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); }
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); }
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); }
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); }
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; ArSonarDevice sonar; ArSick sick; robot.addRangeDevice(&sonar); ArServerBase server; // Argument parser: ArArgumentParser parser(&argc, argv); parser.loadDefaultArguments(); // Connector and server opener: ArRobotConnector robotConnector(&parser, &robot); if(!robotConnector.connectRobot()) { ArLog::log(ArLog::Terse, "popupExample: Could not connect to the robot."); if(parser.checkHelpAndWarnUnparsed()) { Aria::logOptions(); } Aria::exit(1); } ArLaserConnector laserConnector(&parser, &robot, &robotConnector); ArServerSimpleOpener simpleOpener(&parser); // Get command-line and other parameters if(!Aria::parseArgs() || !parser.checkHelpAndWarnUnparsed()) { Aria::logOptions(); Aria::exit(1); } robot.runAsync(true); // connect to the laser if(!laserConnector.connectLasers()) { ArLog::log(ArLog::Normal, "popupExample: Warning: Could not connect to lasers."); } // Open the server if(!simpleOpener.open(&server)) { ArLog::log(ArLog::Terse, "popupExample: Error, could not open server."); return 1; } server.runAsync(); ArLog::log(ArLog::Normal, "popupExample: Server running. Press control-C to exit."); ArLog::log(ArLog::Normal, "popupExample: Each time an obstacle is detected near the robot, a new popup message will be created. Connect with MobileEyes to see them."); // Sends robot position etc. ArServerInfoRobot robotInfoServer(&server, &robot); // This service sends drawings e.g. showing range device positions ArServerInfoDrawings drawingsServer(&server); drawingsServer.addRobotsRangeDevices(&robot); // This service can send messages to clients to display as popup dialogs: ArServerHandlerPopup popupServer(&server); // This object contains the robot sensor interpretation task and creates // popups: SensorDetectPopup(&robot, &popupServer); // modes for controlling robot movement ArServerModeStop modeStop(&server, &robot); ArServerModeRatioDrive modeRatioDrive(&server, &robot); ArServerModeWander modeWander(&server, &robot); modeStop.addAsDefaultMode(); modeStop.activate(); // allow configuration of driving and other settings 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 robot.enableMotors(); robot.waitForRunExit(); Aria::exit(0); }
int main(int argc, char **argv) { // Initialize Aria and Arnl global information Aria::init(); Arnl::init(); // You can change default ArLog options in this call, but the settings in the parameter file // (arnl.p) which is loaded below (Aria::getConfig()->parseFile()) will override the options. //ArLog::init(ArLog::File, ArLog::Normal, "log.txt", true, true); // Used to parse the command line arguments. ArArgumentParser parser(&argc, argv); // Load default arguments for this computer (from /etc/Aria.args, environment // variables, and other places) parser.loadDefaultArguments(); #ifdef ARNL_LASER // Tell the laser connector to always connect the first laser since // this program always requires a laser. parser.addDefaultArgument("-connectLaser"); #endif // The robot object ArRobot robot; // handle messages from robot controller firmware and log the contents robot.addPacketHandler(new ArGlobalRetFunctor1<bool, ArRobotPacket*>(&handleDebugMessage)); // This object is used to connect to the robot, which can be configured via // command line arguments. 