Ejemplo n.º 1
0
// Search for the item specified by index and ensure the item is visible.
bool ObxTreeView::select(const QModelIndex & index)
{
    selected_ = -1;
    for(int i = 0; i < all_items_.size(); ++i)
    {
        if (all_items_.at(i)->index() == index)
        {
            selected_ = i;
            break;
        }
    }

    if (selected_ < 0)
    {
        return false;
    }

    // Update tree widget if necessary.
    int new_page = selected_ / itemsPerPage() + 1;
    first_visible_ = (new_page - 1) * items_per_page_;
    if (isVisible())
    {
        updateTreeWidget();
        reportPosition();
    }
    return true;
}
Ejemplo n.º 2
0
void GraphicalReporter::reportGame(const Quackle::Game &game, Quackle::ComputerPlayer *computerPlayer)
{
	reportHeader(game);

	for (Quackle::PositionList::const_iterator it = game.history().begin(); it != game.history().end(); ++it)
	{
		reportPosition(*it, computerPlayer);
	}
}
Ejemplo n.º 3
0
void ObxTreeView::setModel(QStandardItemModel * model)
{
    header_bar_.setModel(model);
    model_ = model;
    all_items_.clear();
    setupInternalModel(model_, model_->invisibleRootItem(), -1);
    if (isVisible())
    {
        updateTreeWidget();
        reportPosition();
    }
}
Ejemplo n.º 4
0
void ObxTreeView::resizeEvent(QResizeEvent *)
{
    // Need to calculate the first_visible according to the select item.
    if (selected_ < 0)
    {
        selected_ = 0;
    }

    first_visible_ = selected_ / itemsPerPage() * itemsPerPage();
    updateTreeWidget();
    updateLayout(itemsPerPage());
    reportPosition();
}
Ejemplo n.º 5
0
bool ObxTreeView::jumpToPage(int page)
{
    if (page < 1 || page > pages() || page == currentPage())
    {
        return false;
    }

    first_visible_  = (page - 1)* items_per_page_;
    selected_ = first_visible_;
    updateTreeWidget();
    reportPosition();
    return true;
}
Ejemplo n.º 6
0
bool DuokanTreeView::pageDown()
{
    int new_pos = first_visible_ + items_per_page_;
    if (new_pos >= all_items_.size())
    {
        emit exceed(false);
        return false;
    }

    first_visible_ = new_pos;
    selected_ = first_visible_;
    updateTreeWidget();
    reportPosition();
    return true;
}
Ejemplo n.º 7
0
bool DuokanTreeView::pageUp()
{
    if (first_visible_ <= 0)
    {
        emit exceed(true);
        return false;
    }

    first_visible_ -= items_per_page_;
    if (first_visible_ < 0)
    {
        first_visible_ = 0;
    }
    selected_ = first_visible_;
    updateTreeWidget();
    reportPosition();
    return true;
}
Ejemplo n.º 8
0
bool ObxTreeView::pageDown()
{
    int new_pos = first_visible_ + items_per_page_;
    if (new_pos >= all_items_.size())
    {
        emit exceed(false);
        if (selected_ < all_items_.size() - 1)
        {
            navigate(all_items_.size() - 1 - selected_);
        }
        return false;
    }

    first_visible_ = new_pos;
    selected_ = first_visible_;
    updateTreeWidget();
    reportPosition();
    return true;
}
Ejemplo n.º 9
0
bool ObxTreeView::navigate(int offset)
{
    // Check new position is valid or not.
    int new_select = selected_ + offset;
    if (new_select < 0 ||
        new_select >= all_items_.size())
    {
        return false;
    }

    bool page_changed = false;
    selected_ = new_select;
    if (new_select < first_visible_)
    {
        first_visible_ -= itemsPerPage();
        page_changed = true;
    }
    else if (new_select >= first_visible_ + itemsPerPage())
    {
        first_visible_ += itemsPerPage();
        page_changed = true;
    }

    updateTreeWidget();

    if (page_changed)
    {
        reportPosition();
    }
    else
    {
        onyx::screen::instance().flush();
        onyx::screen::instance().updateWidget(
            this,
            onyx::screen::ScreenProxy::DW,
            false,
            onyx::screen::ScreenCommand::WAIT_ALL);
    }
    return true;
}
/**
 * xDest - destination X in steps
 * yDest - destination Y in steps
 * zDest - destination Z in steps
 * maxStepsPerSecond - maximum number of steps per second
 * maxAccelerationStepsPerSecond - maximum number of acceleration in steps per second
 */
int StepperControl::moveToCoords(		long xDest, long yDest, long zDest, 
						unsigned int xMaxSpd, unsigned int yMaxSpd, unsigned int zMaxSpd,
                				bool xHome, bool yHome, bool zHome) {

 	unsigned long currentMillis         = 0;
	unsigned long timeStart             = millis();

	int incomingByte     = 0;
	int error            = 0;

	// load motor settings

	loadMotorSettings();

	// if a speed is given in the command, use that instead of the config speed

	if (xMaxSpd > 0 && xMaxSpd < speedMax[0]) {
		speedMax[0] = xMaxSpd;
	}

	if (yMaxSpd > 0 && yMaxSpd < speedMax[1]) {
		speedMax[1] = yMaxSpd;
	}

	if (zMaxSpd > 0 && zMaxSpd < speedMax[2]) {
		speedMax[2] = zMaxSpd;
	}

        axisX.setMaxSpeed(speedMax[0]);
        axisY.setMaxSpeed(speedMax[1]);
        axisZ.setMaxSpeed(speedMax[2]);

