Exemplo n.º 1
0
void NaoMarkServiceDetection::callback(const std::string &key, const AL::ALValue &value, const AL::ALValue &msg) 
{
	AL::ALValue marks = fMemoryProxy.getData("LandmarkDetected");

	if(marks.getSize() > 0 && !_isMarkFound)
	{
		int TimeStampField = marks[0][1];
		if((int)marks[1][0][1][0] == _markToFind)
		{
			if((float)marks[1][0][0][3] < 0.2f)
			{
				if(_isAllowedToMove)
					motionProxy->moveToward(0.5f,0,marks[1][0][0][1]);
				_naoMarkDetected = true;
			}
			else
			{
				motionProxy->moveToward(0,0,0);
				_isMarkFound = true;
			}
		}
		else
			motionProxy->moveToward(0,0,0);
	}
}
Exemplo n.º 2
0
void Bumper::init() {
  try {
    /** Create a proxy to ALMemory.
    */
    fMemoryProxy = AL::ALMemoryProxy(getParentBroker());

    fState = fMemoryProxy.getData("RightBumperPressed");
    /** Subscribe to event LeftBumperPressed
    * Arguments:
    * - name of the event
    * - name of the module to be called for the callback
    * - name of the bound method to be called on event
    */
    fMemoryProxy.subscribeToEvent("RightBumperPressed", "Bumper",
                                  "onRightBumperPressed");
  }
  catch (const AL::ALError& e) {
    qiLogError("module.example") << e.what() << std::endl;
  }
}
Exemplo n.º 3
0
void Bumper::onRightBumperPressed() {
  qiLogInfo("module.example") << "Executing callback method on right bumper event" << std::endl;
  /**
  * As long as this is defined, the code is thread-safe.
  */
  AL::ALCriticalSection section(fCallbackMutex);

  /**
  * Check that the bumper is pressed.
  */
  fState =  fMemoryProxy.getData("RightBumperPressed");
  if (fState  > 0.5f) {
    return;
  }
  try {
    fTtsProxy = AL::ALTextToSpeechProxy(getParentBroker());
    fTtsProxy.say("Right bumper pressed");
  }
  catch (const AL::ALError& e) {
    qiLogError("module.example") << e.what() << std::endl;
  }
}
Exemplo n.º 4
0
  /**
   * The constructor initializes the shared memory for communicating with bhuman.
   * It also establishes a communication with NaoQi and prepares all data structures
   * required for this communication.
   * @param pBroker A NaoQi broker that allows accessing other NaoQi modules.
   */
  BHuman(boost::shared_ptr<AL::ALBroker> pBroker) :
    ALModule(pBroker, "BHuman"),
    data((LBHData*) MAP_FAILED),
    sem(SEM_FAILED),
    proxy(0),
    memory(0),
    dcmTime(0),
    lastReadingActuators(-1),
    actuatorDrops(0),
    frameDrops(allowedFrameDrops + 1),
    state(sitting),
    phase(0.f),
    ledIndex(0),
    rightEarLEDsChangedTime(0),
    startPressedTime(0),
    lastBHumanStartTime(0)
  {
    setModuleDescription("A module that provides basic ipc NaoQi DCM access using shared memory.");
    fprintf(stderr, "libbhuman: Starting.\n");

    assert(lbhNumOfSensorIds == sizeof(sensorNames) / sizeof(*sensorNames));
    assert(lbhNumOfActuatorIds == sizeof(actuatorNames) / sizeof(*actuatorNames));
    assert(lbhNumOfTeamInfoIds == sizeof(teamInfoNames) / sizeof(*teamInfoNames));

    // create shared memory
    memoryHandle = shm_open(LBH_MEM_NAME, O_CREAT | O_RDWR, S_IRUSR | S_IWUSR);
    if(memoryHandle == -1)
      perror("libbhuman: shm_open");
    else if(ftruncate(memoryHandle, sizeof(LBHData)) == -1)
      perror("libbhuman: ftruncate");
    else
    {
      // map the shared memory
      data = (LBHData*) mmap(NULL, sizeof(LBHData), PROT_READ | PROT_WRITE, MAP_SHARED, memoryHandle, 0);
      if(data == MAP_FAILED)
        perror("libbhuman: mmap");
      else
      {
        memset(data, 0, sizeof(LBHData));

        // open semaphore
        sem = sem_open(LBH_SEM_NAME, O_CREAT | O_RDWR, S_IRUSR | S_IWUSR, 0);
        if(sem == SEM_FAILED)
          perror("libbhuman: sem_open");
        else
          try
          {
            // get the robot name
            memory = new AL::ALMemoryProxy(pBroker);

            std::string robotName = (std::string) memory->getData("Device/DeviceList/ChestBoard/BodyNickName", 0);
            strncpy(data->robotName, robotName.c_str(), sizeof(data->robotName));

            // create "positionRequest" and "hardnessRequest" alias
            proxy = new AL::DCMProxy(pBroker);

            AL::ALValue params;
            AL::ALValue result;
            params.arraySetSize(1);
            params.arraySetSize(2);

            params[0] = std::string("positionActuators");
            params[1].arraySetSize(lbhNumOfPositionActuatorIds);
            for(int i = 0; i < lbhNumOfPositionActuatorIds; ++i)
              params[1][i] = std::string(actuatorNames[i]);
            result = proxy->createAlias(params);

            params[0] = std::string("hardnessActuators");
            params[1].arraySetSize(lbhNumOfHardnessActuatorIds);
            for(int i = 0; i < lbhNumOfHardnessActuatorIds; ++i)
              params[1][i] = std::string(actuatorNames[headYawHardnessActuator + i]);
            result = proxy->createAlias(params);

            params[0] = std::string("usRequest");
            params[1].arraySetSize(1);
            params[1][0] = std::string(actuatorNames[usActuator]);
            result = proxy->createAlias(params);

