Exemplo n.º 1
0
int main(int argc, char** argv)
{
  Aria::init();
  ArArgumentParser parser(&argc, argv);
  parser.loadDefaultArguments();
  ArRobot robot;
  ArSonarDevice sonar;

  // Connect to the robot, get some initial data from it such as type and name,
  // and then load parameter files for this robot.
  ArRobotConnector robotConnector(&parser, &robot);
  if(!robotConnector.connectRobot())
  {
    ArLog::log(ArLog::Terse, "actionExample: Could not connect to the robot.");
    if(parser.checkHelpAndWarnUnparsed())
    {
        // -help not given
        Aria::logOptions();
        Aria::exit(1);
    }
  }

  if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
  {
    Aria::logOptions();
    Aria::exit(1);
  }

  ArLog::log(ArLog::Normal, "actionExample: Connected to robot.");

  // Create instances of the actions defined above, plus ArActionStallRecover, 
  // a predefined action from Aria.
  ActionGo go(500, 350);
  ActionTurn turn(400, 10);
  ArActionStallRecover recover;

    
  // Add the range device to the robot. You should add all the range 
  // devices and such before you add actions
  robot.addRangeDevice(&sonar);

 
  // Add our actions in order. The second argument is the priority, 
  // with higher priority actions going first, and possibly pre-empting lower
  // priority actions.
  robot.addAction(&recover, 100);
  robot.addAction(&go, 50);
  robot.addAction(&turn, 49);

  // Enable the motors, disable amigobot sounds
  robot.enableMotors();

  // Run the robot processing cycle.
  // 'true' means to return if it loses connection,
  // after which we exit the program.
  robot.run(true);
  
  Aria::exit(0);
}
Exemplo n.º 2
0
int main (int argc, char** argv) {
	
	Aria::init();
	Arnl::init();
	ArRobot robot;
	ArArgumentParser parser(&argc, argv);
	parser.loadDefaultArguments();
	ArRobotConnector robotConnector(&parser, &robot);
	//ArAnalogGyro gyro = new 
	ArAnalogGyro gyro(&robot);
	if (!robotConnector.connectRobot()) {
		ArLog::log(ArLog::Terse, "Could not connect to the robot.");
		if(parser.checkHelpAndWarnUnparsed())
		{
			// -help not given, just exit.
			Aria::logOptions();
			Aria::exit(1);
			return 1;
		}
	}
	
	ArSonarDevice sonarDev;
	robot.addRangeDevice(&sonarDev);
	
	robot.runAsync(true);
	
	ArMap map("office.map");
	// set it up to ignore empty file names (otherwise if a configuration omits
	// the map file, the whole configuration change will fail)
	map.setIgnoreEmptyFileName(true);
	// ignore the case, so that if someone is using MobileEyes or
	// MobilePlanner from Windows and changes the case on a map name,
	// it will still work.
	map.setIgnoreCase(true);
	
	ArSonarLocalizationTask locTask(&robot, &sonarDev, &map);
	
	locTask.localizeRobotAtHomeBlocking();
	
	robot.runAsync(true);
	robot.enableMotors();
	//robot.lock();
	robot.setVel(200);
	//robot.unlock();
	ArPose pose;
	locTask.forceUpdatePose(pose);
	while(true) {
	//while (robot.blockingConnect()){
		//robot.lock();
		//ArPose pose  = robot.getPose();
		//pose.setX(100);
		//robot.moveTo(pose);
		//t = robot.getLastOdometryTime();
		//int a = interp.getPose(t, &pose);
		ArLog::log(ArLog::Normal, "x = %f \t y = %f\n", pose.getX(), pose.getY());
		//robot.unlock();
	} 
}
Exemplo n.º 3
0
int main(int argc, char **argv)
{
  Aria::init();
  ArRobot robot;

  ArSerialConnection serialConnection;
  ArTcpConnection tcpConnection;
    
  if (tcpConnection.open("localhost", 8101)) {
    robot.setDeviceConnection(&tcpConnection);
  } else {
    serialConnection.setPort("/dev/ttyUSB0");
    robot.setDeviceConnection(&serialConnection);
  }
  robot.blockingConnect();
   
  printf("Setting robot to run async\n");
  robot.runAsync(false);

  printf("Turning off sound\n");
  robot.comInt(ArCommands::SOUNDTOG, 0);

  printf("Enabling motors\n");
  robot.enableMotors();

  // add a set of actions that combine together to effect the wander behavior
  /*ArActionStallRecover recover;
  ArActionBumpers bumpers;
  ArActionAvoidFront avoidFrontNear("Avoid Front Near", 225, 0);
  ArActionAvoidFront avoidFrontFar;
  ArActionConstantVelocity constantVelocity("Constant Velocity", 400);
  robot.addAction(&recover, 100);
  robot.addAction(&bumpers, 75);
  robot.addAction(&avoidFrontNear, 50);
  robot.addAction(&avoidFrontFar, 49);
  robot.addAction(&constantVelocity, 25);*/

  printf("Locking\n");
  robot.lock();
  robot.setVel(100.0);
  robot.unlock();
  printf("Sleeping\n");
  ArUtil::sleep(3*1000);
  printf("Awake\n");

  
  // wait for robot task loop to end before exiting the program
  //while (true);
  //robot.waitForRunExit();
  

  Aria::exit(0);
  return 0;
}
Exemplo n.º 4
0
bool RosAriaNode::enable_motors_cb(std_srvs::Empty::Request& request, std_srvs::Empty::Response& response)
{
    ROS_INFO("RosAria: Enable motors request.");
    robot->lock();
    if(robot->isEStopPressed())
        ROS_WARN("RosAria: Warning: Enable motors requested, but robot also has E-Stop button pressed. Motors will not enable.");
    robot->enableMotors();
    robot->unlock();
	// todo could wait and see if motors do become enabled, and send a response with an error flag if not
    return true;
}
Exemplo n.º 5
0
int main(int argc, char** argv)
{
  Aria::init();

  ArSimpleConnector conn(&argc, argv);
  ArRobot robot;
  ArSonarDevice sonar;

  // Create instances of the actions defined above, plus ArActionStallRecover, 
  // a predefined action from Aria.
  ActionGo go(500, 350);
  ActionTurn turn(400, 10);
  ArActionStallRecover recover;

    
  // Parse all command-line arguments
  if(!Aria::parseArgs())
  {
    Aria::logOptions();
    return 1;
  }
  
  // Connect to the robot
  if(!conn.connectRobot(&robot))
  {
    ArLog::log(ArLog::Terse, "actionExample: Could not connect to robot! Exiting.");
    return 2;
  }

  // Add the range device to the robot. You should add all the range 
  // devices and such before you add actions
  robot.addRangeDevice(&sonar);

 
  // Add our actions in order. The second argument is the priority, 
  // with higher priority actions going first, and possibly pre-empting lower
  // priority actions.
  robot.addAction(&recover, 100);
  robot.addAction(&go, 50);
  robot.addAction(&turn, 49);

  // Enable the motors, disable amigobot sounds
  robot.enableMotors();

  // Run the robot processing cycle.
  // 'true' means to return if it loses connection,
  // after which we exit the program.
  robot.run(true);
  
  Aria::shutdown();
  return 0;
}
Exemplo n.º 6
0
void SetupRobot(void)
{
	puts("attempting to connect to robot");
	RobotConnectoin.setPort("COM8");
	RobotConnectoin.setBaud(9600);
	robot.setDeviceConnection(&RobotConnectoin);
	if(!robot.blockingConnect()){puts("not connected to robot");Aria::shutdown();}
	robot.addRangeDevice(&sonarDev);
	robot.addRangeDevice(&bumpers);
	robot.enableMotors();
	robot.enableSonar();
	robot.requestEncoderPackets();
	robot.setCycleChained(false);
//	robot.setRotVelMax(robot.getRotVelMax());
}
Exemplo n.º 7
0
int main (int argc, char** argv) {
	
	Aria::init();
	Arnl::init();
	ArRobot robot;
	ArArgumentParser parser(&argc, argv);
	parser.loadDefaultArguments();
	ArRobotConnector robotConnector(&parser, &robot);
	//ArAnalogGyro gyro = new 
	ArAnalogGyro gyro(&robot);
	if (!robotConnector.connectRobot()) {
		ArLog::log(ArLog::Terse, "Could not connect to the robot.");
		if(parser.checkHelpAndWarnUnparsed())
		{
			// -help not given, just exit.
			Aria::logOptions();
			Aria::exit(1);
			return 1;
		}
	}
	
	ArSonarDevice sonarDev;
	

//	robot.runAsync(true);
	
//	ArMap map("office.map");
	// set it up to ignore empty file names (otherwise if a configuration omits
	// the map file, the whole configuration change will fail)
//	map.setIgnoreEmptyFileName(true);
	// ignore the case, so that if someone is using MobileEyes or
	// MobilePlanner from Windows and changes the case on a map name,
	// it will still work.
//	map.setIgnoreCase(true);


	robot.runAsync(true);
	robot.enableMotors();
	robot.moveTo(ArPose(0,0,0));
	//robot.lock();
	robot.comInt(ArCommands::ENABLE, 1);
	robot.addRangeDevice(&sonarDev);
	//robot.unlock();
//	ArSonarLocalizationTask locTask(&robot, &sonarDev, &map);
<<<<<<< HEAD
int RosAriaNode::Setup()
{
	ArArgumentBuilder *args;

	args = new ArArgumentBuilder();
	args->add("-rp"); //pass robot's serial port to Aria
	args->add(serial_port.c_str());
	conn = new ArSimpleConnector(args);


	robot = new ArRobot();
	robot->setCycleTime(1);

	ArLog::init(ArLog::File, ArLog::Verbose, "aria.log", true);

	//parse all command-line arguments
	if (!Aria::parseArgs())
	{
		Aria::logOptions();
		return 1;
	}

	// Connect to the robot
	if (!conn->connectRobot(robot)) {
		ArLog::log(ArLog::Terse, "rotate: Could not connect to robot! Exiting.");
		return 1;
	}

	//Sonar sensor
	sonar.setMaxRange(Max_Range);
	robot->addRangeDevice(&sonar);
	robot->enableSonar();

	// Enable the motors
	robot->enableMotors();

	robot->runAsync(true);

	return 0;
}
Exemplo n.º 9
0
/*!
 * Sets up for path planning.
 *
 * @return true if successful.
 */
bool
Advanced::initializePathPlanningTask(void)
{
#ifdef SONARNL
  if(myRobot && mySonar && myMap)
    myPathPlanningTask = new ArPathPlanningTask(myRobot, mySonar,
                        myMap);
#else
  if(myRobot && mySick && mySonar && myMap)
    myPathPlanningTask = new ArPathPlanningTask(myRobot, mySick, mySonar,
                        myMap);
#endif

  if(!myPathPlanningTask){
    return false;
  }else{
    myRobot->lock();
    myRobot->enableMotors();
    myRobot->unlock();
    return true;
  }
}
Exemplo n.º 10
0
int main(int argc, char **argv)
{

//----------------------initialized robot server------------------------------------------
  Aria::init();
  Arnl::init();
  
  ArServerBase server;
	
//-----------------------------------------------------------------------------------
	VCCHandler ptz(&robot); 		//create keyboard for control vcc50i

	
	G_PTZHandler->reset();
	ArUtil::sleep(300);
	G_PTZHandler->panSlew(30);
//-----------------------------------------------------------------------------------

  argc = 2 ;

  argv[0] = "-map";
  argv[1] = "map20121111.map";
  
  // Parse the command line arguments.
  ArArgumentParser parser(&argc, argv);

  // Set up our simpleConnector
  ArSimpleConnector simpleConnector(&parser);

  // Set up our simpleOpener
  ArServerSimpleOpener simpleOpener(&parser);
  

//*******
  // Set up our client for the central server
//   ArClientSwitchManager clientSwitch(&server, &parser);
//************
  
  // Load default arguments for this computer (from /etc/Aria.args, environment
  // variables, and other places)
//   parser.loadDefaultArguments();

  // set up a gyro
  ArAnalogGyro gyro(&robot);
  //gyro.activate();
  // Parse arguments for the simple connector.
//   if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
//   {
//     ArLog::log(ArLog::Normal, "\nUsage: %s -map mapfilename\n", argv[0]);
//     Aria::logOptions();
//     Aria::exit(1);
//   }


  // The laser object, will be used if we have one


  // Add the laser to the robot
  robot.addRangeDevice(&sick);

  // Sonar, must be added to the robot, used by teleoperation and wander to
  // detect obstacles, and for localization if SONARNL
  ArSonarDevice sonarDev;

  // Add the sonar to the robot
  robot.addRangeDevice(&sonarDev);
  
  // Set up where we'll look for files
  char fileDir[1024];
  ArUtil::addDirectories(fileDir, sizeof(fileDir), "./", "maps");
  ArLog::log(ArLog::Normal, "Installation directory is: %s\nMaps directory is: %s\n", Aria::getDirectory(), fileDir);
  
  // Set up the map, this will look for files in the examples
  // directory (unless the file name starts with a /, \, or .
  // You can take out the 'fileDir' argument to look in the current directory
  // instead
  
  ArMap arMap(fileDir);
  // set it up to ignore empty file names (otherwise the parseFile
  // on the config will fail)
  arMap.setIgnoreEmptyFileName(true);
  
//********************************
//Localization
//********************************
  

  ArLocalizationManager locManager(&robot, &arMap);
  ArLog::log(ArLog::Normal, "Creating laser localization task");
  ArLocalizationTask locTask (&robot, &sick, &arMap);
  locManager.addLocalizationTask(&locTask);

  
//*******************************
//Path planning
//*******************************
  
  // Make the path task planning task
  ArPathPlanningTask pathTask(&robot, &sick, &sonarDev, &arMap);
  G_PathPlanning = &pathTask;
  // Set up things so data can be logged (only do it with the laser
  // since it can overrun a 9600 serial connection which the sonar is
  // more likely to have)
  ArDataLogger dataLogger(&robot);
  dataLogger.addToConfig(Aria::getConfig());

  
  
  
  // add our logging to the config
//   ArLog::addToConfig(Aria::getConfig());

  // First open the server 
  if (!simpleOpener.open(&server, fileDir, 240))
  {
    if (simpleOpener.wasUserFileBad())
      ArLog::log(ArLog::Normal, "Bad user file");
    else
      ArLog::log(ArLog::Normal, "Could not open server port");
    exit(2);
  }

  // Connect the robot
  if (!simpleConnector.connectRobot(&robot))
  {
    ArLog::log(ArLog::Normal, "Could not connect to robot... exiting");
    Aria::exit(3);
  }

  
//-----------------------------------------------
//**************************
  // Set up a class that'll put the movement and gyro parameters into ArConfig
  ArRobotConfig robotConfig(&robot);
  robotConfig.addAnalogGyro(&gyro);
//*****************************
  
  
  robot.enableMotors();
  robot.clearDirectMotion();

  // if we are connected to a simulator, reset it to its start position
  robot.comInt(ArCommands::RESETSIMTOORIGIN, 1);
  robot.moveTo(ArPose(0,0,0));


  // Set up laser using connector (command line arguments, etc.)
   simpleConnector.setupLaser(&sick);

  // Start the robot thread.
  robot.runAsync(true);
  
  // Start the laser thread.
  sick.runAsync();

  // Try to connect the laser
  if (!sick.blockingConnect())
    ArLog::log(ArLog::Normal, "Warning: Couldn't connect to SICK laser, it won't be used");
  else
    ArLog::log(ArLog::Normal, "Connected to laser.");

//***************************************
  // Add additional range devices to the robot and path planning task.
  // IRs if the robot has them.
  robot.lock();
//   ArIRs irs;
//   robot.addRangeDevice(&irs);
//   pathTask.addRangeDevice(&irs, ArPathPlanningTask::CURRENT);
//******************************************


  // Forbidden regions from the map
  ArForbiddenRangeDevice forbidden(&arMap);
  robot.addRangeDevice(&forbidden);

  // This is the place to add a range device which will hold sensor data
  // and delete it appropriately to replan around blocked paths.
  ArGlobalReplanningRangeDevice replanDev(&pathTask);

  // Create objects that add network services:
  
  // Drawing in the map display:
  ArServerInfoDrawings drawings(&server);
  drawings.addRobotsRangeDevices(&robot);
  drawings.addRangeDevice(&replanDev);

  /* If you want to draw the destination put this code back in:
  ArServerDrawingDestination destination(
	  &drawings, &pathTask, "destination",
	  500, 500,
	  new ArDrawingData("polyDots",
			    ArColor(0xff, 0xff, 0x0),
			    800, // size
			    49), // just below the robot
  */ 

  /* If you want to see the local path planning area use this 
    (You can enable this particular drawing from custom commands 
    which is set up down below in ArServerInfoPath) 
  ArDrawingData drawingDataP("polyLine", ArColor(200,200,200), 1, 75);
  ArFunctor2C<ArPathPlanningTask, ArServerClient *, ArNetPacket *> 
  drawingFunctorP(pathTask, &ArPathPlanningTask::drawSearchRectangle);
  drawings.addDrawing(&drawingDataP, "Local Plan Area", &drawingFunctorP); 
  */

  /* If you want to see the points making up the local path in addition to the
   * main path use this. 
  ArDrawingData drawingDataP2("polyDots", ArColor(0,128,0), 100, 70);
  ArFunctor2C<ArPathPlanningTask, ArServerClient *, ArNetPacket *> 
  drawingFunctorP2(pathTask, &ArPathPlanningTask::drawPathPoints);
  drawings.addDrawing(&drawingDataP2, "Path Points", &drawingFunctorP2);
  */

  // Misc. simple commands:
  ArServerHandlerCommands commands(&server);
	

  // These provide various kinds of information to the client:
  ArServerInfoRobot serverInfoRobot(&server, &robot);
  ArServerInfoSensor serverInfoSensor(&server, &robot);
  ArServerInfoPath serverInfoPath(&server, &robot, &pathTask);
  serverInfoPath.addSearchRectangleDrawing(&drawings);
  serverInfoPath.addControlCommands(&commands);
//-------------------------receive commands or events from client---------------------
  
//   ArServerHandlerCommands commands(&server);
	server.addData("RobotVideo"			,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&VideoServerBase::RobotVideoCB) ,"","");
	server.addData("turn"						,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&turn_func) ,"","");
	server.addData("RobotMotion"	  ,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&S_RobotMotion) ,"","");
	server.addData("CameraMotion"   ,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&S_CameraMotion) ,"","");
	server.addData("RobotTurnLeft"  ,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&S_RobotTurnLeft) ,"","");
	server.addData("RobotTurnRight" ,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&S_RobotTurnRight) ,"","");
	server.addData("TargetApproach" ,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&S_TargetApproach) ,"","");
	server.addData("TargetApproachObstacles" ,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&S_TargetApproach_Obstacles) ,"","");
	server.addData("GlassesCancel" ,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&S_GlassesCancel) ,"","");
	server.addData("Calibration" ,"", new ArGlobalFunctor2<ArServerClient *, ArNetPacket*>(&S_Calibration) ,"","");

	server.addClientRemovedCallback(new ArGlobalFunctor1< ArServerClient * >(&clientCloseCallback));
//-------------------------receive commands or events from client---------------------


  
//***********************  
  ArServerInfoLocalization serverInfoLocalization (&server, &robot, &locManager);
  ArServerHandlerLocalization serverLocHandler (&server, &robot, &locManager);


  // Provide the map to the client (and related controls):
  // This uses both lines and points now, since everything except
  // sonar localization uses both (path planning with sonar still uses both)
  ArServerHandlerMap serverMap(&server, &arMap);

  

  // Add some simple (custom) commands for testing and debugging:
  ArServerSimpleComUC uCCommands(&commands, &robot);                   // Send any command to the microcontroller
  ArServerSimpleComMovementLogging loggingCommands(&commands, &robot); // configure logging
  ArServerSimpleComGyro gyroCommands(&commands, &robot, &gyro);        // monitor the gyro
  ArServerSimpleComLogRobotConfig configCommands(&commands, &robot);   // trigger logging of the robot config parameters
  ArServerSimpleServerCommands serverCommands(&commands, &server);     // monitor networking behavior (track packets sent etc.)