	// Load coordinates into axis class

	long sourcePoint[3]     = {0,0,0};
	sourcePoint[0] 		= CurrentState::getInstance()->getX();
	sourcePoint[1] 		= CurrentState::getInstance()->getY();
	sourcePoint[2] 		= CurrentState::getInstance()->getZ();

	long currentPoint[3]    = {0,0,0};
	currentPoint[0] 	= CurrentState::getInstance()->getX();
	currentPoint[1]		= CurrentState::getInstance()->getY();
	currentPoint[2]		= CurrentState::getInstance()->getZ();

	long destinationPoint[3]= {0,0,0};
	destinationPoint[0] 	= xDest;
        destinationPoint[1] 	= yDest;
        destinationPoint[2] 	= zDest;

	// Load coordinates into motor control

	axisX.loadCoordinates(currentPoint[0],destinationPoint[0],xHome);
	axisY.loadCoordinates(currentPoint[1],destinationPoint[1],yHome);
	axisZ.loadCoordinates(currentPoint[2],destinationPoint[2],zHome);

	// Prepare for movement

	storeEndStops();
	reportEndStops();


	axisX.setDirectionAxis();
	axisY.setDirectionAxis();
	axisZ.setDirectionAxis();

        enableMotors();

	// Start movement

	axisActive[0] = true;
	axisActive[1] = true;
	axisActive[2] = true;


	axisX.checkMovement();
	axisY.checkMovement();
	axisZ.checkMovement();

	Timer1.start();

	// Let the interrupt handle all the movements
	while (axisActive[0] || axisActive[1] || axisActive[2]) {

		delay(1);

		axisActive[0] = axisX.isAxisActive();
		axisActive[1] = axisY.isAxisActive();
		axisActive[2] = axisZ.isAxisActive();

	        storeEndStops();

		// Check timeouts
		if (axisActive[0] == true && ((millis() >= timeStart && millis() - timeStart > timeOut[0] * 1000) || (millis() < timeStart && millis() > timeOut[0] * 1000))) {
			error = 1;
		}
		if (axisActive[1] == true && ((millis() >= timeStart && millis() - timeStart > timeOut[0] * 1000) || (millis() < timeStart && millis() > timeOut[0] * 1000))) {
			error = 1;
		}
		if (axisActive[2] == true && ((millis() >= timeStart && millis() - timeStart > timeOut[0] * 1000) || (millis() < timeStart && millis() > timeOut[0] * 1000))) {
			error = 1;
		}

		// Check if there is an emergency stop command
		if (Serial.available() > 0) {
                	incomingByte = Serial.read();
			if (incomingByte == 69 || incomingByte == 101) {
				error = 1;
			}
	        }

		if (error == 1) {
			Serial.print("R99 error\n");
			Timer1.stop();
			axisActive[0] = false;
			axisActive[1] = false;
			axisActive[2] = false;
		}

		// Periodically send message still active
		currentMillis++;
		if (currentMillis % 2500 == 0)
		{
			Serial.print("R04\n");
		}

	}

	Serial.print("R99 stopped\n");

	Timer1.stop();
	disableMotors();

	currentPoint[0] = axisX.currentPoint();
	currentPoint[1] = axisY.currentPoint();
	currentPoint[2] = axisZ.currentPoint();

	CurrentState::getInstance()->setX(currentPoint[0]);
	CurrentState::getInstance()->setY(currentPoint[1]);
	CurrentState::getInstance()->setZ(currentPoint[2]);

        storeEndStops();
	reportEndStops();
	reportPosition();

	return error;
}
int StepperControl::calibrateAxis(int axis) {

	// Load motor settings

	loadMotorSettings();

	//unsigned long timeStart             = millis();

        bool movementDone    = false;

	int  paramValueInt   = 0;
	int  stepsCount	     = 0;
	int  incomingByte    = 0;
	int  error           = 0;


	bool invertEndStops = false;
	int parEndInv;
	int parNbrStp;

	// Prepare for movement

	storeEndStops();
	reportEndStops();


	// Select the right axis
	StepperControlAxis calibAxis;
	switch (axis) {
		case 0:
			calibAxis      = axisX;
			parEndInv      = MOVEMENT_INVERT_ENDPOINTS_X;
			parNbrStp      = MOVEMENT_AXIS_NR_STEPS_X;
			invertEndStops = endStInv[0];
			break;
		case 1:
			calibAxis      = axisY;
			parEndInv      = MOVEMENT_INVERT_ENDPOINTS_Y;;
			parNbrStp      = MOVEMENT_AXIS_NR_STEPS_Y;
			invertEndStops = endStInv[0];
			break;
		case 2:
			calibAxis      = axisZ;
			parEndInv      = MOVEMENT_INVERT_ENDPOINTS_Z;
			parNbrStp      = MOVEMENT_AXIS_NR_STEPS_Z;
			invertEndStops = endStInv[0];
			break;
		default:
			Serial.print("R99 Calibration error: invalid axis selected\n");
			return 1;
	}


	// Preliminary checks

	if (calibAxis.endStopMin() || calibAxis.endStopMax()) {
		Serial.print("R99 Calibration error: end stop active before start\n");
		return 1;
	}

