/** \brief Main function. */
int main(void)
{
uint8_t i;
/* Initialize the board hardware and system clocks. */
board_init();
sysclk_init();
/* Detection of all RESET excepted WDT RESET. */
if (reset_cause_get_causes() & ~CHIP_RESET_CAUSE_WDT) {
/* Wait for 2 s. */
delay_ms(2000);
state_flag = START_OF_PROG;
reset_cause_clear_causes(
CHIP_RESET_CAUSE_POR |
CHIP_RESET_CAUSE_EXTRST |
CHIP_RESET_CAUSE_BOD_CPU |
CHIP_RESET_CAUSE_OCD |
CHIP_RESET_CAUSE_SOFT |
CHIP_RESET_CAUSE_SPIKE);
} else {
reset_cause_clear_causes(CHIP_RESET_CAUSE_WDT);
}
while (true) {
led_display(state_flag);
switch (state_flag) {
case START_OF_PROG:
/* Writing test. */
wdt_set_timeout_period(WDT_TIMEOUT_PERIOD_8CLK);
if (wdt_get_timeout_period() != WDT_TIMEOUT_PERIOD_8CLK) {
state_flag = ERROR_STATE;
break;
}
wdt_set_timeout_period(WDT_TIMEOUT_PERIOD_250CLK);
if (wdt_get_timeout_period() != WDT_TIMEOUT_PERIOD_250CLK) {
state_flag = ERROR_STATE;
break;
}
/* Wait for 2 s. */
delay_ms(2000);
state_flag = WDT_MCU_RESET;
break;
case WDT_MCU_RESET:
/* Wait for 2 s. */
delay_ms(2000);
state_flag = REFRESH_NO_WIN;
wdt_reset_mcu();
break;
case REFRESH_NO_WIN:
/* Enable WDT 500 ms. */
wdt_set_timeout_period(WDT_TIMEOUT_PERIOD_500CLK);
wdt_enable();
for (i = 0; i < 8; i++) {
/* Wait for 8x 250 ms = 2 s. */
delay_ms(250);
wdt_reset();
}
wdt_disable();
state_flag = REFRESH_WINDOW;
break;
case REFRESH_WINDOW:
/* Enable Window 250 ms & WDT 500 ms. */
wdt_set_timeout_period(WDT_TIMEOUT_PERIOD_500CLK);
wdt_enable();
if (!(wdt_set_window_period(WDT_WINDOW_PERIOD_250CLK)))
{
state_flag = ERROR_STATE;
break;
}
if (!(wdt_enable_window_mode())) {
state_flag = ERROR_STATE;
break;
}
for (i = 0; i < 4; i++) {
/* Wait for 500 ms. */
delay_ms(500);
wdt_reset();
}
wdt_disable();
state_flag = WDT_RST_NO_WIN;
break;
case WDT_RST_NO_WIN:
state_flag = WDT_RST_WINDOW;
/* Enable WDT 2 s. */
wdt_set_timeout_period(WDT_TIMEOUT_PERIOD_2KCLK);
wdt_enable();
while (true) {
/* Wait for Watchdog reset. */
}
break;
case WDT_RST_WINDOW:
state_flag = WDT_RST_RFSH_W;
/* Enable Window 1 s & WDT 1 s. */
wdt_set_timeout_period(WDT_TIMEOUT_PERIOD_1KCLK);
wdt_enable();
if (!(wdt_set_window_period(WDT_WINDOW_PERIOD_1KCLK))) {
state_flag = ERROR_STATE;
break;
}
if (!(wdt_enable_window_mode())) {
state_flag = ERROR_STATE;
break;
}
while (true) {
/* Wait for Watchdog reset. */
}
break;
case WDT_RST_RFSH_W:
state_flag = END_OF_PROG;
/* Enable Window 4 s & WDT 250 ms. */
wdt_set_timeout_period(WDT_TIMEOUT_PERIOD_250CLK);
wdt_enable();
if (!(wdt_set_window_period(WDT_WINDOW_PERIOD_4KCLK))) {
state_flag = ERROR_STATE;
break;
}
if (!(wdt_enable_window_mode())) {
state_flag = ERROR_STATE;
break;
}
/* Wait for 2 s. */
delay_ms(2000);
wdt_reset();
while (true) {
/* Wait for Watchdog reset. */
}
break;
case ERROR_STATE:
while (true) {
led_display(ERROR_STATE);
/* Wait for 500 ms. */
delay_ms(500);
/* Blinking. */
led_display(~ERROR_STATE);
/* Wait for 500 ms. */
delay_ms(500);
}
break;
case END_OF_PROG:
default:
/* Wait for 2 s. */
delay_ms(2000);
reset_do_soft_reset();
break;
}
}
}
/**************************************************************************************************
* Handle received HID set feature reports
*/
void HID_set_feature_report_out(uint8_t *report)
{
uint8_t response[UDI_HID_REPORT_OUT_SIZE];
response[0] = report[0] | 0x80;
response[1] = report[1];
response[2] = report[2];
uint16_t addr;
addr = *(uint16_t *)(report+1);
switch(report[0])
{
// no-op
case CMD_NOP:
break;
// write to RAM page buffer
case CMD_RESET_POINTER:
page_ptr = 0;
return;
// read from RAM page buffer
case CMD_READ_BUFFER:
memcpy(response, &page_buffer[page_ptr], UDI_HID_REPORT_OUT_SIZE);
page_ptr += UDI_HID_REPORT_OUT_SIZE;
page_ptr &= APP_SECTION_PAGE_SIZE-1;
break;
// erase entire application section
case CMD_ERASE_APP_SECTION:
SP_WaitForSPM();
SP_EraseApplicationSection();
return;
// calculate application and bootloader section CRCs
case CMD_READ_FLASH_CRCS:
SP_WaitForSPM();
*(uint32_t *)&response[3] = SP_ApplicationCRC();
*(uint32_t *)&response[7] = SP_BootCRC();
break;
// read MCU IDs
case CMD_READ_MCU_IDS:
response[3] = MCU.DEVID0;
response[4] = MCU.DEVID1;
response[5] = MCU.DEVID2;
response[6] = MCU.REVID;
break;
// read fuses
case CMD_READ_FUSES:
response[3] = SP_ReadFuseByte(0);
response[4] = SP_ReadFuseByte(1);
response[5] = SP_ReadFuseByte(2);
response[6] = 0xFF;
response[7] = SP_ReadFuseByte(4);
response[8] = SP_ReadFuseByte(5);
break;
// write RAM page buffer to application section page
case CMD_WRITE_PAGE:
if (addr > (APP_SECTION_SIZE / APP_SECTION_PAGE_SIZE)) // out of range
{
response[1] = 0xFF;
response[2] = 0xFF;
break;
}
SP_WaitForSPM();
SP_LoadFlashPage(page_buffer);
SP_WriteApplicationPage(APP_SECTION_START + ((uint32_t)addr * APP_SECTION_PAGE_SIZE));
page_ptr = 0;
break;
// read application page to RAM buffer and return first 32 bytes
case CMD_READ_PAGE:
if (addr > (APP_SECTION_SIZE / APP_SECTION_PAGE_SIZE)) // out of range
{
response[1] = 0xFF;
response[2] = 0xFF;
}
else
{
memcpy_P(page_buffer, (const void *)(APP_SECTION_START + (APP_SECTION_PAGE_SIZE * addr)), APP_SECTION_PAGE_SIZE);
memcpy(&response[3], page_buffer, 32);
page_ptr = 0;
}
break;
// erase user signature row
case CMD_ERASE_USER_SIG_ROW:
SP_WaitForSPM();
SP_EraseUserSignatureRow();
break;
// write RAM buffer to user signature row
case CMD_WRITE_USER_SIG_ROW:
SP_WaitForSPM();
SP_LoadFlashPage(page_buffer);
SP_WriteUserSignatureRow();
break;
// read user signature row to RAM buffer and return first 32 bytes
case CMD_READ_USER_SIG_ROW:
if (addr > (USER_SIGNATURES_PAGE_SIZE - 32))
{
response[1] = 0xFF;
response[2] = 0xFF;
}
else
{
memcpy_P(page_buffer, (const void *)(USER_SIGNATURES_START + addr), USER_SIGNATURES_SIZE);
memcpy(&response[3], page_buffer, 32);
page_ptr = 0;
}
break;
case CMD_READ_SERIAL:
{
uint8_t i;
uint8_t j = 3;
uint8_t b;
for (i = 0; i < 6; i++)
{
b = SP_ReadCalibrationByte(offsetof(NVM_PROD_SIGNATURES_t, LOTNUM0) + i);
response[j++] = hex_to_char(b >> 4);
response[j++] = hex_to_char(b & 0x0F);
}
response[j++] = '-';
b = SP_ReadCalibrationByte(offsetof(NVM_PROD_SIGNATURES_t, LOTNUM0) + 6);
response[j++] = hex_to_char(b >> 4);
response[j++] = hex_to_char(b & 0x0F);
response[j++] = '-';
for (i = 7; i < 11; i++)
{
b = SP_ReadCalibrationByte(offsetof(NVM_PROD_SIGNATURES_t, LOTNUM0) + i);
response[j++] = hex_to_char(b >> 4);
response[j++] = hex_to_char(b & 0x0F);
}
response[j] = '\0';
break;
}
case CMD_READ_BOOTLOADER_VERSION:
response[3] = BOOTLOADER_VERSION;
break;
case CMD_RESET_MCU:
reset_do_soft_reset();
response[1] = 0xFF; // failed
break;
case CMD_READ_EEPROM:
if (addr > (EEPROM_SIZE - 32))
{
response[1] = 0xFF;
response[2] = 0xFF;
}
else
{
EEP_EnableMapping();
memcpy_P(page_buffer, (const void *)(MAPPED_EEPROM_START + addr), APP_SECTION_PAGE_SIZE);
EEP_DisableMapping();
memcpy(&response[3], page_buffer, 32);
page_ptr = 0;
}
break;
case CMD_WRITE_EEPROM:
if (addr > (EEPROM_SIZE / EEPROM_PAGE_SIZE))
{
response[1] = 0xFF;
response[2] = 0xFF;
}
else
{
EEP_LoadPageBuffer(&report[3], EEPROM_PAGE_SIZE);
EEP_AtomicWritePage(addr);
}
break;
// unknown command
default:
response[0] = 0xFF;
break;
}
udi_hid_generic_send_report_in(response);
}
/**
* \brief Main function.