  /* Set up the possible modes for remote control from a client such as
   * MobileEyes:
   */

  // Mode To go to a goal or other specific point:
  ArServerModeGoto modeGoto(&server, &robot, &pathTask, &arMap, ArPose(0,0,0));

  // Add a simple (custom) command that allows you to give a list of 
  // goals to tour, instead of all. Useful for testing and debugging.
  modeGoto.addTourGoalsInListSimpleCommand(&commands);

  // Mode To stop and remain stopped:
  ArServerModeStop modeStop(&server, &robot);

  // cause the sonar to turn off automatically
  // when the robot is stopped, and turn it back on when commands to move
  // are sent. (Note, this should not be done if you need the sonar
  // data to localize, or for other purposes while stopped)
  ArSonarAutoDisabler sonarAutoDisabler(&robot);

  // Teleoperation modes To drive by keyboard, joystick, etc:
  ArServerModeRatioDrive modeRatioDrive(&server, &robot);  // New, improved mode
  ArServerModeDrive modeDrive(&server, &robot);            // Older mode for compatability

  // Drive mode's configuration and custom (simple) commands:
  modeRatioDrive.addToConfig(Aria::getConfig(), "Teleop settings");
  modeDrive.addControlCommands(&commands);
  modeRatioDrive.addControlCommands(&commands);

  // Wander mode 
//   ArServerModeWander modeWander(&server, &robot);
//*********************************
  // Prevent driving if localization is lost:
  ArActionLost actionLostRatioDrive (&locManager, NULL, &modeRatioDrive);
  modeRatioDrive.getActionGroup ()->addAction (&actionLostRatioDrive, 110);

  // Prevent wandering if lost:
//   ArActionLost
//   actionLostWander (&locManager, NULL, &modeWander);
//   modeWander.getActionGroup ()->addAction (&actionLostWander, 110);

  // This provides a small table of interesting information for the client
  // to display to the operator:
  ArServerInfoStrings stringInfo(&server);
  Aria::getInfoGroup()->addAddStringCallback(stringInfo.getAddStringFunctor());
  
  Aria::getInfoGroup()->addStringInt(
	  "Motor Packet Count", 10, 
	  new ArConstRetFunctorC<int, ArRobot>(&robot, 
					       &ArRobot::getMotorPacCount));


  // Make Stop mode the default (If current mode deactivates without entering
  // a new mode, then Stop Mode will be selected)
  modeStop.addAsDefaultMode();






  // Create the service that allows the client to monitor the communication 
  // between the robot and the client.
  //
  ArServerHandlerCommMonitor handlerCommMonitor(&server);

  // Create service that allows client to change configuration parameters in ArConfig 
  ArServerHandlerConfig handlerConfig(&server, Aria::getConfig(),
				      Arnl::getTypicalDefaultParamFileName(),
				      Aria::getDirectory());



  // Read in parameter files.  read the paras from input
  Aria::getConfig()->useArgumentParser(&parser);
  if (!Aria::getConfig()->parseFile(Arnl::getTypicalParamFileName()))
  {
    ArLog::log(ArLog::Normal, "Trouble loading configuration file, exiting");
    Aria::exit(5);
  }

  // Warn about unknown params.
  if (!simpleOpener.checkAndLog() || !parser.checkHelpAndWarnUnparsed())
  {
    ArLog::log(ArLog::Normal, "\nUsage: %s -map mapfilename\n", argv[0]);
    simpleConnector.logOptions();
    simpleOpener.logOptions();
    Aria::exit(6);
  }

  // Warn if there is no map
  if (arMap.getFileName() == NULL || strlen(arMap.getFileName()) <= 0)
  {
    ArLog::log(ArLog::Normal, "");
    ArLog::log(ArLog::Normal, "### Warning, No map file is set up, you can make a map with sickLogger or arnlServer, and Mapper3; More info in docs/Mapping.txt and README.txt. Set the map with the -map command line option, or by changing the config with MobileEyes or by editing the config file.");
    ArLog::log(ArLog::Normal, "");    
  }

  // find out where we'll want to put files
  ArLog::log(ArLog::Normal, "");
  ArLog::log(ArLog::Normal, 
	     "Directory for maps and file serving: %s", fileDir);
  
  ArLog::log(ArLog::Normal, "See the ARNL README.txt for more information");
  ArLog::log(ArLog::Normal, "");

  // If you want MobileSim to try and load up the same map as you are
  // using in guiServer then uncomment out the next line and this object
  // will send a command to MobileSim to do so, but make sure you start 
  // MobileSim from the Arnl/examples directory or use the --cwd option, 
  // so that the map names used by MobileSim match  the map names used 
  // by guiServer
  //ArSimMapSwitcher mapSwitcher(&robot, &arMap);

/******************************************************
 * ****************************************************
 * 			Camera 
 * ****************************************************
 * *****************************************************/
	
  
  robot.unlock();
    // Localize robot at home.
  locTask.localizeRobotAtHomeBlocking();

  locTask.forceUpdatePose(ArPose(0,0,0));

  resetMotion();
  

	

// robot.enableMotors();
// robot.runAsync(true);
  //locTask.localizeRobotAtHomeBlocking();
  server.runAsync();

  VideoServerBase videoserver;
  videoserver.runAsync();

	robot.comInt(ArCommands::SOUNDTOG, 0);
	
	//G_PathPlanning->pathPlanToPose(ArPose(1500, -1500 , -32),true,true);
	//while(G_PathPlanning->getState() != ArPathPlanningTask::REACHED_GOAL );

	//S_TargetApproach_Obstacles1();

	//ArUtil::sleep(5000);


 //   G_PTZHandler->panRel(60);
	//	ArUtil::sleep(3000);
	//while(1)
	//S_TargetApproach1();
	cout << "done!!!!!!!---------------------" <<endl;
  robot.waitForRunExit();
  Aria::exit(0);
}
Exemplo n.º 11
0
int main (int argc, char** argv) {
	
	Aria::init();
	Arnl::init();
	ArRobot robot;
	ArArgumentParser parser(&argc, argv);
	parser.loadDefaultArguments();
	ArRobotConnector robotConnector(&parser, &robot);
	if (!robotConnector.connectRobot()) {
		ArLog::log(ArLog::Terse, "Could not connect to the robot.");
		if(parser.checkHelpAndWarnUnparsed())
		{
			// -help not given, just exit.
			Aria::logOptions();
			Aria::exit(1);
			return 1;
		}
	}
	
	ArSonarDevice sonarDev;
	ArLog::log(ArLog::Normal, "OK");
	char fileDir[1024];
	ArUtil::addDirectories(fileDir, sizeof(fileDir), Aria::getDirectory(), "examples");
	ArLog::log(ArLog::Normal, "Installation directory is: %s\nMaps directory is: %s\n", Aria::getDirectory(), fileDir);
	//		strcpy(fileDir, "columbia.map");
	ArLog::log(ArLog::Normal, "file Maps directory is: %s\n",fileDir);
	ArMap map(fileDir);
	map.readFile("columbia.map");
	// set it up to ignore empty file names (otherwise the parseFile
	// on the config will fail)
	map.setIgnoreEmptyFileName(true);



	robot.addRangeDevice(&sonarDev);
	// set home pose
	robot.moveTo(ArPose(0,0,0));

	ArPathPlanningTask pathPlan(&robot, &sonarDev, &map);
	ArActionGoto gotoPoseAction("goto");
//	gotoPoseAction.activate();
//	pathPlan.getPathPlanActionGroup()->addAction(&gotoPoseAction, 50);
//	pathPlan.getPathPlanAction()->activate();
	ArForbiddenRangeDevice forbidden(&map);
	robot.addRangeDevice(&forbidden);
	pathPlan.addRangeDevice(&forbidden, ArPathPlanningTask::CURRENT);
//	pathPlan.planAndSetupAction(ArPose(0, 0, 0));
//	pathPlan.
/*
	if (pathPlan.pathPlanToPose(ArPose(1000, 1000, 0), true, true))
		ArLog::log(ArLog::Normal, "OK");
	else
		ArLog::log(ArLog::Normal, "FAILED");
*/
	// create functor
	ArGlobalFunctor1<ArPose> goalDone(&addGoalDone);// = new ArGlobalFunctor1(&addGoalDone);
	ArGlobalFunctor1<ArPose> goalFail(&addGoalFailed);
	ArGlobalFunctor1<ArPose> goalFinished(&addGoalFinished);
	ArGlobalFunctor1<ArPose> goalInterrupted(&addGoalInterrupted);

	// add functor
	pathPlan.addGoalDoneCB(&goalDone);
	pathPlan.addGoalFailedCB(&goalFail);
	pathPlan.addGoalFinishedCB(&goalFinished);
	pathPlan.addGoalInterruptedCB(&goalInterrupted);

	robot.runAsync(true);
	robot.enableMotors();
	pathPlan.runAsync();

//	ArPathPlanningTask::PathPlanningState state = pathPlan.getState();
//	while(!pathPlan.pathPlanToPose(ArPose(1000, 1000, 0), true, true));
	pathPlan.pathPlanToPose(ArPose(1000, 1000, 0), true, true);
	ArPathPlanningTask::PathPlanningState state = pathPlan.getState();
	char* s = "";
	switch(state)
	  {
	    case ArPathPlanningTask::NOT_INITIALIZED: {s = "NOT_INITIALIZED"; break;}
	    case ArPathPlanningTask::PLANNING_PATH: { s = "PLANNING_PATH";break;}
	    case ArPathPlanningTask::MOVING_TO_GOAL:{s = "MOVING_TO_GOAL";break;}
	    case ArPathPlanningTask::REACHED_GOAL: {s = "REACHED_GOAL";break;}
	    case ArPathPlanningTask::FAILED_PLAN: { s = "FAILED_PLAN";break;}
	    case ArPathPlanningTask::FAILED_MOVE: { s="FAILED_MOVE";break;}
	    case ArPathPlanningTask::ABORTED_PATHPLAN:{s = "ABORTED_PATHPLAN";break;}
//	    case ArPathPlanningTask::INVALID:
//	    default:
//	      return "UNKNOWN";
	  }
	ArLog::log(ArLog::Normal,s);
	robot.waitForRunExit();
//	pathPlan.
//	char* text = new char[512];
//	pathPlan.getStatusString(text, sizeof(text));
//	 printf("Planning status: %s.\n", text);
//	while(pathPlan.pathPlanToPose(ArPose(1000, 1000, 0), true, true));
	Aria::shutdown();
//	Arnl::s;
	Aria::exit(0);
}
int main(int argc, char **argv)
{
    Aria::init();
    ArArgumentParser parser(&argc, argv);
    parser.loadDefaultArguments();
    ArRobot robot;
    ArRobotConnector robotConnector(&parser, &robot);
    if(!robotConnector.connectRobot())
    {
      ArLog::log(ArLog::Terse, "teleopActionsExample: Could not connect to the robot.");
      if(parser.checkHelpAndWarnUnparsed())
      {
          Aria::logOptions();
          Aria::exit(1);
      }
    }
    if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
    {
      Aria::logOptions();
      Aria::exit(1);
    }
    ArLog::log(ArLog::Normal, "teleopActionsExample: Connected.");

  
  // limiter for close obstacles
  ArActionLimiterForwards limiter("speed limiter near", 300, 600, 250);
  // limiter for far away obstacles
  ArActionLimiterForwards limiterFar("speed limiter far", 300, 1100, 400);
  // limiter that checks IR sensors (like Peoplebot has)
  ArActionLimiterTableSensor tableLimiter;
  // limiter so we don't bump things backwards
  ArActionLimiterBackwards backwardsLimiter;
  // the joydrive action
  ArActionJoydrive joydriveAct;
  // the keydrive action
  ArActionKeydrive keydriveAct;
  
  // sonar device, used by the limiter actions.
  ArSonarDevice sonar;



  printf("This program will allow you to use a joystick or keyboard to control the robot.\nYou can use the arrow keys to drive, and the spacebar to stop.\nFor joystick control press the trigger button and then drive.\nPress escape to exit.\n");

  // if we don't have a joystick, let 'em know
  if (!joydriveAct.joystickInited())
    printf("Do not have a joystick, only the arrow keys on the keyboard will work.\n");
  
  // add the sonar to the robot
  robot.addRangeDevice(&sonar);


  // set the robots maximum velocity (sonar don't work at all well if you're
  // going faster)
  robot.setAbsoluteMaxTransVel(400);

  // enable the motor
  robot.enableMotors();

  // Add the actions, with the limiters as highest priority, then the teleop.
  // actions.  This will keep the teleop. actions from being able to drive too 
  // fast and hit something
  robot.addAction(&tableLimiter, 100);
  robot.addAction(&limiter, 95);
  robot.addAction(&limiterFar, 90);
  robot.addAction(&backwardsLimiter, 85);
  robot.addAction(&joydriveAct, 50);
  robot.addAction(&keydriveAct, 45);

  // Configure the joydrive action so it will let the lower priority actions
  // (i.e. keydriveAct) request motion if the joystick button is
  // not pressed.
  joydriveAct.setStopIfNoButtonPressed(false);

  
  // run the robot, true means that the run will exit if connection lost
  robot.run(true);
  
  Aria::exit(0);
}
Exemplo n.º 13
0
int main(int argc, char** argv)
{
    ros::init(argc, argv, "terabot_arm_hardware_interface");
    ros::NodeHandle node;
    std::cout << "argc= "<<argc<<" argv= "<<argv<<std::endl;
    hardware_interface::JointStateInterface jnt_state_interface_;
    hardware_interface::PositionJointInterface jnt_pos_interface_;

    //**********************************************************
    //**********************************************************
     Aria::init();
      static float defaultJointSpeed = 15;
      ArLog::init(ArLog::StdErr, ArLog::Normal);
      ArArgumentParser parser(&argc, argv);
      parser.loadDefaultArguments();
      ArRobot robot;
      ArTerabotArm arm(&robot);
      

      
      
      ArRobotConnector robotConnector(&parser, &robot);

      if(!robotConnector.connectRobot())
      {
        ArLog::log(ArLog::Terse, "terabotArm: Could not connect to the robot.");
        if(parser.checkHelpAndWarnUnparsed())
        {
            Aria::logOptions();
            Aria::exit(1);
        }
      }
      if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
      {
        Aria::logOptions();
        Aria::exit(1);
      }

      ArLog::log(ArLog::Normal, "terabotArm: Connected to mobile robot.");


      if(!arm.open())
      {
          ArLog::log(ArLog::Terse, "terabotArm: Error opening serial connection to arm");
          Aria::exit(1);
      }


      robot.runAsync(true);
      
      arm.powerOn();
      arm.reset();
      arm.enable();
      arm.setAllJointSpeeds(defaultJointSpeed);
     
      ArUtil::sleep(5000);
      
      robot.lock();
  
      robot.enableMotors(); 
      robot.unlock();
    
    
    
      TerabotArmInterface robot1(&robot, &arm, node);   
    
    //**********************************************************
    //**********************************************************
    
  //  TerabotArmInterface robot1(&robot, &arm);
    std::cout << "after creating the object"<<std::endl;
    robot1.init(jnt_state_interface_, jnt_pos_interface_);
    controller_manager::ControllerManager cm(&robot1, node);
    


    ros::AsyncSpinner spinner(4);
    spinner.start();

    ros::Time previous=ros::Time::now();

    ros::Rate rate(10.0);
    while (ros::ok())
    {
        ros::Duration period;
        robot1.readHW();
        ros::Time now=ros::Time::now();
        period=now-previous;
        //std::cout << "period:"<<period<<std::endl;
        cm.update(now, period);
        robot1.writeHW();
        rate.sleep();

    }

    spinner.stop();

    return 0;
}
int __cdecl _tmain (int argc, char** argv)
{

	//------------ I N I C I O   M A I N    D E L   P R O G R A M A   D E L    R O B O T-----------//

	  //inicializaion de variables
	  Aria::init();
	  ArArgumentParser parser(&argc, argv);
	  parser.loadDefaultArguments();
	  ArSimpleConnector simpleConnector(&parser);
	  ArRobot robot;
	  ArSonarDevice sonar;
	  ArAnalogGyro gyro(&robot);
	  robot.addRangeDevice(&sonar);
	  ActionGos go(500, 350);	  
	  robot.addAction(&go, 48);
	  ActionTurns turn(400, 110);
	  robot.addAction(&turn, 49);
	  ActionTurns turn2(400, 110);
	  robot.addAction(&turn2, 49);

	  // presionar tecla escape para salir del programa
	  ArKeyHandler keyHandler;
	  Aria::setKeyHandler(&keyHandler);
	  robot.attachKeyHandler(&keyHandler);
	  printf("Presionar ESC para salir\n");

	  // uso de sonares para evitar colisiones con las paredes u 
	  // obstaculos grandes, mayores a 8cm de alto
	  ArActionLimiterForwards limiterAction("limitador velocidad cerca", 300, 600, 250);
	  ArActionLimiterForwards limiterFarAction("limitador velocidad lejos", 300, 1100, 400);
	  ArActionLimiterTableSensor tableLimiterAction;
	  robot.addAction(&tableLimiterAction, 100);
	  robot.addAction(&limiterAction, 95);
	  robot.addAction(&limiterFarAction, 90);


	  // Inicializon la funcion de goto
	  ArActionGoto gotoPoseAction("goto");
	  robot.addAction(&gotoPoseAction, 50);
	  
	  // Finaliza el goto si es que no hace nada
	  ArActionStop stopAction("stop");
	  robot.addAction(&stopAction, 40);

	  // Parser del CLI
	  if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
	  {    
		Aria::logOptions();
		exit(1);
	  }
	  
	  // Conexion del robot
	  if (!simpleConnector.connectRobot(&robot))
	  {
		printf("Could not connect to robot... exiting\n");
		Aria::exit(1);
	  }
	  robot.runAsync(true);

	  // enciende motores, apaga sonidos
	  robot.enableMotors();
	  robot.comInt(ArCommands::SOUNDTOG, 0);