	Serial.print("R99");
	Serial.print(" axis ");
	Serial.print(calibAxis.label);
	Serial.print(" calibration start");
	Serial.print("\n");

	// Move towards home

        calibAxis.enableMotor();
	calibAxis.setDirectionHome();

	stepsCount = 0;
	movementDone = false;
	while (!movementDone && error == 0) {

                // Check if there is an emergency stop command
                if (Serial.available() > 0) {
                        incomingByte = Serial.read();
                        if (incomingByte == 69 || incomingByte == 101) {
                                movementDone = true;
				error = 1;
                        }
                }

		// Move until the end stop for home position is reached
		if ((!calibAxis.endStopMin() && !calibAxis.endStopMax()) && !movementDone) {

			calibAxis.setMotorStep();

			delayMicroseconds(1000000 / speedMin[axis] /2);

			stepsCount++;
	                if (stepsCount % (speedMin[axis] * 3) == 0)
	                {
				// Periodically send message still active
	                        Serial.print("R04\n");
	                }

			calibAxis.resetMotorStep();
			delayMicroseconds(1000000 / speedMin[axis] /2);

		} else {
			movementDone = true;

			// If end stop for home is active, set the position to zero
			if (calibAxis.endStopMax())
			{
				invertEndStops = true;
			}
		}
	}

	Serial.print("R99");
	Serial.print(" axis ");
	Serial.print(calibAxis.label);
	Serial.print(" at first end stop");
	Serial.print("\n");

	// Report back the end stop setting

	if (error == 0) {
		if (invertEndStops) {
			paramValueInt = 1;
		} else {
			paramValueInt = 0;
		}

		Serial.print("R23");
		Serial.print(" ");
		Serial.print("P");
		Serial.print(parEndInv);
		Serial.print(" ");
		Serial.print("V");
		Serial.print(paramValueInt);
		Serial.print("\n");
	}

	// Store the status of the system

        storeEndStops();
	reportEndStops();

	// Move into the other direction now, and measure the number of steps

	stepsCount = 0;
	movementDone = false;
	calibAxis.setDirectionAway();

	while (!movementDone && error == 0) {

                // Check if there is an emergency stop command
                if (Serial.available() > 0) {
                        incomingByte = Serial.read();
                        if (incomingByte == 69 || incomingByte == 101) {
                                movementDone = true;
				error = 1;
                        }
                }

		// Move until the end stop at the other side of the axis is reached
		if (((!invertEndStops && !calibAxis.endStopMax()) || (invertEndStops && !calibAxis.endStopMin())) && !movementDone) {

			calibAxis.setMotorStep();
			stepsCount++;

			delayMicroseconds(1000000 / speedMin[axis] /2);

	                if (stepsCount % (speedMin[axis] * 3) == 0)
        	        {
				// Periodically send message still active
	                        Serial.print("R04\n");
	                }


			calibAxis.resetMotorStep();
			delayMicroseconds(1000000 / speedMin[axis] /2);

		} else {
			movementDone = true;
		}
	}


	Serial.print("R99");
	Serial.print(" axis ");
	Serial.print(calibAxis.label);
	Serial.print(" at second end stop");
	Serial.print("\n");

	// Report back the end stop setting

	if (error == 0) {
		Serial.print("R23");
		Serial.print(" ");
		Serial.print("P");
		Serial.print(parNbrStp);
		Serial.print(" ");
		Serial.print("V");
		Serial.print(stepsCount);
		Serial.print("\n");
	}

	calibAxis.disableMotor();

        storeEndStops();
	reportEndStops();


        switch (axis) {
		case 0:
			CurrentState::getInstance()->setX(stepsCount);
			break;
		case 1:
		        CurrentState::getInstance()->setY(stepsCount);
			break;
		case 2:
		        CurrentState::getInstance()->setZ(stepsCount);
			break;
	}

	reportPosition();

	return error;
}
int StepperControl::calibrateAxis(int axis)
{

  // Load motor and encoder settings

  loadMotorSettings();
  loadEncoderSettings();

  //unsigned long timeStart             = millis();

  bool movementDone = false;

  int paramValueInt = 0;
  int stepsCount = 0;
  int incomingByte = 0;
  int error = 0;

  bool invertEndStops = false;
  int parEndInv;
  int parNbrStp;

  float *missedSteps;
  int *missedStepsMax;
  long *lastPosition;
  float *encoderStepDecay;
  bool *encoderEnabled;
  int *axisStatus;
  long *axisStepsPerMm;

  // Prepare for movement

  storeEndStops();
  reportEndStops();

  // Select the right axis
  StepperControlAxis *calibAxis;
  StepperControlEncoder *calibEncoder;

