// // io_context.hpp // ~~~~~~~~~~~~~~ // // Copyright (c) 2003-2023 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_IO_CONTEXT_HPP #define ASIO_IO_CONTEXT_HPP #if defined(_MSC_VER) && (_MSC_VER >= 1200) # pragma once #endif // defined(_MSC_VER) && (_MSC_VER >= 1200) #include "asio/detail/config.hpp" #include #include #include #include "asio/async_result.hpp" #include "asio/detail/concurrency_hint.hpp" #include "asio/detail/cstdint.hpp" #include "asio/detail/wrapped_handler.hpp" #include "asio/error_code.hpp" #include "asio/execution.hpp" #include "asio/execution_context.hpp" #if defined(ASIO_HAS_CHRONO) # include "asio/detail/chrono.hpp" #endif // defined(ASIO_HAS_CHRONO) #if defined(ASIO_WINDOWS) || defined(__CYGWIN__) # include "asio/detail/winsock_init.hpp" #elif defined(__sun) || defined(__QNX__) || defined(__hpux) || defined(_AIX) \ || defined(__osf__) # include "asio/detail/signal_init.hpp" #endif #if defined(ASIO_HAS_IOCP) # include "asio/detail/win_iocp_io_context.hpp" #else # include "asio/detail/scheduler.hpp" #endif #include "asio/detail/push_options.hpp" namespace asio { namespace detail { #if defined(ASIO_HAS_IOCP) typedef win_iocp_io_context io_context_impl; class win_iocp_overlapped_ptr; #else typedef scheduler io_context_impl; #endif struct io_context_bits { ASIO_STATIC_CONSTEXPR(uintptr_t, blocking_never = 1); ASIO_STATIC_CONSTEXPR(uintptr_t, relationship_continuation = 2); ASIO_STATIC_CONSTEXPR(uintptr_t, outstanding_work_tracked = 4); ASIO_STATIC_CONSTEXPR(uintptr_t, runtime_bits = 3); }; } // namespace detail /// Provides core I/O functionality. /** * The io_context class provides the core I/O functionality for users of the * asynchronous I/O objects, including: * * @li asio::ip::tcp::socket * @li asio::ip::tcp::acceptor * @li asio::ip::udp::socket * @li asio::deadline_timer. * * The io_context class also includes facilities intended for developers of * custom asynchronous services. * * @par Thread Safety * @e Distinct @e objects: Safe.@n * @e Shared @e objects: Safe, with the specific exceptions of the restart() * and notify_fork() functions. Calling restart() while there are unfinished * run(), run_one(), run_for(), run_until(), poll() or poll_one() calls results * in undefined behaviour. The notify_fork() function should not be called * while any io_context function, or any function on an I/O object that is * associated with the io_context, is being called in another thread. * * @par Concepts: * Dispatcher. * * @par Synchronous and asynchronous operations * * Synchronous operations on I/O objects implicitly run the io_context object * for an individual operation. The io_context functions run(), run_one(), * run_for(), run_until(), poll() or poll_one() must be called for the * io_context to perform asynchronous operations on behalf of a C++ program. * Notification that an asynchronous operation has completed is delivered by * invocation of the associated handler. Handlers are invoked only by a thread * that is currently calling any overload of run(), run_one(), run_for(), * run_until(), poll() or poll_one() for the io_context. * * @par Effect of exceptions thrown from handlers * * If an exception is thrown from a handler, the exception is allowed to * propagate through the throwing thread's invocation of run(), run_one(), * run_for(), run_until(), poll() or poll_one(). No other threads that are * calling any of these functions are affected. It is then the responsibility * of the application to catch the exception. * * After the exception has been caught, the run(), run_one(), run_for(), * run_until(), poll() or poll_one() call may be restarted @em without the need * for an intervening call to restart(). This allows the thread to rejoin the * io_context object's thread pool without impacting any other threads in the * pool. * * For example: * * @code * asio::io_context io_context; * ... * for (;;) * { * try * { * io_context.run(); * break; // run() exited normally * } * catch (my_exception& e) * { * // Deal with exception as appropriate. * } * } * @endcode * * @par Submitting arbitrary tasks to the io_context * * To submit functions to the io_context, use the @ref asio::dispatch, * @ref asio::post or @ref asio::defer free functions. * * For example: * * @code void my_task() * { * ... * } * * ... * * asio::io_context io_context; * * // Submit a function to the io_context. * asio::post(io_context, my_task); * * // Submit a lambda object to the io_context. * asio::post(io_context, * []() * { * ... * }); * * // Run the io_context until it runs out of work. * io_context.run(); @endcode * * @par Stopping the io_context from running out of work * * Some applications may need to prevent an io_context object's run() call from * returning when there is no more work to do. For example, the io_context may * be being run in a background thread that is launched prior to the * application's asynchronous operations. The run() call may be kept running by * using the @ref make_work_guard function to create an object of type * asio::executor_work_guard: * * @code asio::io_context io_context; * asio::executor_work_guard * = asio::make_work_guard(io_context); * ... @endcode * * To effect a shutdown, the application will then need to call the io_context * object's stop() member function. This will cause the io_context run() call * to return as soon as possible, abandoning unfinished operations and without * permitting ready handlers to be dispatched. * * Alternatively, if the application requires that all operations and handlers * be allowed to finish normally, the work object may be explicitly reset. * * @code asio::io_context io_context; * asio::executor_work_guard * = asio::make_work_guard(io_context); * ... * work.reset(); // Allow run() to exit. @endcode */ class io_context : public execution_context { private: typedef detail::io_context_impl impl_type; #if defined(ASIO_HAS_IOCP) friend class detail::win_iocp_overlapped_ptr; #endif #if !defined(ASIO_NO_DEPRECATED) struct initiate_dispatch; struct initiate_post; #endif // !defined(ASIO_NO_DEPRECATED) public: template class basic_executor_type; template friend class basic_executor_type; /// Executor used to submit functions to an io_context. typedef basic_executor_type, 0> executor_type; #if !defined(ASIO_NO_DEPRECATED) class work; friend class work; #endif // !defined(ASIO_NO_DEPRECATED) class service; #if !defined(ASIO_NO_EXTENSIONS) \ && !defined(ASIO_NO_TS_EXECUTORS) class strand; #endif // !defined(ASIO_NO_EXTENSIONS) // && !defined(ASIO_NO_TS_EXECUTORS) /// The type used to count the number of handlers executed by the context. typedef std::size_t count_type; /// Constructor. ASIO_DECL io_context(); /// Constructor. /** * Construct with a hint about the required level of concurrency. * * @param concurrency_hint A suggestion to the implementation on how many * threads it should allow to run simultaneously. */ ASIO_DECL explicit io_context(int concurrency_hint); /// Destructor. /** * On destruction, the io_context performs the following sequence of * operations: * * @li For each service object @c svc in the io_context set, in reverse order * of the beginning of service object lifetime, performs * @c svc->shutdown(). * * @li Uninvoked handler objects that were scheduled for deferred invocation * on the io_context, or any associated strand, are destroyed. * * @li For each service object @c svc in the io_context set, in reverse order * of the beginning of service object lifetime, performs * delete static_cast(svc). * * @note The destruction sequence described above permits programs to * simplify their resource management by using @c shared_ptr<>. Where an * object's lifetime is tied to the lifetime of a connection (or some other * sequence of asynchronous operations), a @c shared_ptr to the object would * be bound into the handlers for all asynchronous operations associated with * it. This works as follows: * * @li When a single connection ends, all associated asynchronous operations * complete. The corresponding handler objects are destroyed, and all * @c shared_ptr references to the objects are destroyed. * * @li To shut down the whole program, the io_context function stop() is * called to terminate any run() calls as soon as possible. The io_context * destructor defined above destroys all handlers, causing all @c shared_ptr * references to all connection objects to be destroyed. */ ASIO_DECL ~io_context(); /// Obtains the executor associated with the io_context. executor_type get_executor() ASIO_NOEXCEPT; /// Run the io_context object's event processing loop. /** * The run() function blocks until all work has finished and there are no * more handlers to be dispatched, or until the io_context has been stopped. * * Multiple threads may call the run() function to set up a pool of threads * from which the io_context may execute handlers. All threads that are * waiting in the pool are equivalent and the io_context may choose any one * of them to invoke a handler. * * A normal exit from the run() function implies that the io_context object * is stopped (the stopped() function returns @c true). Subsequent calls to * run(), run_one(), poll() or poll_one() will return immediately unless there * is a prior call to restart(). * * @return The number of handlers that were executed. * * @note Calling the run() function from a thread that is currently calling * one of run(), run_one(), run_for(), run_until(), poll() or poll_one() on * the same io_context object may introduce the potential for deadlock. It is * the caller's reponsibility to avoid this. * * The poll() function may also be used to dispatch ready handlers, but * without blocking. */ ASIO_DECL count_type run(); #if !defined(ASIO_NO_DEPRECATED) /// (Deprecated: Use non-error_code overload.) Run the io_context object's /// event processing loop. /** * The run() function blocks until all work has finished and there are no * more handlers to be dispatched, or until the io_context has been stopped. * * Multiple threads may call the run() function to set up a pool of threads * from which the io_context may execute handlers. All threads that are * waiting in the pool are equivalent and the io_context may choose any one * of them to invoke a handler. * * A normal exit from the run() function implies that the io_context object * is stopped (the stopped() function returns @c true). Subsequent calls to * run(), run_one(), poll() or poll_one() will return immediately unless there * is a prior call to restart(). * * @param ec Set to indicate what error occurred, if any. * * @return The number of handlers that were executed. * * @note Calling the run() function from a thread that is currently calling * one of run(), run_one(), run_for(), run_until(), poll() or poll_one() on * the same io_context object may introduce the potential for deadlock. It is * the caller's reponsibility to avoid this. * * The poll() function may also be used to dispatch ready handlers, but * without blocking. */ ASIO_DECL count_type run(asio::error_code& ec); #endif // !defined(ASIO_NO_DEPRECATED) #if defined(ASIO_HAS_CHRONO) || defined(GENERATING_DOCUMENTATION) /// Run the io_context object's event processing loop for a specified /// duration. /** * The run_for() function blocks until all work has finished and there are no * more handlers to be dispatched, until the io_context has been stopped, or * until the specified duration has elapsed. * * @param rel_time The duration for which the call may block. * * @return The number of handlers that were executed. */ template std::size_t run_for(const chrono::duration& rel_time); /// Run the io_context object's event processing loop until a specified time. /** * The run_until() function blocks until all work has finished and there are * no more handlers to be dispatched, until the io_context has been stopped, * or until the specified time has been reached. * * @param abs_time The time point until which the call may block. * * @return The number of handlers that were executed. */ template std::size_t run_until(const chrono::time_point& abs_time); #endif // defined(ASIO_HAS_CHRONO) || defined(GENERATING_DOCUMENTATION) /// Run the io_context object's event processing loop to execute at most one /// handler. /** * The run_one() function blocks until one handler has been dispatched, or * until the io_context has been stopped. * * @return The number of handlers that were executed. A zero return value * implies that the io_context object is stopped (the stopped() function * returns @c true). Subsequent calls to run(), run_one(), poll() or * poll_one() will return immediately unless there is a prior call to * restart(). * * @note Calling the run_one() function from a thread that is currently * calling one of run(), run_one(), run_for(), run_until(), poll() or * poll_one() on the same io_context object may introduce the potential for * deadlock. It is the caller's reponsibility to avoid this. */ ASIO_DECL count_type run_one(); #if !defined(ASIO_NO_DEPRECATED) /// (Deprecated: Use non-error_code overload.) Run the io_context object's /// event processing loop to execute at most one handler. /** * The run_one() function blocks until one handler has been dispatched, or * until the io_context has been stopped. * * @return The number of handlers that were executed. A zero return value * implies that the io_context object is stopped (the stopped() function * returns @c true). Subsequent calls to run(), run_one(), poll() or * poll_one() will return immediately unless there is a prior call to * restart(). * * @return The number of handlers that were executed. * * @note Calling the run_one() function from a thread that is currently * calling one of run(), run_one(), run_for(), run_until(), poll() or * poll_one() on the same io_context object may introduce the potential for * deadlock. It is the caller's reponsibility to avoid this. */ ASIO_DECL count_type run_one(asio::error_code& ec); #endif // !defined(ASIO_NO_DEPRECATED) #if defined(ASIO_HAS_CHRONO) || defined(GENERATING_DOCUMENTATION) /// Run the io_context object's event processing loop for a specified duration /// to execute at most one handler. /** * The run_one_for() function blocks until one handler has been dispatched, * until the io_context has been stopped, or until the specified duration has * elapsed. * * @param rel_time The duration for which the call may block. * * @return The number of handlers that were executed. */ template std::size_t run_one_for(const chrono::duration& rel_time); /// Run the io_context object's event processing loop until a specified time /// to execute at most one handler. /** * The run_one_until() function blocks until one handler has been dispatched, * until the io_context has been stopped, or until the specified time has * been reached. * * @param abs_time The time point until which the call may block. * * @return The number of handlers that were executed. */ template std::size_t run_one_until( const chrono::time_point& abs_time); #endif // defined(ASIO_HAS_CHRONO) || defined(GENERATING_DOCUMENTATION) /// Run the io_context object's event processing loop to execute ready /// handlers. /** * The poll() function runs handlers that are ready to run, without blocking, * until the io_context has been stopped or there are no more ready handlers. * * @return The number of handlers that were executed. */ ASIO_DECL count_type poll(); #if !defined(ASIO_NO_DEPRECATED) /// (Deprecated: Use non-error_code overload.) Run the io_context object's /// event processing loop to execute ready handlers. /** * The poll() function runs handlers that are ready to run, without blocking, * until the io_context has been stopped or there are no more ready handlers. * * @param ec Set to indicate what error occurred, if any. * * @return The number of handlers that were executed. */ ASIO_DECL count_type poll(asio::error_code& ec); #endif // !defined(ASIO_NO_DEPRECATED) /// Run the io_context object's event processing loop to execute one ready /// handler. /** * The poll_one() function runs at most one handler that is ready to run, * without blocking. * * @return The number of handlers that were executed. */ ASIO_DECL count_type poll_one(); #if !defined(ASIO_NO_DEPRECATED) /// (Deprecated: Use non-error_code overload.) Run the io_context object's /// event processing loop to execute one ready handler. /** * The poll_one() function runs at most one handler that is ready to run, * without blocking. * * @param ec Set to indicate what error occurred, if any. * * @return The number of handlers that were executed. */ ASIO_DECL count_type poll_one(asio::error_code& ec); #endif // !defined(ASIO_NO_DEPRECATED) /// Stop the io_context object's event processing loop. /** * This function does not block, but instead simply signals the io_context to * stop. All invocations of its run() or run_one() member functions should * return as soon as possible. Subsequent calls to run(), run_one(), poll() * or poll_one() will return immediately until restart() is called. */ ASIO_DECL void stop(); /// Determine whether the io_context object has been stopped. /** * This function is used to determine whether an io_context object has been * stopped, either through an explicit call to stop(), or due to running out * of work. When an io_context object is stopped, calls