	  // Imprimo algunos datos del robot como posicion velocidad y bateria
		robot.lock();
		ArLog::log(ArLog::Normal, "Posicion=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Bateria=%.2fV",
			robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getBatteryVoltage());
		robot.unlock();

	  const int duration = 100000; //msec
	  ArLog::log(ArLog::Normal, "Completados los puntos en %d segundos", duration/1000);

	  // ============================ INICIO CONFIG COM =================================//
	    CSerial serial;
		LONG    lLastError = ERROR_SUCCESS;

		// Trata de abrir el com seleccionado
		lLastError = serial.Open(_T("COM3"),0,0,false);
		if (lLastError != ERROR_SUCCESS)
			return ::ShowError(serial.GetLastError(), _T("Imposible abrir el COM"));

		// Inicia el puerto serial (9600,8N1)
		lLastError = serial.Setup(CSerial::EBaud9600,CSerial::EData8,CSerial::EParNone,CSerial::EStop1);
		if (lLastError != ERROR_SUCCESS)
			return ::ShowError(serial.GetLastError(), _T("Imposible setear la config del COM"));

		// Register only for the receive event
		lLastError = serial.SetMask(CSerial::EEventBreak |
									CSerial::EEventCTS   |
									CSerial::EEventDSR   |
									CSerial::EEventError |
									CSerial::EEventRing  |
									CSerial::EEventRLSD  |
									CSerial::EEventRecv);
		if (lLastError != ERROR_SUCCESS)
			return ::ShowError(serial.GetLastError(), _T("Unable to set COM-port event mask"));

		// Use 'non-blocking' reads, because we don't know how many bytes
		// will be received. This is normally the most convenient mode
		// (and also the default mode for reading data).
		lLastError = serial.SetupReadTimeouts(CSerial::EReadTimeoutNonblocking);
		if (lLastError != ERROR_SUCCESS)
			return ::ShowError(serial.GetLastError(), _T("Unable to set COM-port read timeout."));
		// ============================ FIN CONFIG COM =================================//

	  bool first = true;
	  int goalNum = 0;
	  int color = 3;
	  ArTime start;
	  start.setToNow();
	  while (Aria::getRunning()) 
	  {
		robot.lock();

		// inicia el primer punto 
		if (first || gotoPoseAction.haveAchievedGoal())
		{
		  first = false;
		  
		  goalNum++; //cambia de 0 a 1 el contador
		  printf("El contador esta en: --> %d <---\n",goalNum);
		  if (goalNum > 20)
			goalNum = 1;

		  //comienza la secuencia de puntos
		  if (goalNum == 1)
		  {
			gotoPoseAction.setGoal(ArPose(1150, 0));
			ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
			gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			// Imprimo algunos datos del robot como posicion velocidad y bateria
			robot.lock();
			ArLog::log(ArLog::Normal, "Posicion=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Bateria=%.2fV",
				robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getBatteryVoltage());
			robot.unlock();
			// Create the sound queue.
			ArSoundsQueue soundQueue;
			// Run the sound queue in a new thread
			soundQueue.runAsync();
			std::vector<const char*> filenames;
			filenames.push_back("sound-r2a.wav");
			soundQueue.play(filenames[0]);
		  }
		  else if (goalNum == 2)
		  {
			  printf("Gira 90 grados izquierda\n");
			  robot.unlock();
			  turn.myActivate = 1;
			  turn.myDirection = 1;
			  turn.activate();
			  ArUtil::sleep(1000);
			  turn.deactivate();
			  turn.myActivate = 0;
			  turn.myDirection = 0;
			  robot.lock();
		  }
		  else if (goalNum == 3)
		  {
			gotoPoseAction.setGoal(ArPose(1150, 2670));
			ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
			gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			// Imprimo algunos datos del robot como posicion velocidad y bateria
			robot.lock();
			ArLog::log(ArLog::Normal, "Posicion=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Bateria=%.2fV",
				robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getBatteryVoltage());
			robot.unlock();
		  }
		  else if (goalNum == 4)
		  {
			  printf("Gira 90 grados izquierda\n");
			  robot.unlock();
			  turn2.myActivate = 1;
			  turn2.myDirection = 1;
			  turn2.activate();
			  ArUtil::sleep(1000);
			  turn2.deactivate();
			  turn2.myActivate = 0;
			  turn2.myDirection = 0;
			  robot.lock();
		  }
		  else if (goalNum == 5)
		  {
			gotoPoseAction.setGoal(ArPose(650, 2670));
			ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
			gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
		  }
		  else if (goalNum == 6)
		  {
			  printf("Gira 90 grados izquierda\n");
			  robot.unlock();
			  turn2.myActivate = 1;
			  turn2.myDirection = 1;
			  turn2.activate();
			  ArUtil::sleep(1000);
			  turn2.deactivate();
			  turn2.myActivate = 0;
			  turn2.myDirection = 0;
			  robot.lock();
		  }
		  else if (goalNum == 7)
		  {
			gotoPoseAction.setGoal(ArPose(650, 0));
			ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
			gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
		  }
		  else if (goalNum == 8)
		  {
			gotoPoseAction.setGoal(ArPose(1800,1199));
			ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
			gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
		  }
		  else if (goalNum == 9)
		  {
			gotoPoseAction.setGoal(ArPose(2600, 1199));
			ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
			gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
		  }
		  else if (goalNum == 10)
		  {
			  if (color == 1)
			  {
				gotoPoseAction.setGoal(ArPose(2800, 850));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
			  if (color == 2)
			  {
				gotoPoseAction.setGoal(ArPose(3500, 1199));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY()); 
			  }
			  if (color == 3)
			  {
				gotoPoseAction.setGoal(ArPose(2800, 1550));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
		  }
		  else if (goalNum == 11)
		  {
			  if (color == 1)
			  {
				gotoPoseAction.setGoal(ArPose(2800, 613));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
			  if (color == 2)
			  {
				  printf("Gira 180 grados derecha\n");
				  robot.unlock();
				  turn2.myActivate = 1;
				  turn2.myDirection = 2;
				  turn2.activate();
				  ArUtil::sleep(2000);
				  turn2.deactivate();
				  turn2.myActivate = 0;
				  turn2.myDirection = 0;
				  robot.lock();
				  goalNum = 19;
			  }
			  if (color == 3)
			  {
				gotoPoseAction.setGoal(ArPose(2800, 1785));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
		  }
		  else if (goalNum == 12)
		  {
			  if (color == 1)
			  {
				gotoPoseAction.setGoal(ArPose(3300, 413));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
			  if (color == 3)
			  {
				gotoPoseAction.setGoal(ArPose(3300, 1985));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
		  }
		  else if (goalNum == 13)
		  {
			  if (color == 1)
			  {
				gotoPoseAction.setGoal(ArPose(3500, 413));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
			  if (color == 3)
			  {
				gotoPoseAction.setGoal(ArPose(3500, 1985));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
		  }
		  else if (goalNum == 14)
		  {
			  robot.unlock();
			  //Valor para el while
			  bool fContinue = true;
				// <<<<<<------------- 1 Parte Secuencia: BAJA BRAZO ------------->>>>>> //
				lLastError = serial.Write("b");
				if (lLastError != ERROR_SUCCESS)
					return ::ShowError(serial.GetLastError(), _T("Unable to send data"));

				//-------------------------E S C U C H A   C O M ----------------------------//
				do
				{
					// Wait for an event
					lLastError = serial.WaitEvent();
					if (lLastError != ERROR_SUCCESS)
						return ::ShowError(serial.GetLastError(), _T("Unable to wait for a COM-port event."));

					// Save event
					const CSerial::EEvent eEvent = serial.GetEventType();

					// Handle break event
					if (eEvent & CSerial::EEventBreak)
					{
						printf("\n### BREAK received ###\n");
					}

					// Handle CTS event
					if (eEvent & CSerial::EEventCTS)
					{
						printf("\n### Clear to send %s ###\n", serial.GetCTS()?"on":"off");
					}

					// Handle DSR event
					if (eEvent & CSerial::EEventDSR)
					{
						printf("\n### Data set ready %s ###\n", serial.GetDSR()?"on":"off");
					}

					// Handle error event
					if (eEvent & CSerial::EEventError)
					{
						printf("\n### ERROR: ");
						switch (serial.GetError())
						{
						case CSerial::EErrorBreak:		printf("Break condition");			break;
						case CSerial::EErrorFrame:		printf("Framing error");			break;
						case CSerial::EErrorIOE:		printf("IO device error");			break;
						case CSerial::EErrorMode:		printf("Unsupported mode");			break;
						case CSerial::EErrorOverrun:	printf("Buffer overrun");			break;
						case CSerial::EErrorRxOver:		printf("Input buffer overflow");	break;
						case CSerial::EErrorParity:		printf("Input parity error");		break;
						case CSerial::EErrorTxFull:		printf("Output buffer full");		break;
						default:						printf("Unknown");					break;
						}
						printf(" ###\n");
					}

					// Handle ring event
					if (eEvent & CSerial::EEventRing)
					{
						printf("\n### RING ###\n");
					}

					// Handle RLSD/CD event
					if (eEvent & CSerial::EEventRLSD)
					{
						printf("\n### RLSD/CD %s ###\n", serial.GetRLSD()?"on":"off");
					}

					// Handle data receive event
					if (eEvent & CSerial::EEventRecv)
					{
						// Read data, until there is nothing left
						DWORD dwBytesRead = 0;
						char szBuffer[101];
						do
						{
							// Lee datos del Puerto COM
							lLastError = serial.Read(szBuffer,sizeof(szBuffer)-1,&dwBytesRead);
							if (lLastError != ERROR_SUCCESS)
								return ::ShowError(serial.GetLastError(), _T("Unable to read from COM-port."));

							if (dwBytesRead > 0)
							{
								//Preseteo color
								int color = 0;
								// Finaliza el dato, asi que sea una string valida
								szBuffer[dwBytesRead] = '\0';
								// Display the data
								printf("%s", szBuffer);

								// <<<<<<----------- 2 Parte Secuencia: CIERRA GRIPPER ----------->>>>>> //
								if (strchr(szBuffer,76))
								{
									lLastError = serial.Write("c");
									if (lLastError != ERROR_SUCCESS)
										return ::ShowError(serial.GetLastError(), _T("Unable to send data"));
								}
								
								// <<<<<<------------- 3 Parte Secuencia: SUBE BRAZO ------------->>>>>> //
								if (strchr(szBuffer,117))
								{
									lLastError = serial.Write("s");
									if (lLastError != ERROR_SUCCESS)
										return ::ShowError(serial.GetLastError(), _T("Unable to send data"));
								}

								// <<<<<<------------- 4 Parte Secuencia: COLOR ------------->>>>>> //
								if (strchr(szBuffer,72))
								{
									lLastError = serial.Write("C");
									if (lLastError != ERROR_SUCCESS)
										return ::ShowError(serial.GetLastError(), _T("Unable to send data"));
								}

								// <<<<<<---------- 5.1 Parte Secuencia: COLOR ROJO---------->>>>>> //
								if (strchr(szBuffer,82))
								{
									color = 1;
									//salir del bucle
									fContinue = false;
								}

								// <<<<<<---------- 5.2 Parte Secuencia: COLOR AZUL ---------->>>>>> //
								if (strchr(szBuffer,66))
								{
									color = 2;
									//salir del bucle
									fContinue = false;
								}

								// <<<<<<---------- 5.3 Parte Secuencia: COLOR VERDE ---------->>>>>> //
								if (strchr(szBuffer,71))
								{
									color = 3;
									//salir del bucle
									fContinue = false;
								}
							}
						}
						while (dwBytesRead == sizeof(szBuffer)-1);
					}
				}
				while (fContinue);
				// Close the port again
				serial.Close();
				robot.lock();
		  }
		  else if (goalNum == 15)
		  {
			  printf("Gira 180 grados derecha\n");
			  robot.unlock();
			  turn2.myActivate = 1;
			  turn2.myDirection = 2;
			  turn2.activate();
			  ArUtil::sleep(2000);
			  turn2.deactivate();
			  turn2.myActivate = 0;
			  turn2.myDirection = 0;
			  robot.lock();
		  }
		  else if (goalNum == 16)
		  {
			  if (color == 1)
			  {
				gotoPoseAction.setGoal(ArPose(3300, 413));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
			  if (color == 3)
			  {
				gotoPoseAction.setGoal(ArPose(3300, 1985));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
		  }
		  else if (goalNum == 17)
		  {
			  if (color == 1)
			  {
				gotoPoseAction.setGoal(ArPose(2800, 603));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
			  if (color == 3)
			  {
				gotoPoseAction.setGoal(ArPose(2800, 1795));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
		  }
		  else if (goalNum == 18)
		  {
			  if (color == 1)
			  {
				gotoPoseAction.setGoal(ArPose(2800, 860));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
			  if (color == 3)
			  {
				gotoPoseAction.setGoal(ArPose(2800, 1540));
				ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
				gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
			  }
		  }
		  else if (goalNum == 19)
		  {
			gotoPoseAction.setGoal(ArPose(2600, 1199));
			ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
			gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
		  }
		  else if (goalNum == 20)
		  {
			gotoPoseAction.setGoal(ArPose(1800, 1199));
			ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f", 
			gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
		  }
		}

		if(start.mSecSince() >= duration) {
		  ArLog::log(ArLog::Normal, "No puede llegar al punto, y la aplicacion saldra en %d", duration/1000);
		  gotoPoseAction.cancelGoal();
		  robot.unlock();
		  ArUtil::sleep(3000);
		  break;
		}
	    
		robot.unlock();
		ArUtil::sleep(10);
	  }

	  // Robot desconectado al terminal el sleep
	  Aria::shutdown();

	//------------ F I N   M A I N    D E L   P R O G R A M A   D E L    R O B O T-----------//
    
    return 0;
}
Exemplo n.º 15
0
int main ( int argc, char *argv[] ){
//cout << "running....\n";
try{
	// Create the socket
	ServerSocket server ( 30000 );

	Aria::init();
	Arnl::init();

	ArRobot robot;
	ArArgumentParser parser(&argc, argv);
	parser.loadDefaultArguments();
	ArSonarDevice sonar;
	ArSimpleConnector simpleConnector(&parser);

	// Our server for mobile eyes
	ArServerBase moServer;

	// Set up our simpleOpener
	ArServerSimpleOpener simpleOpener(&parser);

	parser.loadDefaultArguments();
  	if (!Aria::parseArgs () || !parser.checkHelpAndWarnUnparsed()){
    		Aria::logOptions ();
   		Aria::exit (1);
  	}

	//Add the sonar to the robot
	robot.addRangeDevice(&sonar);

  	// Look for map in the current directory
  	ArMap arMap;
  	// set it up to ignore empty file names (otherwise the parseFile
  	// on the config will fail)
  	arMap.setIgnoreEmptyFileName (true);

	// First open the server 
	if (!simpleOpener.open(&moServer)){
		if (simpleOpener.wasUserFileBad())
    			ArLog::log(ArLog::Normal, "Bad user file");
		else
    			ArLog::log(ArLog::Normal, "Could not open server port");
  		exit(2);
	}

        // Connect to the robot
        if (!simpleConnector.connectRobot (&robot)){
                ArLog::log (ArLog::Normal, "Could not connect to robot... exiting");
                Aria::exit (3);
        }

	// Create the localization task (it will start its own thread here)
	ArSonarLocalizationTask locTask(&robot, &sonar, &arMap);

	ArLocalizationManager locManager(&robot, &arMap);

	ArLog::log(ArLog::Normal, "Creating sonar localization task");
	locManager.addLocalizationTask(&locTask);




	// Set the initial pose to the robot's "Home" position from the map, or
	// (0,0,0) if none, then let the localization thread take over.
	locTask.localizeRobotAtHomeNonBlocking();

	//Create the path planning task
	ArPathPlanningTask pathTask(&robot,&sonar,&arMap);

	ArLog::log(ArLog::Normal, "Robot Server: Connected.");

	robot.enableMotors();
	robot.clearDirectMotion();

	// Start the robot processing cycle running in the background.
	// True parameter means that if the connection is lost, then the
	// run loop ends.
	robot.runAsync(true);

	// Read in parameter files.
  	Aria::getConfig ()->useArgumentParser (&parser);
  	if (!Aria::getConfig ()->parseFile (Arnl::getTypicalParamFileName ())){
		ArLog::log (ArLog::Normal, "Trouble loading configuration file, exiting");
		Aria::exit (5);
	}

	//Create the three states
	robot.lock();
	Follow follow = Follow(&robot,&sonar);
	GoTo goTo(&robot,&pathTask,&arMap);
	Search s(&robot,&sonar);

	// Bumpers.
  	ArBumpers bumpers;
  	robot.addRangeDevice(&bumpers);
  	pathTask.addRangeDevice(&bumpers, ArPathPlanningTask::CURRENT);

  	// Forbidden regions from the map
  	ArForbiddenRangeDevice forbidden(&arMap);
  	robot.addRangeDevice(&forbidden);
  	pathTask.addRangeDevice(&forbidden, ArPathPlanningTask::CURRENT);

  	// Mode To stop and remain stopped:
  	ArServerModeStop modeStop(&moServer, &robot);

  	// Action to slow down robot when localization score drops but not lost.
  	ArActionSlowDownWhenNotCertain actionSlowDown(&locTask);
  	pathTask.getPathPlanActionGroup()->addAction(&actionSlowDown, 140);

  	// Action to stop the robot when localization is "lost" (score too low)
  	ArActionLost actionLostPath(&locTask, &pathTask);
  	pathTask.getPathPlanActionGroup()->addAction(&actionLostPath, 150);

	// These provide various kinds of information to the client:
	ArServerInfoRobot serverInfoRobot(&moServer, &robot);
	ArServerInfoSensor serverInfoSensor(&moServer, &robot);
	ArServerInfoPath serverInfoPath(&moServer, &robot, &pathTask);
	
	// Provide the map to the client (and related controls):
	// This uses both lines and points now, since everything except
	// sonar localization uses both (path planning with sonar still uses both)
  	ArServerHandlerMap serverMap(&moServer, &arMap);
	
	// Provides localization info and allows the client (MobileEyes) to relocalize at a given
	// pose:
	ArServerInfoLocalization serverInfoLocalization(&moServer, &robot, &locTask);
	ArServerHandlerLocalization serverLocHandler(&moServer, &robot, &locTask);

	robot.unlock();

	moServer.runAsync();

	//Main loop
	while (true){
		//The socket to accept connection
		ServerSocket new_sock;
		server.accept ( new_sock );
		int state = 1;		//1 = Follow, 2 = Search, 3 = GoTo
		int lastPos[2];		//Storing last position of BB to search the target
		int data[2];		//matrix with X,Y of BB
		try{
			while ( true ){
				//receive data from tld
				new_sock >> data;
				//cout << data[0] << "," << data[1] << endl;

				if(data[0] != -1)
					lastPos[0] = data[0];