  switch (axis)
  {
  case 0:
    calibAxis = &axisX;
    calibEncoder = &encoderX;
    parEndInv = MOVEMENT_INVERT_ENDPOINTS_X;
    parNbrStp = MOVEMENT_AXIS_NR_STEPS_X;
    invertEndStops = endStInv[0];
    missedSteps = &motorConsMissedSteps[0];
    missedStepsMax = &motorConsMissedStepsMax[0];
    lastPosition = &motorLastPosition[0];
    encoderStepDecay = &motorConsMissedStepsDecay[0];
    encoderEnabled = &motorConsEncoderEnabled[0];
    axisStatus = &axisSubStep[0];
    axisStepsPerMm = &stepsPerMm[0];
    break;
  case 1:
    calibAxis = &axisY;
    calibEncoder = &encoderY;
    parEndInv = MOVEMENT_INVERT_ENDPOINTS_Y;
    parNbrStp = MOVEMENT_AXIS_NR_STEPS_Y;
    invertEndStops = endStInv[1];
    missedSteps = &motorConsMissedSteps[1];
    missedStepsMax = &motorConsMissedStepsMax[1];
    lastPosition = &motorLastPosition[1];
    encoderStepDecay = &motorConsMissedStepsDecay[1];
    encoderEnabled = &motorConsEncoderEnabled[1];
    axisStatus = &axisSubStep[1];
    axisStepsPerMm = &stepsPerMm[1];
    break;
  case 2:
    calibAxis = &axisZ;
    calibEncoder = &encoderZ;
    parEndInv = MOVEMENT_INVERT_ENDPOINTS_Z;
    parNbrStp = MOVEMENT_AXIS_NR_STEPS_Z;
    invertEndStops = endStInv[2];
    missedSteps = &motorConsMissedSteps[2];
    missedStepsMax = &motorConsMissedStepsMax[2];
    lastPosition = &motorLastPosition[2];
    encoderStepDecay = &motorConsMissedStepsDecay[2];
    encoderEnabled = &motorConsEncoderEnabled[2];
    axisStatus = &axisSubStep[2];
    axisStepsPerMm = &stepsPerMm[2];
    break;
  default:
    Serial.print("R99 Calibration error: invalid axis selected\r\n");
    error = 1;
    CurrentState::getInstance()->setLastError(error);
    return error;
  }

  // Preliminary checks

  if (calibAxis->endStopMin() || calibAxis->endStopMax())
  {
    Serial.print("R99 Calibration error: end stop active before start\r\n");
    error = 1;
    CurrentState::getInstance()->setLastError(error);
    return error;
  }

  Serial.print("R99");
  Serial.print(" axis ");
  Serial.print(calibAxis->channelLabel);
  Serial.print(" move to start for calibration");
  Serial.print("\r\n");

  *axisStatus = COMM_REPORT_MOVE_STATUS_START_MOTOR;
  reportStatus(calibAxis, axisStatus[0]);

  // Move towards home
  calibAxis->enableMotor();
  calibAxis->setDirectionHome();
  calibAxis->setCurrentPosition(calibEncoder->currentPosition());

  stepsCount = 0;
  *missedSteps = 0;
  movementDone = false;

  motorConsMissedSteps[0] = 0;
  motorConsMissedSteps[1] = 0;
  motorConsMissedSteps[2] = 0;

  *axisStatus = COMM_REPORT_MOVE_STATUS_CRAWLING;
  reportStatus(calibAxis, axisStatus[0]);

  reportCalib(calibAxis, COMM_REPORT_CALIBRATE_STATUS_TO_HOME);

  while (!movementDone && error == 0)
  {

    #if defined(FARMDUINO_V14)
      checkEncoders();
    #endif

    checkAxisVsEncoder(calibAxis, calibEncoder, &motorConsMissedSteps[axis], &motorLastPosition[axis], &motorConsEncoderLastPosition[axis], &motorConsEncoderUseForPos[axis], &motorConsMissedStepsDecay[axis], &motorConsEncoderEnabled[axis]);

    // Check if there is an emergency stop command
    if (Serial.available() > 0)
    {
      incomingByte = Serial.read();
      if (incomingByte == 69 || incomingByte == 101)
      {
        Serial.print("R99 emergency stop\r\n");
        movementDone = true;
        CurrentState::getInstance()->setEmergencyStop();
        Serial.print(COMM_REPORT_EMERGENCY_STOP);
        CurrentState::getInstance()->printQAndNewLine();
        error = 1;
      }
    }

    // Move until the end stop for home position is reached, either by end stop or motor skipping
    if ((!calibAxis->endStopMin() && !calibAxis->endStopMax()) && !movementDone && (*missedSteps < *missedStepsMax))
    {

      calibAxis->setStepAxis();
      

      delayMicroseconds(100000 / speedHome[axis] / 2);

      stepsCount++;
      if (stepsCount % (speedHome[axis] * 3) == 0)
      {
        // Periodically send message still active
        Serial.print(COMM_REPORT_CMD_BUSY);
        CurrentState::getInstance()->printQAndNewLine();
      }

      if (debugMessages)
      {
        if (stepsCount % (speedHome[axis] / 6) == 0 /*|| *missedSteps > 3*/)
        {
          Serial.print("R99");
          Serial.print(" step count ");
          Serial.print(stepsCount);
          Serial.print(" missed steps ");
          Serial.print(*missedSteps);
          Serial.print(" max steps ");
          Serial.print(*missedStepsMax);
          Serial.print(" cur pos mtr ");
          Serial.print(calibAxis->currentPosition());
          Serial.print(" cur pos enc ");
          Serial.print(calibEncoder->currentPosition());
          Serial.print("\r\n");
        }
      }

      calibAxis->resetMotorStep();
      delayMicroseconds(100000 / speedHome[axis] / 2);
    }
    else
    {
      movementDone = true;
      Serial.print("R99 movement done\r\n");

      // If end stop for home is active, set the position to zero
      if (calibAxis->endStopMax())
      {
        invertEndStops = true;
      }
    }
  }

  reportCalib(calibAxis, COMM_REPORT_CALIBRATE_STATUS_TO_END);

