Exemplo n.º 1
0
void main (void)
{
	unsigned char	flags;

	/* Init the hardware */
	flags = catgenie_init();

#ifdef HAS_BLUETOOTH
	serial_init(BT_BITRATE);
	bluetooth_init();
	serial_term();
#endif /* HAS_BLUETOOTH */

	/* Initialize the serial port */
	serial_init(BITRATE);

	printf("\n*** GenieDiag ***\n");
	if (!nPOR) {
		DBG("Power-on reset\n");
		flags |= POWER_FAILURE;
	} else if (!nBOR) {
		DBG("Brown-out reset\n");
		flags |= POWER_FAILURE;
	}
#ifdef __RESETBITS_ADDR
	else if (!__timeout)
		DBG("Watchdog reset\n");
	else if (!__powerdown)
		DBG("Pin reset (sleep)\n");
	else
		DBG("Pin reset\n");
#else
	else
Exemplo n.º 2
0
int main(void)
{
    // If transport layer is using UART with flow control we need to get one
    // GPIOTE user for the CTS wakeup pin.
    APP_GPIOTE_INIT(1);

    leds_init();

    // Indicate that the application has started up. This can be used to verify that
    // application resets if reset button is pressed or the chip has been reset with
    // a debugger. The led will be off during reset.
    nrf_gpio_pin_set(MAIN_FUNCTION_LED_PIN_NO);

    connectivity_chip_reset();

    bluetooth_init();

    // Enter main loop.
    for (;;)
    {
        uint32_t err_code;

        // Start/restart advertising.
        if (m_start_adv_flag)
        {
            err_code = sd_ble_gap_adv_start(&m_adv_params);
            APP_ERROR_CHECK(err_code);
            nrf_gpio_pin_set(ADVERTISING_LED_PIN_NO);
            m_start_adv_flag = false;
        }

        // Power management.
        power_manage();
    }
}
/* State behaviour */
void behaviour_welcome(state_ptr state)
{
  /* Set events to react to */

  /* Do state actions */

  /* Set menu */
  osMutexWait(mutex_menuHandle, osWaitForever);
  menu_copy(&menu_welcome, &current_menu);
  osMutexRelease(mutex_menuHandle);

  /* Display menu */
  uint32_t i;
  for (i = 0; i < menu_welcome.item_num; i++)
  {
    while (osMailPut(queue_lcdHandle, (void *) &menu_welcome.items[i]) != osOK)
    {
      osDelay(1);
    }
  }

  /* Do state actions */
  bluetooth_init();
  osDelay(2500);
  entry_to_running(state);
}
Exemplo n.º 4
0
static gboolean bluetooth_init_later(gpointer data)
{

    OhmPlugin *plugin = data;

    if (plugin_is_real)
        bluetooth_init(plugin, DBG_BT);
    return FALSE;
}
Exemplo n.º 5
0
void init_octopus(void)
{
	sysclk_init();
	ioport_init();
	leds_init();
	bluetooth_init();
	//bluetooth_init_interrupt();
	switch_init();
	
	//usb_init();	
	
}
Exemplo n.º 6
0
static void plugin_init(OhmPlugin *plugin)
{
    OHM_DEBUG_INIT(media);

    dbusif_init(plugin);
    dresif_init(plugin);
    privacy_init(plugin);
    mute_init(plugin);
    bluetooth_init(plugin);
    audio_init(plugin);

#if 0
    DBG_PRIVACY = DBG_MUTE = DBG_BT = DBG_AUDIO = TRUE;
    DBG_DBUS = DBG_FS = DBG_DRES = TRUE;
#endif
}
Exemplo n.º 7
0
/**
 *
 * @brief Perform basic hardware initialization
 *
 * Initialize the interrupt controller and UARTs present in the
 * platform.
 *
 * @return 0
 */
static int pc_init(struct sys_device *arg)
{
	ARG_UNUSED(arg);

	picInit();    /* NOP if not needed */
	loapicInit(); /* NOP if not needed */

	/*
	 * IOAPIC is initialized with empty interrupt list
	 * If there is a device connected to IOAPIC, the initialization
	 * has to be changed to _IoApicInit (1 << DEV1_IRQ | 1 << DEV2_IRQ)
	 */
	ioapicInit();   /* NOP if not needed */
	consoleInit(); /* NOP if not needed */
	bluetooth_init(); /* NOP if not needed */
	return 0;
}
Exemplo n.º 8
0
/**@brief Function for initializing services that will be used by the application.
 */
static void services_init(void)
{
#if 1
    bluetooth_init();
#else
    /* YOUR_JOB: Add code to initialize the services used by the application.*/
    uint32_t                            err_code;
    ble_adconvert_service_init_t        init;