				//cout << state <<endl; //for debugging
				//Main logic
				switch(state){

					case 1:
						cout << "Following target\n";
						state = follow.run(data);
					break;
					case 2:
						cout << "Searching for target\n";
						state = s.seek(lastPos, data);
					break;
					case 3:
						cout << "Going to ...\n";
						state = goTo.run(data);
					break;
					default:
						cout << "Not a case for state\n";
					break;
				}
				std::cout << "Loc score: " << locTask.getLocalizationScore() << std::endl;
			}
		}
		catch ( SocketException& ) {
			cout << "Lost Connection" << endl;
			robot.lock();
			robot.stop();
			robot.unlock();
		}
	}
}
catch ( SocketException& e ){
	std::cout << "Exception was caught:" << e.description() << "\nExiting.\n";
}

ArLog::log(ArLog::Normal, "RobotServer: Exiting.");
return 0;
}
int main(int argc, char **argv)
{
  Aria::init();
  ArRobot robot;
  ArServerBase server;

  ArArgumentParser parser(&argc, argv);
  ArSimpleConnector simpleConnector(&parser);
  ArServerSimpleOpener simpleOpener(&parser);


  // parse the command line... fail and print the help if the parsing fails
  // or if help was requested
  parser.loadDefaultArguments();
  if (!simpleConnector.parseArgs() || !simpleOpener.parseArgs() || 
      !parser.checkHelpAndWarnUnparsed())
  {    
    simpleConnector.logOptions();
    simpleOpener.logOptions();
    exit(1);
  }

  // Set up where we'll look for files such as config file, user/password file,
  // etc.
  char fileDir[1024];
  ArUtil::addDirectories(fileDir, sizeof(fileDir), Aria::getDirectory(), 
			 "ArNetworking/examples");

  // first open the server up
  if (!simpleOpener.open(&server, fileDir, 240))
  {
    if (simpleOpener.wasUserFileBad())
      printf("Error: Bad user/password/permissions file.\n");
    else
      printf("Error: Could not open server port. Use -help to see options.\n");
    exit(1);
  }


  // Devices
  ArAnalogGyro gyro(&robot);

  ArSonarDevice sonarDev;
  robot.addRangeDevice(&sonarDev);

  ArIRs irs;
  robot.addRangeDevice(&irs);

  ArBumpers bumpers;
  robot.addRangeDevice(&bumpers);

  ArSick sick(361, 180);
  robot.addRangeDevice(&sick);  
  

  ArServerInfoRobot serverInfoRobot(&server, &robot);
  ArServerInfoSensor serverInfoSensor(&server, &robot);

  // This is the service that provides drawing data to the client.
  ArServerInfoDrawings drawings(&server);

  // Convenience function that sets up drawings for all the robot's current
  // range devices (using default shape and color info)
  drawings.addRobotsRangeDevices(&robot);

  // Add our custom drawings
  drawings.addDrawing(
      //                shape:      color:               size:   layer:
      new ArDrawingData("polyLine", ArColor(255, 0, 0),  2,      49),
      "exampleDrawing_Home", 
      new ArGlobalFunctor2<ArServerClient*, ArNetPacket*>(&exampleHomeDrawingNetCallback)
  );
  drawings.addDrawing(                                    
      new ArDrawingData("polyDots", ArColor(0, 255, 0), 250, 48),
      "exampleDrawing_Dots", 
      new ArGlobalFunctor2<ArServerClient*, ArNetPacket*>(&exampleDotsDrawingNetCallback)
  );
  drawings.addDrawing(
      new ArDrawingData("polySegments", ArColor(0, 0, 0), 4, 52),
      "exampleDrawing_XMarksTheSpot", 
      new ArGlobalFunctor2<ArServerClient*, ArNetPacket*>(&exampleXDrawingNetCallback)
  );
  drawings.addDrawing(
      new ArDrawingData("polyArrows", ArColor(255, 0, 255), 500, 100),
      "exampleDrawing_Arrows", 
      new ArGlobalFunctor2<ArServerClient*, ArNetPacket*>(&exampleArrowsDrawingNetCallback)
  );

  // modes for moving the robot
  ArServerModeStop modeStop(&server, &robot);
  ArServerModeDrive modeDrive(&server, &robot);
  ArServerModeRatioDrive modeRatioDrive(&server, &robot);
  ArServerModeWander modeWander(&server, &robot);
  modeStop.addAsDefaultMode();
  modeStop.activate();

  

  // Connect to the robot.
  if (!simpleConnector.connectRobot(&robot))
  {
    printf("Error: Could not connect to robot... exiting\n");
    Aria::shutdown();
    return 1;
  }

  // set up the laser before handing it to the laser mode
  simpleConnector.setupLaser(&sick);

  robot.enableMotors();

  // start the robot cycle running in a background thread
  robot.runAsync(true);

  // start the laser processing cycle in a background thread
  sick.runAsync();

  // connect the laser if it was requested
  if (!simpleConnector.connectLaser(&sick))
  {
    printf("Error: Could not connect to laser... exiting\n");
    Aria::shutdown();
    return 1;
  }

  // log whatever we wanted to before the runAsync
  simpleOpener.checkAndLog();

  // run the server thread in the background
  server.runAsync();

  printf("Server is now running...\n");


  // Add a key handler mostly that windows can exit by pressing
  // escape, note that the key handler prevents you from running this program
  // in the background on Linux.
  ArKeyHandler *keyHandler;
  if ((keyHandler = Aria::getKeyHandler()) == NULL)
  {
    keyHandler = new ArKeyHandler;
    Aria::setKeyHandler(keyHandler);
    robot.lock();
    robot.attachKeyHandler(keyHandler);
    robot.unlock();
    printf("To exit, press escape.\n");
  }

  robot.waitForRunExit();
 

  Aria::shutdown();
  exit(0);  
}
Exemplo n.º 17
0
int main (int argc, char** argv) {
	Aria::init();
	ArRobot robot;
	ArSonarDevice sonar;
	ArArgumentParser parser(&argc, argv);
	parser.loadDefaultArguments();
	ArRobotConnector robotConnector(&parser, &robot);
	if (!robotConnector.connectRobot()) {
		ArLog::log(ArLog::Terse, "Could not connect to the robot.");
		if(parser.checkHelpAndWarnUnparsed())
		{
			Aria::logOptions();
			Aria::exit(1);
			return 1;
		}
	}

	ArSonarDevice sonarDev;
	ArPose* poseList = readPostitions("positions.txt");
	robot.runAsync(true);
	robot.enableMotors();
	robot.moveTo(ArPose(0,0,0));
	robot.comInt(ArCommands::ENABLE, 1);
	robot.addRangeDevice(&sonarDev);
	ArActionGoto gotoPoseAction("goto", ArPose(0, 0, 0), 200);
	ArActionAvoidFront avoidFront("avoid front");
	ArActionStallRecover stallRecover("stall recover");
	robot.addAction(&gotoPoseAction, 50);
	robot.addAction(&avoidFront, 60);
	robot.moveTo(ArPose(0,0,0));
	int length = ARRAY_SIZE(poseList);
	cout<<"do dai"<<length;
	ArServerBase server;
	ArServerSimpleOpener simpleOpener(&parser);
	char fileDir[1024];
	  ArUtil::addDirectories(fileDir, sizeof(fileDir), Aria::getDirectory(),
				 "ArNetworking/examples");

	  // first open the server up
	  if (!simpleOpener.open(&server, fileDir, 240))
	  {
	    if (simpleOpener.wasUserFileBad())
	      printf("Bad user/password/permissions file\n");
	    else
	      printf("Could not open server port\n");
	    exit(1);
	  }
	ArServerInfoRobot serverInfo(&server, &robot);
	GotoGoal gotoGoal(&robot, &sonar, &server, &serverInfo);
	gotoGoal.init(argc, argv);
	float angle = 0;
	VideoCapture cap;
	cap.open(0);
	Rect trackWindow;
	//var check find ball
	bool checkObject = false;
	int hsize = 16;

	namedWindow( "threshold", 0 );
	namedWindow( "trackbar", 0 );
	namedWindow( "Histogram", 0 );
	namedWindow( "main", 0 );
	createTrackbar( "Vmin", "trackbar", &vmin, 256, 0 );
	createTrackbar( "Vmax", "trackbar", &vmax, 256, 0 );
	createTrackbar( "Smin", "trackbar", &smin, 256, 0 );

	CascadeClassifier c;
	c.load("cascade.xml");
	Mat frame, hsv, hue, mask, hist, histimg = Mat::zeros(200, 320, CV_8UC3), backproj;
	float vel = 0;
	int i = 0;
	while(1)
	{
		cap >> frame;
		if( frame.empty() ){
			cout<<"error camera"<<endl;
			break;
		}
		frame.copyTo(image);
		cvtColor(image, hsv, COLOR_BGR2HSV);
		int _vmin = vmin, _vmax = vmax;
		inRange(hsv, Scalar(0, smin, MIN(_vmin,_vmax)),	Scalar(180, 256, MAX(_vmin, _vmax)), mask);
		gotoPoseAction.setGoal(poseList[i]);
		while (!gotoPoseAction.haveAchievedGoal()) 
		{
			ArLog::log(ArLog::Normal, "goal(%.2f, %0.2f) x = %.2f, y = %.2f", poseList[i].getX(), poseList[i].getY(), robot.getX(), robot.getY());
//			if (!checkObject)
			   checkObject = detect(frame, c);
			if (checkObject)
				cout <<"Phat hien doi tuong"<<endl;
			else
				cout <<"Khong phat hien doi tuong"<<endl;
			if (checkObject) {
				if(trackObject(hsv, mask)) {
					float d = distance();
					if (d < 250) {
						gotoGoal.move(-200);
					} else if ( d >= 250 && d <= 300) {
						gotoGoal.stop();
					}
					else {
						vel = d * 0.7;
						vel = (int) (vel/50) * 50;
						if(vel > 200) {
							vel = 200;
							gotoGoal.setVel(vel);
						}
						angle =  determindRotate();
						cout <<"khoang cach: "<<d<<"\tGoc quay: "<<angle<<"\t van toc = "<<vel<<endl;
						if (angle != 0) {
							gotoGoal.stop();
							gotoGoal.rotate(angle);
						}
					}
				}
			}
			imshow("main", image);
			imshow( "threshold", mask );
			imshow( "Histogram", histimg );
		}
		i++;
	}

	ArUtil::sleep(2000);
	Aria::shutdown();

}
Exemplo n.º 18
0
int main (int argc, char** argv) {
	
	Aria::init();
	Arnl::init();
	ArRobot robot;
	ArArgumentParser parser(&argc, argv);
	parser.loadDefaultArguments();
	ArRobotConnector robotConnector(&parser, &robot);
	//ArAnalogGyro gyro = new 
//	ArAnalogGyro gyro(&robot);
	if (!robotConnector.connectRobot()) {
		ArLog::log(ArLog::Terse, "Could not connect to the robot.");
		if(parser.checkHelpAndWarnUnparsed())
		{
			// -help not given, just exit.
			Aria::logOptions();
			Aria::exit(1);
			return 1;
		}
	}
	
	ArSonarDevice sonarDev;
	

//	robot.runAsync(true);
	ArLog::log(ArLog::Normal, "OK");
	ArMap map("office.map");
	// set it up to ignore empty file names (otherwise if a configuration omits
	// the map file, the whole configuration change will fail)
//	map.setIgnoreEmptyFileName(true);
	// ignore the case, so that if someone is using MobileEyes or
	// MobilePlanner from Windows and changes the case on a map name,
	// it will still work.
//	map.setIgnoreCase(true);


	robot.runAsync(true);

//	robot.lock();
//	robot.comInt(ArCommands::ENABLE, 1);
	robot.addRangeDevice(&sonarDev);
//	ArSonarLocalizationTask locTask(&robot, &sonarDev, &map);
//	ArActionAvoidFront avoidFront("avoid front obstacles");
//	ArActionGoto gotoPoseAction("goto");
//	robot.addAction(&gotoPoseAction, 50);
//	robot.addAction(&avoidFront, 60);
//	robot.moveTo(ArPose(0,0,0));
	ArPathPlanningTask pathPlan(&robot, &sonarDev, &map);
//	pathPlan.getRun
//	locTask.localizeRobotAtHomeBlocking();
	ArGlobalFunctor1<ArPose> goalDone(&addGoalDone);// = new ArGlobalFunctor1(&addGoalDone);
	ArGlobalFunctor1<ArPose> goalFail(&addGoalFailed);
	ArGlobalFunctor1<ArPose> goalFinished(&addGoalFinished);
	ArGlobalFunctor1<ArPose> goalInterrupted(&addGoalInterrupted);
	pathPlan.addGoalDoneCB(&goalDone);
	pathPlan.addGoalFailedCB(&goalFail);
	pathPlan.addGoalFinishedCB(&goalFinished);
	pathPlan.addGoalInterruptedCB(&goalInterrupted);

//	ro
//	ArActionPlanAndMoveToGoal gotoGoal (200, 10, pathPlan, NULL, &sonarDev);

//	pathPlan.runAsync();
	robot.enableMotors();
//	while(!pathPlan.pathPlanToPose(ArPose(1000, 1000, 0), true, true));
	pathPlan.pathPlanToPose(ArPose(1000, 1000, 0), true, true);
//	pathPlan.pathPlanToPose(ArPose(1000, 1000, 0), true, true)
	pathPlan.startPathPlanToLocalPose(true);
//	pathPlan.getPathPlanActionGroup()->activate();
//	pathPlan.getCurrentGoal()
//	pathPlan.is
//	robot.unlock();
	/*
	gotoPoseAction.setGoal(ArPose(10000, 15000, 0));
	while (!gotoPoseAction.haveAchievedGoal()) {
		robot.lock();
		printf ("x = %.2f, y = %.2f", robot.getX(), robot.getY());
		robot.unlock();
	}
	*/
//	robot.lock();
//	robot.setVel(200);
//	robot.unlock();
	while (pathPlan.endPathPlanToLocalPose(true));
		//ArUtil::sleep(1000);

//	ArPose pose;
//	locTask.forceUpdatePose(pose);
	
	/*
	while(true) {
	//while (robot.blockingConnect()){
		//robot.lock();
		//ArPose pose  = robot.getPose();
		//pose.setX(100);
		//robot.moveTo(pose);
		//t = robot.getLastOdometryTime();
		//int a = interp.getPose(t, &pose);
		ArLog::log(ArLog::Normal, "x = %f \t y = %f\n", pose.getX(), pose.getY());
		//robot.unlock();
	} 
	* */
}
Exemplo n.º 19
0
int
main(int argc, char *argv[])
{
  // Initialize location of Aria, Arnl and their args.
  Aria::init();
  Arnl::init();

  // The robot object
  ArRobot robot;
#ifndef SONARNL
  // The laser object
  ArSick sick(181, 361);
#endif

  // Parse them command line arguments.
  ArArgumentParser parser(&argc, argv);

  // Set up our simpleConnector
  ArSimpleConnector simpleConnector(&parser);

  // Load default arguments for this computer
  parser.loadDefaultArguments();

  // Parse its arguments for the simple connector.
  simpleConnector.parseArgs();

  // sonar, must be added to the robot, for teleop and wander
  ArSonarDevice sonarDev;
  // add the sonar to the robot
  robot.addRangeDevice(&sonarDev);

  ArMap arMap;
#ifndef SONARNL
  // Initialize the localization
  ArLocalizationTask locTask(&robot, &sick, &arMap);
  // Make the path task
  ArPathPlanningTask pathTask(&robot, &sick, &sonarDev, &arMap);
#else
  // Initialize the localization
  ArSonarLocalizationTask locTask(&robot, &sonarDev, &arMap);
  // Make the path task
  ArPathPlanningTask pathTask(&robot, NULL, &sonarDev, &arMap);
#endif


  // Stop the robot as soon as localization fails.
  ArFunctor1C<ArPathPlanningTask, int>
  locaFailed(&pathTask, &ArPathPlanningTask::trackingFailed);
  locTask.addFailedLocalizationCB(&locaFailed);

  // Read in param files.
  Aria::getConfig()->useArgumentParser(&parser);
  if (!Aria::getConfig()->parseFile(Arnl::getTypicalParamFileName()))
  {
    printf("Trouble loading configuration file, exiting\n");
    exit(1);
  }
  // Warn about unknown params.
  if (!parser.checkHelpAndWarnUnparsed())
  {
    printf("\nUsage: %s -map mapfilename\n\n", argv[0]);
    simpleConnector.logOptions();
    exit(2);
  }

  // Our server
  ArServerBase server;

  // First open the server up
  if (!server.open(7272))
  {
    printf("Could not open server port\n");
    exit(1);
  }

  // Connect the robot
  if (!simpleConnector.connectRobot(&robot))
  {
    printf("Could not connect to robot... exiting\n");
    Aria::shutdown();
    return 1;
  }

  robot.com2Bytes(31, 14, 0);
  robot.com2Bytes(31, 15, 0);
  ArUtil::sleep(100);
  robot.com2Bytes(31, 14, 1);
  robot.com2Bytes(31, 15, 1);
  robot.enableMotors();
  robot.clearDirectMotion();

#ifndef SONARNL
  // Set up the laser before handing it to the laser mode
  simpleConnector.setupLaser(&sick);

  // Add the laser to the robot
  robot.addRangeDevice(&sick);
#endif

  // Start the robot thread.
  robot.runAsync(true);

#ifndef SONARNL
  // Start the laser thread.
  sick.runAsync();

  // Connect the laser
  if (!sick.blockingConnect())
  {
    printf("Couldn't connect to sick, exiting\n");
    Aria::shutdown();
    return 1;
  }
#endif

  ArUtil::sleep(300);

  // If you want to set the number of samples change the line below
  locTask.setNumSamples(2000);
  // Localize the robot to home
  if(locTask.localizeRobotAtHomeBlocking())
  {
    printf("Successfully localized at home.\n");
  }
  else
  {
    printf("WARNING: Unable to localize at home position!\n");
  }


  robot.lock();
  // attach stuff to the server
  ArServerInfoRobot serverInfoRobot(&server, &robot);
  ArServerInfoSensor serverInfoSensor(&server, &robot);
  ArServerInfoPath serverInfoPath(&server, &robot, &pathTask);
  ArServerInfoLocalization serverInfoLocalization(&server, &robot, &locTask);

#ifndef SONARNL
  // Set it up to handle maps.
  ArServerHandlerMap serverMap(&server, &arMap, ArServerHandlerMap::POINTS);
#else
  ArServerHandlerMap serverMap(&server, &arMap, ArServerHandlerMap::LINES);
#endif

  // Set up a service that allows the client to monitor the communication
  // between the robot and the client.
  //
  ArServerHandlerCommMonitor serverCommMonitor(&server);


  //ArServerModeGoto modeGoto(&server, &robot, &pathTask);
  //ArServerModeStop modeStop(&server, &robot);
  //ArServerModeDrive modeDrive(&server, &robot);

  SimpleTask simpleTask(&robot, &pathTask);

  robot.unlock();
  // Read in param files.
  Aria::getConfig()->parseFile(Arnl::getTypicalParamFileName());

  // Now let it spin off in its own thread
  server.run();
  exit(0);

}
Exemplo n.º 20
0
int main(int argc, char **argv)
{
  // mandatory init
  Aria::init();

  //ArLog::init(ArLog::StdOut, ArLog::Verbose);

  // set up our parser
  ArArgumentParser parser(&argc, argv);

