void GetEEPRomData(uint8_t start, uint8_t stop, uint8_t * data) {
// println_W("Getting eeprom page: ");p_int_W(start+DATASTART);print_W(" to ");p_int_W(stop+DATASTART);
//WORD_VAL raw;
uint8_t i = 0;
if (start > stop) {
//println_W("###ERROR eeprom");
return;
}
int total = 0;
do {
total++;
if (total > 5)
return;
LoadCorePacket(&downstreamPacketTemp);
for (i = 0; i < (stop - start); i++) {
//Writes over the old packet to avoid mis-reads
downstreamPacketTemp.use.data[i] = data[i];
}
downstreamPacketTemp.use.head.Method = BOWLER_GET;
downstreamPacketTemp.use.head.RPC = GetRPCValue(eepd);
downstreamPacketTemp.use.data[0] = start + DATASTART;
downstreamPacketTemp.use.data[1] = stop + DATASTART;
downstreamPacketTemp.use.head.DataLegnth = 6;
SendPacketToCoProc(&downstreamPacketTemp);
buttonCheck(12);
} while (downstreamPacketTemp.use.head.RPC != GetRPCValue(eepd));
for (i = 0; i < (stop - start); i++) {
data[i] = downstreamPacketTemp.use.data[i + 1];
}
// println_W("Rx<<");
// printBowlerPacketDEBUG(&downstreamPacketTemp,WARN_PRINT);
}
bool handleButtons(float x, float y)
{
if(translateButton.contains(x,y))
transM = TRANS_TRANSLATION;
else if(rotateButton.contains(x,y))
transM = TRANS_ROTATION;
else if(scaleButton.contains(x,y))
transM = TRANS_SCALE;
else if(XButton.contains(x,y))
axisM = X_AXIS;
else if(YButton.contains(x,y))
axisM = Y_AXIS;
else if(ZButton.contains(x,y))
axisM = Z_AXIS;
else if(tetraButton.contains(x,y))
createShape(SHAPE_TETRAHEDRON);
else if(cubeButton.contains(x,y))
createShape(SHAPE_CUBE);
else if(octButton.contains(x,y))
createShape(SHAPE_OCTAHEDRON);
else if(sphereButton.contains(x,y))
createShape(SHAPE_SPHERE);
else if(cylinderButton.contains(x,y))
createShape(SHAPE_CYLINDER);
else if(planeButton.contains(x,y))
createShape(SHAPE_PLANE);
else if(deleteButton.contains(x,y))
deleteShape();
else if(RButton.contains(x,y))
colorM = COLOR_R;
else if(GButton.contains(x,y))
colorM = COLOR_G;
else if(BButton.contains(x,y))
colorM = COLOR_B;
else if(loadButton.contains(x,y))
{
idCounter = load("default.mcg", &listOfShapes);
if(idCounter <= 0)
{
idCounter = 1;
listOfShapes.clear();
}
}
else if(saveButton.contains(x,y))
save("default", listOfShapes);
else return false;
buttonCheck();
return true;
}
void GetAllModes(BowlerPacket * pack) {
// println_I("GetAllModes");
int total = 0;
do {
total++;
if (total > 5) {
// println_I("Failed returning");
return;
}
LoadGACM(pack);
SendPacketToCoProc(pack);
buttonCheck(14);
} while (pack->use.head.RPC != GetRPCValue("gacm"));
//print_I("..done");
}
void seedWithButtonPress() {
// turn on teensy LED
PORTD |= 0b01000000;
// Configure port B for the buttons....
DDRB |= 0b00001100;
// Wait for the button press on SW0 while iterating the seed
unsigned int seed = 0;
while (!((PINB >> PB0) & 1)) {
buttonCheck();
seed++;
}
// Seed the random number generator
srand(seed);
// What does dgbI do? where is it from?