  Serial.print("R99");
  Serial.print(" axis ");
  Serial.print(calibAxis->channelLabel);
  Serial.print(" at starting point");
  Serial.print("\r\n");

  // Report back the end stop setting

  if (error == 0)
  {
    if (invertEndStops)
    {
      paramValueInt = 1;
    }
    else
    {
      paramValueInt = 0;
    }

    Serial.print("R23");
    Serial.print(" ");
    Serial.print("P");
    Serial.print(parEndInv);
    Serial.print(" ");
    Serial.print("V");
    Serial.print(paramValueInt);
    //Serial.print("\r\n");
    CurrentState::getInstance()->printQAndNewLine();
  }

  // Store the status of the system

  storeEndStops();
  reportEndStops();

  // Move into the other direction now, and measure the number of steps

  Serial.print("R99");
  Serial.print(" axis ");
  Serial.print(calibAxis->channelLabel);
  Serial.print(" calibrating length");
  Serial.print("\r\n");

  stepsCount = 0;
  movementDone = false;
  *missedSteps = 0;
  calibAxis->setDirectionAway();
  calibAxis->setCurrentPosition(calibEncoder->currentPosition());

  motorConsMissedSteps[0] = 0;
  motorConsMissedSteps[1] = 0;
  motorConsMissedSteps[2] = 0;

  long encoderStartPoint = calibEncoder->currentPosition();
  long encoderEndPoint = calibEncoder->currentPosition();

  while (!movementDone && error == 0)
  {

    #if defined(FARMDUINO_V14)
       checkEncoders();
    #endif

    checkAxisVsEncoder(calibAxis, calibEncoder, &motorConsMissedSteps[axis], &motorLastPosition[axis], &motorConsEncoderLastPosition[axis], &motorConsEncoderUseForPos[axis], &motorConsMissedStepsDecay[axis], &motorConsEncoderEnabled[axis]);

    // Check if there is an emergency stop command
    if (Serial.available() > 0)
    {
      incomingByte = Serial.read();
      if (incomingByte == 69 || incomingByte == 101)
      {
        Serial.print("R99 emergency stop\r\n");
        movementDone = true;
        CurrentState::getInstance()->setEmergencyStop();
        Serial.print(COMM_REPORT_EMERGENCY_STOP);
        CurrentState::getInstance()->printQAndNewLine();
        error = 1;
      }
    }

    // Ignore the missed steps at startup time
    if (stepsCount < 10)
    {
      *missedSteps = 0;
    }

    // Move until the end stop at the other side of the axis is reached
    if (((!invertEndStops && !calibAxis->endStopMax()) || (invertEndStops && !calibAxis->endStopMin())) && !movementDone && (*missedSteps < *missedStepsMax))
    {

      calibAxis->setStepAxis();
      stepsCount++;

      //checkAxisVsEncoder(&axisX, &encoderX, &motorConsMissedSteps[0], &motorLastPosition[0], &motorConsMissedStepsDecay[0], &motorConsEncoderEnabled[0]);

      delayMicroseconds(100000 / speedHome[axis] / 2);

      if (stepsCount % (speedHome[axis] * 3) == 0)
      {
        // Periodically send message still active
        Serial.print(COMM_REPORT_CMD_BUSY);
        //Serial.print("\r\n");
        CurrentState::getInstance()->printQAndNewLine();

        Serial.print("R99");
        Serial.print(" step count: ");
        Serial.print(stepsCount);
        Serial.print("\r\n");
      }

      calibAxis->resetMotorStep();
      delayMicroseconds(100000 / speedHome[axis] / 2);
    }
    else
    {
      Serial.print("R99 movement done\r\n");
      movementDone = true;
    }
  }

  Serial.print("R99");
  Serial.print(" axis ");
  Serial.print(calibAxis->channelLabel);
  Serial.print(" at end point");
  Serial.print("\r\n");

  encoderEndPoint = calibEncoder->currentPosition();

  // if the encoder is enabled, use the encoder data instead of the step count

  if (encoderEnabled)
  {
    stepsCount = abs(encoderEndPoint - encoderStartPoint);
  }

  // Report back the end stop setting

  if (error == 0)
  {
    Serial.print("R23");
    Serial.print(" ");
    Serial.print("P");
    Serial.print(parNbrStp);
    Serial.print(" ");
    Serial.print("V");
    Serial.print((float)stepsCount);
    CurrentState::getInstance()->printQAndNewLine();
  }

  *axisStatus = COMM_REPORT_MOVE_STATUS_STOP_MOTOR;
  reportStatus(calibAxis, axisStatus[0]);

  calibAxis->disableMotor();

  storeEndStops();
  reportEndStops();

  switch (axis)
  {
  case 0:
    CurrentState::getInstance()->setX(stepsCount);
    break;
  case 1:
    CurrentState::getInstance()->setY(stepsCount);
    break;
  case 2:
    CurrentState::getInstance()->setZ(stepsCount);
    break;
  }

  reportPosition();

  *axisStatus = COMM_REPORT_MOVE_STATUS_IDLE;
  reportStatus(calibAxis, axisStatus[0]);

  reportCalib(calibAxis, COMM_REPORT_CALIBRATE_STATUS_IDLE);