to run(), run_one(), * poll() or poll_one() will return immediately without invoking any * handlers. * * @return @c true if the io_context object is stopped, otherwise @c false. */ ASIO_DECL bool stopped() const; /// Restart the io_context in preparation for a subsequent run() invocation. /** * This function must be called prior to any second or later set of * invocations of the run(), run_one(), poll() or poll_one() functions when a * previous invocation of these functions returned due to the io_context * being stopped or running out of work. After a call to restart(), the * io_context object's stopped() function will return @c false. * * This function must not be called while there are any unfinished calls to * the run(), run_one(), poll() or poll_one() functions. */ ASIO_DECL void restart(); #if !defined(ASIO_NO_DEPRECATED) /// (Deprecated: Use restart().) Reset the io_context in preparation for a /// subsequent run() invocation. /** * This function must be called prior to any second or later set of * invocations of the run(), run_one(), poll() or poll_one() functions when a * previous invocation of these functions returned due to the io_context * being stopped or running out of work. After a call to restart(), the * io_context object's stopped() function will return @c false. * * This function must not be called while there are any unfinished calls to * the run(), run_one(), poll() or poll_one() functions. */ void reset(); /// (Deprecated: Use asio::dispatch().) Request the io_context to /// invoke the given handler. /** * This function is used to ask the io_context to execute the given handler. * * The io_context guarantees that the handler will only be called in a thread * in which the run(), run_one(), poll() or poll_one() member functions is * currently being invoked. The handler may be executed inside this function * if the guarantee can be met. * * @param handler The handler to be called. The io_context will make * a copy of the handler object as required. The function signature of the * handler must be: @code void handler(); @endcode * * @note This function throws an exception only if: * * @li the handler's @c asio_handler_allocate function; or * * @li the handler's copy constructor * * throws an exception. */ template ASIO_INITFN_AUTO_RESULT_TYPE_PREFIX(LegacyCompletionHandler, void ()) dispatch(ASIO_MOVE_ARG(LegacyCompletionHandler) handler) ASIO_INITFN_AUTO_RESULT_TYPE_SUFFIX(( async_initiate( declval(), handler, this))); /// (Deprecated: Use asio::post().) Request the io_context to invoke /// the given handler and return immediately. /** * This function is used to ask the io_context to execute the given handler, * but without allowing the io_context to call the handler from inside this * function. * * The io_context guarantees that the handler will only be called in a thread * in which the run(), run_one(), poll() or poll_one() member functions is * currently being invoked. * * @param handler The handler to be called. The io_context will make * a copy of the handler object as required. The function signature of the * handler must be: @code void handler(); @endcode * * @note This function throws an exception only if: * * @li the handler's @c asio_handler_allocate function; or * * @li the handler's copy constructor * * throws an exception. */ template ASIO_INITFN_AUTO_RESULT_TYPE_PREFIX(LegacyCompletionHandler, void ()) post(ASIO_MOVE_ARG(LegacyCompletionHandler) handler) ASIO_INITFN_AUTO_RESULT_TYPE_SUFFIX(( async_initiate( declval(), handler, this))); /// (Deprecated: Use asio::bind_executor().) Create a new handler that /// automatically dispatches the wrapped handler on the io_context. /** * This function is used to create a new handler function object that, when * invoked, will automatically pass the wrapped handler to the io_context * object's dispatch function. * * @param handler The handler to be wrapped. The io_context will make a copy * of the handler object as required. The function signature of the handler * must be: @code void handler(A1 a1, ... An an); @endcode * * @return A function object that, when invoked, passes the wrapped handler to * the io_context object's dispatch function. Given a function object with the * signature: * @code R f(A1 a1, ... An an); @endcode * If this function object is passed to the wrap function like so: * @code io_context.wrap(f); @endcode * then the return value is a function object with the signature * @code void g(A1 a1, ... An an); @endcode * that, when invoked, executes code equivalent to: * @code io_context.dispatch(boost::bind(f, a1, ... an)); @endcode */ template #if defined(GENERATING_DOCUMENTATION) unspecified #else detail::wrapped_handler #endif wrap(Handler handler); #endif // !defined(ASIO_NO_DEPRECATED) private: io_context(const io_context&) ASIO_DELETED; io_context& operator=(const io_context&) ASIO_DELETED; // Helper function to add the implementation. ASIO_DECL impl_type& add_impl(impl_type* impl); // Backwards compatible overload for use with services derived from // io_context::service. template friend Service& use_service(io_context& ioc); #if defined(ASIO_WINDOWS) || defined(__CYGWIN__) detail::winsock_init<> init_; #elif defined(__sun) || defined(__QNX__) || defined(__hpux) || defined(_AIX) \ || defined(__osf__) detail::signal_init<> init_; #endif // The implementation. impl_type& impl_; }; namespace detail { } // namespace detail /// Executor implementation type used to submit functions to an io_context. template class io_context::basic_executor_type : detail::io_context_bits, Allocator { public: /// Copy constructor. basic_executor_type( const basic_executor_type& other) ASIO_NOEXCEPT : Allocator(static_cast(other)), target_(other.target_) { if (Bits & outstanding_work_tracked) if (context_ptr()) context_ptr()->impl_.work_started(); } #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION) /// Move constructor. basic_executor_type(basic_executor_type&& other) ASIO_NOEXCEPT : Allocator(ASIO_MOVE_CAST(Allocator)(other)), target_(other.target_) { if (Bits & outstanding_work_tracked) other.target_ = 0; } #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION) /// Destructor. ~basic_executor_type() ASIO_NOEXCEPT { if (Bits & outstanding_work_tracked) if (context_ptr()) context_ptr()->impl_.work_finished(); } /// Assignment operator. basic_executor_type& operator=( const basic_executor_type& other) ASIO_NOEXCEPT; #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION) /// Move assignment operator. basic_executor_type& operator=( basic_executor_type&& other) ASIO_NOEXCEPT; #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION) #if !defined(GENERATING_DOCUMENTATION) private: friend struct asio_require_fn::impl; friend struct asio_prefer_fn::impl; #endif // !defined(GENERATING_DOCUMENTATION) /// Obtain an executor with the @c blocking.possibly property. /** * Do not call this function directly. It is intended for use with the * asio::require customisation point. * * For example: * @code auto ex1 = my_io_context.get_executor(); * auto ex2 = asio::require(ex1, * asio::execution::blocking.possibly); @endcode */ ASIO_CONSTEXPR basic_executor_type require( execution::blocking_t::possibly_t) const { return basic_executor_type(context_ptr(), *this, bits() & ~blocking_never); } /// Obtain an executor with the @c blocking.never property. /** * Do not call this function directly. It is intended for use with the * asio::require customisation point. * * For example: * @code auto ex1 = my_io_context.get_executor(); * auto ex2 = asio::require(ex1, * asio::execution::blocking.never); @endcode */ ASIO_CONSTEXPR basic_executor_type require( execution::blocking_t::never_t) const { return basic_executor_type(context_ptr(), *this, bits() | blocking_never); } /// Obtain an executor with the @c relationship.fork property. /** * Do not call this function directly. It is intended for use with the * asio::require customisation point. * * For example: * @code auto ex1 = my_io_context.get_executor(); * auto ex2 = asio::require(ex1, * asio::execution::relationship.fork); @endcode */ ASIO_CONSTEXPR basic_executor_type require( execution::relationship_t::fork_t) const { return basic_executor_type(context_ptr(), *this, bits() & ~relationship_continuation); } /// Obtain an executor with the @c relationship.continuation property. /** * Do not call this function directly. It is intended for use with the * asio::require customisation point. * * For example: * @code auto ex1 = my_io_context.get_executor(); * auto ex2 = asio::require(ex1, * asio::execution::relationship.continuation); @endcode */ ASIO_CONSTEXPR basic_executor_type require( execution::relationship_t::continuation_t) const { return basic_executor_type(context_ptr(), *this, bits() | relationship_continuation); } /// Obtain an executor with the @c outstanding_work.tracked property. /** * Do not call this function directly. It is intended for use with the * asio::require customisation point. * * For example: * @code auto ex1 = my_io_context.get_executor(); * auto ex2 = asio::require(ex1, * asio::execution::outstanding_work.tracked); @endcode */ ASIO_CONSTEXPR basic_executor_type require(execution::outstanding_work_t::tracked_t) const { return basic_executor_type( context_ptr(), *this, bits()); } /// Obtain an executor with the @c outstanding_work.untracked property. /** * Do not call this function directly. It is intended for use with the * asio::require customisation point. * * For example: * @code auto ex1 = my_io_context.get_executor(); * auto ex2 = asio::require(ex1, * asio::execution::outstanding_work.untracked); @endcode */ ASIO_CONSTEXPR basic_executor_type require(execution::outstanding_work_t::untracked_t) const { return basic_executor_type( context_ptr(), *this, bits()); } /// Obtain an executor with the specified @c allocator property. /** * Do not call this function directly. It is intended for use with the * asio::require customisation point. * * For example: * @code auto ex1 = my_io_context.get_executor(); * auto ex2 = asio::require(ex1, * asio::execution::allocator(my_allocator)); @endcode */ template ASIO_CONSTEXPR basic_executor_type require(execution::allocator_t a) const { return basic_executor_type( context_ptr(), a.value(), bits()); } /// Obtain an executor with the default @c allocator property. /** * Do not call this function directly. It is intended for use with the * asio::require customisation point. * * For example: * @code auto ex1 = my_io_context.get_executor(); * auto ex2 = asio::require(ex1, * asio::execution::allocator); @endcode */ ASIO_CONSTEXPR basic_executor_type, Bits> require(execution::allocator_t) const { return basic_executor_type, Bits>( context_ptr(), std::allocator(), bits()); } #if !defined(GENERATING_DOCUMENTATION) private: friend struct asio_query_fn::impl; friend struct asio::execution::detail::mapping_t<0>; friend struct asio::execution::detail::outstanding_work_t<0>; #endif // !defined(GENERATING_DOCUMENTATION) /// Query the current value of the @c mapping property. /** * Do not call this function directly. It is intended for use with the * asio::query customisation point. * * For example: * @code auto ex = my_io_context.get_executor(); * if (asio::query(ex, asio::execution::mapping) * == asio::execution::mapping.thread) * ... @endcode */ static ASIO_CONSTEXPR execution::mapping_t query( execution::mapping_t) ASIO_NOEXCEPT { return execution::mapping.thread; } /// Query the current value of the @c context property. /** * Do not call this function directly. It is