    // Initialize XXX Service.
    memset(&init, 0, sizeof(init));
    init.evt_handler                = on_ble_service_evt;
    init.ble_adconvert_service_advalue_initial_value.advalue = 0;
    err_code = ble_adconvert_service_init(&m_adconv, &init);
    APP_ERROR_CHECK(err_code);
#endif
}
Exemplo n.º 9
0
void init(int use_http, char *address, int port){
    // Setup periferal and library
    init_gui();
    init_motors();
    init_sensor();
	init_compass();
	calibrate_compass(0); // 0 = do not execute a new calibration of the compass	

	// Load ball predefined positions
	get_positions(POINTS_FILE_NAME, &positions, &n_points);

	// Start bluetooth
	if(use_http)
		bluetooth_test_init(address, port);
    else 
		bluetooth_init();
	
	//bluetooth_register_and_start(fAction_t, fAck_t, fLead_t, fStart_t, fStop_t, fWait_t, fKick_t, fCancel_t);
    bluetooth_register_and_start(&follower_action_cb, NULL, &lead_cb, &start_cb, &stop_cb, NULL, NULL, &cancel_cb);

	// Reset global variables
  	send_action_flag = 1;
	act = 0;
    end_game = 0;
    start_game = 0;
    wait = 0;
	cancel = 0;
	// Waiting for the game start
	set_light(LIT_LEFT, LIT_GREEN);
	set_light(LIT_RIGHT, LIT_GREEN);
    while(!start_game); //start game, robot rank and snake size  initialized by start_cb

	// Initial position
	home.x = BORDER_X_MAX/2;
	home.y = (snake_size - robot_rank -1)*40 + 20;
	center.x = BORDER_X_MAX/4;
	center.y = BORDER_Y_MAX/2;
	robot = home;
	
	printf("[DEBUG] Starting position X: %d, Y: %d, T: %d\n", robot.x , robot.y, robot.t);
	
	update_sensor(SENSOR_GYRO);
    gyro_init_val = get_sensor_value(SENSOR_GYRO);
    set_light(LIT_LEFT, LIT_OFF);
	set_light(LIT_RIGHT, LIT_OFF);
}
Exemplo n.º 10
0
int main(void)
{
	_delay_ms(250);

	servo_init();
	ir_init();
	bluetooth_init();
	ultrasonic_init();
	buttons_init();
	sei();
	
    while(1) {
		comm_exec();
		move_proc();
		
		if (button_get_state(1)) move_enable(false);
		if (button_get_state(2)) move_enable(true);
    }
}
/* State behaviour */
void behaviour_h2h_connect(state_ptr state)
{
  /* Set events to react to */
  state->back = h2h_connect_to_main;
  state->h2h_connect = h2h_connect_to_h2h_ongoing;

  /* Do state actions */

  /* Set menu */
  osMailPut(queue_input_menuHandle, (void *) &menu_h2h_connect);

  /* Display menu */
  uint32_t i;
  for (i = 0; i < menu_h2h_connect.item_num; i++)
  {
    osMailPut(queue_lcdHandle, (void *) &menu_h2h_connect.items[i]);
  }
  
  /* Do state actions */
  bluetooth_init();
}
Exemplo n.º 12
0
int main(void)
{

	_delay_ms(50);
	init_task_man();
	USART_INIT_POLLING();
	bluetooth_init();
//	USART_INIT_INTERRUPT();
	AVC_init(1);
	sei();
//	usart_put_c('t');
	_delay_ms(200);
//	AVC_add_tx_transaction_from_list(SELF_REGISTER);
	sei();
	
