doc/html/boost_asio/example/cpp20/operations/composed_2.cpp
//
// composed_2.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 <boost/asio/deferred.hpp>
#include <boost/asio/io_context.hpp>
#include <boost/asio/ip/tcp.hpp>
#include <boost/asio/use_future.hpp>
#include <boost/asio/write.hpp>
#include <cstring>
#include <iostream>
#include <string>
#include <type_traits>
#include <utility>
using boost::asio::ip::tcp;
// NOTE: This example requires the new boost::asio::async_initiate function. For
// an example that works with the Networking TS style of completion tokens,
// please see an older version of asio.
//------------------------------------------------------------------------------
// This next simplest example of a composed asynchronous operation involves
// repackaging multiple operations but choosing to invoke just one of them. All
// of these underlying operations have the same completion signature. The
// asynchronous operation requirements are met by delegating responsibility to
// the underlying operations.
template <
boost::asio::completion_token_for<void(boost::system::error_code, std::size_t)>
CompletionToken>
auto async_write_message(tcp::socket& socket,
const char* message, bool allow_partial_write,
CompletionToken&& token)
// The return type of the initiating function is deduced from the combination
// of:
//
// - the CompletionToken type,
// - the completion handler signature, and
// - the asynchronous operation's initiation function object.
//
// When the completion token is a simple callback, the return type is void.
// However, when the completion token is boost::asio::yield_context (used for
// stackful coroutines) the return type would be std::size_t, and when the
// completion token is boost::asio::use_future it would be std::future<std::size_t>.
// When the completion token is boost::asio::deferred, the return type differs for
// each asynchronous operation.
//
// In C++20 we can omit the return type as it is automatically deduced from
// the return type of boost::asio::async_initiate.
{
// In addition to determining the mechanism by which an asynchronous
// operation delivers its result, a completion token also determines the time
// when the operation commences. For example, when the completion token is a
// simple callback the operation commences before the initiating function
// returns. However, if the completion token's delivery mechanism uses a
// future, we might instead want to defer initiation of the operation until
// the returned future object is waited upon.
//
// To enable this, when implementing an asynchronous operation we must
// package the initiation step as a function object. The initiation function
// object's call operator is passed the concrete completion handler produced
// by the completion token. This completion handler matches the asynchronous
// operation's completion handler signature, which in this example is:
//
// void(boost::system::error_code error, std::size_t)
//
// The initiation function object also receives any additional arguments
// required to start the operation. (Note: We could have instead passed these
// arguments in the lambda capture set. However, we should prefer to
// propagate them as function call arguments as this allows the completion
// token to optimise how they are passed. For example, a lazy future which
// defers initiation would need to make a decay-copy of the arguments, but
// when using a simple callback the arguments can be trivially forwarded
// straight through.)
auto initiation = [](
boost::asio::completion_handler_for<void(boost::system::error_code, std::size_t)>
auto&& completion_handler,
tcp::socket& socket,
const char* message,
bool allow_partial_write)
{
if (allow_partial_write)
{
// When delegating to an underlying operation we must take care to
// perfectly forward the completion handler. This ensures that our
// operation works correctly with move-only function objects as
// callbacks.
return socket.async_write_some(
boost::asio::buffer(message, std::strlen(message)),
std::forward<decltype(completion_handler)>(completion_handler));
}
else
{
// As above, we must perfectly forward the completion handler when calling
// the alternate underlying operation.
return boost::asio::async_write(socket,
boost::asio::buffer(message, std::strlen(message)),
std::forward<decltype(completion_handler)>(completion_handler));
}
};
// The boost::asio::async_initiate function takes:
//
// - our initiation function object,
// - the completion token,
// - the completion handler signature, and
// - any additional arguments we need to initiate the operation.
//
// It then asks the completion token to create a completion handler (i.e. a
// callback) with the specified signature, and invoke the initiation function
// object with this completion handler as well as the additional arguments.
// The return value of async_initiate is the result of our operation's
// initiating function.
//
// Note that we wrap non-const reference arguments in std::reference_wrapper
// to prevent incorrect decay-copies of these objects.
return boost::asio::async_initiate<
CompletionToken, void(boost::system::error_code, std::size_t)>(
initiation, token, std::ref(socket), message, allow_partial_write);
}
//------------------------------------------------------------------------------
void test_callback()
{
boost::asio::io_context io_context;
tcp::acceptor acceptor(io_context, {tcp::v4(), 55555});
tcp::socket socket = acceptor.accept();
// Test our asynchronous operation using a lambda as a callback.
async_write_message(socket, "Testing callback\r\n", false,
[](const boost::system::error_code& error, std::size_t n)
{
if (!error)
{
std::cout << n << " bytes transferred\n";
}
else
{
std::cout << "Error: " << error.message() << "\n";
}
});
io_context.run();
}
//------------------------------------------------------------------------------
void test_deferred()
{
boost::asio::io_context io_context;
tcp::acceptor acceptor(io_context, {tcp::v4(), 55555});
tcp::socket socket = acceptor.accept();
// 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.
boost::asio::async_operation auto op = async_write_message(
socket, "Testing deferred\r\n", false, boost::asio::deferred);
// Launch the operation using a lambda as a callback.
std::move(op)(
[](const boost::system::error_code& error, std::size_t n)
{
if (!error)
{
std::cout << n << " bytes transferred\n";
}
else
{
std::cout << "Error: " << error.message() << "\n";
}
});
io_context.run();
}
//------------------------------------------------------------------------------
void test_future()
{
boost::asio::io_context io_context;
tcp::acceptor acceptor(io_context, {tcp::v4(), 55555});
tcp::socket socket = acceptor.accept();
// 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<std::size_t> f = async_write_message(
socket, "Testing future\r\n", false, boost::asio::use_future);
io_context.run();
try
{
// Get the result of the operation.
std::size_t n = f.get();
std::cout << n << " bytes transferred\n";
}
catch (const std::exception& e)
{
std::cout << "Error: " << e.what() << "\n";
}
}
//------------------------------------------------------------------------------
int main()
{
test_callback();
test_deferred();
test_future();
}