intended for use with the * asio::query customisation point. * * For example: * @code auto ex = my_io_context.get_executor(); * asio::io_context& ctx = asio::query( * ex, asio::execution::context); @endcode */ io_context& query(execution::context_t) const ASIO_NOEXCEPT { return *context_ptr(); } /// Query the current value of the @c blocking property. /** * Do not call this function directly. It is intended for use with the * asio::query customisation point. * * For example: * @code auto ex = my_io_context.get_executor(); * if (asio::query(ex, asio::execution::blocking) * == asio::execution::blocking.always) * ... @endcode */ ASIO_CONSTEXPR execution::blocking_t query( execution::blocking_t) const ASIO_NOEXCEPT { return (bits() & blocking_never) ? execution::blocking_t(execution::blocking.never) : execution::blocking_t(execution::blocking.possibly); } /// Query the current value of the @c relationship property. /** * Do not call this function directly. It is intended for use with the * asio::query customisation point. * * For example: * @code auto ex = my_io_context.get_executor(); * if (asio::query(ex, asio::execution::relationship) * == asio::execution::relationship.continuation) * ... @endcode */ ASIO_CONSTEXPR execution::relationship_t query( execution::relationship_t) const ASIO_NOEXCEPT { return (bits() & relationship_continuation) ? execution::relationship_t(execution::relationship.continuation) : execution::relationship_t(execution::relationship.fork); } /// Query the current value of the @c outstanding_work property. /** * Do not call this function directly. It is intended for use with the * asio::query customisation point. * * For example: * @code auto ex = my_io_context.get_executor(); * if (asio::query(ex, asio::execution::outstanding_work) * == asio::execution::outstanding_work.tracked) * ... @endcode */ static ASIO_CONSTEXPR execution::outstanding_work_t query( execution::outstanding_work_t) ASIO_NOEXCEPT { return (Bits & outstanding_work_tracked) ? execution::outstanding_work_t(execution::outstanding_work.tracked) : execution::outstanding_work_t(execution::outstanding_work.untracked); } /// Query the current value of the @c allocator property. /** * Do not call this function directly. It is intended for use with the * asio::query customisation point. * * For example: * @code auto ex = my_io_context.get_executor(); * auto alloc = asio::query(ex, * asio::execution::allocator); @endcode */ template ASIO_CONSTEXPR Allocator query( execution::allocator_t) const ASIO_NOEXCEPT { return static_cast(*this); } /// Query the current value of the @c allocator property. /** * Do not call this function directly. It is intended for use with the * asio::query customisation point. * * For example: * @code auto ex = my_io_context.get_executor(); * auto alloc = asio::query(ex, * asio::execution::allocator); @endcode */ ASIO_CONSTEXPR Allocator query( execution::allocator_t) const ASIO_NOEXCEPT { return static_cast(*this); } public: /// Determine whether the io_context is running in the current thread. /** * @return @c true if the current thread is running the io_context. Otherwise * returns @c false. */ bool running_in_this_thread() const ASIO_NOEXCEPT; /// Compare two executors for equality. /** * Two executors are equal if they refer to the same underlying io_context. */ friend bool operator==(const basic_executor_type& a, const basic_executor_type& b) ASIO_NOEXCEPT { return a.target_ == b.target_ && static_cast(a) == static_cast(b); } /// Compare two executors for inequality. /** * Two executors are equal if they refer to the same underlying io_context. */ friend bool operator!=(const basic_executor_type& a, const basic_executor_type& b) ASIO_NOEXCEPT { return a.target_ != b.target_ || static_cast(a) != static_cast(b); } /// Execution function. template void execute(ASIO_MOVE_ARG(Function) f) const; #if !defined(ASIO_NO_TS_EXECUTORS) public: /// Obtain the underlying execution context. io_context& context() const ASIO_NOEXCEPT; /// Inform the io_context that it has some outstanding work to do. /** * This function is used to inform the io_context that some work has begun. * This ensures that the io_context's run() and run_one() functions do not * exit while the work is underway. */ void on_work_started() const ASIO_NOEXCEPT; /// Inform the io_context that some work is no longer outstanding. /** * This function is used to inform the io_context that some work has * finished. Once the count of unfinished work reaches zero, the io_context * is stopped and the run() and run_one() functions may exit. */ void on_work_finished() const ASIO_NOEXCEPT; /// Request the io_context to invoke the given function object. /** * This function is used to ask the io_context to execute the given function * object. If the current thread is running the io_context, @c dispatch() * executes the function before returning. Otherwise, the function will be * scheduled to run on the io_context. * * @param f The function object to be called. The executor will make a copy * of the handler object as required. The function signature of the function * object must be: @code void function(); @endcode * * @param a An allocator that may be used by the executor to allocate the * internal storage needed for function invocation. */ template void dispatch(ASIO_MOVE_ARG(Function) f, const OtherAllocator& a) const; /// Request the io_context to invoke the given function object. /** * This function is used to ask the io_context to execute the given function * object. The function object will never be executed inside @c post(). * Instead, it will be scheduled to run on the io_context. * * @param f The function object to be called. The executor will make a copy * of the handler object as required. The function signature