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; #ifdef ARNL_GPSLOC // GPS connector. ArGPSConnector gpsConnector(&parser); #endif // Set up our simpleOpener, used to set up the networking server ArServerSimpleOpener simpleOpener(&parser); #ifdef ARNL_LASER // the laser connector ArLaserConnector laserConnector(&parser, &robot, &robotConnector); #endif // used to connect to camera PTZ control ArPTZConnector ptzConnector(&parser, &robot); #ifdef ARNL_MULTIROBOT // Used to connect to a "central server" which can be used as a proxy // for multiple robot servers, and as a way for them to also communicate with // each other. (objects implementing some of these inter-robot communication // features are created below). // NOTE: If the central server is running on the same host as robot server(s), // then you must use the -serverPort argument to instruct these robot-control // server(s) to use different ports than the default 7272, since the central // server will use that port. ArClientSwitchManager clientSwitch(&server, &parser); #endif // 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); #ifdef ARNL_GPSLOC // On the Seekur, power to the GPS receiver is switched on by this command. // (A third argument of 0 would turn it off). On other robots this command is // ignored. If this fails, you may need to reset the port with ARIA demo or // seekurPower program (turn port off then on again). If the port is already // on, it will have no effect on the GPS (it will remain powered.) // Do this now before connecting to lasers to give it plenty of time to power // on, initialize, and find a good position before GPS localization begins. ArLog::log(ArLog::Normal, "Turning on GPS power... (Seekur/Seekur Jr. power port 6)"); robot.com2Bytes(116, 6, 1); #endif #ifdef ARNL_LASER // connect the laser(s) if it was requested, this adds them to the // robot too, and starts them running in their own threads ArLog::log(ArLog::Normal, "Connecting to laser(s) configured in parameters..."); if (!laserConnector.connectLasers()) { ArLog::log(ArLog::Normal, "Error: Could not connect to laser(s). Exiting."); Aria::exit(2); } ArLog::log(ArLog::Normal, "Done connecting to laser(s)."); #endif #if defined(ARNL_LASERLOC) || defined(ARNL_MAPPING) // 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(); #endif /* 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 threads */ #ifdef ARNL_MULTILOC ArLocalizationManager locManager(&robot, &map); #define LOCTASK locManager #endif #ifdef ARNL_LASERLOC ArLog::log(ArLog::Normal, "Creating laser localization task"); // Laser Monte-Carlo Localization ArLocalizationTask locTask(&robot, firstLaser, &map); #ifdef ARNL_MULTILOC locManager.addLocalizationTask(&locTask); #else #define LOCTASK locTask #endif #endif #ifdef ARNL_SONARLOC ArLog::log(ArLog::Normal, "Creating sonar localization task"); ArSonarLocalizationTask locTask(&robot, &sonarDev, &map); #ifdef ARNL_MULTILOC locManager.addLocalizationTask(&locTask); #else #define LOCTASK locTask #endif #endif #ifndef ARNL_GPSLOC // A callback function, which is called if localization fails ArGlobalFunctor1<int> locFailedCB(&locFailed); locTask.setFailedCallBack(&locFailedCB); //, &locTask); #endif #ifdef ARNL_GPSLOC ArLog::log(ArLog::Normal, "Connecting to GPS..."); // Connect to GPS ArGPS *gps = gpsConnector.createGPS(&robot); if(!gps || !gps->connect()) { ArLog::log(ArLog::Terse, "Error connecting to GPS device." "Try -gpsType, -gpsPort, and/or -gpsBaud command-line arguments." "Use -help for help. Exiting."); Aria::exit(5); } // set up GPS localization task ArLog::log(ArLog::Normal, "Creating GPS localization task"); ArGPSLocalizationTask gpsLocTask(&robot, gps, &map); #ifdef ARNL_MULTILOC locManager.addLocalizationTask(&gpsLocTask); #else #define LOCTASK gpsLocTask #endif #endif #ifdef ARNL_LASER // Set some options and callbacks 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); // 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)); } #endif /* 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 */ robot.unlock(); // Service to provide drawings of data in the map display : ArServerInfoDrawings drawings(&server); drawings.addRobotsRangeDevices(&robot); #ifdef ARNL_LASERLOC /* 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); #endif #ifdef ARNL_GPSLOC /* Show the positions calculated by GPS localization */ ArDrawingData