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1 //
2 // composed_6.cpp
3 // ~~~~~~~~~~~~~~
4 //
5 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
6 //
7 // Distributed under the Boost Software License, Version 1.0. (See accompanying
8 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
9 //
10 
11 #include <boost/asio/executor_work_guard.hpp>
12 #include <boost/asio/io_context.hpp>
13 #include <boost/asio/ip/tcp.hpp>
14 #include <boost/asio/steady_timer.hpp>
15 #include <boost/asio/use_future.hpp>
16 #include <boost/asio/write.hpp>
17 #include <functional>
18 #include <iostream>
19 #include <memory>
20 #include <sstream>
21 #include <string>
22 #include <type_traits>
23 #include <utility>
24 
25 using boost::asio::ip::tcp;
26 
27 // NOTE: This example requires the new boost::asio::async_initiate function. For
28 // an example that works with the Networking TS style of completion tokens,
29 // please see an older version of asio.
30 
31 //------------------------------------------------------------------------------
32 
33 // This composed operation shows composition of multiple underlying operations.
34 // It automatically serialises a message, using its I/O streams insertion
35 // operator, before sending it N times on the socket. To do this, it must
36 // allocate a buffer for the encoded message and ensure this buffer's validity
37 // until all underlying async_write operation complete. A one second delay is
38 // inserted prior to each write operation, using a steady_timer.
39 
40 // In addition to determining the mechanism by which an asynchronous operation
41 // delivers its result, a completion token also determines the time when the
42 // operation commences. For example, when the completion token is a simple
43 // callback the operation commences before the initiating function returns.
44 // However, if the completion token's delivery mechanism uses a future, we
45 // might instead want to defer initiation of the operation until the returned
46 // future object is waited upon.
47 //
48 // To enable this, when implementing an asynchronous operation we must package
49 // the initiation step as a function object.
50 struct async_write_message_initiation
51 {
52   // The initiation function object's call operator is passed the concrete
53   // completion handler produced by the completion token. This completion
54   // handler matches the asynchronous operation's completion handler signature,
55   // which in this example is:
56   //
57   //   void(boost::system::error_code error)
58   //
59   // The initiation function object also receives any additional arguments
60   // required to start the operation. (Note: We could have instead passed these
61   // arguments as members in the initiaton function object. However, we should
62   // prefer to propagate them as function call arguments as this allows the
63   // completion token to optimise how they are passed. For example, a lazy
64   // future which defers initiation would need to make a decay-copy of the
65   // arguments, but when using a simple callback the arguments can be trivially
66   // forwarded straight through.)
67   template <typename CompletionHandler>
operator ()async_write_message_initiation68   void operator()(CompletionHandler&& completion_handler, tcp::socket& socket,
69       std::unique_ptr<std::string> encoded_message, std::size_t repeat_count,
70       std::unique_ptr<boost::asio::steady_timer> delay_timer) const
71   {
72     // In this example, the composed operation's intermediate completion
73     // handler is implemented as a hand-crafted function object.
74     struct intermediate_completion_handler
75     {
76       // The intermediate completion handler holds a reference to the socket as
77       // it is used for multiple async_write operations, as well as for
78       // obtaining the I/O executor (see get_executor below).
79       tcp::socket& socket_;
80 
81       // The allocated buffer for the encoded message. The std::unique_ptr
82       // smart pointer is move-only, and as a consequence our intermediate
83       // completion handler is also move-only.
84       std::unique_ptr<std::string> encoded_message_;
85 
86       // The repeat count remaining.
87       std::size_t repeat_count_;
88 
89       // A steady timer used for introducing a delay.
90       std::unique_ptr<boost::asio::steady_timer> delay_timer_;
91 
92       // To manage the cycle between the multiple underlying asychronous
93       // operations, our intermediate completion handler is implemented as a
94       // state machine.
95       enum { starting, waiting, writing } state_;
96 
97       // As our composed operation performs multiple underlying I/O operations,
98       // we should maintain a work object against the I/O executor. This tells
99       // the I/O executor that there is still more work to come in the future.
100       typename std::decay<decltype(boost::asio::prefer(
101             std::declval<tcp::socket::executor_type>(),
102             boost::asio::execution::outstanding_work.tracked))>::type io_work_;
103 
104       // The user-supplied completion handler, called once only on completion
105       // of the entire composed operation.
106       typename std::decay<CompletionHandler>::type handler_;
107 
108       // By having a default value for the second argument, this function call
109       // operator matches the completion signature of both the async_write and
110       // steady_timer::async_wait operations.
111       void operator()(const boost::system::error_code& error, std::size_t = 0)
112       {
113         if (!error)
114         {
115           switch (state_)
116           {
117           case starting:
118           case writing:
119             if (repeat_count_ > 0)
120             {
121               --repeat_count_;
122               state_ = waiting;
123               delay_timer_->expires_after(std::chrono::seconds(1));
124               delay_timer_->async_wait(std::move(*this));
125               return; // Composed operation not yet complete.
126             }
127             break; // Composed operation complete, continue below.
128           case waiting:
129             state_ = writing;
130             boost::asio::async_write(socket_,
131                 boost::asio::buffer(*encoded_message_), std::move(*this));
132             return; // Composed operation not yet complete.
133           }
134         }
135 
136         // This point is reached only on completion of the entire composed
137         // operation.
138 
139         // Deallocate the encoded message before calling the user-supplied
140         // completion handler.
141         encoded_message_.reset();
142 
143         // Call the user-supplied handler with the result of the operation.
