// // callback_wrapper.cpp // ~~~~~~~~~~~~~~~~~~~~ // // 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) // #include #include //------------------------------------------------------------------------------ // This is a mock implementation of an API that uses a move-only function object // for exposing a callback. The callback has the signature void(std::string). template void read_input(const std::string& prompt, Callback cb) { std::thread( [prompt, cb = std::move(cb)]() mutable { std::cout << prompt << ": "; std::cout.flush(); std::string line; std::getline(std::cin, line); std::move(cb)(std::move(line)); }).detach(); } //------------------------------------------------------------------------------ // This is an asynchronous operation that wraps the callback-based API. // The initiating function for the asynchronous operation. template CompletionToken> auto async_read_input(const std::string& prompt, CompletionToken&& token) { // Define a function object that contains the code to launch the asynchronous // operation. This is passed the concrete completion handler, followed by any // additional arguments that were passed through the call to async_initiate. auto init = []( asio::completion_handler_for auto handler, const std::string& prompt) { // According to the rules for asynchronous operations, we need to track // outstanding work against the handler's associated executor until the // asynchronous operation is complete. auto work = asio::make_work_guard(handler); // Launch the operation with a callback that will receive the result and // pass it through to the asynchronous operation's completion handler. read_input(prompt, [ handler = std::move(handler), work = std::move(work) ](std::string result) mutable { // Get the handler's associated allocator. If the handler does not // specify an allocator, use the recycling allocator as the default. auto alloc = asio::get_associated_allocator( handler, asio::recycling_allocator()); // Dispatch the completion handler through the handler's associated // executor, using the handler's associated allocator. asio::dispatch(work.get_executor(), asio::bind_allocator(alloc, [ handler = std::move(handler), result = std::string(result) ]() mutable { std::move(handler)(result); })); }); }; // The async_initiate function is used to transform the supplied completion // token to the completion handler. When calling this function we explicitly // specify the completion signature of the operation. We must also return the // result of the call since the completion token may produce a return value, // such as a future. return asio::async_initiate( init, // First, pass the function object that launches the operation, token, // then the completion token that will be transformed to a handler, prompt); // and, finally, any additional arguments to the function object. } //------------------------------------------------------------------------------ void test_callback() { asio::io_context io_context; // Test our asynchronous operation using a lambda as a callback. We will use // an io_context to specify an associated executor. async_read_input("Enter your name", asio::bind_executor(io_context, [](const std::string& result) { std::cout << "Hello " << result << "\n"; })); io_context.run(); } //------------------------------------------------------------------------------ void test_deferred() { asio::io_context io_context; // Test our asynchronous operation using the deferred completion token. This // token causes the operation's initiating function to package up the // operation with its arguments to return a function object, which may then be // used to launch the asynchronous operation. auto op = async_read_input("Enter your name", asio::deferred); // Launch our asynchronous operation using a lambda as a callback. We will use // an io_context to obtain an associated executor. std::move(op)( asio::bind_executor(io_context, [](const std::string& result) { std::cout << "Hello " << result << "\n"; })); io_context.run(); } //------------------------------------------------------------------------------ void test_future() { // Test our asynchronous operation using the use_future completion token. // This token causes the operation's initiating function to return a future, // which may be used to synchronously wait for the result of the operation. std::future f = async_read_input("Enter your name", asio::use_future); std::string result = f.get(); std::cout << "Hello " << result << "\n"; } //------------------------------------------------------------------------------ int main() { test_callback(); test_deferred(); test_future(); }