// dbgI((int) seed, 10);
// turn off teensy LED
PORTD = 0b00000000;
}
void SetLockCode(char * code) {
//WORD_VAL raw;
uint8_t i = 0;
LoadCorePacket(&downstreamPacketTemp);
downstreamPacketTemp.use.head.Method = BOWLER_POST;
downstreamPacketTemp.use.head.RPC = GetRPCValue(eepd);
downstreamPacketTemp.use.data[0] = LOCKSTART;
downstreamPacketTemp.use.data[1] = DATASTART;
while (code[i] != '\0') {
downstreamPacketTemp.use.data[2 + i] = code[i];
i++;
buttonCheck(8);
if (i == LOCKSIZE)
break;
}
downstreamPacketTemp.use.data[2 + i] = '\0';
downstreamPacketTemp.use.head.DataLegnth = 6 + LOCKSIZE;
SendPacketToCoProc(&downstreamPacketTemp);
}
boolean GetLockCode(char * code) {
//WORD_VAL raw;
uint8_t i = 0;
LoadCorePacket(&downstreamPacketTemp);
downstreamPacketTemp.use.head.Method = BOWLER_GET;
downstreamPacketTemp.use.head.RPC = GetRPCValue(eepd);
downstreamPacketTemp.use.data[0] = LOCKSTART;
downstreamPacketTemp.use.data[1] = DATASTART;
downstreamPacketTemp.use.head.DataLegnth = 6;
SendPacketToCoProc(&downstreamPacketTemp);
while (downstreamPacketTemp.use.data[i + 2] != '\0') {
code[i] = downstreamPacketTemp.use.data[2 + i];
i++;
buttonCheck(10);
if (i == LOCKSIZE)
break;
}
code[i] = '\0';
return isAscii(code);
}
void SetName(char * name) {
//WORD_VAL raw;
uint8_t i = 0;
println_E(name);
LoadCorePacket(&downstreamPacketTemp);
downstreamPacketTemp.use.head.Method = BOWLER_POST;
downstreamPacketTemp.use.head.RPC = GetRPCValue(eepd);
downstreamPacketTemp.use.data[0] = NAMESTART;
downstreamPacketTemp.use.data[1] = LOCKSTART;
while (name[i] != '\0') {
downstreamPacketTemp.use.data[2 + i] = name[i];
i++;
buttonCheck(9);
if (i == NAMESIZE)
break;
}
downstreamPacketTemp.use.data[2 + i] = '\0';
downstreamPacketTemp.use.head.DataLegnth = 6 + i + 1;
printPacket(&downstreamPacketTemp,ERROR_PRINT);
SendPacketToCoProc(&downstreamPacketTemp);
}
void _SetChannelValueCoProc(uint8_t PIN, uint8_t state) {
uint8_t retry = 0;
do {
if (retry > 0) {
//println_E("#*#*SetChannelValueCoProc did not return RDY pin: ");p_int_E(PIN);print_E(" mode: ");printMode(GetChannelMode(PIN),ERROR_PRINT);
//printPacket(&downstreamPacketTemp,ERROR_PRINT);
return;
}
LoadCorePacket(&downstreamPacketTemp);
downstreamPacketTemp.use.head.Method = BOWLER_POST;
downstreamPacketTemp.use.head.RPC = GetRPCValue("schv");
downstreamPacketTemp.use.data[0] = PIN;
set32bit(&downstreamPacketTemp, state, 1);
set32bit(&downstreamPacketTemp, 0, 5); // zero ms
downstreamPacketTemp.use.head.DataLegnth = 4 + 1 + 4 + 4;
SendPacketToCoProc(&downstreamPacketTemp);
setDataTableCurrentValue(PIN, state);
retry++;
buttonCheck(13);
} while (downstreamPacketTemp.use.head.RPC != _RDY);
}
boolean GetName(char * name) {
//WORD_VAL raw;
uint8_t i = 0;
LoadCorePacket(&downstreamPacketTemp);
downstreamPacketTemp.use.head.Method = BOWLER_GET;
downstreamPacketTemp.use.head.RPC = GetRPCValue(eepd);
downstreamPacketTemp.use.data[0] = NAMESTART;
downstreamPacketTemp.use.data[1] = LOCKSTART;
downstreamPacketTemp.use.head.DataLegnth = 6;