            // prepare positionRequest
            positionRequest.arraySetSize(6);
            positionRequest[0] = std::string("positionActuators");
            positionRequest[1] = std::string("ClearAll");
            positionRequest[2] = std::string("time-separate");
            positionRequest[3] = 0;
            positionRequest[4].arraySetSize(1);
            positionRequest[5].arraySetSize(lbhNumOfPositionActuatorIds);
            for(int i = 0; i < lbhNumOfPositionActuatorIds; ++i)
              positionRequest[5][i].arraySetSize(1);

            // prepare hardnessRequest
            hardnessRequest.arraySetSize(6);
            hardnessRequest[0] = std::string("hardnessActuators");
            hardnessRequest[1] = std::string("ClearAll");
            hardnessRequest[2] = std::string("time-separate");
            hardnessRequest[3] = 0;
            hardnessRequest[4].arraySetSize(1);
            hardnessRequest[5].arraySetSize(lbhNumOfHardnessActuatorIds);
            for(int i = 0; i < lbhNumOfHardnessActuatorIds; ++i)
              hardnessRequest[5][i].arraySetSize(1);

            // prepare usRequest
            usRequest.arraySetSize(6);
            usRequest[0] = std::string("usRequest");
            usRequest[1] = std::string("Merge"); // doesn't work with "ClearAll"
            usRequest[2] = std::string("time-separate");
            usRequest[3] = 0;
            usRequest[4].arraySetSize(1);
            usRequest[5].arraySetSize(1);
            usRequest[5][0].arraySetSize(1);

            // prepare ledRequest
            ledRequest.arraySetSize(3);
            ledRequest[1] = std::string("ClearAll");
            ledRequest[2].arraySetSize(1);
            ledRequest[2][0].arraySetSize(2);
            ledRequest[2][0][1] = 0;

            // prepare sensor pointers
            for(int i = 0; i < lbhNumOfSensorIds; ++i)
              sensorPtrs[i] = (float*) memory->getDataPtr(sensorNames[i]);
            resetUsMeasurements();

            // initialize requested actuators
            memset(requestedActuators, 0, sizeof(requestedActuators));
            for(int i = faceLedRedLeft0DegActuator; i < chestBoardLedRedActuator; ++i)
              requestedActuators[i] = -1.f;

            // register "onPreProcess" and "onPostProcess" callbacks
            theInstance = this;
            proxy->getGenericProxy()->getModule()->atPreProcess(&onPreProcess);
            proxy->getGenericProxy()->getModule()->atPostProcess(&onPostProcess);

            fprintf(stderr, "libbhuman: Started!\n");
            return; // success
          }
          catch(AL::ALError& e)
          {
            fprintf(stderr, "libbhuman: %s\n", e.toString().c_str());
          }
      }
    }
    close(); // error
  }
Exemplo n.º 5
0
  /**
   * The method reads all sensors. It also detects if the chest button was pressed
   * for at least three seconds. In that case, it shuts down the robot.
   */
  void readSensors()
  {
    // get new sensor values and copy them to the shared memory block
    try
    {
      // copy sensor values into the shared memory block
      int writingSensors = 0;
      if(writingSensors == data->newestSensors)
        ++writingSensors;
      if(writingSensors == data->readingSensors)
        if(++writingSensors == data->newestSensors)
          ++writingSensors;
      assert(writingSensors != data->newestSensors);
      assert(writingSensors != data->readingSensors);

      float* sensors = data->sensors[writingSensors];
      for(int i = 0; i < lbhNumOfSensorIds; ++i)
        sensors[i] = *sensorPtrs[i];

      AL::ALValue value = memory->getData("GameCtrl/RoboCupGameControlData");
      if(value.isBinary() && value.getSize() == sizeof(RoboCup::RoboCupGameControlData))
        memcpy(&data->gameControlData[writingSensors], value, sizeof(RoboCup::RoboCupGameControlData));

      data->newestSensors = writingSensors;

      // detect shutdown request via chest-button
      if(*sensorPtrs[chestButtonSensor] == 0.f)
        startPressedTime = dcmTime;
      else if(state != shuttingDown && startPressedTime && dcmTime - startPressedTime > 3000)
      {
        if(*sensorPtrs[rBumperRightSensor] != 0.f || *sensorPtrs[rBumperLeftSensor] != 0.f ||
           *sensorPtrs[lBumperRightSensor] != 0.f || *sensorPtrs[lBumperLeftSensor] != 0.f)
          (void) !system("( /home/nao/bin/bhumand stop && sudo shutdown -r now ) &");
        else
          (void) !system("( /home/nao/bin/bhumand stop && sudo shutdown -h now ) &");
        state = preShuttingDown;
      }
    }
    catch(AL::ALError& e)
    {
      fprintf(stderr, "libbhuman: %s\n", e.toString().c_str());
    }

    // raise the semaphore
    if(sem != SEM_FAILED)
    {
      int sval;
      if(sem_getvalue(sem, &sval) == 0)
      {
        if(sval < 1)
        {
          sem_post(sem);
          frameDrops = 0;
        }
        else
        {
          if(frameDrops == 0)
            fprintf(stderr, "libbhuman: dropped sensor data.\n");
          ++frameDrops;
        }
      }
    }
  }