of the function * object must be: @code void function(); @endcode * * @param a An allocator that may be used by the executor to allocate the * internal storage needed for function invocation. */ template void post(ASIO_MOVE_ARG(Function) f, const OtherAllocator& a) const; /// Request the io_context to invoke the given function object. /** * This function is used to ask the io_context to execute the given function * object. The function object will never be executed inside @c defer(). * Instead, it will be scheduled to run on the io_context. * * If the current thread belongs to the io_context, @c defer() will delay * scheduling the function object until the current thread returns control to * the pool. * * @param f The function object to be called. The executor will make a copy * of the handler object as required. The function signature of the function * object must be: @code void function(); @endcode * * @param a An allocator that may be used by the executor to allocate the * internal storage needed for function invocation. */ template void defer(ASIO_MOVE_ARG(Function) f, const OtherAllocator& a) const; #endif // !defined(ASIO_NO_TS_EXECUTORS) private: friend class io_context; template friend class basic_executor_type; // Constructor used by io_context::get_executor(). explicit basic_executor_type(io_context& i) ASIO_NOEXCEPT : Allocator(), target_(reinterpret_cast(&i)) { if (Bits & outstanding_work_tracked) context_ptr()->impl_.work_started(); } // Constructor used by require(). basic_executor_type(io_context* i, const Allocator& a, uintptr_t bits) ASIO_NOEXCEPT : Allocator(a), target_(reinterpret_cast(i) | bits) { if (Bits & outstanding_work_tracked) if (context_ptr()) context_ptr()->impl_.work_started(); } io_context* context_ptr() const ASIO_NOEXCEPT { return reinterpret_cast(target_ & ~runtime_bits); } uintptr_t bits() const ASIO_NOEXCEPT { return target_ & runtime_bits; } // The underlying io_context and runtime bits. uintptr_t target_; }; #if !defined(ASIO_NO_DEPRECATED) /// (Deprecated: Use executor_work_guard.) Class to inform the io_context when /// it has work to do. /** * The work class is used to inform the io_context when work starts and * finishes. This ensures that the io_context object's run() function will not * exit while work is underway, and that it does exit when there is no * unfinished work remaining. * * The work class is copy-constructible so that it may be used as a data member * in a handler class. It is not assignable. */ class io_context::work { public: /// Constructor notifies the io_context that work is starting. /** * The constructor is used to inform the io_context that some work has begun. * This ensures that the io_context object's run() function will not exit * while the work is underway. */ explicit work(asio::io_context& io_context); /// Copy constructor notifies the io_context that work is starting. /** * The constructor is used to inform the io_context that some work has begun. * This ensures that the io_context object's run() function will not exit * while the work is underway. */ work(const work& other); /// Destructor notifies the io_context that the work is complete. /** * The destructor is used to inform the io_context that some work has * finished. Once the count of unfinished work reaches zero, the io_context * object's run() function is permitted to exit. */ ~work(); /// Get the io_context associated with the work. asio::io_context& get_io_context(); private: // Prevent assignment. void operator=(const work& other); // The io_context implementation. detail::io_context_impl& io_context_impl_; }; #endif // !defined(ASIO_NO_DEPRECATED) /// Base class for all io_context services. class io_context::service : public execution_context::service { public: /// Get the io_context object that owns the service. asio::io_context& get_io_context(); private: /// Destroy all user-defined handler objects owned by the service. ASIO_DECL virtual void shutdown(); #if !defined(ASIO_NO_DEPRECATED) /// (Deprecated: Use shutdown().) Destroy all user-defined handler objects /// owned by the service. ASIO_DECL virtual void shutdown_service(); #endif // !defined(ASIO_NO_DEPRECATED) /// Handle notification of a fork-related event to perform any necessary /// housekeeping. /** * This function is not a pure virtual so that services only have to * implement it if necessary. The default implementation does nothing. */ ASIO_DECL virtual void notify_fork( execution_context::fork_event event); #if !defined(ASIO_NO_DEPRECATED) /// (Deprecated: Use notify_fork().) Handle notification of a fork-related /// event to perform any necessary housekeeping. /** * This function is not a pure virtual so that services only have to * implement it if necessary. The default implementation does nothing. */ ASIO_DECL virtual void fork_service( execution_context::fork_event event); #endif // !defined(ASIO_NO_DEPRECATED) protected: /// Constructor. /** * @param owner The io_context object that owns the service. */ ASIO_DECL service(asio::io_context& owner); /// Destructor. ASIO_DECL virtual ~service(); }; namespace detail { // Special service base class to keep classes header-file only. template class service_base : public asio::io_context::service { public: static asio::detail::service_id id; // Constructor. service_base(asio::io_context& io_context) : asio::io_context::service(io_context) { } }; template asio::detail::service_id service_base::id; } // namespace detail #if !defined(GENERATING_DOCUMENTATION) namespace traits { #if !defined(ASIO_HAS_DEDUCED_EQUALITY_COMPARABLE_TRAIT) template struct equality_comparable< asio::io_context::basic_executor_type > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = true); }; #endif // !defined(ASIO_HAS_DEDUCED_EQUALITY_COMPARABLE_TRAIT) #if !defined(ASIO_HAS_DEDUCED_EXECUTE_MEMBER_TRAIT) template struct execute_member< asio::io_context::basic_executor_type, Function > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = false); typedef void result_type; }; #endif // !defined(ASIO_HAS_DEDUCED_EXECUTE_MEMBER_TRAIT) #if !defined(ASIO_HAS_DEDUCED_REQUIRE_MEMBER_TRAIT) template struct require_member< asio::io_context::basic_executor_type, asio::execution::blocking_t::possibly_t > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = false); typedef asio::io_context::basic_executor_type< Allocator, Bits> result_type; }; template struct require_member< asio::io_context::basic_executor_type, asio::execution::blocking_t::never_t > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = false); typedef asio::io_context::basic_executor_type< Allocator, Bits> result_type; }; template struct require_member< asio::io_context::basic_executor_type, asio::execution::relationship_t::fork_t > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = false); typedef asio::io_context::basic_executor_type< Allocator, Bits> result_type; }; template struct require_member< asio::io_context::basic_executor_type, asio::execution::relationship_t::continuation_t > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = false); typedef asio::io_context::basic_executor_type< Allocator, Bits> result_type; }; template struct require_member< asio::io_context::basic_executor_type, asio::execution::outstanding_work_t::tracked_t > : asio::detail::io_context_bits { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = false); typedef asio::io_context::basic_executor_type< Allocator, Bits | outstanding_work_tracked> result_type; }; template struct require_member< asio::io_context::basic_executor_type, asio::execution::outstanding_work_t::untracked_t > : asio::detail::io_context_bits { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = false); typedef asio::io_context::basic_executor_type< Allocator, Bits & ~outstanding_work_tracked> result_type; }; template struct require_member< asio::io_context::basic_executor_type, asio::execution::allocator_t > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = false); typedef asio::io_context::basic_executor_type< std::allocator, Bits> result_type; }; template struct require_member< asio::io_context::basic_executor_type, asio::execution::allocator_t > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = false); typedef asio::io_context::basic_executor_type< OtherAllocator, Bits> result_type; }; #endif // !defined(ASIO_HAS_DEDUCED_REQUIRE_MEMBER_TRAIT) #if !defined(ASIO_HAS_DEDUCED_QUERY_STATIC_CONSTEXPR_MEMBER_TRAIT) template struct query_static_constexpr_member< asio::io_context::basic_executor_type, Property, typename asio::enable_if< asio::is_convertible< Property, asio::execution::outstanding_work_t >::value >::type > : asio::detail::io_context_bits { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = true); typedef asio::execution::outstanding_work_t result_type; static ASIO_CONSTEXPR result_type value() ASIO_NOEXCEPT { return (Bits & outstanding_work_tracked) ? execution::outstanding_work_t(execution::outstanding_work.tracked) : execution::outstanding_work_t(execution::outstanding_work.untracked); } }; template struct query_static_constexpr_member< asio::io_context::basic_executor_type, Property, typename asio::enable_if< asio::is_convertible< Property, asio::execution::mapping_t >::value >::type > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = true); typedef asio::execution::mapping_t::thread_t result_type; static ASIO_CONSTEXPR result_type value() ASIO_NOEXCEPT { return result_type(); } }; #endif // !defined(ASIO_HAS_DEDUCED_QUERY_STATIC_CONSTEXPR_MEMBER_TRAIT) #if !defined(ASIO_HAS_DEDUCED_QUERY_MEMBER_TRAIT) template struct query_member< asio::io_context::basic_executor_type, Property, typename asio::enable_if< asio::is_convertible< Property, asio::execution::blocking_t >::value >::type > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = true); typedef asio::execution::blocking_t result_type; }; template struct query_member< asio::io_context::basic_executor_type, Property, typename asio::enable_if< asio::is_convertible< Property, asio::execution::relationship_t >::value >::type > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = true); typedef asio::execution::relationship_t result_type; }; template struct query_member< asio::io_context::basic_executor_type, asio::execution::context_t > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = true); typedef asio::io_context& result_type; }; template struct query_member< asio::io_context::basic_executor_type, asio::execution::allocator_t > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = true); typedef Allocator result_type; }; template struct query_member< asio::io_context::basic_executor_type, asio::execution::allocator_t > { ASIO_STATIC_CONSTEXPR(bool, is_valid = true); ASIO_STATIC_CONSTEXPR(bool, is_noexcept = true); typedef Allocator result_type; }; #endif // !defined(ASIO_HAS_DEDUCED_QUERY_MEMBER_TRAIT) } // namespace traits namespace execution { template <> struct is_executor : false_type { }; } // namespace execution #endif // !defined(GENERATING_DOCUMENTATION) } // namespace asio #include "asio/detail/pop_options.hpp" #include "asio/impl/io_context.hpp" #if defined(ASIO_HEADER_ONLY) # include "asio/impl/io_context.ipp" #endif // defined(ASIO_HEADER_ONLY) // If both io_context.hpp and strand.hpp have been included, automatically // include the header file needed for the io_context::strand class. #if !defined(ASIO_NO_EXTENSIONS) # if defined(ASIO_STRAND_HPP) # include "asio/io_context_strand.hpp" # endif // defined(ASIO_STRAND_HPP) #endif // !defined(ASIO_NO_EXTENSIONS) #endif // ASIO_IO_CONTEXT_HPP