SendPacketToCoProc(&downstreamPacketTemp);
printPacket(&downstreamPacketTemp,WARN_PRINT);
while (downstreamPacketTemp.use.data[i] != '\0') {
name[i] = downstreamPacketTemp.use.data[i];
i++;
buttonCheck(11);
if (i == NAMESIZE)
break;
}
name[i] = '\0';
println_W(name);
return isAscii(name);
}
// main
// ===============================================================
// ===============================================================
// ===============================================================
// ===============================================================
int main(void)
{
uint8_t i1, i2, i3, i4;
uint8_t bus_address;
uint8_t rx_type;
uint8_t k_row;
k_row = 0;
refresh_row = 0;
scan_keypad = 0;
key_read = key_write = 0;
rx_read = rx_write = 0;
intensity_index = 15;
reply_type = _REPLY_KEYPAD;
DDRB = 0xfe; // input pin 1, outputs else
DDRC = 0xff; // output
DDRD = 0xff; // output
bus_address = ADDR; // initialized value, default 100 or from makefile
// we will overwrite this with the value stored in eeprom
// led refresh interrupt
TCCR0A = 0;
TCCR0B = (1<<CS02);// | (1<<CS00); // prescale io/256
TIMSK0 = (1 << OCIE0A) | (1 << OCIE0B);// | (1 << TOIE0);
OCR0A = LED_REFRESH_RATE;
OCR0B = ints[intensity_index];
TCCR2A = 0;
TCCR2B = (1<<CS22) | (1<<CS21); // prescale io/256
TIMSK2 = (1 << OCIE2A) | (1 << OCIE2B);// | (1 << OCIE0B);// | (1 << TOIE0);
OCR2A = d1ints[intensity_index];
OCR2B = d2ints[intensity_index];
// keypad interrupt
TCCR1A = 0;
TCCR1B = (1<<CS12) | (1<<CS10);
TIMSK1 = (1<<OCIE1A);
OCR1A = KEYPAD_REFRESH_RATE;
buttonInit();
sei();
twi_init();
twi_setAddress(bus_address);
twi_attachSlaveRxEvent(processRx);
twi_attachSlaveTxEvent(processTx);
// loop
// ===============================================================
// ===============================================================
while(1) {
if(scan_keypad) {
//for(k_row=0;k_row<8;k_row++) {
button_last[k_row] = button_current[k_row];
//_delay_us(5);
PORTB |= B2_KCOL_SH;
_delay_us(5);
for(i1=0;i1<8;i1++) {
i2 = !(PINB & B0_KCOL_Q);
PORTB |= B1_KCOL_CLK;
//_delay_us(2);
PORTB &= ~B1_KCOL_CLK;
if (i2)
button_current[k_row] |= (1 << i1);
else
button_current[k_row] &= ~(1 << i1);
buttonCheck(k_row,i1);
if(button_event[k_row] & (1<<i1)) {
button_event[k_row] &= ~(1<<i1);
key_changes[key_write]= ((!i2)<<7) + ((7-i1)*8) + (k_row);
key_write++;
key_write %= 128;
}
}
PORTB &= ~B2_KCOL_SH;
k_row++;
k_row %= 8;
PORTC = k_row;//(PINC | 0x07) | k_row;
scan_keypad = 0;
}
if(rx_read != rx_write) {
rx_type = rx[rx_read];
if(rx_type == _QUERY) {
i1 = 0;
} else if(rx_type == _SLEEP) {
TIMSK0 = 0;
TIMSK1 = 0;
TIMSK2 = 0;
PORTD = 0;
} else if(rx_type == _WAKE) {
TIMSK0 = (1 << OCIE0A) | (1 << OCIE0B);
TIMSK1 = (1<<OCIE1A);
} else if(rx_type == _KEYPAD_REQUEST) {
reply_type = _REPLY_KEYPAD;
} else if(rx_type == _LED_SET0) {
// _LED_SET0 //////////////////////////////////////////////
i3 = rx[(rx_read + 1)%128];
i1 = i3 & 0x0f;
i2 = i3 >> 4;
lights[i1] &= ~(1<<i2);