  CurrentState::getInstance()->setLastError(error);
  return error;
}
/**
 * xDest - destination X in steps
 * yDest - destination Y in steps
 * zDest - destination Z in steps
 * maxStepsPerSecond - maximum number of steps per second
 * maxAccelerationStepsPerSecond - maximum number of acceleration in steps per second
 */
int StepperControl::moveToCoords(double xDestScaled, double yDestScaled, double zDestScaled,
                                 unsigned int xMaxSpd, unsigned int yMaxSpd, unsigned int zMaxSpd,
                                 bool xHome, bool yHome, bool zHome)
{

  long xDest = xDestScaled * stepsPerMm[0];
  long yDest = yDestScaled * stepsPerMm[1];
  long zDest = zDestScaled * stepsPerMm[2];

  unsigned long currentMillis = 0;
  unsigned long timeStart = millis();

  serialMessageNr = 0;
  serialMessageDelay = 0;

  int incomingByte = 0;
  int error = 0;
  bool emergencyStop = false;
  unsigned int commandSpeed[3];

  // if a speed is given in the command, use that instead of the config speed

  if (xMaxSpd > 0 && xMaxSpd < speedMax[0])
  {
    commandSpeed[0] = xMaxSpd;
  }
  else
  {
    commandSpeed[0] = speedMax[0];
  }

  if (yMaxSpd > 0 && yMaxSpd < speedMax[1])
  {
    commandSpeed[1] = yMaxSpd;
  }
    else
  {
    commandSpeed[1] = speedMax[1];
  }

  if (zMaxSpd > 0 && zMaxSpd < speedMax[2])
  {
    commandSpeed[2] = zMaxSpd;
  }
    else
  {
    commandSpeed[2] = speedMax[2];
  }

  axisX.setMaxSpeed(commandSpeed[0]);
  axisY.setMaxSpeed(commandSpeed[1]);
  axisZ.setMaxSpeed(commandSpeed[2]);

  // Load coordinates into axis class

  long sourcePoint[3] = {0, 0, 0};
  sourcePoint[0] = CurrentState::getInstance()->getX();
  sourcePoint[1] = CurrentState::getInstance()->getY();
  sourcePoint[2] = CurrentState::getInstance()->getZ();

  long currentPoint[3] = {0, 0, 0};
  currentPoint[0] = CurrentState::getInstance()->getX();
  currentPoint[1] = CurrentState::getInstance()->getY();
  currentPoint[2] = CurrentState::getInstance()->getZ();

  long destinationPoint[3] = {0, 0, 0};
  destinationPoint[0] = xDest;
  destinationPoint[1] = yDest;
  destinationPoint[2] = zDest;

  motorConsMissedSteps[0] = 0;
  motorConsMissedSteps[1] = 0;
  motorConsMissedSteps[2] = 0;

  motorConsMissedStepsPrev[0] = 0;
  motorConsMissedStepsPrev[1] = 0;
  motorConsMissedStepsPrev[2] = 0;

  motorLastPosition[0] = currentPoint[0];
  motorLastPosition[1] = currentPoint[1];
  motorLastPosition[2] = currentPoint[2];

  // Load coordinates into motor control
  // Report back coordinates if target coordinates changed

  if (axisX.loadCoordinates(currentPoint[0], destinationPoint[0], xHome))
  {
    Serial.print(COMM_REPORT_COORD_CHANGED_X);
    Serial.print(" X");
    Serial.print(axisX.destinationPosition() / stepsPerMm[0]);
    CurrentState::getInstance()->printQAndNewLine();
  }

  if (axisY.loadCoordinates(currentPoint[1], destinationPoint[1], yHome))
  {
    Serial.print(COMM_REPORT_COORD_CHANGED_Y);
    Serial.print(" Y");
    Serial.print(axisY.destinationPosition() / stepsPerMm[1]);
    CurrentState::getInstance()->printQAndNewLine();
  }

  if (axisZ.loadCoordinates(currentPoint[2], destinationPoint[2], zHome))
  {
    Serial.print(COMM_REPORT_COORD_CHANGED_Z);
    Serial.print(" Z");
    Serial.print(axisZ.destinationPosition() / stepsPerMm[2]);
    CurrentState::getInstance()->printQAndNewLine();
  }
  // Prepare for movement

  axisX.movementStarted = false;
  axisY.movementStarted = false;
  axisZ.movementStarted = false;

  storeEndStops();
  reportEndStops();

  axisX.setDirectionAxis();
  axisY.setDirectionAxis();
  axisZ.setDirectionAxis();

  // Enable motors

  axisSubStep[0] = COMM_REPORT_MOVE_STATUS_START_MOTOR;
  axisSubStep[1] = COMM_REPORT_MOVE_STATUS_START_MOTOR;
  axisSubStep[2] = COMM_REPORT_MOVE_STATUS_START_MOTOR;

  reportStatus(&axisX, axisSubStep[0]);
  reportStatus(&axisY, axisSubStep[1]);
  reportStatus(&axisZ, axisSubStep[2]);

  enableMotors();

  // Start movement

  axisActive[0] = true;
  axisActive[1] = true;
  axisActive[2] = true;

  if (xHome || yHome || zHome)
  {
    if (!xHome) { axisX.deactivateAxis(); }
    if (!yHome) { axisY.deactivateAxis(); }
    if (!zHome) { axisZ.deactivateAxis(); }

    axisActive[0] = xHome;
    axisActive[1] = yHome;
    axisActive[2] = zHome;
  }

  axisX.checkMovement();
  axisY.checkMovement();
  axisZ.checkMovement();

  axisX.setTicks();
  axisY.setTicks();
  axisZ.setTicks();

  emergencyStop = CurrentState::getInstance()->isEmergencyStop();