//	wdt_enable( WDTO_2S );
	
	while(1){
		// Reset watchdog.
//        wdt_reset();
		process_tasks();
	}
	
}
Exemplo n.º 13
0
static void* a2dp_thread(void *d)
{
	struct bluetooth_data* data = (struct bluetooth_data*)d;
	a2dp_command_t command = A2DP_CMD_NONE;
	int err = 0;

	DBG("a2dp_thread started");
	prctl(PR_SET_NAME, (int)"a2dp_thread", 0, 0, 0);

	pthread_mutex_lock(&data->mutex);

	data->started = 1;
	pthread_cond_signal(&data->thread_start);

	while (1)
	{
		while (1) {
			pthread_cond_wait(&data->thread_wait, &data->mutex);

			/* Initialization needed */
			if (data->state == A2DP_STATE_NONE &&
				data->command != A2DP_CMD_QUIT) {
				err = bluetooth_init(data);
			}

			/* New state command signaled */
			if (command != data->command) {
				command = data->command;
				break;
			}
		}

		switch (command) {
			case A2DP_CMD_CONFIGURE:
				if (data->state != A2DP_STATE_INITIALIZED)
					break;
				err = bluetooth_configure(data);
				break;

			case A2DP_CMD_START:
				if (data->state != A2DP_STATE_CONFIGURED)
					break;
				err = bluetooth_start(data);
				break;

			case A2DP_CMD_STOP:
				if (data->state != A2DP_STATE_STARTED)
					break;
				err = bluetooth_stop(data);
				break;

			case A2DP_CMD_QUIT:
				bluetooth_close(data);
				sbc_finish(&data->sbc);
				a2dp_free(data);
				goto done;

			case A2DP_CMD_INIT:
				/* already called bluetooth_init() */
			default:
				break;
		}
		// reset last command in case of error to allow
		// re-execution of the same command
		if (err < 0) {
			command = A2DP_CMD_NONE;
		}
	}

done:
	pthread_mutex_unlock(&data->mutex);
	DBG("a2dp_thread finished");
	return NULL;
}
Exemplo n.º 14
0
void picture_transfer_init() {
	bluetooth_init();
}
Exemplo n.º 15
0
static int __init lenovo_sl_laptop_init(void)
{
	int ret;
	acpi_status status;

#if LINUX_VERSION_CODE >= KERNEL_VERSION(2,6,28)
	if (!acpi_video_backlight_support())
		control_backlight = 1;
#endif

	hkey_handle = ec0_handle = NULL;

	if (acpi_disabled)
		return -ENODEV;

	lensl_wq = create_singlethread_workqueue(LENSL_WORKQUEUE_NAME);
	if (!lensl_wq) {
		vdbg_printk(LENSL_ERR, "Failed to create a workqueue\n");
		return -ENOMEM;
	}

	status = acpi_get_handle(NULL, LENSL_HKEY, &hkey_handle);
	if (ACPI_FAILURE(status)) {
		vdbg_printk(LENSL_ERR,
			"Failed to get ACPI handle for %s\n", LENSL_HKEY);
		return -ENODEV;
	}
	status = acpi_get_handle(NULL, LENSL_EC0, &ec0_handle);
	if (ACPI_FAILURE(status)) {
		vdbg_printk(LENSL_ERR,
			"Failed to get ACPI handle for %s\n", LENSL_EC0);
		return -ENODEV;
	}

	lensl_pdev = platform_device_register_simple(LENSL_DRVR_NAME, -1,
							NULL, 0);
	if (IS_ERR(lensl_pdev)) {
		ret = PTR_ERR(lensl_pdev);
		lensl_pdev = NULL;
		vdbg_printk(LENSL_ERR, "Failed to register platform device\n");
		return ret;
	}

	ret = hkey_inputdev_init();
	if (ret)
		return -ENODEV;

	bluetooth_init();
	if (control_backlight)
		backlight_init();

	led_init();
	mutex_init(&hkey_poll_mutex);
	hkey_poll_start();
	hwmon_init();

	if (debug_ec)
		lenovo_sl_procfs_init();

	vdbg_printk(LENSL_INFO, "Loaded Lenovo ThinkPad SL Series driver\n");
	return 0;
}
Exemplo n.º 16
0
/******************************************************************
 * 			Main-function
 */
int main(void) {