drawingDataG("polyDots", ArColor(100,100,255), 130, 61); ArFunctor2C<ArGPSLocalizationTask, ArServerClient *, ArNetPacket *> drawingFunctorG(&gpsLocTask, &ArGPSLocalizationTask::drawGPSPoints); drawings.addDrawing(&drawingDataG, "GPS Points", &drawingFunctorG); ArDrawingData drawingDataG2("polyDots", ArColor(255,100,100), 100, 62); ArFunctor2C<ArGPSLocalizationTask, ArServerClient *, ArNetPacket *> drawingFunctorG2(&gpsLocTask, &ArGPSLocalizationTask::drawKalmanPoints); drawings.addDrawing(&drawingDataG2, "Kalman Points", &drawingFunctorG2); ArDrawingData drawingDataG3("polyDots", ArColor(100,255,100), 70, 63); ArFunctor2C<ArGPSLocalizationTask, ArServerClient *, ArNetPacket *> drawingFunctorG3(&gpsLocTask, &ArGPSLocalizationTask::drawOdoPoints); drawings.addDrawing(&drawingDataG3, "Odom. Points", &drawingFunctorG3); ArDrawingData drawingDataG4("polyDots", ArColor(255,50,50), 100, 75); ArFunctor2C<ArGPSLocalizationTask, ArServerClient *, ArNetPacket *> drawingFunctorG4(&gpsLocTask, &ArGPSLocalizationTask::drawKalmanRangePoints); drawings.addDrawing(&drawingDataG4, "KalRange Points", &drawingFunctorG4); ArDrawingData drawingDataG5("polySegments", ArColor(100,0,255), 1, 78); ArFunctor2C<ArGPSLocalizationTask, ArServerClient *, ArNetPacket *> drawingFunctorG5(&gpsLocTask, &ArGPSLocalizationTask::drawKalmanVariance); drawings.addDrawing(&drawingDataG5, "VarGPS", &drawingFunctorG5); #endif // "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); // 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()); // This service causes the client to show simple dialog boxes ArServerHandlerPopup popupServer(&server); /* Set up the possible modes for remote control from a client such as * MobileEyes: */ // Mode To stop and remain stopped: ArServerModeStop modeStop(&server, &robot); #ifndef ARNL_SONARLOC // 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); #endif // Teleoperation modes To drive by keyboard, joystick, etc: ArServerModeRatioDrive modeRatioDrive(&server, &robot); // 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, NULL, &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, NULL, &modeWander); modeWander.getActionGroup()->addAction(&actionLostWander, 110); // Tool to log data periodically to a file ArDataLogger dataLogger(&robot, "datalog.txt"); dataLogger.addToConfig(Aria::getConfig()); // make it configurable through ArConfig // Automatically add anything from the global info group to the data logger. Aria::getInfoGroup()->addAddStringCallback(dataLogger.getAddStringFunctor()); // 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()); // The following statements add fields to a set of informational data called // the InfoGroup. These are served to MobileEyes for displayi (turn on by enabling Details // and Custom Details in the View menu of MobileEyes.) Aria::getInfoGroup()->addStringInt( "Motor Packet Count", 10, new ArConstRetFunctorC<int, ArRobot>(&robot, &ArRobot::getMotorPacCount)); #ifdef ARNL_LASERLOC 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"); #elif defined(ARNL_SONARLOC) Aria::getInfoGroup()->addStringDouble( "Sonar Localization Score", 8, new ArRetFunctorC<double, ArSonarLocalizationTask>( &locTask, &ArSonarLocalizationTask::getLocalizationScore), "%.03f"); Aria::getInfoGroup()->addStringInt( "Sonar Loc Num Samples", 8, new ArRetFunctorC<int, ArSonarLocalizationTask>( &locTask, &ArSonarLocalizationTask::getCurrentNumSamples), "%4d"); #endif #ifdef ARNL_GPSLOC const char *dopfmt = "%2.4f"; const char *posfmt = "%2.8f"; const char *altfmt = "%3.6f m"; Aria::getInfoGroup()->addStringString( "GPS Fix Mode", 25, new ArConstRetFunctorC<const char*, ArGPS>(gps, &ArGPS::getFixTypeName) ); Aria::getInfoGroup()->addStringInt( "GPS Num. Satellites", 4, new ArConstRetFunctorC<int, ArGPS>(gps, &ArGPS::getNumSatellitesTracked) ); Aria::getInfoGroup()->addStringDouble( "GPS HDOP", 12, new ArConstRetFunctorC<double, ArGPS>(gps, &ArGPS::getHDOP), dopfmt ); Aria::getInfoGroup()->addStringDouble( "GPS