} else if(rx_type == _LED_SET1) {
void fail(){
while(true) {
SetColor(1,1,0);
buttonCheck(1);
}
}
int main(int argc, char *argv[]) {
int button, buttonCount;
#if defined(DEBUG)
int daemonize = 0;
#else
int daemonize = 1;
#endif
// Setup signal handling before we start
signal(SIGHUP, signal_handler);
signal(SIGTERM, signal_handler);
signal(SIGINT, signal_handler);
signal(SIGQUIT, signal_handler);
int c;
while( (c = getopt(argc, argv, "nh|help")) != -1) {
switch(c){
case 'h':
PrintUsage(argc, argv);
exit(0);
break;
case 'n':
daemonize = 0;
break;
default:
PrintUsage(argc, argv);
exit(0);
break;
}
}
syslog(LOG_INFO, "%s daemon starting up", DAEMON_NAME);
// Setup syslog logging - see SETLOGMASK(3)
#if defined(DEBUG)
setlogmask(LOG_UPTO(LOG_DEBUG));
openlog(DAEMON_NAME, LOG_CONS | LOG_NDELAY | LOG_PERROR | LOG_PID, LOG_USER);
#else
setlogmask(LOG_UPTO(LOG_INFO));
openlog(DAEMON_NAME, LOG_CONS, LOG_USER);
#endif
/* Our process ID and Session ID */
pid_t pid, sid;
if (daemonize) {
syslog(LOG_INFO, "starting the daemonizing process");
/* Fork off the parent process */
pid = fork();
if (pid < 0) {
exit(EXIT_FAILURE);
}
/* If we got a good PID, then
we can exit the parent process. */
if (pid > 0) {
exit(EXIT_SUCCESS);
}
/* Change the file mode mask */
umask(0);
/* Create a new SID for the child process */
sid = setsid();
if (sid < 0) {
/* Log the failure */
exit(EXIT_FAILURE);
}
/* Change the current working directory */
if ((chdir("/")) < 0) {
/* Log the failure */
exit(EXIT_FAILURE);
}
/* Close out the standard file descriptors */
close(STDIN_FILENO);
close(STDOUT_FILENO);
close(STDERR_FILENO);
}
//****************************************************
// TODO: Insert core of your daemon processing here
//****************************************************
while(1){
button = buttonCheck();
if(button == 0){
//Debounce protector
while(button == 0){ button = buttonCheck();}
if(buttonCount == 0) buttonCount = 1;
else buttonCount = 0;
if(buttonCount == 1){
//Kill the code
system("kill -9 'cat /var/run/studentCode.pid'");
//Print program termination message.
system("wall /programKillMsg");
setLED(4);
}
//Reset the robot
fullReset();
if( buttonCount == 0){
//Print message
system("wall /resetMessage");
//Run the code again.
system("/RUNCODE/runMe");
}
usleep(500000);
}
}
syslog(LOG_INFO, "%s daemon exiting", DAEMON_NAME);
//****************************************************
// TODO: Free any allocated resources before exiting
//****************************************************
exit(0);
}
int main(void)
{
uint8 i1, i2, i3;
uint8 rx0, rx1, rx_pos, rx_roll;
uint8 led_data[8];
t_message serial_in;
t_message serial_out;
io_pin_t ioRXF; ioRXF.port = B; ioRXF.pin = 1;
io_pin_t ioRD; ioRD.port = B; ioRD.pin = 2;
io_pin_t ioWR; ioWR.port = B; ioWR.pin = 3;
io_pin_t ioPWREN; ioPWREN.port = C; ioPWREN.pin = 0;
io_pin_t ioLOAD; ioLOAD.port = C; ioLOAD.pin = 6; // 164 SH/LD
io_pin_t ioDATA; ioDATA.port = C; ioDATA.pin = 7; // 165 QH
io_pin_t ioCLKSEL; ioCLKSEL.port = A; ioCLKSEL.pin = 6; // 164 CLK