	/**************************************
	 * 	Set the clock to run at 80 MHz
	 */
	SysCtlClockSet(SYSCTL_SYSDIV_2_5|SYSCTL_USE_PLL|SYSCTL_XTAL_16MHZ|SYSCTL_OSC_MAIN);

	/**************************************
	 * 	Enable the floating-point-unit
	 */
	FPUEnable();
	// We also want Lazystacking, so enable that too
	FPULazyStackingEnable();
	// We also want to put numbers close to zero to zero
	FPUFlushToZeroModeSet(FPU_FLUSH_TO_ZERO_EN);

	/**************************************
	 * 	Init variables
	 */
	uint16_t mapData[MAP_DATA_SIZE];
	uint8_t stepDir = 0;

	/**************************************
	 * 	Init peripherals used
	 */
	bluetooth_init();
	init_stepper();							// Init the GPIOs used for the stepper and loading LED
	InitI2C1();								// Init the communication with the lidar-unit through I2C
	InitPWM();
	setupTimers();

	/**************************************
	 * 	State 2
	 */
	// Disable the timers that are used
	disableTimer(TIMER1_BASE);
	disableTimer(TIMER2_BASE);

	// Enable all interrupts
	IntMasterEnable();
	/**************************************
	 * 	State 3
	 */
	// Indicate we should start with a scan regardless of what other things we have already got
	// from UART-interrupt
	// This means setting the appropriate bit in the status vector
	stat_vec |= TAKE_MEAS;

	/**************************************
	 * 	State 4
	 */
	// Contains main-loop where decisions should be made
	for ( ; ; ) {
		/**********************************
		 * 	Decision tree
		 */
		// Highest priority case first


		// Check both interrupts at each iteration in the loop
		if ( int_vec & UART_INT ) {
			// Reset the indication
			int_vec &= ~UART_INT;

			// Remove drive-stop flag to enable movement
			stat_vec &= ~DRIVE_STOP;

			// Init data array
			uint8_t dataArr[MAX_UART_MSG_SIZE];

			// Collect the message
			if ( readUARTMessage(dataArr, MAX_UART_MSG_SIZE) < SUCCESS ) {
				// If we have recieved more data than fits in the vector we should simply
				// go in here again and grab data
				int_vec |= UART_INT;
			}
			// We have gathered a message
			// and now need to determine what the message is
			parseMsg(dataArr, MAX_UART_MSG_SIZE);
		}
		// Checking drive (movement) interrupt
		if ( int_vec & TIMER2_INT ) {
			int_vec &= ~TIMER2_INT;
			// Disable TIMER2
			disableTimer(TIMER2_BASE);
			// Set drive-stop in status vector
			stat_vec |= DRIVE_STOP;
		}
		// Checking measure interrupt
		if ( int_vec & TIMER1_INT ) {
			int_vec &= ~TIMER1_INT;
			// Disable TIMER1
			disableTimer(TIMER1_BASE);

			// Take reading from LIDAR
			mapData[stepCount++] = readLidar();
			SysCtlDelay(2000);

			// Take step
			// Note: We need to take double meas at randvillkor (100) !!!!!
			if ( stepCount > 0 && stepCount < 100 ) {
				stepDir = 1;
			}
			else if ( stepCount >= 100 && stepCount < 200) {
				stepDir = 0;
			}
			else {
				stepDir = 1;
				stepCount = 0;

				// Reset busy-flag
				stat_vec &= ~TAKE_MEAS;
			}
			step = takeStep(step, stepDir);

			// Request reading from LIDAR
			reqLidarMeas();

			if ( stat_vec & TAKE_MEAS ) {
				// Restart TIMER1
				enableTimer(TIMER1_BASE, (SYSCLOCK / MEASUREMENT_DELAY));
			}
			else {
				sendUARTDataVector(mapData, MAP_DATA_SIZE);
				stat_vec &= ~BUSY;
			}
		}