VDOP", 5, new ArConstRetFunctorC<double, ArGPS>(gps, &ArGPS::getVDOP), dopfmt ); Aria::getInfoGroup()->addStringDouble( "GPS PDOP", 5, new ArConstRetFunctorC<double, ArGPS>(gps, &ArGPS::getPDOP), dopfmt ); Aria::getInfoGroup()->addStringDouble( "Latitude", 15, new ArConstRetFunctorC<double, ArGPS>(gps, &ArGPS::getLatitude), posfmt ); Aria::getInfoGroup()->addStringDouble( "Longitude", 15, new ArConstRetFunctorC<double, ArGPS>(gps, &ArGPS::getLongitude), posfmt ); Aria::getInfoGroup()->addStringDouble( "Altitude", 8, new ArConstRetFunctorC<double, ArGPS>(gps, &ArGPS::getAltitude), altfmt ); // only some GPS receivers provide these, but you can uncomment them // here to enable them if yours does. /* const char *errfmt = "%2.4f m"; Aria::getInfoGroup()->addStringDouble( "GPS Lat. Err.", 6, new ArConstRetFunctorC<double, ArGPS>(gps, &ArGPS::getLatitudeError), errfmt ); Aria::getInfoGroup()->addStringDouble( "GPS Lon. Err.", 6, new ArConstRetFunctorC<double, ArGPS>(gps, &ArGPS::getLongitudeError), errfmt ); Aria::getInfoGroup()->addStringDouble( "GPS Alt. Err.", 6, new ArConstRetFunctorC<double, ArGPS>(gps, &ArGPS::getAltitudeError), errfmt ); */ Aria::getInfoGroup()->addStringDouble( "MOGS Localization Score", 8, new ArRetFunctorC<double, ArGPSLocalizationTask>( &gpsLocTask, &ArGPSLocalizationTask::getLocalizationScore), "%.03f" ); #endif // 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) ); } // Display system CPU and wireless network status ArSystemStatus::startPeriodicUpdate(1000); // update every 1 second Aria::getInfoGroup()->addStringDouble("CPU Use", 10, ArSystemStatus::getCPUPercentFunctor(), "% 4.0f%%"); Aria::getInfoGroup()->addStringInt("Wireless Link Quality", 9, ArSystemStatus::getWirelessLinkQualityFunctor(), "%d"); Aria::getInfoGroup()->addStringInt("Wireless Link Noise", 9, ArSystemStatus::getWirelessLinkNoiseFunctor(), "%d"); Aria::getInfoGroup()->addStringInt("Wireless Signal", 9, ArSystemStatus::getWirelessLinkSignalFunctor(), "%d"); // stats on how far its driven since software started Aria::getInfoGroup()->addStringDouble("Distance Travelled (m)", 20, new ArRetFunctorC<double, ArRobot>(&robot, &ArRobot::getOdometerDistanceMeters), "%.2f"); Aria::getInfoGroup()->addStringDouble("Run time (min)", 20, new ArRetFunctorC<double, ArRobot>(&robot, &ArRobot::getOdometerTimeMinutes), "%.2f"); #ifdef ARNL_GPSLOC // Add some "custom commands" for setting up initial GPS offset and heading. gpsLocTask.addLocalizationInitCommands(&commands); // Add some commands for manually creating map objects based on GPS positions: // ArGPSMapTools gpsMapTools(gps, &robot, &commands, &map); // Add command to set simulated GPS position manually if(gpsConnector.getGPSType() == ArGPSConnector::Simulator) { ArSimulatedGPS *simGPS = dynamic_cast<ArSimulatedGPS*>(gps); // simGPS->setDummyPosition(42.80709, -71.579047, 100); commands.addStringCommand("GPS:setDummyPosition", "Manually set a new dummy position for simulated GPS. Provide latitude (required), longitude (required) and altitude (optional)", new ArFunctor1C<ArSimulatedGPS, ArArgumentBuilder*>(simGPS, &ArSimulatedGPS::setDummyPositionFromArgs) ); } #endif // 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? #ifdef ARNL_MAPPING /* 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); #ifdef ARNL_LASERLOC // 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)); #endif #ifdef ARNL_GPSLOC // Save GPS positions in the .2d scan log when making a map handlerMapping.addLocationData("robotGPS", gpsLocTask.getPoseInterpPositionCallback()); // add the starting latitude and longitude info to the .2d scan log handlerMapping.addMappingStartCallback( new ArFunctor1C<ArGPSLocalizationTask, ArServerHandlerMapping *> (&gpsLocTask, &ArGPSLocalizationTask::addScanInfo, &handlerMapping)); #endif // Make it so our "lost" actions don't stop us while mapping