boost_1_45_0/libs/asio/example/porthopper/client.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //
 // client.cpp
 // ~~~~~~~~~~
 //
 // Copyright (c) 2003-2010 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/lambda/lambda.hpp>
 #include <boost/lambda/bind.hpp>
 #include <boost/lambda/if.hpp>
 #include <boost/shared_ptr.hpp>
 #include <algorithm>
 #include <cstdlib>
 #include <exception>
 #include <iostream>
 #include <string>
 #include "protocol.hpp"

 using namespace boost;
 using boost::asio::ip::tcp;
 using boost::asio::ip::udp;

 int main(int argc, char* argv[])
 {
   try
   {
     if (argc != 3)
     {
       std::cerr << "Usage: client <host> <port>\n";
       return 1;
     }
     using namespace std; // For atoi.
     std::string host_name = argv[1];
     std::string port = argv[2];

     boost::asio::io_service io_service;

     // Determine the location of the server.
     tcp::resolver resolver(io_service);
     tcp::resolver::query query(host_name, port);
     tcp::endpoint remote_endpoint = *resolver.resolve(query);

     // Establish the control connection to the server.
     tcp::socket control_socket(io_service);
     control_socket.connect(remote_endpoint);

     // Create a datagram socket to receive data from the server.
     boost::shared_ptr<udp::socket> data_socket(
         new udp::socket(io_service, udp::endpoint(udp::v4(), 0)));

     // Determine what port we will receive data on.
     udp::endpoint data_endpoint = data_socket->local_endpoint();

     // Ask the server to start sending us data.
     control_request start = control_request::start(data_endpoint.port());
     boost::asio::write(control_socket, start.to_buffers());

     unsigned long last_frame_number = 0;
     for (;;)
     {
       // Receive 50 messages on the current data socket.
       for (int i = 0; i < 50; ++i)
       {
         // Receive a frame from the server.
         frame f;
         data_socket->receive(f.to_buffers(), 0);
         if (f.number() > last_frame_number)
         {
           last_frame_number = f.number();
           std::cout << "\n" << f.payload();
         }
       }

       // Time to switch to a new socket. To ensure seamless handover we will
       // continue to receive packets using the old socket until data arrives on
       // the new one.
       std::cout << " Starting renegotiation";

       // Create the new data socket.
       boost::shared_ptr<udp::socket> new_data_socket(
           new udp::socket(io_service, udp::endpoint(udp::v4(), 0)));

       // Determine the new port we will use to receive data.
       udp::endpoint new_data_endpoint = new_data_socket->local_endpoint();

       // Ask the server to switch over to the new port.
       control_request change = control_request::change(
           data_endpoint.port(), new_data_endpoint.port());
       boost::system::error_code control_result;
       boost::asio::async_write(control_socket, change.to_buffers(),
           (
             lambda::var(control_result) = lambda::_1
           ));

       // Try to receive a frame from the server on the new data socket. If we
       // successfully receive a frame on this new data socket we can consider
       // the renegotation complete. In that case we will close the old data
       // socket, which will cause any outstanding receive operation on it to be
       // cancelled.
       frame f1;
       boost::system::error_code new_data_socket_result;
       new_data_socket->async_receive(f1.to_buffers(),
           (
             // Note: lambda::_1 is the first argument to the callback handler,
             // which in this case is the error code for the operation.
             lambda::var(new_data_socket_result) = lambda::_1,
             lambda::if_(!lambda::_1)
             [
               // We have successfully received a frame on the new data socket,
               // so we can close the old data socket. This will cancel any
               // outstanding receive operation on the old data socket.
               lambda::var(data_socket) = boost::shared_ptr<udp::socket>()
             ]
           ));