  // load the default arguments 
  parser.loadDefaultArguments();

  // robot
  ArRobot robot;
  // set up our simple connector
  ArRobotConnector robotConnector(&parser, &robot);


  // add a gyro, it'll see if it should attach to the robot or not
  ArAnalogGyro gyro(&robot);


  // set up the robot for connecting
  if (!robotConnector.connectRobot())
  {
    printf("Could not connect to robot... exiting\n");
    Aria::exit(1);
  }

  ArDataLogger dataLogger(&robot, "dataLog.txt");
  dataLogger.addToConfig(Aria::getConfig());
  
  // our base server object
  ArServerBase server;

  ArLaserConnector laserConnector(&parser, &robot, &robotConnector);
  ArServerSimpleOpener simpleOpener(&parser);


  ArClientSwitchManager clientSwitchManager(&server, &parser);

  // parse the command line... fail and print the help if the parsing fails
  // or if the help was requested
  if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
  {    
    Aria::logOptions();
    Aria::exit(1);
  }

  // Set up where we'll look for files such as user/password 
  char fileDir[1024];
  ArUtil::addDirectories(fileDir, sizeof(fileDir), Aria::getDirectory(), 
			 "ArNetworking/examples");

  // first open the server up
  if (!simpleOpener.open(&server, fileDir, 240))
  {
    if (simpleOpener.wasUserFileBad())
      printf("Bad user/password/permissions file\n");
    else
      printf("Could not open server port\n");
    exit(1);
  }

  // Range devices:
 
 
  ArSonarDevice sonarDev;
  robot.addRangeDevice(&sonarDev);

  ArIRs irs;
  robot.addRangeDevice(&irs);

  ArBumpers bumpers;
  robot.addRangeDevice(&bumpers);

  // attach services to the server
  ArServerInfoRobot serverInfoRobot(&server, &robot);
  ArServerInfoSensor serverInfoSensor(&server, &robot);
  ArServerInfoDrawings drawings(&server);

  // modes for controlling robot movement
  ArServerModeStop modeStop(&server, &robot);
  ArServerModeRatioDrive modeRatioDrive(&server, &robot);  
  ArServerModeWander modeWander(&server, &robot);
  modeStop.addAsDefaultMode();
  modeStop.activate();

  // set up the simple commands
  ArServerHandlerCommands commands(&server);
  ArServerSimpleComUC uCCommands(&commands, &robot);  // send commands directly to microcontroller
  ArServerSimpleComMovementLogging loggingCommands(&commands, &robot); // control debug logging
  ArServerSimpleComGyro gyroCommands(&commands, &robot, &gyro); // configure gyro
  ArServerSimpleComLogRobotConfig configCommands(&commands, &robot); // control more debug logging
  ArServerSimpleServerCommands serverCommands(&commands, &server); // control ArNetworking debug logging
  ArServerSimpleLogRobotDebugPackets logRobotDebugPackets(&commands, &robot, ".");  // debugging tool

  // ArServerModeDrive is an older drive mode. ArServerModeRatioDrive is newer and generally performs better,
  // but you can use this for old clients if neccesary.
  //ArServerModeDrive modeDrive(&server, &robot);
  //modeDrive.addControlCommands(&commands); // configure the drive modes (e.g. enable/disable safe drive)

  ArServerHandlerConfig serverHandlerConfig(&server, Aria::getConfig()); // make a config handler
  ArLog::addToConfig(Aria::getConfig()); // let people configure logging

  modeRatioDrive.addToConfig(Aria::getConfig(), "Teleop settings"); // able to configure teleop settings
  modeRatioDrive.addControlCommands(&commands);

  // Forward video if either ACTS or SAV server are running.
  // You can find out more about SAV and ACTS on our website
  // http://robots.activmedia.com. ACTS is for color tracking and is
  // a separate product. SAV just does software A/V transmitting and is
  // free to all our customers. Just run ACTS or SAV server before you
  // start this program and this class here will forward video from the
  // server to the client.
  ArHybridForwarderVideo videoForwarder(&server, "localhost", 7070);
  
  // Control a pan/tilt/zoom camera, if one is installed, and the video
  // forwarder was enabled above.
  ArPTZ *camera = NULL;
  ArServerHandlerCamera *handlerCamera = NULL;
  ArCameraCollection *cameraCollection = NULL;
  if (videoForwarder.isForwardingVideo())
  {
    bool invertedCamera = false;
    camera = new ArVCC4(&robot,	invertedCamera, 
			ArVCC4::COMM_UNKNOWN, true, true);
    camera->init();

    cameraCollection = new ArCameraCollection();
    cameraCollection->addCamera("Cam1", "VCC4", "Camera", "VCC4");
    handlerCamera = new ArServerHandlerCamera("Cam1", 
		                              &server, 
					      &robot,
					      camera, 
					      cameraCollection);
  }

  // You can use this class to send a set of arbitrary strings 
  // for MobileEyes to display, this is just a small example
  ArServerInfoStrings stringInfo(&server);
  Aria::getInfoGroup()->addAddStringCallback(stringInfo.getAddStringFunctor());
  Aria::getInfoGroup()->addStringInt(
	  "Motor Packet Count", 10, 
	  new ArConstRetFunctorC<int, ArRobot>(&robot, 
					       &ArRobot::getMotorPacCount));
  /*
  Aria::getInfoGroup()->addStringInt(
	  "Laser Packet Count", 10, 
	  new ArRetFunctorC<int, ArSick>(&sick, 
					 &ArSick::getSickPacCount));
  */
  
  // start the robot running, true means that if we lose connection the run thread stops
  robot.runAsync(true);


  // connect the laser(s) if it was requested
  if (!laserConnector.connectLasers())
  {
    printf("Could not connect to lasers... exiting\n");
    Aria::exit(2);
  }
  

  drawings.addRobotsRangeDevices(&robot);

  // log whatever we wanted to before the runAsync
  simpleOpener.checkAndLog();
  // now let it spin off in its own thread
  server.runAsync();

  printf("Server is now running...\n");

  // Add a key handler so that you can exit by pressing
  // escape. Note that a key handler prevents you from running
  // a program in the background on Linux, since it expects an 
  // active terminal to read keys from; remove this if you want
  // to run it in the background.
  ArKeyHandler *keyHandler;
  if ((keyHandler = Aria::getKeyHandler()) == NULL)
  {
    keyHandler = new ArKeyHandler;
    Aria::setKeyHandler(keyHandler);
    robot.lock();
    robot.attachKeyHandler(keyHandler);
    robot.unlock();
    printf("To exit, press escape.\n");
  }

  // Read in parameter files.
  std::string configFile = "serverDemoConfig.txt";
  Aria::getConfig()->setBaseDirectory("./");
  if (Aria::getConfig()->parseFile(configFile.c_str(), true, true))
  {
    ArLog::log(ArLog::Normal, "Loaded config file %s", configFile.c_str());
  }
  else
  {
    if (ArUtil::findFile(configFile.c_str()))
    {
      ArLog::log(ArLog::Normal, 
		 "Trouble loading configuration file %s, continuing",
		 configFile.c_str());
    }
    else
    {
      ArLog::log(ArLog::Normal, 
		 "No configuration file %s, will try to create if config used",
		 configFile.c_str());
    }
  }

  clientSwitchManager.runAsync();

  robot.lock();
  robot.enableMotors();
  robot.unlock();

  robot.waitForRunExit();
  Aria::exit(0);
}
Exemplo n.º 21
0
int main(int argc, char *argv[])
{
    // Initialize location of Aria, Arnl and their args.
    Aria::init();
    Arnl::init();


    // The robot object
    ArRobot robot;

    // Parse the command line arguments.
    ArArgumentParser parser(&argc, argv);

    // Read data_index if exists
    int data_index;
    bool exist_data_index;
    parser.checkParameterArgumentInteger("dataIndex",&data_index,&exist_data_index);


    // Load default arguments for this computer (from /etc/Aria.args, environment
    // variables, and other places)
    parser.loadDefaultArguments();


    // Object that connects to the robot or simulator using program options
    ArRobotConnector robotConnector(&parser, &robot);


    // set up a gyro
    ArAnalogGyro gyro(&robot);

    ArLog::init(ArLog::File,ArLog::Normal,"run.log",false,true,true);

    // Parse arguments for the simple connector.
    if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
    {
        ArLog::log(ArLog::Normal, "\nUsage: %s -map mapfilename\n", argv[0]);
        Aria::logOptions();
        Aria::exit(1);
    }

    // Collision avoidance actions at higher priority
    ArActionAvoidFront avoidAction("avoid",200);
    ArActionLimiterForwards limiterAction("speed limiter near", 150, 500, 150);
    ArActionLimiterForwards limiterFarAction("speed limiter far", 300, 1100, 400);
    ArActionLimiterTableSensor tableLimiterAction;
    //robot.addAction(&tableLimiterAction, 100);
    //robot.addAction(&avoidAction,100);
    //robot.addAction(&limiterAction, 95);
    //robot.addAction(&limiterFarAction, 90);

    // Goto action at lower priority
    ArActionGoto gotoPoseAction("goto");
    //robot.addAction(&gotoPoseAction, 50);
    gotoPoseAction.setCloseDist(750);

    // Stop action at lower priority, so the robot stops if it has no goal
    ArActionStop stopAction("stop");
    //robot.addAction(&stopAction, 40);




    // Connect the robot
    if (!robotConnector.connectRobot())
    {
        ArLog::log(ArLog::Normal, "Could not connect to robot... exiting");
        Aria::exit(3);
    }

    if(!robot.isConnected())
    {
        ArLog::log(ArLog::Terse, "Internal error: robot connector succeeded but ArRobot::isConnected() is false!");
    }




    // Connector for laser rangefinders
    ArLaserConnector laserConnector(&parser, &robot, &robotConnector);


    // Sonar, must be added to the robot, used by teleoperation and wander to
    // detect obstacles, and for localization if SONARNL
    ArSonarDevice sonarDev;

    // Add the sonar to the robot
    robot.addRangeDevice(&sonarDev);

    // Start the robot thread.
    robot.runAsync(true);


    // Connect to the laser(s) if lasers were configured in this robot's parameter
    // file or on the command line, and run laser processing thread if applicable
    // for that laser class.  For the purposes of this demo, add all
    // possible lasers to ArRobot's list rather than just the ones that were
    // connected by this call so when you enter laser mode, you
    // can then interactively choose which laser to use from that list of all
    // lasers mentioned in robot parameters and on command line. Normally,
    // only connected lasers are put in ArRobot's list.
    if (!laserConnector.connectLasers(
                false,  // continue after connection failures
                true,  // add only connected lasers to ArRobot
                true    // add all lasers to ArRobot
            ))
    {
        ArLog::log(ArLog::Normal ,"Could not connect to lasers... exiting\n");
        Aria::exit(2);
    }


    // Puntero a laser
    ArSick* sick=(ArSick*)robot.findLaser(1);



    // Conectamos el laser
    sick->asyncConnect();

    //Esperamos a que esté encendido
    while(!sick->isConnected())
    {
        ArUtil::sleep(100);
    }

    ArLog::log(ArLog::Normal ,"Laser conectado\n");




    // Set up things so data can be logged (only do it with the laser
    // since it can overrun a 9600 serial connection which the sonar is
    // more likely to have)
    ArDataLogger dataLogger(&robot);
    dataLogger.addToConfig(Aria::getConfig());

    // add our logging to the config
    //ArLog::addToConfig(Aria::getConfig());




    // Set up a class that'll put the movement and gyro parameters into ArConfig
    ArRobotConfig robotConfig(&robot);
    robotConfig.addAnalogGyro(&gyro);



    // Add additional range devices to the robot and path planning task.
    // IRs if the robot has them.
    robot.lock();
    ArIRs irs;
    robot.addRangeDevice(&irs);

    // Bumpers.
    ArBumpers bumpers;
    robot.addRangeDevice(&bumpers);


    // cause the sonar to turn off automatically
    // when the robot is stopped, and turn it back on when commands to move
    // are sent. (Note, this should not be done if you need the sonar
    // data to localize, or for other purposes while stopped)
    ArSonarAutoDisabler sonarAutoDisabler(&robot);



    // Read in parameter files.
    Aria::getConfig()->useArgumentParser(&parser);
    if (!Aria::getConfig()->parseFile(Arnl::getTypicalParamFileName()))
    {
        ArLog::log(ArLog::Normal, "Trouble loading configuration file, exiting");
        Aria::exit(5);
    }




    //Configuracion del laser
    sick->setMinDistBetweenCurrent(0);

    robot.enableMotors();
    robot.setAbsoluteMaxTransVel(1000);

    /* Finally, get ready to run the robot: */
    robot.unlock();



    Controlador driver(&robot);

    if(exist_data_index){
    	driver.setDataIndex(data_index);
    }

    driver.runAsync();


    ControlHandler handler(&driver,&robot);
    // Use manual key handler
    //handler.addKeyHandlers(&robot);
    robot.addSensorInterpTask("ManualKeyHandler",50,handler.getFunctor());
    ArLog::log(ArLog::Normal ,"Añadido manejador teclado\n");












//    double x,y,dist,angle;

//    ArPose punto;
//    ArPose origen=robot.getPose();

//    sick->lockDevice();

//    for(int i=-90;i<90;i++){
//	// Obtengo la medida de distancia y angulo
//	dist=sick->currentReadingPolar(i,i+1,&angle);

//	// Obtengo coordenadas del punto usando el laser como referencia
//	x=dist*ArMath::cos(angle);
//	y=dist*ArMath::sin(angle);

//	//Roto los puntos
//	ArMath::pointRotate(&x,&y,-origen.getTh());
//	punto.setX(x);
//	punto.setY(y);

//	punto=punto + origen;

//	printf("Medida: %d\t Angulo:%.2f\t Angulo:%.2f\t Distancia:%0.2f\t X:%0.2f\t Y:%0.2f\n",i,angle,angle+origen.getTh(),dist,punto.getX(),punto.getY());
//    }
//    printf("Medidas adquiridas\n");

//    sick->unlockDevice();


    robot.waitForRunExit();


    //ArUtil::sleep(10000);


    return 0;

}
Exemplo n.º 22
0
int main(int argc, char **argv)
{
  Aria::init();
  ArRobot robot;
  ArArgumentParser parser(&argc, argv);
  ArSimpleConnector simpleConnector(&parser);

  // The base server object, manages all connections to clients.
  ArServerBase server;

  // This object simplifies configuration and opening of the ArServerBase
  // object.
  ArServerSimpleOpener simpleOpener(&parser);

  // parse the command line. fail and print the help if the parsing fails
  // or if the help was requested with -help
  parser.loadDefaultArguments();
  if (!simpleConnector.parseArgs() || !simpleOpener.parseArgs() || 
      !parser.checkHelpAndWarnUnparsed())
  {    
    simpleConnector.logOptions();
    simpleOpener.logOptions();
    exit(1);
  }

  // Use the ArSimpleOpener to open the server port
  if (!simpleOpener.open(&server))
  {
    ArLog::log(ArLog::Terse, "Error: Could not open server on port %d", simpleOpener.getPort());
    exit(1);
  }


  //
  // Create services attached to the base server:
  // 
  
  // Robot position etc.:
  ArServerInfoRobot serverInfoRobot(&server, &robot);

  // Robot control modes (only one mode can be active at once):
  ArServerModeStop modeStop(&server, &robot);    
  // old ArServerModeDrive modeDrive(&server, &robot); 
  ArServerModeRatioDrive modeRatioDrive(&server, &robot);
  ArServerModeWander modeWander(&server, &robot);
  modeStop.addAsDefaultMode();
  modeStop.activate();

  // This provides a simple way to add new commands.
  ArServerHandlerCommands commands(&server);

  // Add our custom command. ArServerHandlerCommands also has other methods
  // for adding commands taht take different kinds of arguments, or no
  // arguments.
  ArGlobalFunctor1<ArArgumentBuilder*> customCommandFunctor(&customCommandHandler);
  commands.addStringCommand("ExampleCustomCommand", "Example of a custom command. simpleServerExample will print out the text sent with the command.", &customCommandFunctor);
 
  // These objects provide various debugging and diagnostic custom commands:
  ArServerSimpleComUC uCCommands(&commands, &robot);  // Get information about the robot
  ArServerSimpleComMovementLogging loggingCommands(&commands, &robot);  // Control logging
  modeRatioDrive.addControlCommands(&commands);  // Drive mode diagnostics

  // This provides the client (e.g. MobileEyes) with a simple table of string values
  // (called an InfoGroup). An InfoGroup is kept globally by Aria.
  // The values in the table sent to clients are retrieved periodically by calling a 
  // functor.
  ArServerInfoStrings stringInfo(&server);
  Aria::getInfoGroup()->addAddStringCallback(stringInfo.getAddStringFunctor());

  // Here are some example entries in the InfoGroup:
  Aria::getInfoGroup()->addStringInt(
	  "Motor Packet Count", 10, 
	  new ArConstRetFunctorC<int, ArRobot>(&robot, 
					       &ArRobot::getMotorPacCount));

  //
  // Connect to the robot:
  // 
  
  if (!simpleConnector.connectRobot(&robot))
  {
    printf("Error: Could not connect to robot... exiting\n");
    Aria::shutdown();
    return 1;
  }


  robot.enableMotors();
  robot.runAsync(true);

  // The simple opener might have information to display right before starting 
  // the server thread:
  simpleOpener.checkAndLog();

  // now let the server base run in a new thread, accepting client connections.
  server.runAsync();

  ArLog::log(ArLog::Normal, "Server is now running... Press Ctrl-C to exit.");

  robot.waitForRunExit();
  Aria::shutdown();
  exit(0);  
}
int main(int argc, char **argv) 
{

  Aria::init();
  ArRobot robot;
  ArArgumentParser argParser(&argc, argv);
  ArSimpleConnector connector(&argParser);
  ArGripper gripper(&robot);
  ArSonarDevice sonar;
  robot.addRangeDevice(&sonar);

  argParser.loadDefaultArguments();

  if (!Aria::parseArgs() || !argParser.checkHelpAndWarnUnparsed())
  {
    Aria::logOptions();
    Aria::shutdown();
    return 1;
  }
  
  if (!connector.connectRobot(&robot))
  {
    ArLog::log(ArLog::Terse, "gripperExample: Could not connect to robot... exiting");
    Aria::shutdown();
    return 2;
  }
  ArLog::log(ArLog::Normal, "gripperExample: Connected to robot.");

  ArLog::log(ArLog::Normal, "gripperExample: GripperType=%d", gripper.getType());
  gripper.logState();
  if(gripper.getType() == ArGripper::NOGRIPPER)
  {
    ArLog::log(ArLog::Terse, "gripperExample: Error: Robot does not have a gripper. Exiting.");
    Aria::shutdown();
    return -1;
  }