io_pin_t ioCLKIN; ioCLKIN.port = A; ioCLKIN.pin = 7;
io_pin_t ioSET; ioSET.port = A; ioSET.pin = 5; // 164 A
uint8 firstRun = true;
DDRB &= ~(1 << ioRXF.pin); PORTB |= (1 << ioRXF.pin);
DDRB |= (1 << ioRD.pin); PORTB |= (1 << ioRD.pin);
DDRB |= (1 << ioWR.pin); PORTB |= (1 << ioWR.pin);
DDRC &= ~(1 << ioPWREN.pin); PORTC |= (1 << ioPWREN.pin);
DDRC |= (1 << ioLOAD.pin); PORTC |= (1 << ioLOAD.pin);
DDRC &= ~(1 << ioDATA.pin); PORTC |= (1 << ioDATA.pin);
DDRA |= (1 << ioCLKSEL.pin); PORTA |= (1 << ioCLKSEL.pin);
DDRA |= (1 << ioCLKIN.pin); PORTA |= (1 << ioCLKIN.pin);
DDRA |= (1 << ioSET.pin); PORTA |= (1 << ioSET.pin);
output_pin(ioSET, 1); // clear out row selector
for (i1 = 0; i1 < 8; i1++) {
led_data[i1] = 0;
output_pin(ioCLKSEL, 1); // clear out row selector
output_pin(ioCLKSEL, 0);
}
buttonInit();
rx0 = 0;
rx_pos = 0;
rx_roll = 0;
sei();
// init SPI
SPCR = (1 << SPE) | (1 << MSTR) | (SPI2X);
DDRB |= (1 << PB5)|(1 << PB4)|(1 << PB7);
spi_led(11, 7); // set scan limit to full range
spi_led(10, 15); // set to max intensity
for(i1 = 1; i1 < 9; i1++) {
spi_led(i1, i1); // print startup pattern
}
spi_led(12, 1); // come out of shutdown mode
spi_led(15, 0); // test mode off
for(i1=0;i1<64;) {
spi_led(10, (64-i1)/4); // set to max intensity
if(!input_pin(ioPWREN)) i1++; // wait for USB enumeration, to prevent auto-sleep
_delay_ms(8);
}
for(i1 = 1; i1 < 9; i1++)
spi_led(i1, 0); // clear led data
spi_led(10, 15); // set to max intensity
// ******** main loop ********
while (1) {
// read incoming serial **********************************************
PORTD = 0; // setup PORTD for input
DDRD = 0; // input w/ tristate
while(!(input_pin(ioRXF))) {
output_pin(ioRD, 0);
if (rx_pos == 0) {
rx0 = PIND;
rx_pos = 1;
}
else {
uint8 msg_type, msg_data0;
rx1 = PIND;
rx_pos = 0;
// *********** process packet here
serial_in.data0 = rx0;
serial_in.data1 = rx1;
msg_type = messageGetType(serial_in);
switch (msg_type) {
case kMessageTypeLedTest:
msg_data0 = messageGetLedTestState(serial_in);
spi_led(15, msg_data0);
break;
case kMessageTypeLedIntensity:
msg_data0 = messageGetLedIntensity(serial_in);
spi_led(10, msg_data0);
break;
case kMessageTypeLedStateChange:
i1 = messageGetLedX(serial_in);
i2 = messageGetLedY(serial_in);
if(messageGetLedState(serial_in) == 0)
led_data[i2] &= ~(1 << i1);
else
led_data[i2] |= (1 << i1);
spi_led(i2 + 1, led_data[i2]);
break;
case kMessageTypeAdcEnable:
if (messageGetAdcEnableState(serial_in))
enableAdc(messageGetAdcEnablePort(serial_in));
else
disableAdc(messageGetAdcEnablePort(serial_in));
break;
case kMessageTypeShutdown:
msg_data0 = messageGetShutdownState(serial_in);
spi_led(12, msg_data0);
break;
case kMessageTypeLedSetRow:
if (firstRun == true) {
for (i1 = 0; i1 < 8; i1++) {
led_data[i1] = 0;
spi_led(i1 + 1, led_data[i1]);
}
firstRun = false;
}
i1 = (messageGetLedRowIndex(serial_in) & 0x7); // mask this value so we don't write to an invalid address.
// this will have to change for 100h.
