From 19fcec84d8d7d21e796c7624e521b60d28ee21ed Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Sun, 7 Apr 2024 20:45:59 +0200 Subject: Adding upstream version 16.2.11+ds. Signed-off-by: Daniel Baumann --- .../libs/beast/example/echo-op/CMakeLists.txt | 23 ++ src/boost/libs/beast/example/echo-op/Jamfile | 15 + src/boost/libs/beast/example/echo-op/echo_op.cpp | 377 +++++++++++++++++++++ 3 files changed, 415 insertions(+) create mode 100644 src/boost/libs/beast/example/echo-op/CMakeLists.txt create mode 100644 src/boost/libs/beast/example/echo-op/Jamfile create mode 100644 src/boost/libs/beast/example/echo-op/echo_op.cpp (limited to 'src/boost/libs/beast/example/echo-op') diff --git a/src/boost/libs/beast/example/echo-op/CMakeLists.txt b/src/boost/libs/beast/example/echo-op/CMakeLists.txt new file mode 100644 index 000000000..d0e086b6e --- /dev/null +++ b/src/boost/libs/beast/example/echo-op/CMakeLists.txt @@ -0,0 +1,23 @@ +# +# Copyright (c) 2016-2017 Vinnie Falco (vinnie dot falco at gmail 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) +# +# Official repository: https://github.com/boostorg/beast +# + +GroupSources(include/boost/beast beast) +GroupSources(example/echo-op "/") + +add_executable (echo-op + ${BOOST_BEAST_FILES} + Jamfile + echo_op.cpp +) + +target_link_libraries(echo-op + lib-asio + lib-beast) + +set_property(TARGET echo-op PROPERTY FOLDER "example") diff --git a/src/boost/libs/beast/example/echo-op/Jamfile b/src/boost/libs/beast/example/echo-op/Jamfile new file mode 100644 index 000000000..caeb767e2 --- /dev/null +++ b/src/boost/libs/beast/example/echo-op/Jamfile @@ -0,0 +1,15 @@ +# +# Copyright (c) 2016-2017 Vinnie Falco (vinnie dot falco at gmail 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) +# +# Official repository: https://github.com/boostorg/beast +# + +exe echo-op : + echo_op.cpp + : + coverage:no + ubasan:no + ; diff --git a/src/boost/libs/beast/example/echo-op/echo_op.cpp b/src/boost/libs/beast/example/echo-op/echo_op.cpp new file mode 100644 index 000000000..475940beb --- /dev/null +++ b/src/boost/libs/beast/example/echo-op/echo_op.cpp @@ -0,0 +1,377 @@ +// +// Copyright (c) 2016-2019 Vinnie Falco (vinnie dot falco at gmail 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) +// +// Official repository: https://github.com/boostorg/beast +// + +#include +#include +#include +#include +#include +#include + +namespace net = boost::asio; +namespace beast = boost::beast; + +//[example_core_echo_op_1 + +template< + class AsyncStream, + class DynamicBuffer, + class CompletionToken> +auto +async_echo (AsyncStream& stream, DynamicBuffer& buffer, CompletionToken&& token) + +//] + -> + typename net::async_result< + typename std::decay::type, + void(beast::error_code)>::return_type; + +//------------------------------------------------------------------------------ + +//[example_core_echo_op_2 + +/** Asynchronously read a line and echo it back. + + This function is used to asynchronously read a line ending + in a newline (`"\n"`) from the stream, and then write + it back. + + This call always returns immediately. The asynchronous operation + will continue until one of the following conditions is true: + + @li A line was read in and written back on the stream + + @li An error occurs. + + The algorithm, known as a composed asynchronous operation, + is implemented in terms of calls to the stream's `async_read_some` + and `async_write_some` function. The program must ensure that no + other reads or writes are performed until this operation completes. + + Since the length of the line is not known ahead of time, the + implementation may read additional characters that lie past the + first line. These characters are stored in the dynamic buffer_. + The same dynamic buffer must be presented again in each call, + to provide the implementation with any leftover bytes. + + @param stream The stream to operate on. The type must meet the + requirements of AsyncReadStream and @AsyncWriteStream + + @param buffer A dynamic buffer to hold implementation-defined + temporary data. Ownership is not transferred; the caller is + responsible for ensuring that the lifetime of this object is + extended least until the completion handler is invoked. + + @param token The handler to be called when the operation completes. + The implementation takes ownership of the handler by performing a decay-copy. + The handler must be invocable with this signature: + @code + void handler( + beast::error_code error // Result of operation. + ); + @endcode + + Regardless of whether the asynchronous operation completes immediately or + not, the handler will not be invoked from within this function. Invocation + of the handler will be performed in a manner equivalent to using + `net::post`. +*/ +template< + class AsyncStream, + class DynamicBuffer, + class CompletionToken> +auto +async_echo ( + AsyncStream& stream, + DynamicBuffer& buffer, /*< Unlike Asio, we pass by non-const reference instead of rvalue-ref >*/ + CompletionToken&& token) -> + typename net::async_result< /*< `async_result` deduces the return type from the completion handler >*/ + typename std::decay::type, + void(beast::error_code) /*< The completion handler signature goes here >*/ + >::return_type; +//] + +//[example_core_echo_op_3 + +template +class echo_op; + +// This example uses the Asio's stackless "fauxroutines", implemented +// using a macro-based solution. It makes the code easier to write and +// easier to read. This include file defines the necessary macros and types. +#include + +// Read a line and echo it back +// +template< + class AsyncStream, + class DynamicBuffer, + class CompletionToken> +auto +async_echo( + AsyncStream& stream, + DynamicBuffer& buffer, + CompletionToken&& token) -> + typename net::async_result< + typename std::decay::type, + void(beast::error_code)>::return_type /*< The completion handler signature goes here >*/ +{ + // Perform some type checks using static assert, this helps + // with more friendly error messages when passing the wrong types. + static_assert( + beast::is_async_stream::value, + "AsyncStream type requirements not met"); + static_assert( + net::is_dynamic_buffer::value, + "DynamicBuffer type requirements not met"); + + // This class template deduces the actual handler type from a + // CompletionToken, captures a local reference to the handler, + // and creates the `async_result` object which becomes the + // return value of this initiating function. + + net::async_completion init(token); + + // The helper macro BOOST_ASIO_HANDLER_TYPE converts the completion + // token type into a concrete handler type of the correct signature. + + using handler_type = BOOST_ASIO_HANDLER_TYPE(CompletionToken, void(beast::error_code)); + + // The class template `async_base` holds the caller's completion + // handler for us, and provides all of the boilerplate for forwarding + // the associated allocator and associated executor from the caller's + // handler to our operation. It also maintains a `net::executor_work_guard` + // for the executor associated with the stream. This work guard is + // inexpensive, and prevents the execution context from running out + // of work. It is usually necessary although rarely it can be skipped + // depending on the operation (this echo example needs it because it + // performs more than one asynchronous operation in a row). + // We declare this type alias to make the code easier to read. + + using base_type = beast::async_base< + handler_type, /*< The type of the completion handler obtained from the token >*/ + beast::executor_type /*< The type of executor used by the stream to dispatch asynchronous operations >*/ + >; + + // This nested class implements the echo composed operation as a + // stateful completion handler. We derive from `async_base` to + // take care of boilerplate and we derived from asio::coroutine to + // allow the reenter and yield keywords to work. + + struct echo_op : base_type, boost::asio::coroutine + { + AsyncStream& stream_; + DynamicBuffer& buffer_; + + echo_op( + AsyncStream& stream, + DynamicBuffer& buffer, + handler_type&& handler) + : base_type( + std::move(handler), /*< The `async_base` helper takes ownership of the handler, >*/ + stream.get_executor()) /*< and also needs to know which executor to use. >*/ + , stream_(stream) + , buffer_(buffer) + { + // Launch the operation directly from the constructor. We + // pass `false` for `cont` to indicate that the calling + // thread does not represent a continuation of our + // asynchronous control flow. + (*this)({}, 0, false); + } + + // If a newline is present in the buffer sequence, this function returns + // the number of characters from the beginning of the buffer up to the + // newline, including the newline character. Otherwise it returns zero. + + std::size_t + find_newline(typename DynamicBuffer::const_buffers_type const& buffers) + { + // The `buffers_iterator` class template provides random-access + // iterators into a buffer sequence. Use the standard algorithm + // to look for the new line if it exists. + + auto begin = net::buffers_iterator< + typename DynamicBuffer::const_buffers_type>::begin(buffers); + auto end = net::buffers_iterator< + typename DynamicBuffer::const_buffers_type>::end(buffers); + auto result = std::find(begin, end, '\n'); + + if(result == end) + return 0; // not found + + return result + 1 - begin; + } + + // This is the entry point of our completion handler. Every time an + // asynchronous operation completes, this function will be invoked. + + void + operator()( + beast::error_code ec, + std::size_t bytes_transferred = 0, + bool cont = true) /*< Second and subsequent invocations will seee `cont=true`. */ + { + // The `reenter` keyword