  // Teleoperation actions with obstacle-collision avoidance
  ArActionLimiterTableSensor tableLimit;
  robot.addAction(&tableLimit, 110);
  ArActionLimiterForwards limitNearAction("near", 300, 600, 250);
  robot.addAction(&limitNearAction, 100);
  ArActionLimiterForwards limitFarAction("far", 300, 1100, 400);
  robot.addAction(&limitFarAction, 90);
  ArActionLimiterBackwards limitBackAction;
  robot.addAction(&limitBackAction, 50);
  ArActionJoydrive joydriveAction("joydrive", 400, 15);
  robot.addAction(&joydriveAction, 40);
  joydriveAction.setStopIfNoButtonPressed(false);
  ArActionKeydrive keydriveAction;
  robot.addAction(&keydriveAction, 30);
  

  // Handlers to control the gripper and print out info (classes defined above)
  PrintGripStatus printStatus(&gripper);
  GripperControlHandler gripControl(&gripper);
  printStatus.addRobotTask(&robot);
  gripControl.addKeyHandlers(&robot);

  // enable motors and run (if we lose connection to the robot, exit)
  ArLog::log(ArLog::Normal, "You may now operate the robot with arrow keys or joystick. Operate the gripper with the u, d, o, c, and page up/page down keys.");
  robot.enableMotors();
  robot.run(true);
  
  Aria::shutdown();
  return 0;
}
int _tmain(int argc, char** argv)
{
    //-------------- M A I N    D E L   P R O G R A M A   D E L    R O B O T------------//
    //----------------------------------------------------------------------------------//

    //inicializaion de variables
    Aria::init();
    ArArgumentParser parser(&argc, argv);
    parser.loadDefaultArguments();
    ArSimpleConnector simpleConnector(&parser);
    ArRobot robot;
    ArSonarDevice sonar;
    ArAnalogGyro gyro(&robot);
    robot.addRangeDevice(&sonar);
    ActionTurns turn(400, 55);
    robot.addAction(&turn, 49);
    ActionTurns turn2(400, 55);
    robot.addAction(&turn2, 49);
    turn.deactivate();
    turn2.deactivate();

    // presionar tecla escape para salir del programa
    ArKeyHandler keyHandler;
    Aria::setKeyHandler(&keyHandler);
    robot.attachKeyHandler(&keyHandler);
    printf("Presionar ESC para salir\n");

    // uso de sonares para evitar colisiones con las paredes u
    // obstaculos grandes, mayores a 8cm de alto
    ArActionLimiterForwards limiterAction("limitador velocidad cerca", 300, 600, 250);
    ArActionLimiterForwards limiterFarAction("limitador velocidad lejos", 300, 1100, 400);
    ArActionLimiterTableSensor tableLimiterAction;
    robot.addAction(&tableLimiterAction, 100);
    robot.addAction(&limiterAction, 95);
    robot.addAction(&limiterFarAction, 90);


    // Inicializon la funcion de goto
    ArActionGoto gotoPoseAction("goto");
    robot.addAction(&gotoPoseAction, 50);

    // Finaliza el goto si es que no hace nada
    ArActionStop stopAction("stop");
    robot.addAction(&stopAction, 40);

    // Parser del CLI
    if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
    {
        Aria::logOptions();
        exit(1);
    }

    // Conexion del robot
    if (!simpleConnector.connectRobot(&robot))
    {
        printf("Could not connect to robot... exiting\n");
        Aria::exit(1);
    }
    robot.runAsync(true);

    // enciende motores, apaga sonidos
    robot.enableMotors();
    robot.comInt(ArCommands::SOUNDTOG, 0);

    // Imprimo algunos datos del robot como posicion velocidad y bateria
    robot.lock();
    ArLog::log(ArLog::Normal, "Posicion=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Bateria=%.2fV",
               robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getBatteryVoltage());
    robot.unlock();

    const int duration = 100000; //msec
    ArLog::log(ArLog::Normal, "Completados los puntos en %d segundos", duration/1000);

    bool first = true;
    int goalNum = 0;
    int color = 3;
    ArTime start;
    start.setToNow();
    while (Aria::getRunning())
    {
        robot.lock();

        // inicia el primer punto
        if (first || gotoPoseAction.haveAchievedGoal())
        {
            first = false;

            goalNum++; //cambia de 0 a 1 el contador
            printf("El contador esta en: --> %d <---\n",goalNum);
            if (goalNum > 20)
                goalNum = 1;

            //comienza la secuencia de puntos
            if (goalNum == 1)
            {
                gotoPoseAction.setGoal(ArPose(1150, 0));
                ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                           gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                // Imprimo algunos datos del robot como posicion velocidad y bateria
                robot.lock();
                ArLog::log(ArLog::Normal, "Posicion=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Bateria=%.2fV",
                           robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getBatteryVoltage());
                robot.unlock();
            }
            else if (goalNum == 2)
            {
                printf("Gira 90 grados izquierda\n");
                robot.unlock();
                turn.myActivate = 1;
                turn.myDirection = 1;
                turn.activate();
                ArUtil::sleep(1000);
                turn.deactivate();
                turn.myActivate = 0;
                turn.myDirection = 0;
                robot.lock();
            }
            else if (goalNum == 3)
            {
                gotoPoseAction.setGoal(ArPose(1150, 2670));
                ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                           gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                // Imprimo algunos datos del robot como posicion velocidad y bateria
                robot.lock();
                ArLog::log(ArLog::Normal, "Posicion=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Bateria=%.2fV",
                           robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getBatteryVoltage());
                robot.unlock();
            }
            else if (goalNum == 4)
            {
                printf("Gira 90 grados izquierda\n");
                robot.unlock();
                turn2.myActivate = 1;
                turn2.myDirection = 1;
                turn2.activate();
                ArUtil::sleep(1000);
                turn2.deactivate();
                turn2.myActivate = 0;
                turn2.myDirection = 0;
                robot.lock();
            }
            else if (goalNum == 5)
            {
                gotoPoseAction.setGoal(ArPose(650, 2670));
                ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                           gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
            }
            else if (goalNum == 6)
            {
                printf("Gira 90 grados izquierda\n");
                robot.unlock();
                turn2.myActivate = 1;
                turn2.myDirection = 1;
                turn2.activate();
                ArUtil::sleep(1000);
                turn2.deactivate();
                turn2.myActivate = 0;
                turn2.myDirection = 0;
                robot.lock();
            }
            else if (goalNum == 7)
            {
                gotoPoseAction.setGoal(ArPose(650, 0));
                ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                           gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
            }
            else if (goalNum == 8)
            {
                gotoPoseAction.setGoal(ArPose(1800,1199));
                ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                           gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
            }
            else if (goalNum == 9)
            {
                gotoPoseAction.setGoal(ArPose(2600, 1199));
                ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                           gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
            }
            else if (goalNum == 10)
            {
                if (color == 1)
                {
                    gotoPoseAction.setGoal(ArPose(2800, 850));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
                if (color == 2)
                {
                    gotoPoseAction.setGoal(ArPose(3500, 1199));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
                if (color == 3)
                {
                    gotoPoseAction.setGoal(ArPose(2800, 1550));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
            }
            else if (goalNum == 11)
            {
                if (color == 1)
                {
                    gotoPoseAction.setGoal(ArPose(2800, 613));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
                if (color == 2)
                {
                    printf("Gira 180 grados derecha\n");
                    robot.unlock();
                    turn2.myActivate = 1;
                    turn2.myDirection = 2;
                    turn2.activate();
                    ArUtil::sleep(2000);
                    turn2.deactivate();
                    turn2.myActivate = 0;
                    turn2.myDirection = 0;
                    robot.lock();
                    goalNum = 19;
                }
                if (color == 3)
                {
                    gotoPoseAction.setGoal(ArPose(2800, 1785));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
            }
            else if (goalNum == 12)
            {
                if (color == 1)
                {
                    gotoPoseAction.setGoal(ArPose(3300, 413));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
                if (color == 3)
                {
                    gotoPoseAction.setGoal(ArPose(3300, 1985));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
            }
            else if (goalNum == 13)
            {
                if (color == 1)
                {
                    gotoPoseAction.setGoal(ArPose(3500, 413));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
                if (color == 3)
                {
                    gotoPoseAction.setGoal(ArPose(3500, 1985));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
            }
            else if (goalNum == 14)
            {
                //secuencia de drop de la figura
            }
            else if (goalNum == 15)
            {
                printf("Gira 180 grados derecha\n");
                robot.unlock();
                turn2.myActivate = 1;
                turn2.myDirection = 2;
                turn2.activate();
                ArUtil::sleep(2000);
                turn2.deactivate();
                turn2.myActivate = 0;
                turn2.myDirection = 0;
                robot.lock();
            }
            else if (goalNum == 16)
            {
                if (color == 1)
                {
                    gotoPoseAction.setGoal(ArPose(3300, 413));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
                if (color == 3)
                {
                    gotoPoseAction.setGoal(ArPose(3300, 1985));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
            }
            else if (goalNum == 17)
            {
                if (color == 1)
                {
                    gotoPoseAction.setGoal(ArPose(2800, 603));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
                if (color == 3)
                {
                    gotoPoseAction.setGoal(ArPose(2800, 1795));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
            }
            else if (goalNum == 18)
            {
                if (color == 1)
                {
                    gotoPoseAction.setGoal(ArPose(2800, 860));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
                if (color == 3)
                {
                    gotoPoseAction.setGoal(ArPose(2800, 1540));
                    ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                               gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
                }
            }
            else if (goalNum == 19)
            {
                gotoPoseAction.setGoal(ArPose(2600, 1199));
                ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                           gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
            }
            else if (goalNum == 20)
            {
                gotoPoseAction.setGoal(ArPose(1800, 1199));
                ArLog::log(ArLog::Normal, "Siguiente punto en %.0f %.0f",
                           gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
            }
        }

        if(start.mSecSince() >= duration) {
            ArLog::log(ArLog::Normal, "No puede llegar al punto, y la aplicacion saldra en %d", duration/1000);
            gotoPoseAction.cancelGoal();
            robot.unlock();
            ArUtil::sleep(3000);
            break;
        }

        robot.unlock();
        ArUtil::sleep(10);
    }

    // Robot desconectado al terminal el sleep
    Aria::shutdown();

//----------------------------------------------------------------------------------//

    return 0;
}
Exemplo n.º 25
0
int main(int argc, char **argv)
{
    Aria::init();
    //ArLog::init(ArLog::StdOut, ArLog::Verbose);
    // robot
    ArRobot robot;
    /// our server
    ArServerBase server;

    // set up our parser
    ArArgumentParser parser(&argc, argv);
    // set up our simple connector
    ArSimpleConnector simpleConnector(&parser);

    // set up a gyro
    ArAnalogGyro gyro(&robot);

    // load the default arguments
    parser.loadDefaultArguments();

    // parse the command line... fail and print the help if the parsing fails
    // or if the help was requested
    if (!simpleConnector.parseArgs() || !parser.checkHelpAndWarnUnparsed())
    {
        simpleConnector.logOptions();
        exit(1);
    }

    if (!server.loadUserInfo("userServerTest.userInfo"))
    {
        printf("Could not load user info, exiting\n");
        exit(1);
    }

    server.logUsers();

    // first open the server up
    if (!server.open(7272))
    {
        printf("Could not open server port\n");
        exit(1);
    }

    // sonar, must be added to the robot
    ArSonarDevice sonarDev;
    // add the sonar to the robot
    robot.addRangeDevice(&sonarDev);

    ArIRs irs;
    robot.addRangeDevice(&irs);

    ArBumpers bumpers;
    robot.addRangeDevice(&bumpers);

    // a laser in case one is used
    ArSick sick(361, 180);
    // add the laser to the robot
    robot.addRangeDevice(&sick);




    // attach stuff to the server
    ArServerInfoRobot serverInfoRobot(&server, &robot);
    ArServerInfoSensor serverInfoSensor(&server, &robot);
    ArServerInfoDrawings drawings(&server);
    drawings.addRobotsRangeDevices(&robot);

    // ways of moving the robot
    ArServerModeStop modeStop(&server, &robot);
    ArServerModeDrive modeDrive(&server, &robot);
    ArServerModeRatioDrive modeRatioDrive(&server, &robot);
    ArServerModeWander modeWander(&server, &robot);
    modeStop.addAsDefaultMode();
    modeStop.activate();

    // set up the simple commands
    ArServerHandlerCommands commands(&server);
    // add the commands for the microcontroller
    ArServerSimpleComUC uCCommands(&commands, &robot);
    // add the commands for logging
    ArServerSimpleComMovementLogging loggingCommands(&commands, &robot);
    // add the commands for the gyro
    ArServerSimpleComGyro gyroCommands(&commands, &robot, &gyro);

    // add the commands to enable and disable safe driving to the simple commands
    modeDrive.addControlCommands(&commands);

    // Forward any video if we have some to forward.. this will forward
    // from SAV or ACTS, you can find both on our website
    // http://robots.activmedia.com, ACTS is for color tracking and is
    // charged for but SAV just does software A/V transmitting and is
    // free to all our customers... just run ACTS or SAV before you
    // start this program and this class here will forward video from it
    // to MobileEyes
    ArHybridForwarderVideo videoForwarder(&server, "localhost", 7070);

    // make a camera to use in case we have video
    ArPTZ *camera = NULL;
    ArServerHandlerCamera *handlerCamera = NULL;
    // if we have video then set up a camera
    if (videoForwarder.isForwardingVideo())
    {
        bool invertedCamera = false;
        camera = new ArVCC4(&robot,	invertedCamera,
                            ArVCC4::COMM_UNKNOWN, true, true);
        camera->init();
        handlerCamera = new ArServerHandlerCamera(&server, &robot, camera);
    }

    server.logCommandGroups();
    server.logCommandGroupsToFile("userServerTest.commandGroups");

    // now let it spin off in its own thread
    server.runAsync();

    // set up the robot for connecting
    if (!simpleConnector.connectRobot(&robot))
    {
        printf("Could not connect to robot... exiting\n");
        Aria::shutdown();
        return 1;
    }

    // set up the laser before handing it to the laser mode
    simpleConnector.setupLaser(&sick);

    robot.enableMotors();
    // start the robot running, true so that if we lose connection the run stops
    robot.runAsync(true);

    sick.runAsync();

    // connect the laser if it was requested
    if (!simpleConnector.connectLaser(&sick))
    {
        printf("Could not connect to laser... exiting\n");
        Aria::shutdown();
        return 1;
    }

    robot.waitForRunExit();
    // now exit
    Aria::shutdown();
    exit(0);
}
Exemplo n.º 26
0
int main(int argc, char **argv)
{
  Aria::init();
  ArArgumentParser parser(&argc, argv);
  parser.loadDefaultArguments();
  ArRobot robot;
  ArAnalogGyro gyro(&robot);
  ArSonarDevice sonar;
  ArRobotConnector robotConnector(&parser, &robot);
  ArLaserConnector laserConnector(&parser, &robot, &robotConnector);


  // Connect to the robot, get some initial data from it such as type and name,
  // and then load parameter files for this robot.
  if(!robotConnector.connectRobot())
  {
    ArLog::log(ArLog::Terse, "gotoActionExample: Could not connect to the robot.");
    if(parser.checkHelpAndWarnUnparsed())
    {
        // -help not given
        Aria::logOptions();
        Aria::exit(1);
    }
  }

  if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
  {
    Aria::logOptions();
    Aria::exit(1);
  }

  ArLog::log(ArLog::Normal, "gotoActionExample: Connected to robot.");

  robot.addRangeDevice(&sonar);
  robot.runAsync(true);

  // Make a key handler, so that escape will shut down the program
  // cleanly
  ArKeyHandler keyHandler;
  Aria::setKeyHandler(&keyHandler);
  robot.attachKeyHandler(&keyHandler);
  printf("You may press escape to exit\n");

  // Collision avoidance actions at higher priority
  ArActionLimiterForwards limiterAction("speed limiter near", 300, 600, 250);
  ArActionLimiterForwards limiterFarAction("speed limiter far", 300, 1100, 400);
  ArActionLimiterTableSensor tableLimiterAction;
  robot.addAction(&tableLimiterAction, 100);
  robot.addAction(&limiterAction, 95);
  robot.addAction(&limiterFarAction, 90);

  // Goto action at lower priority
  ArActionGoto gotoPoseAction("goto");
  robot.addAction(&gotoPoseAction, 50);
  
  // Stop action at lower priority, so the robot stops if it has no goal
  ArActionStop stopAction("stop");
  robot.addAction(&stopAction, 40);


  // turn on the motors, turn off amigobot sounds
  robot.enableMotors();
  robot.comInt(ArCommands::SOUNDTOG, 0);

  const int duration = 30000; //msec
  ArLog::log(ArLog::Normal, "Going to four goals in turn for %d seconds, then cancelling goal and exiting.", duration/1000);

  bool first = true;
  int goalNum = 0;
  ArTime start;
  start.setToNow();
  while (Aria::getRunning()) 
  {
    robot.lock();

    // Choose a new goal if this is the first loop iteration, or if we 
    // achieved the previous goal.
    if (first || gotoPoseAction.haveAchievedGoal())
    {
      first = false;
      goalNum++;
      if (goalNum > 4)
        goalNum = 1; // start again at goal #1

      // set our positions for the different goals
      if (goalNum == 1)
        gotoPoseAction.setGoal(ArPose(2500, 0));
      else if (goalNum == 2)
        gotoPoseAction.setGoal(ArPose(2500, 2500));
      else if (goalNum == 3)
        gotoPoseAction.setGoal(ArPose(0, 2500));
      else if (goalNum == 4)
        gotoPoseAction.setGoal(ArPose(0, 0));

      ArLog::log(ArLog::Normal, "Going to next goal at %.0f %.0f", 
		    gotoPoseAction.getGoal().getX(), gotoPoseAction.getGoal().getY());
    }

    if(start.mSecSince() >= duration) {
      ArLog::log(ArLog::Normal, "%d seconds have elapsed. Cancelling current goal, waiting 3 seconds, and exiting.", duration/1000);
      gotoPoseAction.cancelGoal();
      robot.unlock();
      ArUtil::sleep(3000);
      break;
    }

    robot.unlock();
    ArUtil::sleep(100);
  }
  
  // Robot disconnected or time elapsed, shut down
  Aria::exit(0);
  return 0;
}
int main(int argc, char** argv)
{
  Aria::init();
  ArArgumentParser argParser(&argc, argv);
  ArSimpleConnector con(&argParser);
  ArRobot robot;
  ArSonarDevice sonar;

  argParser.loadDefaultArguments();
  if(!Aria::parseArgs() || !argParser.checkHelpAndWarnUnparsed())
  {
    Aria::logOptions();
    return 1;
  }

  /* - the action group for teleoperation actions: */
  teleop = new ArActionGroup(&robot);

  // don't hit any tables (if the robot has IR table sensors)
  teleop->addAction(new ArActionLimiterTableSensor, 100);

  // limiter for close obstacles
  teleop->addAction(new ArActionLimiterForwards("speed limiter near", 
						300, 600, 250), 95);

  // limiter for far away obstacles
  teleop->addAction(new ArActionLimiterForwards("speed limiter far", 
					       300, 1100, 400), 90);

  // limiter so we don't bump things backwards
  teleop->addAction(new ArActionLimiterBackwards, 85);

  // the joydrive action (drive from joystick)
  ArActionJoydrive joydriveAct("joydrive", 400, 15);
  teleop->addAction(&joydriveAct, 50);

