Ejemplo n.º 1
0
/*!
 * @brief Thread handling the RTC
 */
void ToggleThread(void *data)
{
	LEDs_Off(LED_BLUE);
	LEDs_Off(LED_GREEN);
	LEDs_Off(LED_YELLOW);
	LEDs_Off(LED_ORANGE);
	Touch_EnableScan(bTRUE);
	uint8_t values = 0;
	for (;;)
	{
		//At least 5s, so 501 * 10ms > 5s
		if (Touch_Wait(501, &values) == OS_TIMEOUT)
		{
			break;
		}
		SetLeds(values);
	}
	LEDs_Off(LED_BLUE);
	LEDs_Off(LED_GREEN);
	LEDs_Off(LED_YELLOW);
	LEDs_Off(LED_ORANGE);
	Touch_EnableScan(bFALSE);
	(*Callback)((void *)0);
	OS_ERROR error = OS_ThreadDelete(OS_PRIORITY_SELF);
}
Ejemplo n.º 2
0
void ModeSelect::StartModeSelect(void)
{
  mode_new = 0;
  mode_act = 0;
  blinkcnt = 0;
  timecnt = 0;

  EELIB_Command command;
  EELIB_Result result;
  uint8_t buf8;


  button_state = ReadButton();
  button_debounce = 0;

  command[0] = EELIB_IAP_COMMAND_EEPROM_READ;
  command[1] = 0; // Eeprom address
  command[2] = (uint32_t) &buf8;
  command[3] = 1; // Read length
  command[4] = SystemCoreClock / 1000;
  EELIB_entry(command, result);

  if (result[0] != EELIB_IAP_STATUS_CMD_SUCCESS) {
    buf8 = 0;
  }

  if (buf8 >= MODENUM)
    buf8 = 0;
  mode_new = buf8;
  mode_act = buf8;
  SetLeds();
}
Ejemplo n.º 3
0
void Robot::TeleopInit() {
	double startTime = GetRTC();
	printf("Robot: TeleopInit at %f seconds, %d ticks", startTime, ticks);
	// If we'd previously run an autonomous, record how long it lasted
	if (m_startTicks > 0) {
		double elapsedTime = startTime - m_startTime;
		int elapsedTicks = ticks - m_startTicks;
		printf(", prior autonomous ran for %f seconds, %d ticks, %5.2f tps.",
				elapsedTime, elapsedTicks, elapsedTicks/elapsedTime);
	}
	printf("\n");
	m_startTicks = ticks;
	m_startTime = startTime;

	// uncomment only for calibrating vision
//	CommandBase::navXSubsystem->zeroYaw(0);

	if (mp_autonomousCommand != NULL) {
		mp_autonomousCommand->Cancel();
	}
	// begin teleop "polling" commands
	CommandBase::driveJoystickCommand->Start();
	CommandBase::intakeRollerCommand->Start();
	CommandBase::flapCommand->Start();
	SetLeds(NORMAL);
}
Ejemplo n.º 4
0
void vParTestToggleLED( unsigned portBASE_TYPE uxLED )
{
	/* Toggle the state of the requested LED. */
	if (uxLED < partstNUM_LEDS)
	{
		ulLEDReg ^= ( 1 << uxLED );
		SetLeds( ulLEDReg );
	}
}
Ejemplo n.º 5
0
// alle 10 ms aufrufen
bool ModeSelect::DoModeSelect(void)
{
  if (ButtonDebounce())
  {
    mode_new = mode_new+1;
    if (mode_new >= MODENUM)
      mode_new = 0;
    blinkcnt = 7;
    timecnt = MODELED_HPRD;
    SetLeds();
  } else if (blinkcnt != 0)
  {
    if (timecnt > 0)
      timecnt--;
    if (timecnt == 0)
    {
      blinkcnt--;
      if (blinkcnt > 0)
      {
        timecnt = MODELED_HPRD;
        SetSingleLed(mode_new, (blinkcnt & 1) != 0);
      } else {
        if (mode_act != mode_new)
        {
          mode_act = mode_new;
          SetSingleLed(mode_new, true);
          // Neuen Modus noch abspeichern.
          uint32_t command[5], result[4];
          uint8_t buf8 = mode_act;
          command[0] = EELIB_IAP_COMMAND_EEPROM_WRITE;
          command[1] = 0; // Eeprom address
          command[2] = (uint32_t) &buf8;
          command[3] = 1; // Write length
          command[4] = SystemCoreClock / 1000;
          EELIB_entry(command, result);
          if (result[0] != EELIB_IAP_STATUS_CMD_SUCCESS) {
            // doof das...
          }