		// Check the drive_stop flag, which always should be set unless we should move
		if ( stat_vec & DRIVE_STOP ) {
			// Stop all movement
			SetPWMLevel(0,0);
			halt();

			// MAKE SURE all drive-flags are not set
			stat_vec &= ~(DRIVE_F | DRIVE_L | DRIVE_R | DRIVE_LL | BUSY);
		}
		// Should we drive?
		else if ( stat_vec & DRIVE ) {
			// Remove drive flag
			stat_vec &= ~DRIVE;
			// Increase PWM
			increase_PWM(0,MAX_FORWARD_SPEED,0,MAX_FORWARD_SPEED);
			if ( stat_vec & DRIVE_F ) {
				enableTimer(TIMER2_BASE, DRIVE_FORWARD_TIME);
			}
			else if ( stat_vec & DRIVE_LL ) {
				enableTimer(TIMER2_BASE, DRIVE_TURN_180_TIME);
			}
			else {
				enableTimer(TIMER2_BASE, DRIVE_TURN_TIME);
			}
		}
		if ( !(stat_vec & BUSY) ) {
			// Tasks
			switch ( stat_vec ) {
				case ((uint8_t)DRIVE_F) :
					// Call drive function
					go_forward();
					// Set the drive flag & BUSY
					stat_vec |= DRIVE | BUSY;
					break;
				case ((uint8_t)DRIVE_L) :
					// Call drive-left function
					go_left();
					// Set the drive flag
					stat_vec |= DRIVE | BUSY;
					break;
				case ((uint8_t)DRIVE_R) :
					// Call drive-right function
					go_right();
					// Set the drive flag
					stat_vec |= DRIVE | BUSY;
					break;
				case ((uint8_t)DRIVE_LL) :
					// Call turn 180-degrees function
					go_back();
					// Set the drive flag
					stat_vec |= DRIVE | BUSY;
					break;
				case ((uint8_t)TAKE_MEAS) :
					// Request reading from LIDAR
					reqLidarMeas();
					// Start TIMER1
					enableTimer(TIMER1_BASE, (SYSCLOCK / MEASUREMENT_DELAY)); // if sysclock = 1 s, 1/120 = 8.3 ms
					// We are busy
					stat_vec |= BUSY;
					break;

				default:
					break;
			}
		}
	}
}
Exemplo n.º 17
0
/*--------------------------------------------------------------------------*/
int
main(int argc, char **argv)
{
  /*
  * Initalize hardware.
  */
  msp430_cpu_init();
  clock_init();

  uart_init(9600); /* Must come before first printf */

  /* xmem_init(); */

  PRINTF("iWatch 0.10 build at " __TIME__ " " __DATE__ "\n");
  UCSCTL8 &= ~BIT2;
  
  /*
  * Hardware initialization done!
  */

  /*
  * Initialize Contiki and our processes.
  */
  process_init();
  process_start(&etimer_process, NULL);
  
  rtimer_init();
  ctimer_init();

  energest_init();
  ENERGEST_ON(ENERGEST_TYPE_CPU);

  backlight_init();
  battery_init();
  SPI_FLASH_Init();

  if (system_testing())
  {
    clock_time_t t;

    backlight_on(200, 0);
    t = clock_seconds();
    // sleep 1
    while(clock_seconds() - t <= 3);
    printf("$$OK BACKLIGHT\n");
    t = clock_seconds();
    while(clock_seconds() - t <= 3);
    backlight_on(0, 0);

    motor_on(200, 0);
    // sleep 1s
    t = clock_seconds();
    while(clock_seconds() - t <= 3);
    printf("$$OK MOTOR\n");
    t = clock_seconds();
    while(clock_seconds() - t <= 3);
    motor_on(0, 0);

#if PRODUCT_W001
    I2C_Init();
    codec_init();
    codec_bypass(1);
    // sleep 1s
    t = clock_seconds();
    while(clock_seconds() - t <= 3);
    printf("$$OK MIC\n");
    // sleep 1s
    t = clock_seconds();
    while(clock_seconds() - t <= 3);
    codec_bypass(0);

    codec_shutdown();
#endif
  }

  int reason = CheckUpgrade();

  window_init(reason);

  button_init();
  rtc_init();
  CFSFontWrapperLoad();

  system_init(); // check system status and do factor reset if needed

  I2C_Init();

