bool CLI_process(CLIContext *context)
{
while (true) {
char *end = strpbrk(context->buffer, "\r\n");
if (end == NULL)
return true;
*end = 0;
if (bufferStartsWith(context, "quit")) {
addToOutput(context, "EXIT");
return false;
}
const char *ptr;
if (bufferStartsWith(context, "set uart mode") ||
bufferStartsWith(context, "set uart tx") ||
bufferStartsWith(context, "set sys iofunc")) {
/* Ignored */
addToOutput(context, "AOK\r\n");
} else if ((ptr=bufferStartsWith(context,
"set uart instant ")) != NULL) {
uint32_t baud = parseDecimal(ptr);
if (baud > 0) {
Serial_setBaud(baud);
addToOutput(context, "AOK\r\n");
} else {
addToOutput(context, "ERROR\r\n");
}
} else if ((ptr=bufferStartsWith(context, "set sys mask ")) != NULL) {
uint32_t mask = parseHex(ptr, &ptr);
if (!(*ptr)) {
addToOutput(context, "ERROR\r\n");
} else if (*ptr == '0') {
GPIO_setMode(mask, false);
addToOutput(context, "AOK\r\n");
} else {
GPIO_setMode(mask, true);
addToOutput(context, "AOK\r\n");
}
} else if ((ptr=bufferStartsWith(context, "set sys output ")) != NULL) {
uint32_t output = parseHex(ptr, &ptr);
if (!(*ptr)) {
addToOutput(context, "ERROR\r\n");
} else {
uint32_t mask = parseHex(ptr, &ptr);
GPIO_setOutput(mask, output);
addToOutput(context, "AOK\r\n");
}
} else if (end != &context->buffer[0]) {
addToOutput(context, "ERROR\r\n");
}
memmove(context->buffer, end+1, strlen(end+1)+1);
}
}
/**************************************************************************************************
* \fn nRFInit()
* \brief Initialisation du module nRF24L01
*
**************************************************************************************************/
void nRFInit(GPIO_Handle HandleGPIO,SPI_Handle HandleSPI,GPIO_Number_e CePin,GPIO_Number_e CSNPin)
{
uint8_t i = 0;
HandleRF.structCePin = CePin;
HandleRF.structCSNPin = CSNPin;
// Configure gpio for RF module
GPIO_setMode(HandleGPIO, CSNPin, GPIO_0_Mode_GeneralPurpose); //CSN used to activate SPI communication
GPIO_setMode(HandleGPIO, CePin, GPIO_0_Mode_GeneralPurpose); //CE used to activate PTX or RTX mode
GPIO_setDirection(HandleGPIO, CePin, GPIO_Direction_Output);
GPIO_setDirection(HandleGPIO, CSNPin, GPIO_Direction_Output);
// set pin high for normal operation
nRF_setCSN(true,HandleGPIO);
// set mcu memory to zero
for(i = 0; i < 10;i++){
HandleRF.Reg[i] = 0;
}
for(i = 0; i < 10;i++){
HandleRF.RXADDR[i] = 0;
HandleRF.TXADDR[i] = 0;
}
nRF_setCE(false,HandleGPIO); // CE is low for spi communication
HandleRF.Reg[R_CONFIG] = TX_MODE|EN_CRC; //No interupts + TX mode
nRF_WriteRegister(HandleSPI,HandleGPIO,CONFIG,HandleRF.Reg[R_CONFIG]); //update nrf
nRF_WriteRegister(HandleSPI,HandleGPIO,RF_SETUP,RATE_1MBPS|OUPUTPOWER_M6DB);
nRF_WriteRegister(HandleSPI,HandleGPIO,RX_PW_P0,PLAYER_BUFFER_SIZE);
nRF_WriteRegister(HandleSPI,HandleGPIO,RX_PW_P1,PLAYER_BUFFER_SIZE);
//nRF_WriteRegister(HandleSPI,HandleGPIO,RF_CH,0x02); //par defaut = 2
nRF_WriteRegister(HandleSPI,HandleGPIO,EN_RXADDR,DATAPIPE_0); //enable data pipe 0
nRF_WriteRXADDR(HandleSPI,HandleGPIO, 0x07, RX_ADDR_P0); // set the Rx adresse E0