i2 = messageGetLedRowState(serial_in);
led_data[i1] = i2;
spi_led(i1 + 1, led_data[i1]);
break;
case kMessageTypeLedSetColumn:
if (firstRun == true) {
for (i1 = 0; i1 < 8; i1++) {
led_data[i1] = 0;
spi_led(i1 + 1, led_data[i1]);
}
firstRun = false;
}
i1 = (messageGetLedColumnIndex(serial_in) & 0x7);
i2 = messageGetLedColumnState(serial_in);
for (i3 = 0; i3 < 8; i3++) {
if (i2 & (1 << i3))
led_data[i3] |= 1 << i1;
else
led_data[i3] &= ~(1 << i1);
spi_led(i3 + 1, led_data[i3]);
}
break;
}
}
output_pin(ioRD,1);
}
// check if there's a stray single packet
if (rx_pos == 1)
rx_roll++;
else
rx_roll = 0; // this can be moved to after the packet is processed
// if single packet is "lost" trash it after a chance to get a match
if(rx_roll > 80) {
rx_roll = 0;
rx_pos = 0;
}
// output serial data **********************************************
PORTD = 0; // setup PORTD for output
DDRD = 0xFF;
// button check proto
output_pin(ioSET,0);
for (i1 = 0; i1 < 8; i1++) {
output_pin(ioCLKSEL, 1);
output_pin(ioCLKSEL, 0);
output_pin(ioSET, 1);
button_last[i1] = button_current[i1];
output_pin(ioLOAD, 0); // set 165 to load
output_pin(ioLOAD, 1); // 165 shift
for (i2=0; i2 < 8; i2++) {
i3 = input_pin(ioDATA);
i3 = (i3 == 0);
if (i3)
button_current[i1] |= (1 << i2);
else
button_current[i1] &= ~(1 << i2);
buttonCheck(i1, i2);
if (button_event[i1] & (1 << i2)) {
button_event[i1] &= ~(1 << i2);
messagePackButtonPress(&serial_out, (button_state[i1] & (1 << i2)) ? kButtonDownEvent : kButtonUpEvent, i2, i1);
output_pin(ioWR, 1);
PORTD = serial_out.data0;
output_pin(ioWR, 0);
output_pin(ioWR, 1);
PORTD = serial_out.data1;
output_pin(ioWR, 0);
}
output_pin(ioCLKIN, 1);
output_pin(ioCLKIN, 0);
}
}
// ---------------------------------- ADC -------------------------
for (i1 = 0; i1 < kAdcFilterNumAdcs; i1++) {
if (gAdcFilters[i1].dirty == true) {
messagePackAdcVal(&serial_out, i1, gAdcFilters[i1].value);
output_pin(ioWR, 1);
PORTD = serial_out.data0;
output_pin(ioWR, 0);
output_pin(ioWR, 1);
PORTD = serial_out.data1;
output_pin(ioWR, 0);
gAdcFilters[i1].dirty = false;
}
}
}
return 0;
}
int main(int argc, char *argv[]) {
int button, buttonCount;
#if defined(DEBUG)
int daemonize = 0;
#else
int daemonize = 1;
#endif
// Setup signal handling before we start
signal(SIGHUP, signal_handler);
signal(SIGTERM, signal_handler);
signal(SIGINT, signal_handler);
signal(SIGQUIT, signal_handler);
int c;
while( (c = getopt(argc, argv, "nh|help")) != -1) {
switch(c){
case 'h':
PrintUsage(argc, argv);
exit(0);
break;
case 'n':
daemonize = 0;
break;
default:
PrintUsage(argc, argv);
exit(0);
break;
}
}
syslog(LOG_INFO, "%s daemon starting up", DAEMON_NAME);
// Setup syslog logging - see SETLOGMASK(3)
#if defined(DEBUG)
setlogmask(LOG_UPTO(LOG_DEBUG));
openlog(DAEMON_NAME, LOG_CONS | LOG_NDELAY | LOG_PERROR | LOG_PID, LOG_USER);
#else
setlogmask(LOG_UPTO(LOG_INFO));
openlog(DAEMON_NAME, LOG_CONS, LOG_USER);
#endif
/* Our process ID and Session ID */
pid_t pid, sid;
if (daemonize) {
syslog(LOG_INFO, "starting the daemonizing process");
/* Fork off the parent process */
pid = fork();
if (pid < 0) {
exit(EXIT_FAILURE);
}
/* If we got a good PID, then
we can exit the parent process. */
if (pid > 0) {
exit(EXIT_SUCCESS);
}
/* Change the file mode mask */
umask(0);
/* Create a new SID for the child process */
sid = setsid();
if (sid < 0) {
/* Log the failure */
exit(EXIT_FAILURE);
}
/* Change the current working directory */
if ((chdir("/")) < 0) {
/* Log the failure */
exit(EXIT_FAILURE);
}
/* Close out the standard file descriptors */
close(STDIN_FILENO);
close(STDOUT_FILENO);
close(STDERR_FILENO);
}
//****************************************************
// TODO: Insert core of your daemon processing here
//****************************************************
while(button != 0){
button = buttonCheck();
if(button == 0){
while(button == 0){ button = buttonCheck(); buttonCount++;}
//KILL runme process if it doesnt kill itself.
if(buttonCount < 30000) system("/RUNCODE/runMe");
else system("shutdown -r now");
break;
}
}
syslog(LOG_INFO, "%s daemon exiting", DAEMON_NAME);
//****************************************************
// TODO: Free any allocated resources before exiting
//****************************************************
exit(0);
}