  // the keydrive action (drive from keyboard)
  teleop->addAction(new ArActionKeydrive, 45);
  


  /* - the action group for wander actions: */
  wander = new ArActionGroup(&robot);

  // if we're stalled we want to back up and recover
  wander->addAction(new ArActionStallRecover, 100);

  // react to bumpers
  wander->addAction(new ArActionBumpers, 75);

  // turn to avoid things closer to us
  wander->addAction(new ArActionAvoidFront("Avoid Front Near", 225, 0), 50);

  // turn avoid things further away
  wander->addAction(new ArActionAvoidFront, 45);

  // keep moving
  wander->addAction(new ArActionConstantVelocity("Constant Velocity", 400), 25);

  

  /* - use key commands to switch modes, and use keyboard
   *   and joystick as inputs for teleoperation actions. */

  // create key handler if Aria does not already have one
  ArKeyHandler *keyHandler = Aria::getKeyHandler();
  if (keyHandler == NULL)
  {
    keyHandler = new ArKeyHandler;
    Aria::setKeyHandler(keyHandler);
    robot.attachKeyHandler(keyHandler);
  }

  // set the callbacks
  ArGlobalFunctor teleopCB(&teleopMode);
  ArGlobalFunctor wanderCB(&wanderMode);
  keyHandler->addKeyHandler('w', &wanderCB);
  keyHandler->addKeyHandler('W', &wanderCB);
  keyHandler->addKeyHandler('t', &teleopCB);
  keyHandler->addKeyHandler('T', &teleopCB);

  // if we don't have a joystick, let 'em know
  if (!joydriveAct.joystickInited())
    printf("Note: Do not have a joystick, only the arrow keys on the keyboard will work.\n");
  
  // set the joystick so it won't do anything if the button isn't pressed
  joydriveAct.setStopIfNoButtonPressed(false);


  /* - connect to the robot, then enter teleoperation mode.  */

  robot.addRangeDevice(&sonar);
  if(!con.connectRobot(&robot))
  { 
    ArLog::log(ArLog::Terse, "actionGroupExample: Could not connect to the robot.");
    Aria::shutdown();
    return 1;
  }

  robot.enableMotors();
  teleopMode();
  robot.run(true);

  Aria::shutdown();
  return 0;
}
int main(int argc, char **argv)
{

  Aria::init();
  ArRobot robot;
  ArArgumentParser parser(&argc, argv);
  parser.loadDefaultArguments();

  ArLog::log(ArLog::Terse, "WARNING: this program does no sensing or avoiding of obstacles, the robot WILL collide with any objects in the way! Make sure the robot has approximately 3 meters of free space on all sides.");

  // ArRobotConnector connects to the robot, get some initial data from it such as type and name,
  // and then loads parameter files for this robot.
  ArRobotConnector robotConnector(&parser, &robot);
  if(!robotConnector.connectRobot())
  {
    ArLog::log(ArLog::Terse, "simpleMotionCommands: Could not connect to the robot.");
    if(parser.checkHelpAndWarnUnparsed())
    {
        Aria::logOptions();
        Aria::exit(1);
        return 1;
    }
  }
  if (!Aria::parseArgs())
  {
    Aria::logOptions();
    Aria::exit(1);
    return 1;
  }
  
  ArLog::log(ArLog::Normal, "simpleMotionCommands: Connected.");

  // Start the robot processing cycle running in the background.
  // True parameter means that if the connection is lost, then the 
  // run loop ends.
  robot.runAsync(true);

  // Print out some data from the SIP.  

  // We must "lock" the ArRobot object
  // before calling its methods, and "unlock" when done, to prevent conflicts
  // with the background thread started by the call to robot.runAsync() above.
  // See the section on threading in the manual for more about this.
  // Make sure you unlock before any sleep() call or any other code that will
  // take some time; if the robot remains locked during that time, then
  // ArRobot's background thread will be blocked and unable to communicate with
  // the robot, call tasks, etc.
  
  robot.lock();
  ArLog::log(ArLog::Normal, "simpleMotionCommands: Pose=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Rot. Vel=%.2f, Battery=%.2fV",
    robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getRotVel(), robot.getBatteryVoltage());
  robot.unlock();

  // Sleep for 3 seconds.
  ArLog::log(ArLog::Normal, "simpleMotionCommands: Will start driving in 3 seconds...");
  ArUtil::sleep(3000);

  // Set forward velocity to 50 mm/s
  ArLog::log(ArLog::Normal, "simpleMotionCommands: Driving forward at 250 mm/s for 5 sec...");
  robot.lock();
  robot.enableMotors();
  robot.setVel(250);
  robot.unlock();
  ArUtil::sleep(5000);

  ArLog::log(ArLog::Normal, "simpleMotionCommands: Stopping.");
  robot.lock();
  robot.stop();
  robot.unlock();
  ArUtil::sleep(1000);

  ArLog::log(ArLog::Normal, "simpleMotionCommands: Rotating at 10 deg/s for 5 sec...");
  robot.lock();
  robot.setRotVel(10);
  robot.unlock();
  ArUtil::sleep(5000);

  ArLog::log(ArLog::Normal, "simpleMotionCommands: Rotating at -10 deg/s for 10 sec...");
  robot.lock();
  robot.setRotVel(-10);
  robot.unlock();
  ArUtil::sleep(10000);

  ArLog::log(ArLog::Normal, "simpleMotionCommands: Driving forward at 150 mm/s for 5 sec...");
  robot.lock();
  robot.setRotVel(0);
  robot.setVel(150);
  robot.unlock();
  ArUtil::sleep(5000);

  ArLog::log(ArLog::Normal, "simpleMotionCommands: Stopping.");
  robot.lock();
  robot.stop();
  robot.unlock();
  ArUtil::sleep(1000);


  // Other motion command functions include move(), setHeading(),
  // setDeltaHeading().  You can also adjust acceleration and deceleration
  // values used by the robot with setAccel(), setDecel(), setRotAccel(),
  // setRotDecel().  See the ArRobot class documentation for more.

  
  robot.lock();
  ArLog::log(ArLog::Normal, "simpleMotionCommands: Pose=(%.2f,%.2f,%.2f), Trans. Vel=%.2f, Rot. Vel=%.2f, Battery=%.2fV",
    robot.getX(), robot.getY(), robot.getTh(), robot.getVel(), robot.getRotVel(), robot.getBatteryVoltage());
  robot.unlock();

  
  ArLog::log(ArLog::Normal, "simpleMotionCommands: Ending robot thread...");
  robot.stopRunning();

  // wait for the thread to stop
  robot.waitForRunExit();

  // exit
  ArLog::log(ArLog::Normal, "simpleMotionCommands: Exiting.");
  Aria::exit(0);
  return 0;
}
Exemplo n.º 29
0
int main(int argc, char **argv)
{
  Aria::init();
  ArArgumentParser argParser(&argc, argv);
  argParser.loadDefaultArguments();
  ArRobot robot;
  ArRobotConnector robotConnector(&argParser, &robot);
  ArLaserConnector laserConnector(&argParser, &robot, &robotConnector);

  // Always try to connect to the first laser:
  argParser.addDefaultArgument("-connectLaser");

  if(!robotConnector.connectRobot())
  {
    ArLog::log(ArLog::Terse, "Could not connect to the robot.");
    if(argParser.checkHelpAndWarnUnparsed())
    {
        // -help not given, just exit.
        Aria::logOptions();
        Aria::exit(1);
    }
  }


  // Trigger argument parsing
  if (!Aria::parseArgs() || !argParser.checkHelpAndWarnUnparsed())
  {
    Aria::logOptions();
    Aria::exit(1);
  }

  ArKeyHandler keyHandler;
  Aria::setKeyHandler(&keyHandler);
  robot.attachKeyHandler(&keyHandler);

  puts("This program will make the robot wander around. It uses some avoidance\n"
  "actions if obstacles are detected, otherwise it just has a\n"
  "constant forward velocity.\n\nPress CTRL-C or Escape to exit.");
  
  ArSonarDevice sonar;
  robot.addRangeDevice(&sonar);

  robot.runAsync(true);

  
  // try to connect to laser. if fail, warn but continue, using sonar only
  if(!laserConnector.connectLasers())
  {
    ArLog::log(ArLog::Normal, "Warning: unable to connect to requested lasers, will wander using robot sonar only.");
  }


  // turn on the motors, turn off amigobot sounds
  robot.enableMotors();
  robot.comInt(ArCommands::SOUNDTOG, 0);

  // add a set of actions that combine together to effect the wander behavior
  ArActionStallRecover recover;
  ArActionBumpers bumpers;
  ArActionAvoidFront avoidFrontNear("Avoid Front Near", 225, 0);
  ArActionAvoidFront avoidFrontFar;
  ArActionConstantVelocity constantVelocity("Constant Velocity", 400);
  robot.addAction(&recover, 100);
  robot.addAction(&bumpers, 75);
  robot.addAction(&avoidFrontNear, 50);
  robot.addAction(&avoidFrontFar, 49);
  robot.addAction(&constantVelocity, 25);
  
  // wait for robot task loop to end before exiting the program
  robot.waitForRunExit();
  
  Aria::exit(0);
}
int main(int argc, char **argv)
{
  // Initialize Aria and Arnl global information
  Aria::init();
  Arnl::init();


  // The robot object
  ArRobot robot;

  // Parse the command line arguments.
  ArArgumentParser parser(&argc, argv);

  // Set up our simpleConnector, to connect to the robot and laser
  //ArSimpleConnector simpleConnector(&parser);
  ArRobotConnector robotConnector(&parser, &robot);

  // Connect to the robot
  if (!robotConnector.connectRobot())
  {
    ArLog::log(ArLog::Normal, "Error: Could not connect to robot... exiting");
    Aria::exit(3);
  }



  // Set up where we'll look for files. Arnl::init() set Aria's default
  // directory to Arnl's default directory; addDirectories() appends this
  // "examples" directory.
  char fileDir[1024];
  ArUtil::addDirectories(fileDir, sizeof(fileDir), Aria::getDirectory(), 
			 "examples");
  
  
  // To direct log messages to a file, or to change the log level, use these  calls:
  //ArLog::init(ArLog::File, ArLog::Normal, "log.txt", true, true);
  //ArLog::init(ArLog::File, ArLog::Verbose);
 
  // Add a section to the configuration to change ArLog parameters
  ArLog::addToConfig(Aria::getConfig());

  // set up a gyro (if the robot is older and its firmware does not
  // automatically incorporate gyro corrections, then this object will do it)
  ArAnalogGyro gyro(&robot);

  // Our networking server
  ArServerBase server;
  

  // Set up our simpleOpener, used to set up the networking server
  ArServerSimpleOpener simpleOpener(&parser);

  // the laser connector
  ArLaserConnector laserConnector(&parser, &robot, &robotConnector);

  // Tell the laser connector to always connect the first laser since
  // this program always requires a laser.
  parser.addDefaultArgument("-connectLaser");
  
  // Load default arguments for this computer (from /etc/Aria.args, environment
  // variables, and other places)
  parser.loadDefaultArguments();

  // Parse arguments 
  if (!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed())
  {
    logOptions(argv[0]);
    Aria::exit(1);
  }
  

  // This causes Aria::exit(9) to be called if the robot unexpectedly
  // disconnects
  ArGlobalFunctor1<int> shutdownFunctor(&Aria::exit, 9);
  robot.addDisconnectOnErrorCB(&shutdownFunctor);


  // Create an ArSonarDevice object (ArRangeDevice subclass) and 
  // connect it to the robot.
  ArSonarDevice sonarDev;
  robot.addRangeDevice(&sonarDev);



  // This object will allow robot's movement parameters to be changed through
  // a Robot Configuration section in the ArConfig global configuration facility.
  ArRobotConfig robotConfig(&robot);

  // Include gyro configuration options in the robot configuration section.
  robotConfig.addAnalogGyro(&gyro);

  // Start the robot thread.
  robot.runAsync(true);
  

  // connect the laser(s) if it was requested, this adds them to the
  // robot too, and starts them running in their own threads
  if (!laserConnector.connectLasers())
  {
    ArLog::log(ArLog::Normal, "Could not connect to all lasers... exiting\n");
    Aria::exit(2);
  }

  // find the laser we should use for localization and/or mapping,
  // which will be the first laser
  robot.lock();
  ArLaser *firstLaser = robot.findLaser(1);
  if (firstLaser == NULL || !firstLaser->isConnected())
  {
    ArLog::log(ArLog::Normal, "Did not have laser 1 or it is not connected, cannot start localization and/or mapping... exiting");
    Aria::exit(2);
  }
  robot.unlock();


    /* Create and set up map object */
  
  // Set up the map object, this will look for files in the examples
  // directory (unless the file name starts with a /, \, or .
  // You can take out the 'fileDir' argument to look in the program's current directory
  // instead.
  // When a configuration file is loaded into ArConfig later, if it specifies a
  // map file, then that file will be loaded as the map.
  ArMap map(fileDir);
  // set it up to ignore empty file names (otherwise if a configuration omits
  // the map file, the whole configuration change will fail)
  map.setIgnoreEmptyFileName(true);
  // ignore the case, so that if someone is using MobileEyes or
  // MobilePlanner from Windows and changes the case on a map name,
  // it will still work.
  map.setIgnoreCase(true);

    
    /* Create localization and path planning threads */


  ArPathPlanningTask pathTask(&robot, &sonarDev, &map);



  ArLog::log(ArLog::Normal, "Creating laser localization task");
  // Laser Monte-Carlo Localization
  ArLocalizationTask locTask(&robot, firstLaser, &map);



  // Set some options on each laser that the laser connector 
  // connected to.
  std::map<int, ArLaser *>::iterator laserIt;
  for (laserIt = robot.getLaserMap()->begin();
       laserIt != robot.getLaserMap()->end();
       laserIt++)
  {
    int laserNum = (*laserIt).first;
    ArLaser *laser = (*laserIt).second;

    // Skip lasers that aren't connected
    if(!laser->isConnected())
      continue;

    // add the disconnectOnError CB to shut things down if the laser
    // connection is lost
    laser->addDisconnectOnErrorCB(&shutdownFunctor);
    // set the number of cumulative readings the laser will take
    laser->setCumulativeBufferSize(200);
    // add the lasers to the path planning task
    pathTask.addRangeDevice(laser, ArPathPlanningTask::BOTH);
    // set the cumulative clean offset (so that they don't all fire at once)
    laser->setCumulativeCleanOffset(laserNum * 100);
    // reset the cumulative clean time (to make the new offset take effect)
    laser->resetLastCumulativeCleanTime();

    // Add the packet count to the Aria info strings (It will be included in
    // MobileEyes custom details so you can monitor whether the laser data is
    // being received correctly)
    std::string laserPacketCountName;
    laserPacketCountName = laser->getName();
    laserPacketCountName += " Packet Count";
    Aria::getInfoGroup()->addStringInt(
	    laserPacketCountName.c_str(), 10, 
	    new ArRetFunctorC<int, ArLaser>(laser, 
					 &ArLaser::getReadingCount));
  }


  // Used for optional multirobot features (see below) (TODO move to multirobot
  // example?)
  ArClientSwitchManager clientSwitch(&server, &parser);




    /* Start the server */

  // Open the networking server
  if (!simpleOpener.open(&server, fileDir, 240))
  {
    ArLog::log(ArLog::Normal, "Error: Could not open server.");
    exit(2);
  }



    /* Create various services that provide network access to clients (such as
     * MobileEyes), as well as add various additional features to ARNL */


  // ARNL can optionally get information about the positions of other robots from a
  // "central server" (see central server example program), if command
  // line options specifying the address of the central server was given.
  // If there is no central server, then the address of each other robot
  // can instead be given in the configuration, and the multirobot systems
  // will connect to each robot (or "peer") individually.

        // TODO move this to multirobot example?


  bool usingCentralServer = false;
  if(clientSwitch.getCentralServerHostName() != NULL)
    usingCentralServer = true;

  // if we're using the central server then we want to create the
  // multiRobot central classes
  if (usingCentralServer)
  {
    // Make the handler for multi robot information (this sends the
    // information to the central server)
    //ArServerHandlerMultiRobot *handlerMultiRobot = 
    new ArServerHandlerMultiRobot(&server, &robot, 
						      &pathTask,
						      &locTask, &map);
    
    // Normally each robot, and the central server, must all have
    // the same map name for the central server to share robot
    // information.  (i.e. they are operating in the same space).
    // This changes the map name that ArServerHandlerMutliRobot 
    // reports to the central server, in case you want this individual
    // robot to load a different map file name, but still report 
    // the common map file to the central server.
    //handlerMultiRobot->overrideMapName("central.map");

    // the range device that gets the multi robot information from
    // the central server and presents it as virtual range readings
    // to ARNL
    ArMultiRobotRangeDevice *multiRobotRangeDevice = new ArMultiRobotRangeDevice(&server);
    
    robot.addRangeDevice(multiRobotRangeDevice);
    pathTask.addRangeDevice(multiRobotRangeDevice, 
			    ArPathPlanningTask::BOTH);
    
    // Set up options for drawing multirobot information in MobileEyes.
    multiRobotRangeDevice->setCurrentDrawingData(
	    new ArDrawingData("polyDots", ArColor(125, 125, 0),
			      100, 73, 1000), true);
    multiRobotRangeDevice->setCumulativeDrawingData(
	    new ArDrawingData("polyDots", ArColor(125, 0, 125),
			      100, 72, 1000), true);

    // This sets up the localization to use the known poses of other robots
    // for its localization in cases where numerous robots crowd out the map.
    locTask.setMultiRobotCallback(multiRobotRangeDevice->getOtherRobotsCB());
  }
  // if we're not using a central server then create the multirobot peer classes
  else
  {
    // set the path planning so it uses the explicit collision range for how far its planning
    pathTask.setUseCollisionRangeForPlanningFlag(true);
    // make our thing that gathers information from the other servers
    ArServerHandlerMultiRobotPeer *multiRobotPeer = NULL;
    ArMultiRobotPeerRangeDevice *multiRobotPeerRangeDevice = NULL;
    multiRobotPeerRangeDevice = new ArMultiRobotPeerRangeDevice(&map);
    // make our thing that sends information to the other servers
    multiRobotPeer = new ArServerHandlerMultiRobotPeer(&server, &robot, 
						     &pathTask, &locTask);
    // hook the two together so they both know what priority this robot is
    multiRobotPeer->setNewPrecedenceCallback(
	    multiRobotPeerRangeDevice->getSetPrecedenceCallback());
    // hook the two together so they both know what priority this
    // robot's fingerprint is
    multiRobotPeer->setNewFingerprintCallback(
	    multiRobotPeerRangeDevice->getSetFingerprintCallback());
    // hook the two together so that the range device can call on the
    // server handler to change its fingerprint
    multiRobotPeerRangeDevice->setChangeFingerprintCB(
	    multiRobotPeer->getChangeFingerprintCB());
    // then add the robot to the places it needs to be
    robot.addRangeDevice(multiRobotPeerRangeDevice);
    pathTask.addRangeDevice(multiRobotPeerRangeDevice, 
			    ArPathPlanningTask::BOTH);