144         handler_(error);
145       }
146 
147       // It is essential to the correctness of our composed operation that we
148       // preserve the executor of the user-supplied completion handler. With a
149       // hand-crafted function object we can do this by defining a nested type
150       // executor_type and member function get_executor. These obtain the
151       // completion handler's associated executor, and default to the I/O
152       // executor - in this case the executor of the socket - if the completion
153       // handler does not have its own.
154       using executor_type = boost::asio::associated_executor_t<
155           typename std::decay<CompletionHandler>::type,
156           tcp::socket::executor_type>;
157 
158       executor_type get_executor() const noexcept
159       {
160         return boost::asio::get_associated_executor(
161             handler_, socket_.get_executor());
162       }
163 
164       // Although not necessary for correctness, we may also preserve the
165       // allocator of the user-supplied completion handler. This is achieved by
166       // defining a nested type allocator_type and member function
167       // get_allocator. These obtain the completion handler's associated
168       // allocator, and default to std::allocator<void> if the completion
169       // handler does not have its own.
170       using allocator_type = boost::asio::associated_allocator_t<
171           typename std::decay<CompletionHandler>::type,
172           std::allocator<void>>;
173 
174       allocator_type get_allocator() const noexcept
175       {
176         return boost::asio::get_associated_allocator(
177             handler_, std::allocator<void>{});
178       }
179     };
180 
181     // Initiate the underlying async_write operation using our intermediate
182     // completion handler.
183     auto encoded_message_buffer = boost::asio::buffer(*encoded_message);
184     boost::asio::async_write(socket, encoded_message_buffer,
185         intermediate_completion_handler{
186           socket, std::move(encoded_message),
187           repeat_count, std::move(delay_timer),
188           intermediate_completion_handler::starting,
189           boost::asio::prefer(socket.get_executor(),
190               boost::asio::execution::outstanding_work.tracked),
191           std::forward<CompletionHandler>(completion_handler)});
192   }
193 };
194 
195 template <typename T, typename CompletionToken>
async_write_messages(tcp::socket & socket,const T & message,std::size_t repeat_count,CompletionToken && token)196 auto async_write_messages(tcp::socket& socket,
197     const T& message, std::size_t repeat_count,
198     CompletionToken&& token)
199   // The return type of the initiating function is deduced from the combination
200   // of CompletionToken type and the completion handler's signature. When the
201   // completion token is a simple callback, the return type is always void.
202   // In this example, when the completion token is boost::asio::yield_context
203   // (used for stackful coroutines) the return type would be also be void, as
204   // there is no non-error argument to the completion handler. When the
205   // completion token is boost::asio::use_future it would be std::future<void>.
206   -> typename boost::asio::async_result<
207     typename std::decay<CompletionToken>::type,
208     void(boost::system::error_code)>::return_type
209 {
210   // Encode the message and copy it into an allocated buffer. The buffer will
211   // be maintained for the lifetime of the composed asynchronous operation.
212   std::ostringstream os;
213   os << message;
214   std::unique_ptr<std::string> encoded_message(new std::string(os.str()));
215 
216   // Create a steady_timer to be used for the delay between messages.
217   std::unique_ptr<boost::asio::steady_timer> delay_timer(
218       new boost::asio::steady_timer(socket.get_executor()));
219 
220   // The boost::asio::async_initiate function takes:
221   //
222   // - our initiation function object,
223   // - the completion token,
224   // - the completion handler signature, and
225   // - any additional arguments we need to initiate the operation.
226   //
227   // It then asks the completion token to create a completion handler (i.e. a
228   // callback) with the specified signature, and invoke the initiation function
229   // object with this completion handler as well as the additional arguments.
230   // The return value of async_initiate is the result of our operation's
231   // initiating function.
232   //
233   // Note that we wrap non-const reference arguments in std::reference_wrapper
234   // to prevent incorrect decay-copies of these objects.
235   return boost::asio::async_initiate<
236     CompletionToken, void(boost::system::error_code)>(
237       async_write_message_initiation(), token, std::ref(socket),
238       std::move(encoded_message), repeat_count, std::move(delay_timer));
239 }
240 
241 //------------------------------------------------------------------------------
242 
test_callback()243 void test_callback()
244 {
245   boost::asio::io_context io_context;
246 
247   tcp::acceptor acceptor(io_context, {tcp::v4(), 55555});
248   tcp::socket socket = acceptor.accept();
249 
250   // Test our asynchronous operation using a lambda as a callback.
251   async_write_messages(socket, "Testing callback\r\n", 5,
252       [](const boost::system::error_code& error)
253       {
254         if (!error)
255         {
256           std::cout << "Messages sent\n";
257         }
258         else
259         {
260           std::cout << "Error: " << error.message() << "\n";
261         }
262       });
263 
264   io_context.run();
265 }
266 
267 //------------------------------------------------------------------------------
268 
test_future()269 void test_future()
270 {
271   boost::asio::io_context io_context;
272 
273   tcp::acceptor acceptor(io_context, {tcp::v4(), 55555});
274   tcp::socket socket = acceptor.accept();
275 
276   // Test our asynchronous operation using the use_future completion token.
277   // This token causes the operation's initiating function to return a future,
278   // which may be used to synchronously wait for the result of the operation.
279   std::future<void> f = async_write_messages(
280       socket, "Testing future\r\n", 5, boost::asio::use_future);
281 
282   io_context.run();
283 
284   try
285   {
286     // Get the result of the operation.
287     f.get();
288     std::cout << "Messages sent\n";
289   }
290   catch (const std::exception& e)
291   {
292     std::cout << "Error: " << e.what() << "\n";
293   }
294 }
295 
296 //------------------------------------------------------------------------------
297 
main()298 int main()
299 {
300   test_callback();
301   test_future();
302 }
303