transfers control to the last + // yield point, or to the beginning of the scope if + // this is the first time. + + reenter(*this) + { + for(;;) + { + std::size_t pos; + + // Search for a newline in the readable bytes of the buffer + pos = find_newline(buffer_.data()); + + // If we don't have the newline, then read more + if(pos == 0) + { + std::size_t bytes_to_read; + + // Determine the number of bytes to read, + // using available capacity in the buffer first. + + bytes_to_read = std::min( + std::max(512, // under 512 is too little, + buffer_.capacity() - buffer_.size()), + std::min(65536, // and over 65536 is too much. + buffer_.max_size() - buffer_.size())); + + // Read some data into our dynamic buffer_. We transfer + // ownership of the composed operation by using the + // `std::move(*this)` idiom. The `yield` keyword causes + // the function to return immediately after the initiating + // function returns. + + yield stream_.async_read_some( + buffer_.prepare(bytes_to_read), std::move(*this)); + + // After the `async_read_some` completes, control is + // transferred to this line by the `reenter` keyword. + + // Move the bytes read from the writable area to the + // readable area. + + buffer_.commit(bytes_transferred); + + // If an error occurs, deliver it to the caller's completion handler. + if(ec) + break; + + // Keep looping until we get the newline + continue; + } + + // We have our newline, so send the first `pos` bytes of the + // buffers. The function `buffers_prefix` returns the front part + // of the buffers we want. + + yield net::async_write(stream_, + beast::buffers_prefix(pos, buffer_.data()), std::move(*this)); + + // After the `async_write` completes, our completion handler will + // be invoked with the error and the number of bytes transferred, + // and the `reenter` statement above will cause control to jump + // to the following line. The variable `pos` is no longer valid + // (remember that we returned from the function using `yield` above) + // but we can use `bytes_transferred` to know how much of the buffer + // to consume. With "real" coroutines this will be easier and more + // natural. + + buffer_.consume(bytes_transferred); + + // The loop terminates here, and we will either deliver a + // successful result or an error to the caller's completion handler. + + break; + } + + // When a composed operation completes immediately, it must not + // directly invoke the completion handler otherwise it could + // lead to unfairness, starvation, or stack overflow. Therefore, + // if cont == false (meaning, that the call stack still includes + // the frame of the initiating function) then we need to use + // `net::post` to cause us to be called again after the initiating + // function. The function `async_base::invoke` takes care of + // calling the final completion handler, using post if the + // first argument is false, otherwise invoking it directly. + + this->complete(cont, ec); + } + } + }; + + // Create the composed operation and launch it. This is a constructor + // call followed by invocation of operator(). We use BOOST_ASIO_HANDLER_TYPE + // to convert the completion token into the correct handler type, + // allowing user-defined specializations of the async_result template + // to be used. + + echo_op(stream, buffer, std::move(init.completion_handler)); + + // This hook lets the caller see a return value when appropriate. + // For example this might return std::future if + // CompletionToken is net::use_future, or this might + // return an error code if CompletionToken specifies a coroutine. + + return init.result.get(); +} + +// Including this file undefines the macros used by the stackless fauxroutines. +#include + +//] + +struct move_only_handler +{ + move_only_handler() = default; + move_only_handler(move_only_handler&&) = default; + move_only_handler(move_only_handler const&) = delete; + + void operator()(beast::error_code ec) + { + if(ec) + std::cerr << ": " << ec.message() << std::endl; + } +}; + +int main(int argc, char** argv) +{ + if(argc != 3) + { + std::cerr + << "Usage: echo-op
\n" + << "Example:\n" + << " echo-op 0.0.0.0 8080\n"; + return EXIT_FAILURE; + } + + namespace net = boost::asio; + auto const address{net::ip::make_address(argv[1])}; + auto const port{static_cast(std::atoi(argv[2]))}; + + using endpoint_type = net::ip::tcp::endpoint; + + // Create a listening socket, accept a connection, perform + // the echo, and then shut everything down and exit. + net::io_context ioc; + net::ip::tcp::acceptor acceptor{ioc}; + endpoint_type ep{address, port}; + acceptor.open(ep.protocol()); + acceptor.set_option(net::socket_base::reuse_address(true)); + acceptor.bind(ep); + acceptor.listen(); + auto sock = acceptor.accept(); + beast::flat_buffer buffer; + async_echo(sock, buffer, move_only_handler{}); + ioc.run(); + return EXIT_SUCCESS; +} -- cgit v1.2.3