/***************************************************************************************************
* @fn HalLedOnOff
*
* @brief Turns specified LED ON or OFF
*
* @param leds - LED bit mask
* mode - LED_ON,LED_OFF,
*
* @return none
***************************************************************************************************/
void HalLedOnOff (uint8 leds, uint8 mode)
{
if (leds & HAL_LED_1)
{
if (mode == HAL_LED_MODE_ON)
{
HAL_TURN_ON_LED1();
}
else
{
HAL_TURN_OFF_LED1();
}
}
if (leds & HAL_LED_2)
{
if (mode == HAL_LED_MODE_ON)
{
HAL_TURN_ON_LED2();
}
else
{
HAL_TURN_OFF_LED2();
}
}
if (leds & HAL_LED_3)
{
if (mode == HAL_LED_MODE_ON)
{
HAL_TURN_ON_LED3();
}
else
{
HAL_TURN_OFF_LED3();
}
}
if (leds & HAL_LED_4)
{
if (mode == HAL_LED_MODE_ON)
{
HAL_TURN_ON_LED4();
}
else
{
HAL_TURN_OFF_LED4();
}
}
/* Remember current state */
if (mode)
{
HalLedState |= leds;
}
else
{
HalLedState &= (leds ^ 0xFF);
}
}
void sleep(void)
{
if (HAL_STATE_LED2())
{
HAL_TURN_OFF_LED1();
HAL_TURN_OFF_LED3();
HAL_TURN_ON_LED2();
for(uint8 n=0;n<30;n++)
for(uint8 i=0;i<200;i++)
MicroWait(50000);
HAL_TURN_OFF_LED2();
//sbBinded = 0;
}
}
/***************************************************************************************************
* @fn HalLedOnOff
*
* @brief Turns specified LED ON or OFF
*
* @param leds - LED bit mask
* mode - LED_ON,LED_OFF,
*
* @return none
***************************************************************************************************/
void HalLedOnOff( uint8 leds, uint8 mode )
{
if ( leds & HAL_LED_1 )
{
if ( mode == HAL_LED_MODE_ON )
HAL_TURN_ON_LED1();
else
HAL_TURN_OFF_LED1();
}
if ( leds & HAL_LED_2 )
{
if ( mode == HAL_LED_MODE_ON )
HAL_TURN_ON_LED2();
else
HAL_TURN_OFF_LED2();
}
if ( leds & HAL_LED_3 )
{
if ( mode == HAL_LED_MODE_ON )
HAL_TURN_ON_LED3();
else
HAL_TURN_OFF_LED3();
}
if ( leds & HAL_LED_4 )
{
if ( mode == HAL_LED_MODE_ON )
HAL_TURN_ON_LED4();
else
HAL_TURN_OFF_LED4();
}
// Remember current state
if ( mode )
ledState |= leds;
else
ledState &= (0xff ^ leds);
}
/**************************************************************************************************
* @fn halAssertHazardLights
*
* @brief Blink LEDs to indicate an error.
*
* @param none
*
* @return none
**************************************************************************************************
*/
void halAssertHazardLights(void)
{
enum
{
DEBUG_DATA_RSTACK_HIGH_OFS,
DEBUG_DATA_RSTACK_LOW_OFS,
DEBUG_DATA_TX_ACTIVE_OFS,
DEBUG_DATA_RX_ACTIVE_OFS,
#if (defined HAL_MCU_AVR) || (defined HAL_MCU_CC2430)
DEBUG_DATA_INT_MASK_OFS,
#elif (defined HAL_MCU_CC2530) || (defined HAL_MCU_CC2533)
DEBUG_DATA_INT_MASK0_OFS,
DEBUG_DATA_INT_MASK1_OFS,
#endif
DEBUG_DATA_SIZE
};
uint8 buttonHeld;
uint8 debugData[DEBUG_DATA_SIZE];
/* disable all interrupts before anything else */
HAL_DISABLE_INTERRUPTS();
/*-------------------------------------------------------------------------------
* Initialize LEDs and turn them off.
*/
HAL_BOARD_INIT();
HAL_TURN_OFF_LED1();
HAL_TURN_OFF_LED2();
HAL_TURN_OFF_LED3();
HAL_TURN_OFF_LED4();
/*-------------------------------------------------------------------------------
* Master infinite loop.
*/
for (;;)
{
buttonHeld = 0;
/*-------------------------------------------------------------------------------
* "Hazard lights" loop. A held keypress will exit this loop.
*/
do
{
HAL_LED_BLINK_DELAY();
/* toggle LEDS, the #ifdefs are in case HAL has logically remapped non-existent LEDs */
#if (HAL_NUM_LEDS >= 1)
HAL_TOGGLE_LED1();
#if (HAL_NUM_LEDS >= 2)
HAL_TOGGLE_LED2();
#if (HAL_NUM_LEDS >= 3)
HAL_TOGGLE_LED3();
#if (HAL_NUM_LEDS >= 4)
HAL_TOGGLE_LED4();
#endif
#endif
#endif
#endif
/* escape hatch to continue execution, set escape to '1' to continue execution */
{
static uint8 escape = 0;
if (escape)
{
escape = 0;
return;
}
}
/* break out of loop if button is held long enough */
if (HAL_PUSH_BUTTON1())
{
buttonHeld++;
}
else
{
buttonHeld = 0;
}
}
while (buttonHeld != 10); /* loop until button is held specified number of loops */
/*-------------------------------------------------------------------------------
* Just exited from "hazard lights" loop.