  //codec_init();
  //ant_init();
  bluetooth_init();

#ifdef PRODUCT_W004
  //bmx_init();
#else
  mpu6050_init();
#endif

  // check the button status
  if (button_snapshot() & (1 << BUTTON_UP))
  {
    clock_time_t t;
    // delay 1 second
    // button up is pressed, we will set emerging flag
    motor_on(200, CLOCK_SECOND * 2);
    t = clock_seconds();
    while(clock_seconds() - t <= 1);

    if (button_snapshot() & (1 << BUTTON_UP)) 

    system_setemerging();
    motor_on(0, 0);
  }  
  
  if (!system_retail())
  {
    bluetooth_discoverable(1);
  }

#if PRODUCT_W001
  if (system_testing())
    ant_init(MODE_HRM);
#endif
  
  system_restore();

//  protocol_init();
//  protocol_start(1);
  
  process_start(&system_process, NULL);

  /*
  * This is the scheduler loop.
  */
  msp430_dco_required = 0;

  /*
    check firmware update
    */
  if (reason == 0xff)
  {
    printf("Start Upgrade\n");
    Upgrade();
    // never return if sucessfully upgrade
  }

  watchdog_start();

  while(1) {
    int r;
    do {
      /* Reset watchdog. */
      watchdog_periodic();
      r = process_run();
    } while(r > 0);

    /*
    * Idle processing.
    */
    int s = splhigh();          /* Disable interrupts. */
    /* uart1_active is for avoiding LPM3 when still sending or receiving */
    if(process_nevents() != 0) {
      splx(s);                  /* Re-enable interrupts. */
    } else {
      static unsigned long irq_energest = 0;

      /* Re-enable interrupts and go to sleep atomically. */
      ENERGEST_OFF(ENERGEST_TYPE_CPU);
      ENERGEST_ON(ENERGEST_TYPE_LPM);
      /* We only want to measure the processing done in IRQs when we
         are asleep, so we discard the processing time done when we
         were awake. */
      energest_type_set(ENERGEST_TYPE_IRQ, irq_energest);
      watchdog_stop();

      if (shutdown_mode)
      {
        system_shutdown(1); // never return
        LPM4;
      }
      
      if (msp430_dco_required)
      {
        __low_power_mode_0();
      }
      else
      {
        __low_power_mode_3();
      }

      /* We get the current processing time for interrupts that was
         done during the LPM and store it for next time around.  */
      __disable_interrupt();
      irq_energest = energest_type_time(ENERGEST_TYPE_IRQ);
      __enable_interrupt();
      watchdog_start();
      ENERGEST_OFF(ENERGEST_TYPE_LPM);
      ENERGEST_ON(ENERGEST_TYPE_CPU);
    }
  }
}
Exemplo n.º 18
0
/**@brief Function for initializing services that will be used by the application.
 */
static void services_init(void)
{
    uint32_t err_code = bluetooth_init();
    APP_ERROR_CHECK(err_code);
}
Exemplo n.º 19
-11
int
main ()
{
    pio_config_set (LED_GREEN_PIO, PIO_OUTPUT_HIGH);
    pio_config_set (LED_ORANGE_PIO, PIO_OUTPUT_HIGH);
    pio_config_set (LED_RED_PIO, PIO_OUTPUT_HIGH);
    pio_config_set (LED_BLUE_PIO, PIO_OUTPUT_HIGH);

    /* Initialise i2c */
    i2c_motor = i2c_master_init (&i2c_bus_cfg, &i2c_motor_cfg);
    i2c_camera = i2c_master_init (&i2c_bus_cfg, &i2c_camera_cfg);

    /* Initialise bluetooth */
    bluetooth_t btconn = bluetooth_init(115200);
    kernel_init ();
    
    
    kernel_taskRegister (bluetooth_comms_task, BLUETOOTH_COMMS_TASK, btconn, 10);
    kernel_taskRegister (action_commands_task, ACTION_COMMANDS_TASK, btconn, 100);
    
    kernel_start ();
    
    return 0;
   
}