nRF_WriteTXADDR(HandleSPI, HandleGPIO, 0x07); //set the Tx adress for ACK E7
// Read all register for mcu use
nRF_ReadRXADDR( HandleGPIO, HandleSPI, RX_ADDR_P0);
nRF_ReadTXADDR( HandleGPIO, HandleSPI);
HandleRF.Reg[R_STATUS] = nRF_ReadRegister(HandleSPI,HandleGPIO,STATUS);
HandleRF.Reg[R_CONFIG] = nRF_ReadRegister(HandleSPI,HandleGPIO,CONFIG);
HandleRF.Reg[R_RFSETUP] = nRF_ReadRegister(HandleSPI,HandleGPIO,RF_SETUP);
HandleRF.Reg[R_PLLength0] = nRF_ReadRegister(HandleSPI,HandleGPIO,RX_PW_P0);
HandleRF.Reg[R_PLLength1] = nRF_ReadRegister(HandleSPI,HandleGPIO,RX_PW_P1);
HandleRF.Reg[R_RFChannel] = nRF_ReadRegister(HandleSPI,HandleGPIO,RF_CH);
HandleRF.Reg[R_ENRXADDR] = nRF_ReadRegister(HandleSPI,HandleGPIO,EN_RXADDR);
HandleRF.Reg[R_FIFOSTATUS] = nRF_ReadRegister(HandleSPI,HandleGPIO,FIFO_STATUS);
nRF_PowerUp(HandleSPI,HandleGPIO,true);
System_10msDelay(1);
}
void main()
{
memcpy(&RamfuncsRunStart, &RamfuncsLoadStart, (size_t)&RamfuncsLoadSize);
WDOG_Handle myWDog;
myWDog = WDOG_init((void *)WDOG_BASE_ADDR, sizeof(WDOG_Obj));
WDOG_disable(myWDog);
CLK_Handle myClk;
PLL_Handle myPll;
myClk = CLK_init((void *)CLK_BASE_ADDR, sizeof(CLK_Obj));
myPll = PLL_init((void *)PLL_BASE_ADDR, sizeof(PLL_Obj));
CLK_setOscSrc(myClk, CLK_OscSrc_Internal);
PLL_setup(myPll, PLL_Multiplier_12, PLL_DivideSelect_ClkIn_by_2);
GPIO_Handle myGpio;
myGpio = GPIO_init((void *)GPIO_BASE_ADDR, sizeof(GPIO_Obj));
GPIO_setMode(myGpio, GPIO_Number_0, GPIO_0_Mode_GeneralPurpose);
GPIO_setDirection(myGpio, GPIO_Number_0, GPIO_Direction_Output);
GPIO_setMode(myGpio, GPIO_Number_1, GPIO_1_Mode_GeneralPurpose);
GPIO_setDirection(myGpio, GPIO_Number_1, GPIO_Direction_Output);
GPIO_setMode(myGpio, GPIO_Number_2, GPIO_2_Mode_GeneralPurpose);
GPIO_setDirection(myGpio, GPIO_Number_2, GPIO_Direction_Output);
GPIO_setMode(myGpio, GPIO_Number_3, GPIO_3_Mode_GeneralPurpose);
GPIO_setDirection(myGpio, GPIO_Number_3, GPIO_Direction_Output);
GPIO_setHigh(myGpio, GPIO_Number_0);
GPIO_setHigh(myGpio, GPIO_Number_1);
GPIO_setHigh(myGpio, GPIO_Number_2);
GPIO_setHigh(myGpio, GPIO_Number_3);
while(1)
{
GPIO_setLow(myGpio, GPIO_Number_3);
DELAY_US(1000000);
GPIO_setHigh(myGpio, GPIO_Number_3);
DELAY_US(1000000);
}
}
static void gpioCompleted(int fd)
{
gpioFieldCompleted();
switch (post.gpio.mode) {
case GPIO_Disable:
GPIO_setMode(1<<post.gpio.pin, false);
break;
case GPIO_On:
GPIO_setMode(1<<post.gpio.pin, true);
GPIO_setOutput(1<<post.gpio.pin, 1<<post.gpio.pin);
break;
case GPIO_Off:
GPIO_setMode(1<<post.gpio.pin, true);
GPIO_setOutput(1<<post.gpio.pin, 0);
break;
default:
break;
}
serveMainPage(fd);
}
void init_i2c(){
EALLOW;
// Enable Clock routing to the I2C Module
SysCtrlRegs.PCLKCR0.bit.I2CAENCLK = 1;
EDIS;
///////////////////////////////////////////////
/////// GPIO Setup //////////
////// SDA: GPIO28, SCLL GPIO29 //////////
///////////////////////////////////////////////
//Pull-ups are enabled here for ease of debugging. DISABLE pullups for production -- They are are on the master side!!!