       // This loop will continue until we have successfully completed the
       // renegotiation (i.e. received a frame on the new data socket), or some
       // unrecoverable error occurs.
       bool done = false;
       while (!done)
       {
         // Even though we're performing a renegotation, we want to continue
         // receiving data as smoothly as possible. Therefore we will continue to
         // try to receive a frame from the server on the old data socket. If we
         // receive a frame on this socket we will interrupt the io_service,
         // print the frame, and resume waiting for the other operations to
         // complete.
         frame f2;
         done = true; // Let's be optimistic.
         if (data_socket) // Might have been closed by new_data_socket's handler.
         {
           data_socket->async_receive(f2.to_buffers(), 0,
               (
                 lambda::if_(!lambda::_1)
                 [
                   // We have successfully received a frame on the old data
                   // socket. Stop the io_service so that we can print it.
                   lambda::bind(&boost::asio::io_service::stop, &io_service),
                   lambda::var(done) = false
                 ]
               ));
         }

         // Run the operations in parallel. This will block until all operations
         // have finished, or until the io_service is interrupted. (No threads!)
         io_service.reset();
         io_service.run();

         // If the io_service.run() was interrupted then we have received a frame
         // on the old data socket. We need to keep waiting for the renegotation
         // operations to complete.
         if (!done)
         {
           if (f2.number() > last_frame_number)
           {
             last_frame_number = f2.number();
             std::cout << "\n" << f2.payload();
           }
         }
       }

       // Since the loop has finished, we have either successfully completed
       // the renegotation, or an error has occurred. First we'll check for
       // errors.
       if (control_result)
         throw boost::system::system_error(control_result);
       if (new_data_socket_result)
         throw boost::system::system_error(new_data_socket_result);

       // If we get here it means we have successfully started receiving data on
       // the new data socket. This new data socket will be used from now on
       // (until the next time we renegotiate).
       std::cout << " Renegotiation complete";
       data_socket = new_data_socket;
       data_endpoint = new_data_endpoint;
       if (f1.number() > last_frame_number)
       {
         last_frame_number = f1.number();
         std::cout << "\n" << f1.payload();
       }
     }
   }
   catch (std::exception& e)
   {
     std::cerr << "Exception: " << e.what() << std::endl;
   }

   return 0;
 }
	//
	// client.cpp
	// ~~~~~~~~~~
	//
	// Copyright (c) 2003-2010 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/lambda/lambda.hpp>
	#include <boost/lambda/bind.hpp>
	#include <boost/lambda/if.hpp>
	#include <boost/shared_ptr.hpp>
	#include <algorithm>
	#include <cstdlib>
	#include <exception>
	#include <iostream>
	#include <string>
	#include "protocol.hpp"

	using namespace boost;
	using boost::asio::ip::tcp;
	using boost::asio::ip::udp;

	int main(int argc, char* argv[])
	{
	try
	{
	if (argc != 3)
	{
	std::cerr << "Usage: client <host> <port>\n";
	return 1;
	}
	using namespace std; // For atoi.
	std::string host_name = argv[1];
	std::string port = argv[2];

	boost::asio::io_service io_service;

	// Determine the location of the server.
	tcp::resolver resolver(io_service);
	tcp::resolver::query query(host_name, port);
	tcp::endpoint remote_endpoint = *resolver.resolve(query);

	// Establish the control connection to the server.
	tcp::socket control_socket(io_service);
	control_socket.connect(remote_endpoint);

	// Create a datagram socket to receive data from the server.
	boost::shared_ptr<udp::socket> data_socket(
	new udp::socket(io_service, udp::endpoint(udp::v4(), 0)));

	// Determine what port we will receive data on.
	udp::endpoint data_endpoint = data_socket->local_endpoint();

	// Ask the server to start sending us data.
	control_request start = control_request::start(data_endpoint.port());
	boost::asio::write(control_socket, start.to_buffers());

	unsigned long last_frame_number = 0;
	for (;;)
	{
	// Receive 50 messages on the current data socket.
	for (int i = 0; i < 50; ++i)
	{
	// Receive a frame from the server.
	frame f;
	data_socket->receive(f.to_buffers(), 0);
	if (f.number() > last_frame_number)
	{
	last_frame_number = f.number();
	std::cout << "\n" << f.payload();
	}
	}