  // Let the interrupt handle all the movements
  while ((axisActive[0] || axisActive[1] || axisActive[2]) && !emergencyStop)
  {
    #if defined(FARMDUINO_V14)
    checkEncoders();
    #endif

    checkAxisSubStatus(&axisX, &axisSubStep[0]);
    checkAxisSubStatus(&axisY, &axisSubStep[1]);
    checkAxisSubStatus(&axisZ, &axisSubStep[2]);

    axisX.checkTiming();
    axisY.checkTiming();
    axisZ.checkTiming();

    if (axisX.isStepDone())
    {
      axisX.checkMovement();
      checkAxisVsEncoder(&axisX, &encoderX, &motorConsMissedSteps[0], &motorLastPosition[0], &motorConsEncoderLastPosition[0], &motorConsEncoderUseForPos[0], &motorConsMissedStepsDecay[0], &motorConsEncoderEnabled[0]);
      axisX.resetStepDone();
    }

    if (axisY.isStepDone())
    {
      axisY.checkMovement();
      checkAxisVsEncoder(&axisY, &encoderY, &motorConsMissedSteps[1], &motorLastPosition[1], &motorConsEncoderLastPosition[1], &motorConsEncoderUseForPos[1], &motorConsMissedStepsDecay[1], &motorConsEncoderEnabled[1]);
      axisY.resetStepDone();
    }

    if (axisZ.isStepDone())
    {
      axisZ.checkMovement();
      checkAxisVsEncoder(&axisZ, &encoderZ, &motorConsMissedSteps[2], &motorLastPosition[2], &motorConsEncoderLastPosition[2], &motorConsEncoderUseForPos[2], &motorConsMissedStepsDecay[2], &motorConsEncoderEnabled[2]);
      axisZ.resetStepDone();
    }

    if (axisX.isAxisActive() && motorConsMissedSteps[0] > motorConsMissedStepsMax[0])
    {
      axisX.deactivateAxis();
      serialBuffer += "R99";
      serialBuffer += " deactivate motor X due to missed steps";
      serialBuffer += "\r\n";

      if (xHome)
      {
        encoderX.setPosition(0);
        axisX.setCurrentPosition(0);
      }
      else
      {
        error = 1;
      }
    }

    if (axisY.isAxisActive() && motorConsMissedSteps[1] > motorConsMissedStepsMax[1])
    {
      axisY.deactivateAxis();
      serialBuffer += "R99";
      serialBuffer += " deactivate motor Y due to missed steps";
      serialBuffer += "\r\n";
      
      if (yHome)
      {
        encoderY.setPosition(0);
        axisY.setCurrentPosition(0);
      }
      else
      {
        error = 1;
      }
    }

    if (axisZ.isAxisActive() && motorConsMissedSteps[2] > motorConsMissedStepsMax[2])
    {
      axisZ.deactivateAxis();

      serialBuffer += "R99";
      serialBuffer += " deactivate motor Z due to missed steps";
      serialBuffer += "\r\n";

      if (zHome)
      {
        encoderZ.setPosition(0);
        axisZ.setCurrentPosition(0);        
      }
      else
      {
        error = 1;
      }
    }

    if (axisX.endStopAxisReached(false))
    {
      axisX.setCurrentPosition(0);
      encoderX.setPosition(0);
    }

    if (axisY.endStopAxisReached(false))
    {
      axisY.setCurrentPosition(0);
      encoderY.setPosition(0);
    }

    if (axisZ.endStopAxisReached(false))
    {
      axisZ.setCurrentPosition(0);
      encoderZ.setPosition(0);
    }

    axisActive[0] = axisX.isAxisActive();
    axisActive[1] = axisY.isAxisActive();
    axisActive[2] = axisZ.isAxisActive();

    currentPoint[0] = axisX.currentPosition();
    currentPoint[1] = axisY.currentPosition();
    currentPoint[2] = axisZ.currentPosition();

    CurrentState::getInstance()->setX(currentPoint[0]);
    CurrentState::getInstance()->setY(currentPoint[1]);
    CurrentState::getInstance()->setZ(currentPoint[2]);

    storeEndStops();

    // Check timeouts
    if (axisActive[0] == true && ((millis() >= timeStart && millis() - timeStart > timeOut[0] * 1000) || (millis() < timeStart && millis() > timeOut[0] * 1000)))
    {
      serialBuffer += COMM_REPORT_TIMEOUT_X;
      serialBuffer += "\r\n";
      serialBuffer += "R99 timeout X axis\r\n";
      error = 2;
    }
    if (axisActive[1] == true && ((millis() >= timeStart && millis() - timeStart > timeOut[1] * 1000) || (millis() < timeStart && millis() > timeOut[1] * 1000)))
    {
      serialBuffer += COMM_REPORT_TIMEOUT_Y;
      serialBuffer += "\r\n";
      serialBuffer += "R99 timeout Y axis\r\n";
      error = 2;
    }
    if (axisActive[2] == true && ((millis() >= timeStart && millis() - timeStart > timeOut[2] * 1000) || (millis() < timeStart && millis() > timeOut[2] * 1000)))
    {
      serialBuffer += COMM_REPORT_TIMEOUT_Z;
      serialBuffer += "\r\n";
      serialBuffer += "R99 timeout Z axis\r\n";
      error = 2;
    }