GPIO_setPullUp(myGpio,GPIO_Number_28, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio,GPIO_Number_29, GPIO_PullUp_Disable);
// Set qualifications type on SDA and SCL to async (digital signals from another micro don't need multiple validations)
GPIO_setQualification(myGpio, GPIO_Number_28, GPIO_Qual_ASync);
GPIO_setQualification(myGpio, GPIO_Number_29, GPIO_Qual_ASync);
// Setup GPIO Modes
GPIO_setMode(myGpio, GPIO_Number_28, GPIO_28_Mode_SDDA);
GPIO_setMode(myGpio, GPIO_Number_29, GPIO_29_Mode_SCLA);
///////////////////////////////////////////////
////////// Interrupt Setup //////////////
//////////////////////////////////////////////
PIE_registerPieIntHandler(myPie, PIE_GroupNumber_8, PIE_SubGroupNumber_1, (intVec_t)&i2c_int1);
PIE_enableInt(myPie, PIE_GroupNumber_8, PIE_InterruptSource_I2CA1);
CPU_enableInt(myCpu,CPU_IntNumber_8); // Enable the CPU interrupt that is responsible for this PIE group
// Clear all status bits for the i2c module (reset)
I2caRegs.I2CMDR.bit.IRS = 0; // Technically this triggers a i2c reset
// Enable i2c "addressed as slave" interrupt
I2caRegs.I2CIER.bit.AAS = 1;
// Enable the XRDYINT (Transmit read condition interrupt). Enabled so I can see if data is getting to the transmit shift register
I2caRegs.I2CIER.bit.XRDY = 1;
// Change Clock divider
I2caRegs.I2CPSC.all = 2; // Prescaler - set to 128 giving module clk of SYSCLKOUT/129 => 465kHz
// More clock stuff here
I2caRegs.I2CCLKL = 5; // NOTE: must be non zero
I2caRegs.I2CCLKH = 5; // NOTE: must be non zero
// Setup the i2c module in slave mode
I2caRegs.I2CMDR.bit.MST = 0;
// Setup the i2c module as a receiver (so now we are in slave-reciever mode)
I2caRegs.I2CMDR.bit.TRX = 0;
// 7BIT address mode
I2caRegs.I2CMDR.bit.XA = 0;
// 8bit data mode
I2caRegs.I2CMDR.bit.BC = 0;
I2caRegs.I2CIER.bit.RRDY = 1; // Enable Receive Interrupt
// Set i2c address of this module
I2caRegs.I2COAR = 0x50;
I2caRegs.I2CCNT = 4; // Get/send 4 bytes
I2caRegs.I2CDXR = 0xF5; // Fill the transmission buffer
// Re-Enable the Module now that configuration is done
I2caRegs.I2CMDR.bit.IRS = 1;
}
void main(void)
{
CPU_Handle myCpu;
PLL_Handle myPll;
WDOG_Handle myWDog;
// Initialize all the handles needed for this application
myClk = CLK_init((void *)CLK_BASE_ADDR, sizeof(CLK_Obj));
myCpu = CPU_init((void *)NULL, sizeof(CPU_Obj));
myFlash = FLASH_init((void *)FLASH_BASE_ADDR, sizeof(FLASH_Obj));
myGpio = GPIO_init((void *)GPIO_BASE_ADDR, sizeof(GPIO_Obj));
myPie = PIE_init((void *)PIE_BASE_ADDR, sizeof(PIE_Obj));
myPll = PLL_init((void *)PLL_BASE_ADDR, sizeof(PLL_Obj));
myPwm1 = PWM_init((void *)PWM_ePWM1_BASE_ADDR, sizeof(PWM_Obj));
myPwm2 = PWM_init((void *)PWM_ePWM2_BASE_ADDR, sizeof(PWM_Obj));
myPwm3 = PWM_init((void *)PWM_ePWM3_BASE_ADDR, sizeof(PWM_Obj));
myPwm4 = PWM_init((void *)PWM_ePWM4_BASE_ADDR, sizeof(PWM_Obj));
myWDog = WDOG_init((void *)WDOG_BASE_ADDR, sizeof(WDOG_Obj));
// Perform basic system initialization
WDOG_disable(myWDog);
CLK_enableAdcClock(myClk);
(*Device_cal)();
CLK_disableAdcClock(myClk);
//Select the internal oscillator 1 as the clock source
CLK_setOscSrc(myClk, CLK_OscSrc_Internal);
// Setup the PLL for x12 /2 which will yield 60Mhz = 10Mhz * 12 / 2
PLL_setup(myPll, PLL_Multiplier_12, PLL_DivideSelect_ClkIn_by_2);
// Disable the PIE and all interrupts
PIE_disable(myPie);
PIE_disableAllInts(myPie);
CPU_disableGlobalInts(myCpu);
CPU_clearIntFlags(myCpu);
// If running from flash copy RAM only functions to RAM
#ifdef _FLASH
memcpy(&RamfuncsRunStart, &RamfuncsLoadStart, (size_t)&RamfuncsLoadSize);
#endif
// Step 1. Initialize System Control:
// PLL, WatchDog, enable Peripheral Clocks
// This example function is found in the f2802x_SysCtrl.c file.