*/
int main(void)
{
uint8_t key;
/* Initialize the SAM system. */
sysclk_init();
board_init();
/* Initialize the UART console. */
configure_console();
/* Output example information. */
puts(STRING_HEADER);
puts("------ Please select which reset is to be generated ----------\r\n"
" c: Generate core BOD reset\r\n"
" i: Generate I/O BOD reset\r\n"
" w: Generate watchdog reset\r\n"
" s: Generate system reset \r");
if (reset_cause_is_power_on_reset()) {
LED_On(LED0);
}
if (reset_cause_is_cpu_brown_out_detected()) {
puts("-- Reset Cause is Core browm out reset --\r");
}
if (reset_cause_is_io_brown_out_detected()) {
puts("-- Reset Cause is I/O brown out reset --\r");
}
if (reset_cause_is_ocd()) {
puts("-- Reset Cause is system reset request --\r");
}
if (reset_cause_is_external_reset()) {
puts("-- Reset Cause is external reset --\r");
}
if (reset_cause_is_watchdog()) {
puts("-- Reset Cause is watchdog reset --\r");
}
while(1) {
scanf("%c", (char *)&key);
switch (key) {
case 'c':
puts("-- Please press reset button --\r");
BSCIF->BSCIF_BOD18CTRL = BSCIF_BOD18CTRL_EN | BSCIF_BOD18CTRL_ACTION(1) |
BSCIF_BOD18CTRL_HYST | BSCIF_BOD18CTRL_FCD;
BSCIF->BSCIF_BOD18LEVEL |= BSCIF_BOD18LEVEL_VAL(0x3F);
break;
case 'i':
puts("-- Please press reset button --\r");
BSCIF->BSCIF_BOD33CTRL = BSCIF_BOD33CTRL_EN | BSCIF_BOD33CTRL_ACTION(1) |
BSCIF_BOD33CTRL_HYST | BSCIF_BOD33CTRL_FCD;
BSCIF->BSCIF_BOD33LEVEL = BSCIF_BOD33LEVEL_VAL(0x3F);
break;
case 'w':
wdt_reset_mcu();
break;
case 's':
reset_do_soft_reset();
break;
}
}
}
void ManufactureTestButtonPress(void)
{
startTimeout(&biosUnused, BIOS_UNUSED_MS);
while(1)
{
uint8_t red = LED_OFF;
uint8_t green = LED_OFF;
uint8_t blue = LED_OFF;
WatchdogPet();
if (buttonActivated(B_START) & buttonActivated(B_SELECT))
{
delay_ms(500);
reset_do_soft_reset();
}
if(checkTimeout(&biosUnused))
{
cancelTimeout(&biosUnused);
setLEDValue(0, 0, 0);
powerOff(global_header.powerOffSoftware);
}
if( buttonActivated(B_UP) ||
buttonActivated(B_DOWN) ||
buttonActivated(B_LEFT) ||
buttonActivated(B_RIGHT) ||
buttonActivated(B_A) ||
buttonActivated(B_B) ||
buttonActivated(B_X) ||
buttonActivated(B_Y) ||
buttonActivated(B_START) ||
buttonActivated(B_SELECT) ||
buttonActivated(B_LB) ||
buttonActivated(B_RB) ||
buttonActivated(B_LT) ||
buttonActivated(B_RT) ||
buttonActivated(B_JL) ||
buttonActivated(B_JR)
)
{
green = LED_DIM;
}
for(uint8_t idx = 0 ; idx<NUM_JOYSTICKS; idx++)
{
uint16_xy raw;
raw.x = sampleAnalogChannel(joysticks[idx].adc_channel_x);
raw.y = sampleAnalogChannel(joysticks[idx].adc_channel_y);
int16_xy out;
SimpleJoystickAdj( center[idx], &deadzone, &raw, &out );
//Write raw and adjusted X,Y values to USB serial port
PrintXY(raw.x,raw.y);
sendUSBString("->", false);
PrintXY(out.x,out.y);
sendUSBLine("");
if( out.y<0 )
{
//up is yellow
red = LED_DIM;
green = LED_DIM;
}
else if( out.y>0 )
{
//down is blue
blue = LED_DIM;
}
else if( out.x>0 )
{
//right is Red
red = LED_DIM;
}
else if( out.x<0 )
{
//left is green
green = LED_DIM;
}
}
setLEDValue(red, green, blue);
} // end while(1)
}
