #include "asio/detail/socket_ops.hpp" #include "asio/detail/socket_types.hpp" #include "asio/detail/timer_queue.hpp" #include "asio/detail/timer_queue_ptime.hpp" #include "asio/detail/timer_scheduler.hpp" #include "asio/detail/wait_handler.hpp" #include "asio/detail/wait_op.hpp" #if defined(ASIO_WINDOWS_RUNTIME) # include # include #endif // defined(ASIO_WINDOWS_RUNTIME) #include "asio/detail/push_options.hpp" namespace asio { namespace detail { template class deadline_timer_service : public execution_context_service_base > { public: // The time type. typedef typename Time_Traits::time_type time_type; // The duration type. typedef typename Time_Traits::duration_type duration_type; // The implementation type of the timer. This type is dependent on the // underlying implementation of the timer service. struct implementation_type : private asio::detail::noncopyable { time_type expiry; bool might_have_pending_waits; typename timer_queue::per_timer_data timer_data; }; // Constructor. deadline_timer_service(execution_context& context) : execution_context_service_base< deadline_timer_service >(context), scheduler_(asio::use_service(context)) { scheduler_.init_task(); scheduler_.add_timer_queue(timer_queue_); } // Destructor. ~deadline_timer_service() { scheduler_.remove_timer_queue(timer_queue_); } // Destroy all user-defined handler objects owned by the service. void shutdown() { } // Construct a new timer implementation. void construct(implementation_type& impl) { impl.expiry = time_type(); impl.might_have_pending_waits = false; } // Destroy a timer implementation. void destroy(implementation_type& impl) { asio::error_code ec; cancel(impl, ec); } // Move-construct a new timer implementation. void move_construct(implementation_type& impl, implementation_type& other_impl) { scheduler_.move_timer(timer_queue_, impl.timer_data, other_impl.timer_data); impl.expiry = other_impl.expiry; other_impl.expiry = time_type(); impl.might_have_pending_waits = other_impl.might_have_pending_waits; other_impl.might_have_pending_waits = false; } // Move-assign from another timer implementation. void move_assign(implementation_type& impl, deadline_timer_service& other_service, implementation_type& other_impl) { if (this != &other_service) if (impl.might_have_pending_waits) scheduler_.cancel_timer(timer_queue_, impl.timer_data); other_service.scheduler_.move_timer(other_service.timer_queue_, impl.timer_data, other_impl.timer_data); impl.expiry = other_impl.expiry; other_impl.expiry = time_type(); impl.might_have_pending_waits = other_impl.might_have_pending_waits; other_impl.might_have_pending_waits = false; } // Move-construct a new timer implementation. void converting_move_construct(implementation_type& impl, deadline_timer_service&, implementation_type& other_impl) { move_construct(impl, other_impl); } // Move-assign from another timer implementation. void converting_move_assign(implementation_type& impl, deadline_timer_service& other_service, implementation_type& other_impl) { move_assign(impl, other_service, other_impl); } // Cancel any asynchronous wait operations associated with the timer. std::size_t cancel(implementation_type& impl, asio::error_code& ec) { if (!impl.might_have_pending_waits) { ec = asio::error_code(); return 0; } ASIO_HANDLER_OPERATION((scheduler_.context(), "deadline_timer", &impl, 0, "cancel")); std::size_t count = scheduler_.cancel_timer(timer_queue_, impl.timer_data); impl.might_have_pending_waits = false; ec = asio::error_code(); return count; } // Cancels one asynchronous wait operation associated with the timer. std::size_t cancel_one(implementation_type& impl, asio::error_code& ec) { if (!impl.might_have_pending_waits) { ec = asio::error_code(); return 0; } ASIO_HANDLER_OPERATION((scheduler_.context(), "deadline_timer", &impl, 0, "cancel_one")); std::size_t count = scheduler_.cancel_timer( timer_queue_, impl.timer_data, 1); if (count == 0) impl.might_have_pending_waits = false; ec = asio::error_code(); return count; } // Get the expiry time for the timer as an absolute time. time_type expiry(const implementation_type& impl) const { return impl.expiry; } // Get the expiry time for the timer as an absolute time. time_type expires_at(const implementation_type& impl) const { return impl.expiry; } // Get the expiry time for the timer relative to now. duration_type expires_from_now(const implementation_type& impl) const { return Time_Traits::subtract(this->expiry(impl), Time_Traits::now()); } // Set the expiry time for the timer as an absolute time. std::size_t expires_at(implementation_type& impl, const time_type& expiry_time, asio::error_code& ec) { std::size_t count = cancel(impl, ec); impl.expiry = expiry_time; ec = asio::error_code(); return count; } // Set the expiry time for the timer relative to now. std::size_t expires_after(implementation_type& impl, const duration_type& expiry_time, asio::error_code& ec) { return expires_at(impl, Time_Traits::add(Time_Traits::now(), expiry_time), ec); } // Set the expiry time for the timer relative to now. std::size_t expires_from_now(implementation_type& impl, const duration_type& expiry_time, asio::error_code& ec) { return expires_at(impl, Time_Traits::add(Time_Traits::now(), expiry_time), ec); } // Perform a blocking wait on the timer. void wait(implementation_type& impl, asio::error_code& ec) { time_type now = Time_Traits::now(); ec = asio::error_code(); while (Time_Traits::less_than(now, impl.expiry) && !ec) { this->do_wait(Time_Traits::to_posix_duration( Time_Traits::subtract(impl.expiry, now)), ec); now = Time_Traits::now(); } } // Start an asynchronous wait on the timer. template void async_wait(implementation_type& impl, Handler& handler, const IoExecutor& io_ex) { // Allocate and construct an operation to wrap the handler. typedef wait_handler op; typename op::ptr p = { asio::detail::addressof(handler), op::ptr::allocate(handler), 0 }; p.p = new (p.v) op(handler, io_ex); impl.might_have_pending_waits = true; ASIO_HANDLER_CREATION((scheduler_.context(), *p.p, "deadline_timer", &impl, 0, "async_wait")); scheduler_.schedule_timer(timer_queue_, impl.expiry, impl.timer_data, p.p); p.v = p.p = 0; } private: // Helper function to wait given a duration type. The duration type should // either be of type boost::posix_time::time_duration, or implement the // required subset of its interface. template void do_wait(const Duration& timeout, asio::error_code& ec) { #if defined(ASIO_WINDOWS_RUNTIME) std::this_thread::sleep_for( std::chrono::seconds(timeout.total_seconds()) + std::chrono::microseconds(timeout.total_microseconds())); ec = asio::error_code(); #else // defined(ASIO_WINDOWS_RUNTIME) ::timeval tv; tv.tv_sec = timeout.total_seconds(); tv.tv_usec = timeout.total_microseconds() % 1000000; socket_ops::select(0, 0, 0, 0, &tv, ec); #endif // defined(ASIO_WINDOWS_RUNTIME) } // The queue of timers. timer_queue timer_queue_; // The object that schedules and executes timers. Usually a reactor. timer_scheduler& scheduler_; }; } // namespace detail } // namespace asio #include "asio/detail/pop_options.hpp" #endif // ASIO_DETAIL_DEADLINE_TIMER_SERVICE_HPP