handlerMapping.addMappingStartCallback(actionLostRatioDrive.getDisableCB()); handlerMapping.addMappingStartCallback(actionLostWander.getDisableCB()); // And then let them make us stop as usual when done mapping handlerMapping.addMappingEndCallback(actionLostRatioDrive.getEnableCB()); handlerMapping.addMappingEndCallback(actionLostWander.getEnableCB()); #endif // ARNL_MAPPING /* // 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: */ #pragma GPP off #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 #pragma GPP on /* Video image streaming, and camera controls (Requires SAVserver or ACTS) */ // Forward one video stream if either ACTS, ArVideo videoSubServer, // or SAV server are running. // ArHybridForwarderVideo allows this program to be separate from the ArVideo // library. You could replace videoForwarder and the PTZ connection code below // with a call to ArVideo::createVideoServers(), and link the program to the // ArVideo library if you want to include video capture in the same program // as robot control. ArHybridForwarderVideo videoForwarder(&server, "localhost", 7070); // connect to first configured camera PTZ controls (in robot parameter file and // command line options) ptzConnector.connect(); ArCameraCollection cameraCollection; ArPTZ *ptz = ptzConnector.getPTZ(0); if(ptz) { ArLog::log(ArLog::Normal, "Connected to PTZ Camera"); cameraCollection.addCamera("Camera1", ptz->getTypeName(), "Camera", ptz->getTypeName()); videoForwarder.setCameraName("Camera1"); videoForwarder.addToCameraCollection(cameraCollection); new ArServerHandlerCamera("Camera1", &server, &robot, ptz, &cameraCollection); } // Allows client to find any camera servers created above ArServerHandlerCameraCollection cameraCollectionServer(&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); // Read in parameter files. ArLog::log(ArLog::Normal, "Loading config file %s%s into ArConfig...", Aria::getDirectory(), Arnl::getTypicalParamFileName()); if (!Aria::getConfig()->parseFile(Arnl::getTypicalParamFileName())) { ArLog::log(ArLog::Normal, "Could not load ARNL configuration file. Set ARNL environment variable to use non-default installation director.y"); 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"); #ifdef ARNL 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, ""); #elif defined(SONARNL) ArLog::log(ArLog::Normal, " 0) You can find this information in README.txt or docs/SonarMapping.txt"); ArLog::log(ArLog::Normal, " 1) Start up Mapper3Basic"); ArLog::log(ArLog::Normal, " 2) Go to File->New"); ArLog::log(ArLog::Normal, " 3) Draw a line map of your area (make sure it is to scale)"); ArLog::log(ArLog::Normal, " 4) Go to File->Save on Robot"); ArLog::log(ArLog::Normal, " 5) In MobileEyes, go to Tools->Robot Config"); ArLog::log(ArLog::Normal, " 6) Choose the Files section"); ArLog::log(ArLog::Normal, " 7) Enter the path and name of your new .map file for the value of the Map parameter."); ArLog::log(ArLog::Normal, " 8) Press OK and your new map should become the map used"); ArLog::log(ArLog::Normal, ""); #endif #ifdef ARNL_GPSLOC ArLog::log(ArLog::Normal, "\n See docs/GPSMapping.txt for instructions on creating a map for GPS localization"); #endif } // 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. ARNL and SONARNL try 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). // MOGS instead just initializes at the current GPS position. // (You will stil have to drive the robot so it can determine the robot's // heading, however. See GPS Mapping instructions.) LOCTASK.localizeRobotAtHomeBlocking(); #ifdef ARNL_MULTIROBOT // Let the client switch manager (for multirobot) spin off into its own thread // TODO move to multirobot example? clientSwitch.runAsync(); #endif // Start the networking server's thread server.runAsync(); ArLog::log(ArLog::Normal, "Server running. To exit, press CTRL-C."); // Enable the motors and wait until the robot exits (disconnection, etc.) or this program is // canceled. robot.enableMotors(); robot.waitForRunExit(); Aria::exit(0); }