          return true;
        }
      }
    } else {
      // nichts zu tun
    }
  } else {
    // nichts zu tun
  }
  return false;
}
Ejemplo n.º 6
0
void vParTestSetLED( unsigned portBASE_TYPE uxLED, signed portBASE_TYPE xValue )
{
	/* Switch an LED on or off as requested. */
	if (uxLED < partstNUM_LEDS)
	{
		if( xValue )
		{
			ulLEDReg &= ~( 1 << uxLED );
		}
		else
		{
			ulLEDReg |= ( 1 << uxLED );
		}

		SetLeds( ulLEDReg );
	}
}
Ejemplo n.º 7
0
void Robot::DisabledInit() {
	double startTime = GetRTC();
	printf("Robot: Disabled at %f seconds, %d ticks", startTime, ticks);
	// If we'd previously run an autonomous, record how long it lasted
	if (m_startTicks > 0) {
		double elapsedTime = startTime - m_startTime;
		int elapsedTicks = ticks - m_startTicks;
		printf(", prior state ran for %f seconds, %d ticks, %5.2f tps.",
				elapsedTime, elapsedTicks, elapsedTicks/elapsedTime);
	}
	printf("\n");
	m_startTicks = ticks;
	m_startTime = startTime;

	if (mp_autonomousCommand != NULL) {
		mp_autonomousCommand->Cancel();
	}

	printf("LEDs: Turning off\n");
	SetLeds(OFF);
}
Ejemplo n.º 8
0
void Robot::AutonomousInit() {
	m_startTicks = ticks;
	m_startTime = GetRTC();
	printf("Robot: AutononmousInit at %f seconds, %d ticks\n",
			m_startTime, ticks);

	int pos = m_fieldInfo.GetPosition();
	int def = m_fieldInfo.GetDefense();
	int target = m_fieldInfo.GetTarget();
	bool slow = m_fieldInfo.IsCrossingSlowly();
	printf("Autonomous: Position %d | Defense %d | Target %d, Speed %s\n",
			pos, def, target, slow ? "SLOW" : "NORMAL");

	// make sure we don't inadvertently leave the LED ring off
	CommandBase::visionSubsystem->setLedRingState(true);

	// if we've already run auto, delete the existing auto command
	if (mp_autonomousCommand != NULL) {
		delete mp_autonomousCommand;
		mp_autonomousCommand = NULL;
	}
	// create a new dynamic auto command with the selected parameters from the SmartDashboard
	mp_autonomousCommand = new AutonomousDriveAndShoot(pos, def, target);
	mp_autonomousCommand->Start();

	// reset our coordinate system to where the robot is currently located / oriented
	// assume robot was set up correctly (there's nothing else we can do)
	// Robot will start out wedges first, or intake first, depending on the defense
	CommandBase::navXSubsystem->zeroYaw(m_fieldInfo.GetInitialOrientation());
	CommandBase::navXSubsystem->ResetDisplacement();

	CommandBase::driveSubsystem->SetInitialPosition(FieldInfo::startingLocations[pos].x,
													FieldInfo::startingLocations[pos].y);

	CommandBase::driveJoystickCommand->Cancel();
	CommandBase::intakeRollerCommand->Cancel();
	CommandBase::flapCommand->Cancel();
	SetLeds(NORMAL);
}