	// Time to switch to a new socket. To ensure seamless handover we will
	// continue to receive packets using the old socket until data arrives on
	// the new one.
	std::cout << " Starting renegotiation";

	// Create the new data socket.
	boost::shared_ptr<udp::socket> new_data_socket(
	new udp::socket(io_service, udp::endpoint(udp::v4(), 0)));

	// Determine the new port we will use to receive data.
	udp::endpoint new_data_endpoint = new_data_socket->local_endpoint();

	// Ask the server to switch over to the new port.
	control_request change = control_request::change(
	data_endpoint.port(), new_data_endpoint.port());
	boost::system::error_code control_result;
	boost::asio::async_write(control_socket, change.to_buffers(),
	(
	lambda::var(control_result) = lambda::_1
	));

	// Try to receive a frame from the server on the new data socket. If we
	// successfully receive a frame on this new data socket we can consider
	// the renegotation complete. In that case we will close the old data
	// socket, which will cause any outstanding receive operation on it to be
	// cancelled.
	frame f1;
	boost::system::error_code new_data_socket_result;
	new_data_socket->async_receive(f1.to_buffers(),
	(
	// Note: lambda::_1 is the first argument to the callback handler,
	// which in this case is the error code for the operation.
	lambda::var(new_data_socket_result) = lambda::_1,
	lambda::if_(!lambda::_1)
	[
	// We have successfully received a frame on the new data socket,
	// so we can close the old data socket. This will cancel any
	// outstanding receive operation on the old data socket.
	lambda::var(data_socket) = boost::shared_ptr<udp::socket>()
	]
	));

	// This loop will continue until we have successfully completed the
	// renegotiation (i.e. received a frame on the new data socket), or some
	// unrecoverable error occurs.
	bool done = false;
	while (!done)
	{
	// Even though we're performing a renegotation, we want to continue
	// receiving data as smoothly as possible. Therefore we will continue to
	// try to receive a frame from the server on the old data socket. If we
	// receive a frame on this socket we will interrupt the io_service,
	// print the frame, and resume waiting for the other operations to
	// complete.
	frame f2;
	done = true; // Let's be optimistic.
	if (data_socket) // Might have been closed by new_data_socket's handler.
	{
	data_socket->async_receive(f2.to_buffers(), 0,
	(
	lambda::if_(!lambda::_1)
	[
	// We have successfully received a frame on the old data
	// socket. Stop the io_service so that we can print it.
	lambda::bind(&boost::asio::io_service::stop, &io_service),
	lambda::var(done) = false
	]
	));
	}

	// Run the operations in parallel. This will block until all operations
	// have finished, or until the io_service is interrupted. (No threads!)
	io_service.reset();
	io_service.run();

	// If the io_service.run() was interrupted then we have received a frame
	// on the old data socket. We need to keep waiting for the renegotation
	// operations to complete.
	if (!done)
	{
	if (f2.number() > last_frame_number)
	{
	last_frame_number = f2.number();
	std::cout << "\n" << f2.payload();
	}
	}
	}

	// Since the loop has finished, we have either successfully completed
	// the renegotation, or an error has occurred. First we'll check for
	// errors.
	if (control_result)
	throw boost::system::system_error(control_result);
	if (new_data_socket_result)
	throw boost::system::system_error(new_data_socket_result);

	// If we get here it means we have successfully started receiving data on
	// the new data socket. This new data socket will be used from now on
	// (until the next time we renegotiate).
	std::cout << " Renegotiation complete";
	data_socket = new_data_socket;
	data_endpoint = new_data_endpoint;
	if (f1.number() > last_frame_number)
	{
	last_frame_number = f1.number();
	std::cout << "\n" << f1.payload();
	}
	}
	}
	catch (std::exception& e)
	{
	std::cerr << "Exception: " << e.what() << std::endl;
	}

	return 0;
	}