// InitSysCtrl();
// Step 2. Initialize GPIO:
// This example function is found in the f2802x_Gpio.c file and
// illustrates how to set the GPIO to it's default state.
// InitGpio(); // Skipped for this example
// InitEPwmGpio();
// Step 3. Clear all interrupts and initialize PIE vector table:
// Disable CPU interrupts
// DINT;
// Initialize the PIE control registers to their default state.
// The default state is all PIE interrupts disabled and flags
// are cleared.
// This function is found in the f2802x_PieCtrl.c file.
// InitPieCtrl();
// Disable CPU interrupts and clear all CPU interrupt flags:
// IER = 0x0000;
// IFR = 0x0000;
// Initialize the PIE vector table with pointers to the shell Interrupt
// Service Routines (ISR).
// This will populate the entire table, even if the interrupt
// is not used in this example. This is useful for debug purposes.
// The shell ISR routines are found in f2802x_DefaultIsr.c.
// This function is found in f2802x_PieVect.c.
// InitPieVectTable();
// For this case just init GPIO pins for EPwm1, EPwm2, EPwm3, EPwm4
GPIO_setPullUp(myGpio, GPIO_Number_0, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_1, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_0, GPIO_0_Mode_EPWM1A);
GPIO_setMode(myGpio, GPIO_Number_1, GPIO_1_Mode_EPWM1B);
GPIO_setPullUp(myGpio, GPIO_Number_2, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_3, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_2, GPIO_2_Mode_EPWM2A);
GPIO_setMode(myGpio, GPIO_Number_3, GPIO_3_Mode_EPWM2B);
GPIO_setPullUp(myGpio, GPIO_Number_4, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_5, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_4, GPIO_4_Mode_EPWM3A);
GPIO_setMode(myGpio, GPIO_Number_5, GPIO_5_Mode_EPWM3B);
GPIO_setPullUp(myGpio, GPIO_Number_6, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_7, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_6, GPIO_6_Mode_EPWM4A);
GPIO_setMode(myGpio, GPIO_Number_7, GPIO_7_Mode_EPWM4B);
// Setup a debug vector table and enable the PIE
PIE_setDebugIntVectorTable(myPie);
PIE_enable(myPie);
// Step 4. Initialize the Device Peripherals:
CLK_enablePwmClock(myClk, PWM_Number_1);
CLK_enablePwmClock(myClk, PWM_Number_2);
CLK_enablePwmClock(myClk, PWM_Number_3);
CLK_enablePwmClock(myClk, PWM_Number_4);
CLK_enableHrPwmClock(myClk);
// For this example, only initialize the ePWM
// Step 5. User specific code, enable interrupts:
// Calling SFO() updates the HRMSTEP register with calibrated MEP_ScaleFactor.
// HRMSTEP must be populated with a scale factor value prior to enabling
// high resolution period control.
status = SFO_INCOMPLETE;
while (status== SFO_INCOMPLETE) // Call until complete
{
status = SFO();
if (status == SFO_ERROR)
{
error(); // SFO function returns 2 if an error occurs & # of MEP steps/coarse step
} // exceeds maximum of 255.
}
// Some useful PWM period vs Frequency values
// TBCLK = 60 MHz
//===================
// Period Freq
// 1000 30 KHz
// 800 37.5 KHz
// 600 50 KHz
// 500 60 KHz
// 250 120 KHz
// 200 150 KHz
// 100 300 KHz
// 50 600 KHz
// 30 1 MHz
// 25 1.2 MHz
// 20 1.5 MHz
// 12 2.5 MHz
// 10 3 MHz
// 9 3.3 MHz
// 8 3.8 MHz
// 7 4.3 MHz
// 6 5.0 MHz
// 5 6.0 MHz
//====================================================================
// ePWM and HRPWM register initialization
//====================================================================
Period = 500;
PeriodFine=0xFFBF;
CLK_disableTbClockSync(myClk);
HRPWM_Config(myPwm1, Period, 1);
HRPWM_Config(myPwm2, Period, 0);
HRPWM_Config(myPwm3, Period, 0);
HRPWM_Config(myPwm4, Period, 0);
CLK_enableTbClockSync(myClk);
// Software Control variables
Increment_Freq = 1;
Increment_Freq_Fine = 1;
IsrTicker = 0;
UpdatePeriod = 0;
UpdatePeriodFine = 0;
// User control variables:
UpdateCoarse = 0;
UpdateFine = 1;
// Reassign ISRs.
