jacknlliu/listener.cpp

## listener.cpp
#include "ros/ros.h"
#include "std_msgs/String.h"

/**
 * This tutorial demonstrates simple receipt of messages over the ROS system.
 */
void chatterCallback(const std_msgs::String::ConstPtr& msg)
{
  ROS_INFO("I heard: [%s]", msg->data.c_str());
}

int main(int argc, char **argv)
{
  /**
   * The ros::init() function needs to see argc and argv so that it can perform
   * any ROS arguments and name remapping that were provided at the command line.
   * For programmatic remappings you can use a different version of init() which takes
   * remappings directly, but for most command-line programs, passing argc and argv is
   * the easiest way to do it.  The third argument to init() is the name of the node.
   *
   * You must call one of the versions of ros::init() before using any other
   * part of the ROS system.
   */
  ros::init(argc, argv, "listener");

  /**
   * NodeHandle is the main access point to communications with the ROS system.
   * The first NodeHandle constructed will fully initialize this node, and the last
   * NodeHandle destructed will close down the node.
   */
  ros::NodeHandle n;

  /**
   * The subscribe() call is how you tell ROS that you want to receive messages
   * on a given topic.  This invokes a call to the ROS
   * master node, which keeps a registry of who is publishing and who
   * is subscribing.  Messages are passed to a callback function, here
   * called chatterCallback.  subscribe() returns a Subscriber object that you
   * must hold on to until you want to unsubscribe.  When all copies of the Subscriber
   * object go out of scope, this callback will automatically be unsubscribed from
   * this topic.
   *
   * The second parameter to the subscribe() function is the size of the message
   * queue.  If messages are arriving faster than they are being processed, this
   * is the number of messages that will be buffered up before beginning to throw
   * away the oldest ones.
   */
  ros::Subscriber sub = n.subscribe("chatter", 1000, chatterCallback);

  /**
   * ros::spin() will enter a loop, pumping callbacks.  With this version, all
   * callbacks will be called from within this thread (the main one).  ros::spin()
   * will exit when Ctrl-C is pressed, or the node is shutdown by the master.
   */
  ros::spin();

  return 0;
}

## talker.cpp
#include "ros/ros.h"
#include "std_msgs/String.h"

#include <sstream>

/**
 * This tutorial demonstrates simple sending of messages over the ROS system.
 */
int main(int argc, char **argv)
{
  /**
   * The ros::init() function needs to see argc and argv so that it can perform
   * any ROS arguments and name remapping that were provided at the command line.
   * For programmatic remappings you can use a different version of init() which takes
   * remappings directly, but for most command-line programs, passing argc and argv is
   * the easiest way to do it.  The third argument to init() is the name of the node.
   *
   * You must call one of the versions of ros::init() before using any other
   * part of the ROS system.
   */
  ros::init(argc, argv, "talker");

  /**
   * NodeHandle is the main access point to communications with the ROS system.
   * The first NodeHandle constructed will fully initialize this node, and the last
   * NodeHandle destructed will close down the node.
   */
  ros::NodeHandle n;

  /**
   * The advertise() function is how you tell ROS that you want to
   * publish on a given topic name. This invokes a call to the ROS
   * master node, which keeps a registry of who is publishing and who
   * is subscribing. After this advertise() call is made, the master
   * node will notify anyone who is trying to subscribe to this topic name,
   * and they will in turn negotiate a peer-to-peer connection with this
   * node.  advertise() returns a Publisher object which allows you to
   * publish messages on that topic through a call to publish().  Once
   * all copies of the returned Publisher object are destroyed, the topic
   * will be automatically unadvertised.
   *
   * The second parameter to advertise() is the size of the message queue
   * used for publishing messages.  If messages are published more quickly
   * than we can send them, the number here specifies how many messages to
   * buffer up before throwing some away.
   */
  ros::Publisher chatter_pub = n.advertise<std_msgs::String>("chatter", 1000);

  ros::Rate loop_rate(10);

  /**
   * A count of how many messages we have sent. This is used to create
   * a unique string for each message.
   */
  int count = 0;
  while (ros::ok())
  {
    /**
     * This is a message object. You stuff it with data, and then publish it.
     */
    std_msgs::String msg;

    std::stringstream ss;
    ss << "hello world " << count;
    msg.data = ss.str();

    ROS_INFO("%s", msg.data.c_str());

    /**
     * The publish() function is how you send messages. The parameter
     * is the message object. The type of this object must agree with the type
     * given as a template parameter to the advertise<>() call, as was done
     * in the constructor above.
     */
    chatter_pub.publish(msg);

    ros::spinOnce();

    loop_rate.sleep();
    ++count;
  }


  return 0;
}
	#include "ros/ros.h"
	#include "std_msgs/String.h"

