doc/html/boost_asio/example/cpp20/channels/throttling_proxy.cpp
// // throttling_proxy.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 <boost/asio/experimental/as_tuple.hpp> #include <boost/asio/experimental/awaitable_operators.hpp> #include <boost/asio/experimental/channel.hpp> #include <iostream> using boost::asio::awaitable; using boost::asio::buffer; using boost::asio::co_spawn; using boost::asio::detached; using boost::asio::experimental::as_tuple; using boost::asio::experimental::channel; using boost::asio::io_context; using boost::asio::ip::tcp; using boost::asio::steady_timer; using boost::asio::use_awaitable; namespace this_coro = boost::asio::this_coro; using namespace boost::asio::experimental::awaitable_operators; using namespace std::literals::chrono_literals; using token_channel = channel<void(boost::system::error_code, std::size_t)>; awaitable<void> produce_tokens(std::size_t bytes_per_token, steady_timer::duration token_interval, token_channel& tokens) { steady_timer timer(co_await this_coro::executor); for (;;) { co_await tokens.async_send( boost::system::error_code{}, bytes_per_token, use_awaitable); timer.expires_after(token_interval); co_await timer.async_wait(use_awaitable); } } awaitable<void> transfer(tcp::socket& from, tcp::socket& to, token_channel& tokens) { std::array<unsigned char, 4096> data; for (;;) { std::size_t bytes_available = co_await tokens.async_receive(use_awaitable); while (bytes_available > 0) { std::size_t n = co_await from.async_read_some( buffer(data, bytes_available), use_awaitable); co_await async_write(to, buffer(data, n), use_awaitable); bytes_available -= n; } } } awaitable<void> proxy(tcp::socket client, tcp::endpoint target) { constexpr std::size_t number_of_tokens = 100; constexpr size_t bytes_per_token = 20 * 1024; constexpr steady_timer::duration token_interval = 100ms; auto ex = client.get_executor(); tcp::socket server(ex); token_channel client_tokens(ex, number_of_tokens); token_channel server_tokens(ex, number_of_tokens); co_await server.async_connect(target, use_awaitable); co_await ( produce_tokens(bytes_per_token, token_interval, client_tokens) && transfer(client, server, client_tokens) && produce_tokens(bytes_per_token, token_interval, server_tokens) && transfer(server, client, server_tokens) ); } awaitable<void> listen(tcp::acceptor& acceptor, tcp::endpoint target) { for (;;) { auto [e, client] = co_await acceptor.async_accept(as_tuple(use_awaitable)); if (!e) { auto ex = client.get_executor(); co_spawn(ex, proxy(std::move(client), target), detached); } else { std::cerr << "Accept failed: " << e.message() << "\n"; steady_timer timer(co_await this_coro::executor); timer.expires_after(100ms); co_await timer.async_wait(use_awaitable); } } } int main(int argc, char* argv[]) { try { if (argc != 5) { std::cerr << "Usage: throttling_proxy"; std::cerr << " <listen_address> <listen_port>"; std::cerr << " <target_address> <target_port>\n"; return 1; } io_context ctx; auto listen_endpoint = *tcp::resolver(ctx).resolve(argv[1], argv[2], tcp::resolver::passive); auto target_endpoint = *tcp::resolver(ctx).resolve(argv[3], argv[4]); tcp::acceptor acceptor(ctx, listen_endpoint); co_spawn(ctx, listen(acceptor, target_endpoint), detached); ctx.run(); } catch (std::exception& e) { std::cerr << "Exception: " << e.what() << "\n"; } }