*/
/* turn off all LEDs */
HAL_TURN_OFF_LED1();
HAL_TURN_OFF_LED2();
HAL_TURN_OFF_LED3();
HAL_TURN_OFF_LED4();
/* wait for button release */
HAL_DEBOUNCE(!HAL_PUSH_BUTTON1());
/*-------------------------------------------------------------------------------
* Load debug data into memory.
*/
#ifdef HAL_MCU_AVR
{
uint8 * pStack;
pStack = (uint8 *) SP;
pStack++; /* point to return address on stack */
debugData[DEBUG_DATA_RSTACK_HIGH_OFS] = *pStack;
pStack++;
debugData[DEBUG_DATA_RSTACK_LOW_OFS] = *pStack;
}
debugData[DEBUG_DATA_INT_MASK_OFS] = EIMSK;
#endif
#if (defined HAL_MCU_CC2430)
debugData[DEBUG_DATA_INT_MASK_OFS] = RFIM;
#elif (defined HAL_MCU_CC2530) || (defined HAL_MCU_CC2533)
debugData[DEBUG_DATA_INT_MASK0_OFS] = RFIRQM0;
debugData[DEBUG_DATA_INT_MASK1_OFS] = RFIRQM1;
#endif
#if (defined HAL_MCU_AVR) || (defined HAL_MCU_CC2430) || (defined HAL_MCU_CC2530) || \
(defined HAL_MCU_CC2533) || (defined HAL_MCU_MSP430)
debugData[DEBUG_DATA_TX_ACTIVE_OFS] = macTxActive;
debugData[DEBUG_DATA_RX_ACTIVE_OFS] = macRxActive;
#endif
/* initialize for data dump loop */
{
uint8 iBit;
uint8 iByte;
iBit = 0;
iByte = 0;
/*-------------------------------------------------------------------------------
* Data dump loop. A button press cycles data bits to an LED.
*/
while (iByte < DEBUG_DATA_SIZE)
{
/* wait for key press */
while(!HAL_PUSH_BUTTON1());
/* turn on all LEDs for first bit of byte, turn on three LEDs if not first bit */
HAL_TURN_ON_LED1();
HAL_TURN_ON_LED2();
HAL_TURN_ON_LED3();
if (iBit == 0)
{
HAL_TURN_ON_LED4();
}
else
{
HAL_TURN_OFF_LED4();
}
/* wait for debounced key release */
HAL_DEBOUNCE(!HAL_PUSH_BUTTON1());
/* turn off all LEDs */
HAL_TURN_OFF_LED1();
HAL_TURN_OFF_LED2();
HAL_TURN_OFF_LED3();
HAL_TURN_OFF_LED4();
/* output value of data bit to LED1 */
if (debugData[iByte] & (1 << (7 - iBit)))
{
HAL_TURN_ON_LED1();
}
else
{
HAL_TURN_OFF_LED1();
}
/* advance to next bit */
iBit++;
if (iBit == 8)
{
iBit = 0;
iByte++;
}
}
}
/*
* About to enter "hazard lights" loop again. Turn off LED1 in case the last bit
* displayed happened to be one. This guarantees all LEDs are off at the start of
* the flashing loop which uses a toggle operation to change LED states.
*/
HAL_TURN_OFF_LED1();
}
}
/**************************************************************************************************
* @fn main
*
* @brief C-code main functionality.
*
* input parameters
*
* None.
*
* output parameters
*
* None.
*
* @return None.
**************************************************************************************************
*/
void main(void)
{
uint8 time_spent_validating;
uint8 bootloaderForcedByMainApp = FALSE;
uint32 mainAppCommandLocal = mainAppCommand;
vddWait(VDD_MIN_RUN);
mainAppCommand = MAIN_APP_CMD_NONE;
if (mainAppCommandLocal == MAIN_APP_CMD_FORCE_BOOTLOADER)
{
bootloaderForcedByMainApp = TRUE;
}
else if ((mainAppCommandLocal == MAIN_APP_CMD_PASS_THROUGH) || ((SLEEPSTA & LRESET) == RESETWD))
{
// If reset due to WatchDog Timer - Transfer control to the main application immediately.
// WatchDog Timer reset causes the hardware to disconnect the USB. Withought this jump here,
// the SBL code will try to initiaize the CDC too early, which causes undesired behavior on the host
// (e.g. on beaglebone black - the host gets stuck)
asm("LJMP 0x2000\n");
}
sblInit(bootloaderForcedByMainApp);
HAL_TURN_ON_LED1();
HAL_TURN_ON_LED2();
if ((!bootloaderForcedByMainApp) && (sbImgValid(&time_spent_validating)))
{
HAL_TURN_OFF_LED2();
if (sblWait(SBL_WAIT_TIME > time_spent_validating ? SBL_WAIT_TIME - time_spent_validating : 0))
{
HAL_TURN_OFF_LED1();
sbReportState(SB_STATE_EXECUTING_IMAGE);
while(sblIsUartTxPending())
{
sbUartPoll();
}
SLEEP(0x2600); //Give the last bytes in the HW TX fifo (if any) enough time to be transmitted
while (SB1_PRESS || SB2_PRESS);
sblUnInit();
// Simulate a reset for the Application code by an absolute jump to location 0x2000.
asm("LJMP 0x2000\n");
}
}
HAL_TURN_OFF_LED1();
HAL_TURN_ON_LED2();
vddWait(VDD_MIN_NV);
sblExec();
sblUnInit();
asm("LJMP 0x2000\n");
}