	/**
	* This tutorial demonstrates simple receipt of messages over the ROS system.
	*/
	void chatterCallback(const std_msgs::String::ConstPtr& msg)
	{
	ROS_INFO("I heard: [%s]", msg->data.c_str());
	}

	int main(int argc, char **argv)
	{
	/**
	* The ros::init() function needs to see argc and argv so that it can perform
	* any ROS arguments and name remapping that were provided at the command line.
	* For programmatic remappings you can use a different version of init() which takes
	* remappings directly, but for most command-line programs, passing argc and argv is
	* the easiest way to do it. The third argument to init() is the name of the node.
	*
	* You must call one of the versions of ros::init() before using any other
	* part of the ROS system.
	*/
	ros::init(argc, argv, "listener");

	/**
	* NodeHandle is the main access point to communications with the ROS system.
	* The first NodeHandle constructed will fully initialize this node, and the last
	* NodeHandle destructed will close down the node.
	*/
	ros::NodeHandle n;

	/**
	* The subscribe() call is how you tell ROS that you want to receive messages
	* on a given topic. This invokes a call to the ROS
	* master node, which keeps a registry of who is publishing and who
	* is subscribing. Messages are passed to a callback function, here
	* called chatterCallback. subscribe() returns a Subscriber object that you
	* must hold on to until you want to unsubscribe. When all copies of the Subscriber
	* object go out of scope, this callback will automatically be unsubscribed from
	* this topic.
	*
	* The second parameter to the subscribe() function is the size of the message
	* queue. If messages are arriving faster than they are being processed, this
	* is the number of messages that will be buffered up before beginning to throw
	* away the oldest ones.
	*/
	ros::Subscriber sub = n.subscribe("chatter", 1000, chatterCallback);

	/**
	* ros::spin() will enter a loop, pumping callbacks. With this version, all
	* callbacks will be called from within this thread (the main one). ros::spin()
	* will exit when Ctrl-C is pressed, or the node is shutdown by the master.
	*/
	ros::spin();

	return 0;
	}
	#include "ros/ros.h"
	#include "std_msgs/String.h"

	#include <sstream>

	/**
	* This tutorial demonstrates simple sending of messages over the ROS system.
	*/
	int main(int argc, char **argv)
	{
	/**
	* The ros::init() function needs to see argc and argv so that it can perform
	* any ROS arguments and name remapping that were provided at the command line.
	* For programmatic remappings you can use a different version of init() which takes
	* remappings directly, but for most command-line programs, passing argc and argv is
	* the easiest way to do it. The third argument to init() is the name of the node.
	*
	* You must call one of the versions of ros::init() before using any other
	* part of the ROS system.
	*/
	ros::init(argc, argv, "talker");

	/**
	* NodeHandle is the main access point to communications with the ROS system.
	* The first NodeHandle constructed will fully initialize this node, and the last
	* NodeHandle destructed will close down the node.
	*/
	ros::NodeHandle n;

	/**
	* The advertise() function is how you tell ROS that you want to
	* publish on a given topic name. This invokes a call to the ROS
	* master node, which keeps a registry of who is publishing and who
	* is subscribing. After this advertise() call is made, the master
	* node will notify anyone who is trying to subscribe to this topic name,
	* and they will in turn negotiate a peer-to-peer connection with this
	* node. advertise() returns a Publisher object which allows you to
	* publish messages on that topic through a call to publish(). Once
	* all copies of the returned Publisher object are destroyed, the topic
	* will be automatically unadvertised.
	*
	* The second parameter to advertise() is the size of the message queue
	* used for publishing messages. If messages are published more quickly
	* than we can send them, the number here specifies how many messages to
	* buffer up before throwing some away.
	*/
	ros::Publisher chatter_pub = n.advertise<std_msgs::String>("chatter", 1000);

	ros::Rate loop_rate(10);

	/**
	* A count of how many messages we have sent. This is used to create
	* a unique string for each message.
	*/
	int count = 0;
	while (ros::ok())
	{
	/**
	* This is a message object. You stuff it with data, and then publish it.
	*/
	std_msgs::String msg;

	std::stringstream ss;
	ss << "hello world " << count;
	msg.data = ss.str();

	ROS_INFO("%s", msg.data.c_str());

	/**
	* The publish() function is how you send messages. The parameter
	* is the message object. The type of this object must agree with the type
	* given as a template parameter to the advertise<>() call, as was done
	* in the constructor above.
	*/
	chatter_pub.publish(msg);

	ros::spinOnce();

	loop_rate.sleep();
	++count;
	}


	return 0;
	}