    // Check if there is an emergency stop command
    if (Serial.available() > 0)
    {
      incomingByte = Serial.read();
      if (incomingByte == 69 || incomingByte == 101)
      {
        serialBuffer += "R99 emergency stop\r\n";

        Serial.print(COMM_REPORT_EMERGENCY_STOP);
        CurrentState::getInstance()->printQAndNewLine();

        emergencyStop = true;

        axisX.deactivateAxis();
        axisY.deactivateAxis();
        axisZ.deactivateAxis();

        axisActive[0] = false;
        axisActive[1] = false;
        axisActive[2] = false;

        error = 1;
      }
    }

    if (error != 0)
    {
      serialBuffer += "R99 error\r\n";

      axisActive[0] = false;
      axisActive[1] = false;
      axisActive[2] = false;
    }

    // Send the serial buffer one character per cycle to keep motor timing more accuracte
    serialBufferSendNext();

    // Periodically send message still active
    currentMillis++;
    serialMessageDelay++;

    if (serialMessageDelay > 300 && serialBuffer.length() == 0 && serialBufferSending == 0)
    {
      serialMessageDelay = 0;

      switch(serialMessageNr)
      {
        case 0:
          serialBuffer += COMM_REPORT_CMD_BUSY;
          serialBuffer += CurrentState::getInstance()->getQAndNewLine();
          break;
        case 1:
          serialBuffer += CurrentState::getInstance()->getPosition();
          serialBuffer += CurrentState::getInstance()->getQAndNewLine();
          break;

        case 2:

          #if defined(FARMDUINO_EXP_V20)
          serialBuffer += "R89";
          serialBuffer += " X";
          serialBuffer += axisX.getLoad();
          serialBuffer += " Y";
          serialBuffer += axisY.getLoad();
          serialBuffer += " Z";
          serialBuffer += axisZ.getLoad();
          serialBuffer += CurrentState::getInstance()->getQAndNewLine();
          #endif
          break;

      }

      serialMessageNr++;

      #if !defined(FARMDUINO_EXP_V20)
      if (serialMessageNr > 1)
      {
        serialMessageNr = 0;
      }
      #endif

      #if defined(FARMDUINO_EXP_V20)
      
      if (serialMessageNr > 2)
      {
        serialMessageNr = 0;
      }
      #endif

      serialBufferSending = 0;
      
      if (debugMessages /*&& debugInterrupt*/)
      {

				Serial.print("R99");
				Serial.print(" missed step ");
				Serial.print(motorConsMissedSteps[1]);
				Serial.print(" encoder pos ");
				Serial.print(encoderY.currentPosition());
				Serial.print(" axis pos ");
				Serial.print(axisY.currentPosition());
				Serial.print("\r\n");
      }
    }
  }

  serialBufferEmpty();
  Serial.print("R99 stopped\r\n");

  // Send feedback for homing

  if (xHome && !error && !emergencyStop)
  {
    Serial.print(COMM_REPORT_HOMED_X);
    CurrentState::getInstance()->printQAndNewLine();
  }

  if (yHome && !error && !emergencyStop)
  {
    Serial.print(COMM_REPORT_HOMED_Y);
    CurrentState::getInstance()->printQAndNewLine();
  }

  if (zHome && !error && !emergencyStop)
  {
    Serial.print(COMM_REPORT_HOMED_Z);
    CurrentState::getInstance()->printQAndNewLine();
  }

  // Stop motors

  axisSubStep[0] = COMM_REPORT_MOVE_STATUS_STOP_MOTOR;
  axisSubStep[1] = COMM_REPORT_MOVE_STATUS_STOP_MOTOR;
  axisSubStep[2] = COMM_REPORT_MOVE_STATUS_STOP_MOTOR;

  reportStatus(&axisX, axisSubStep[0]);
  reportStatus(&axisY, axisSubStep[1]);
  reportStatus(&axisZ, axisSubStep[2]);

  disableMotors();

  // Report end statuses

  currentPoint[0] = axisX.currentPosition();
  currentPoint[1] = axisY.currentPosition();
  currentPoint[2] = axisZ.currentPosition();

  CurrentState::getInstance()->setX(currentPoint[0]);
  CurrentState::getInstance()->setY(currentPoint[1]);
  CurrentState::getInstance()->setZ(currentPoint[2]);

  storeEndStops();
  reportEndStops();
  reportPosition();
  reportEncoders();

  // Report axis idle

  axisSubStep[0] = COMM_REPORT_MOVE_STATUS_IDLE;
  axisSubStep[1] = COMM_REPORT_MOVE_STATUS_IDLE;
  axisSubStep[2] = COMM_REPORT_MOVE_STATUS_IDLE;

  reportStatus(&axisX, axisSubStep[0]);
  reportStatus(&axisY, axisSubStep[1]);
  reportStatus(&axisZ, axisSubStep[2]);

  disableMotors();

  if (emergencyStop)
  {
    CurrentState::getInstance()->setEmergencyStop();
  }

  Serial.print("R99 error ");
  Serial.print(error);
  Serial.print("\r\n");


  // Return error
  CurrentState::getInstance()->setLastError(error);

  return error;
}