    // Set the range device so that we can see the information its using
    // to avoid, you can comment these out in order to not see them
    multiRobotPeerRangeDevice->setCurrentDrawingData(
	    new ArDrawingData("polyDots", ArColor(125, 125, 0),
			      100, 72, 1000), true);
    multiRobotPeerRangeDevice->setCumulativeDrawingData(
	    new ArDrawingData("polyDots", ArColor(125, 0, 125),
			      100, 72, 1000), true);
    // This sets up the localization to use the known poses of other robots
    // for its localization in cases where numerous robots crowd out the map.
    locTask.setMultiRobotCallback(
	    multiRobotPeerRangeDevice->getOtherRobotsCB());
  }




  /* Add additional range devices to the robot and path planning task (so it
     avoids obstacles detected by these devices) */
  
  // Add IR range device to robot and path planning task (so it avoids obstacles
  // detected by this device)
  robot.lock();
  ArIRs irs;
  robot.addRangeDevice(&irs);
  pathTask.addRangeDevice(&irs, ArPathPlanningTask::CURRENT);

  // Add bumpers range device to robot and path planning task (so it avoids obstacles
  // detected by this device)
  ArBumpers bumpers;
  robot.addRangeDevice(&bumpers);
  pathTask.addRangeDevice(&bumpers, ArPathPlanningTask::CURRENT);

  // Add range device which uses forbidden regions given in the map to give virtual
  // range device readings to ARNL.  (so it avoids obstacles
  // detected by this device)
  ArForbiddenRangeDevice forbidden(&map);
  robot.addRangeDevice(&forbidden);
  pathTask.addRangeDevice(&forbidden, ArPathPlanningTask::CURRENT);

  robot.unlock();


  // Action to slow down robot when localization score drops but not lost.
  ArActionSlowDownWhenNotCertain actionSlowDown(&locTask);
  pathTask.getPathPlanActionGroup()->addAction(&actionSlowDown, 140);

  // Action to stop the robot when localization is "lost" (score too low)
  ArActionLost actionLostPath(&locTask, &pathTask);
  pathTask.getPathPlanActionGroup()->addAction(&actionLostPath, 150);

  // Arnl uses this object when it must replan its path because its
  // path is completely blocked.  It will use an older history of sensor
  // readings to replan this new path.  This should not be used with SONARNL
  // since sonar readings are not accurate enough and may prevent the robot
  // from planning through space that is actually clear.
  ArGlobalReplanningRangeDevice replanDev(&pathTask);

  
  // Service to provide drawings of data in the map display :
  ArServerInfoDrawings drawings(&server);
  drawings.addRobotsRangeDevices(&robot);
  drawings.addRangeDevice(&replanDev);

  /* Draw a box around the local path planning area use this 
    (You can enable this particular drawing from custom commands 
    which is set up down below in ArServerInfoPath) */
  ArDrawingData drawingDataP("polyLine", ArColor(200,200,200), 1, 75);
  ArFunctor2C<ArPathPlanningTask, ArServerClient *, ArNetPacket *> 
    drawingFunctorP(&pathTask, &ArPathPlanningTask::drawSearchRectangle);
  drawings.addDrawing(&drawingDataP, "Local Plan Area", &drawingFunctorP); 

  /* Show the sample points used by MCL */
  ArDrawingData drawingDataL("polyDots", ArColor(0,255,0), 100, 75);
  ArFunctor2C<ArLocalizationTask, ArServerClient *, ArNetPacket *> 
    drawingFunctorL(&locTask, &ArLocalizationTask::drawRangePoints);
  drawings.addDrawing(&drawingDataL, "Localization Points", &drawingFunctorL);


  // "Custom" commands. You can add your own custom commands here, they will
  // be available in MobileEyes' custom commands (enable in the toolbar or
  // access through Robot Tools)
  ArServerHandlerCommands commands(&server);


  // These provide various kinds of information to the client:
  ArServerInfoRobot serverInfoRobot(&server, &robot);
  ArServerInfoSensor serverInfoSensor(&server, &robot);
  ArServerInfoPath serverInfoPath(&server, &robot, &pathTask);
  serverInfoPath.addSearchRectangleDrawing(&drawings);
  serverInfoPath.addControlCommands(&commands);

  // Provides localization info and allows the client (MobileEyes) to relocalize at a given
  // pose:
  ArServerInfoLocalization serverInfoLocalization(&server, &robot, &locTask);
  ArServerHandlerLocalization serverLocHandler(&server, &robot, &locTask);

  // If you're using MobileSim, ArServerHandlerLocalization sends it a command
  // to move the robot's true pose if you manually do a localization through 
  // MobileEyes.  To disable that behavior, use this constructor call instead:
  // ArServerHandlerLocalization serverLocHandler(&server, &robot, true, false);
  // The fifth argument determines whether to send the command to MobileSim.

  // Provide the map to the client (and related controls):
  ArServerHandlerMap serverMap(&server, &map);

  // These objects add some simple (custom) commands to 'commands' for testing and debugging:
  ArServerSimpleComUC uCCommands(&commands, &robot);                   // Send any command to the microcontroller
  ArServerSimpleComMovementLogging loggingCommands(&commands, &robot); // configure logging
  ArServerSimpleComLogRobotConfig configCommands(&commands, &robot);   // trigger logging of the robot config parameters
//  ArServerSimpleServerCommands serverCommands(&commands, &server);     // monitor networking behavior (track packets sent etc.)


  // service that allows the client to monitor the communication link status
  // between the robot and the client.
  //
  ArServerHandlerCommMonitor handlerCommMonitor(&server);



  // service that allows client to change configuration parameters in ArConfig 
  ArServerHandlerConfig handlerConfig(&server, Aria::getConfig(),
				      Arnl::getTypicalDefaultParamFileName(),
				      Aria::getDirectory());



  /* Set up the possible modes for remote control from a client such as
   * MobileEyes:
   */

  // Mode To go to a goal or other specific point:
  ArServerModeGoto modeGoto(&server, &robot, &pathTask, &map,
			    locTask.getRobotHome(),
			    locTask.getRobotHomeCallback());


  // Mode To stop and remain stopped:
  ArServerModeStop modeStop(&server, &robot);

  // Cause the sonar to turn off automatically
  // when the robot is stopped, and turn it back on when commands to move
  // are sent. (Note, if using SONARNL to localize, then don't do this
  // since localization may get lost)
  ArSonarAutoDisabler sonarAutoDisabler(&robot);

  // Teleoperation modes To drive by keyboard, joystick, etc:
  ArServerModeRatioDrive modeRatioDrive(&server, &robot);  
//  ArServerModeDrive modeDrive(&server, &robot);            // Older mode for compatability



  // Prevent normal teleoperation driving if localization is lost using
  // a high-priority action, which enables itself when the particular mode is
  // active.
  // (You have to enter unsafe drive mode to drive when lost.)
  ArActionLost actionLostRatioDrive(&locTask, &pathTask, &modeRatioDrive);
  modeRatioDrive.getActionGroup()->addAction(&actionLostRatioDrive, 110);

  // Add drive mode section to the configuration, and also some custom (simple) commands:
  modeRatioDrive.addToConfig(Aria::getConfig(), "Teleop settings");
  modeRatioDrive.addControlCommands(&commands);

  // Wander mode (also prevent wandering if lost):
  ArServerModeWander modeWander(&server, &robot);
  ArActionLost actionLostWander(&locTask, &pathTask, &modeWander);
  modeWander.getActionGroup()->addAction(&actionLostWander, 110);


  // This provides a small table of interesting information for the client
  // to display to the operator. You can add your own callbacks to show any
  // data you want.
  ArServerInfoStrings stringInfo(&server);
  Aria::getInfoGroup()->addAddStringCallback(stringInfo.getAddStringFunctor());
  
  // Provide a set of informational data (turn on in MobileEyes with
  // View->Custom Details)

  Aria::getInfoGroup()->addStringInt(
	  "Motor Packet Count", 10, 
	  new ArConstRetFunctorC<int, ArRobot>(&robot, 
					       &ArRobot::getMotorPacCount));

  Aria::getInfoGroup()->addStringDouble(
	  "Laser Localization Score", 8, 
	  new ArRetFunctorC<double, ArLocalizationTask>(
		  &locTask, &ArLocalizationTask::getLocalizationScore),
	  "%.03f");
  Aria::getInfoGroup()->addStringInt(
	  "Laser Loc Num Samples", 8, 
	  new ArRetFunctorC<int, ArLocalizationTask>(
		  &locTask, &ArLocalizationTask::getCurrentNumSamples),
	  "%4d");


  // Display gyro status if gyro is enabled and is being handled by the firmware (gyro types 2, 3, or 4).
  // (If the firmware detects an error communicating with the gyro or IMU it
  // returns a flag, and stops using it.)
  // (This gyro type parameter, and fault flag, are only in ARCOS, not Seekur firmware)
  if(robot.getOrigRobotConfig() && robot.getOrigRobotConfig()->getGyroType() > 1)
  {
    Aria::getInfoGroup()->addStringString(
          "Gyro/IMU Status", 10,
          new ArGlobalRetFunctor1<const char*, ArRobot*>(&getGyroStatusString, &robot)
      );
  }


  // Setup the dock if there is a docking system on board.
  ArServerModeDock *modeDock = NULL;
  modeDock = ArServerModeDock::createDock(&server, &robot, &locTask, 
					  &pathTask);
  if (modeDock != NULL)
  {
    modeDock->checkDock();
    modeDock->addAsDefaultMode();
    modeDock->addToConfig(Aria::getConfig());
    modeDock->addControlCommands(&commands);
  }



  // Make Stop mode the default (If current mode deactivates without entering
  // a new mode, then Stop Mode will be selected)
  modeStop.addAsDefaultMode();
    // TODO move up near where stop mode is created?





  /* Services that allow the client to initiate scanning with the laser to
     create maps in Mapper3 (So not possible with SONARNL): */

  ArServerHandlerMapping handlerMapping(&server, &robot, firstLaser, 
					fileDir, "", true);

  // make laser localization stop while mapping
  handlerMapping.addMappingStartCallback(
	  new ArFunctor1C<ArLocalizationTask, bool>
	  (&locTask, &ArLocalizationTask::setIdleFlag, true));

  // and then make it start again when we're doine
  handlerMapping.addMappingEndCallback(
	  new ArFunctor1C<ArLocalizationTask, bool>
	  (&locTask, &ArLocalizationTask::setIdleFlag, false));


  // Make it so our "lost" actions don't stop us while mapping
  handlerMapping.addMappingStartCallback(actionLostPath.getDisableCB());
  handlerMapping.addMappingStartCallback(actionLostRatioDrive.getDisableCB());
  handlerMapping.addMappingStartCallback(actionLostWander.getDisableCB());

  // And then let them make us stop as usual when done mapping
  handlerMapping.addMappingEndCallback(actionLostPath.getEnableCB());
  handlerMapping.addMappingEndCallback(actionLostRatioDrive.getEnableCB());
  handlerMapping.addMappingEndCallback(actionLostWander.getEnableCB());

  // don't let forbidden lines show up as obstacles while mapping
  // (they'll just interfere with driving while mapping, and localization is off anyway)
  handlerMapping.addMappingStartCallback(forbidden.getDisableCB());

  // let forbidden lines show up as obstacles again as usual after mapping
  handlerMapping.addMappingEndCallback(forbidden.getEnableCB());


  /*
  // If we are on a simulator, move the robot back to its starting position,
  // and reset its odometry.
  // This will allow localizeRobotAtHomeBlocking() below will (probably) work (it
  // tries current odometry (which will be 0,0,0) and all the map
  // home points.
  // (Ignored by a real robot)
  //robot.com(ArCommands::SIM_RESET);
  */


  // create a pose storage class, this will let the program keep track
  // of where the robot is between runs...  after we try and restore
  // from this file it will start saving the robot's pose into the
  // file
  ArPoseStorage poseStorage(&robot);
  /// if we could restore the pose from then set the sim there (this
  /// won't do anything to the real robot)... if we couldn't restore
  /// the pose then just reset the position of the robot (which again
  /// won't do anything to the real robot)
  if (poseStorage.restorePose("robotPose"))
    serverLocHandler.setSimPose(robot.getPose());
  else
    robot.com(ArCommands::SIM_RESET);



  /* File transfer services: */
  
#ifdef WIN32
  // Not implemented for Windows yet.
  ArLog::log(ArLog::Normal, "Note, file upload/download services are not implemented for Windows; not enabling them.");
#else
  // This block will allow you to set up where you get and put files
  // to/from, just comment them out if you don't want this to happen
  // /*
  ArServerFileLister fileLister(&server, fileDir);
  ArServerFileToClient fileToClient(&server, fileDir);
  ArServerFileFromClient fileFromClient(&server, fileDir, "/tmp");
  ArServerDeleteFileOnServer deleteFileOnServer(&server, fileDir);
  // */
#endif

    /* Video image streaming, and camera controls (Requires SAVserver or ACTS) */

  // Forward any video if either ACTS or SAV server are running.
  // You can find out more about SAV and ACTS on our website
  // http://robots.activmedia.com. ACTS is for color tracking and is
  // a seperate product. SAV just does software A/V transmitting and is
  // free to all our customers. Just run ACTS or SAV server before you
  // start this program and this class here will forward video from the
  // server to the client.
  ArHybridForwarderVideo videoForwarder(&server, "localhost", 7070);
  
  // make a camera to use in case we have video. the camera collection collects
  // multiple ptz cameras 
  ArPTZ *camera = NULL;
  ArServerHandlerCamera *handlerCamera = NULL;
  ArCameraCollection *cameraCollection = NULL;

  // if we have video then set up a camera 
  if (videoForwarder.isForwardingVideo())
  {

    cameraCollection = new ArCameraCollection();
    cameraCollection->addCamera("Cam1", "PTZ", "Camera", "PTZ");

    videoForwarder.setCameraName("Cam1");
    videoForwarder.addToCameraCollection(*cameraCollection);

    camera = new ArVCC4(&robot); //,	invertedCamera, ArVCC4::COMM_UNKNOWN, true, true);
    // To use an RVision SEE camera instead:
    // camera = new ArRVisionPTZ(&robot);
    camera->init();

    handlerCamera = new ArServerHandlerCamera("Cam1", 
		                                           &server, 
					                                     &robot,
					                                     camera, 
					                                     cameraCollection);

    pathTask.addGoalFinishedCB(
	    new ArFunctorC<ArServerHandlerCamera>(
		    handlerCamera, 
		    &ArServerHandlerCamera::cameraModeLookAtGoalClearGoal));
  }

  // After all of the cameras / videos have been created and added to the collection,
  // then start the collection server.
  //
  if (cameraCollection != NULL) {
    new ArServerHandlerCameraCollection(&server, cameraCollection);
  }




    /* Load configuration values, map, and begin! */

  
  // When parsing the configuration file, also look at the program's command line options 
  // from the command-line argument parser as well as the configuration file.
  // (So you can use any argument on the command line, namely -map.) 
  Aria::getConfig()->useArgumentParser(&parser);
  puts("xxx");puts("aaa"); fflush(stdout);
  // Read in parameter files.
  ArLog::log(ArLog::Normal, "Loading config file %s into ArConfig (base directory %s)...", Arnl::getTypicalParamFileName(), Aria::getConfig()->getBaseDirectory());
  if (!Aria::getConfig()->parseFile(Arnl::getTypicalParamFileName()))
  {
    ArLog::log(ArLog::Normal, "Trouble loading configuration file, exiting");
    Aria::exit(5);
  }

  // Warn about unknown params.
  if (!simpleOpener.checkAndLog() || !parser.checkHelpAndWarnUnparsed())
  {
    logOptions(argv[0]);
    Aria::exit(6);
  }

  // Warn if there is no map
  if (map.getFileName() == NULL || strlen(map.getFileName()) <= 0)
  {
    ArLog::log(ArLog::Normal, "");
    ArLog::log(ArLog::Normal, "### No map file is set up, you can make a map with the following procedure");
    ArLog::log(ArLog::Normal, "   0) You can find this information in README.txt or docs/Mapping.txt");
    ArLog::log(ArLog::Normal, "   1) Connect to this server with MobileEyes");
    ArLog::log(ArLog::Normal, "   2) Go to Tools->Map Creation->Start Scan");
    ArLog::log(ArLog::Normal, "   3) Give the map a name and hit okay");
    ArLog::log(ArLog::Normal, "   4) Drive the robot around your space (see docs/Mapping.txt");
    ArLog::log(ArLog::Normal, "   5) Go to Tools->Map Creation->Stop Scan");
    ArLog::log(ArLog::Normal, "   6) Start up Mapper3");
    ArLog::log(ArLog::Normal, "   7) Go to File->Open on Robot");
    ArLog::log(ArLog::Normal, "   8) Select the .2d you created");
    ArLog::log(ArLog::Normal, "   9) Create a .map");
    ArLog::log(ArLog::Normal, "  10) Go to File->Save on Robot");
    ArLog::log(ArLog::Normal, "  11) In MobileEyes, go to Tools->Robot Config");
    ArLog::log(ArLog::Normal, "  12) Choose the Files section");
    ArLog::log(ArLog::Normal, "  13) Enter the path and name of your new .map file for the value of the Map parameter.");
    ArLog::log(ArLog::Normal, "  14) Press OK and your new map should become the map used");
    ArLog::log(ArLog::Normal, "");    
  }

  // Print a log message notifying user of the directory for map files
  ArLog::log(ArLog::Normal, "");
  ArLog::log(ArLog::Normal, 
	     "Directory for maps and file serving: %s", fileDir);
  
  ArLog::log(ArLog::Normal, "See the ARNL README.txt for more information");
  ArLog::log(ArLog::Normal, "");

  // Do an initial localization of the robot. It tries all the home points
  // in the map, as well as the robot's current odometric position, as possible
  // places the robot is likely to be at startup.   If successful, it will
  // also save the position it found to be the best localized position as the
  // "Home" position, which can be obtained from the localization task (and is
  // used by the "Go to home" network request).
  locTask.localizeRobotAtHomeBlocking();
  
  // Let the client switch manager (for multirobot) spin off into its own thread
  // TODO move to multirobot example?
  clientSwitch.runAsync();

  // Start the networking server's thread
  server.runAsync();


  // Add a key handler so that you can exit by pressing
  // escape. Note that this key handler, however, prevents this program from
  // running in the background (e.g. as a system daemon or run from 
  // the shell with "&") -- it will lock up trying to read the keys; 
  // remove this if you wish to be able to run this program in the background.
  ArKeyHandler *keyHandler;
  if ((keyHandler = Aria::getKeyHandler()) == NULL)
  {
    keyHandler = new ArKeyHandler;
    Aria::setKeyHandler(keyHandler);
    robot.lock();
    robot.attachKeyHandler(keyHandler);
    robot.unlock();
    puts("Server running. To exit, press escape.");
  }


 	
   ArnlASyncTaskExample asyncTaskExample(&pathTask, &robot, &modeGoto, &parser);



  // Enable the motors and wait until the robot exits (disconnection, etc.) or this program is
  // canceled.
  robot.enableMotors();
  robot.waitForRunExit();
  Aria::exit(0);
}