PIE_registerPieIntHandler(myPie, PIE_GroupNumber_3, PIE_SubGroupNumber_1,
(intVec_t)&MainISR);
// Enable PIE group 3 interrupt 1 for EPWM1_INT
PIE_enableInt(myPie, PIE_GroupNumber_3, PIE_InterruptSource_EPWM1);
// Enable CNT_zero interrupt using EPWM1 Time-base
PWM_setIntMode(myPwm1, PWM_IntMode_CounterEqualZero); // Select INT on Zero event
PWM_enableInt(myPwm1); // Enable INT
PWM_setIntPeriod(myPwm1, PWM_IntPeriod_FirstEvent); // Generate INT on 3rd event
PWM_clearIntFlag(myPwm1);
// Enable CPU INT3 for EPWM1_INT:
CPU_enableInt(myCpu, CPU_IntNumber_3);
// Enable global Interrupts and higher priority real-time debug events:
CPU_enableGlobalInts(myCpu);
CPU_enableDebugInt(myCpu);
PWM_forceSync(myPwm1); // Synchronize high resolution phase to start HR period
for(;;)
{
// The below code controls coarse edge movement
if(UpdateCoarse==1)
{
if(Increment_Freq==1) //Increase frequency to 600 kHz
Period= Period - 1;
else
Period= Period + 1; //Decrease frequency to 300 kHz
if(Period<100 && Increment_Freq==1)
Increment_Freq=0;
else if(Period>500 && Increment_Freq==0)
Increment_Freq=1;
UpdatePeriod=1;
}
// The below code controls high-resolution fine edge movement
if(UpdateFine==1)
{
if(Increment_Freq_Fine==1) // Increase high-resolution frequency
PeriodFine=PeriodFine-1;
else
PeriodFine=PeriodFine+1; // Decrement high-resolution frequency
if(PeriodFine<=0x3333 && Increment_Freq_Fine==1)
Increment_Freq_Fine=0;
else if(PeriodFine>= 0xFFBF && Increment_Freq_Fine==0)
Increment_Freq_Fine=1;
UpdatePeriodFine=1;
}
// Call the scale factor optimizer lib function SFO()
// periodically to track for any change due to temp/voltage.
// This function generates MEP_ScaleFactor by running the
// MEP calibration module in the HRPWM logic. This scale
// factor can be used for all HRPWM channels. HRMSTEP
// register is automatically updated by the SFO function.
status = SFO(); // in background, MEP calibration module continuously updates MEP_ScaleFactor
if (status == SFO_ERROR)
{
error(); // SFO function returns 2 if an error occurs & # of MEP steps/coarse step
} // exceeds maximum of 255.
}
}// end main
void main(void)
{
CPU_Handle myCpu;
PLL_Handle myPll;
WDOG_Handle myWDog;
// Initialize all the handles needed for this application
myClk = CLK_init((void *)CLK_BASE_ADDR, sizeof(CLK_Obj));
myCpu = CPU_init((void *)NULL, sizeof(CPU_Obj));
myFlash = FLASH_init((void *)FLASH_BASE_ADDR, sizeof(FLASH_Obj));
myGpio = GPIO_init((void *)GPIO_BASE_ADDR, sizeof(GPIO_Obj));
myPie = PIE_init((void *)PIE_BASE_ADDR, sizeof(PIE_Obj));
myPll = PLL_init((void *)PLL_BASE_ADDR, sizeof(PLL_Obj));
myPwm1 = PWM_init((void *)PWM_ePWM1_BASE_ADDR, sizeof(PWM_Obj));
myPwm2 = PWM_init((void *)PWM_ePWM2_BASE_ADDR, sizeof(PWM_Obj));
myPwm3 = PWM_init((void *)PWM_ePWM3_BASE_ADDR, sizeof(PWM_Obj));
myPwm4 = PWM_init((void *)PWM_ePWM4_BASE_ADDR, sizeof(PWM_Obj));
myWDog = WDOG_init((void *)WDOG_BASE_ADDR, sizeof(WDOG_Obj));
// Perform basic system initialization
WDOG_disable(myWDog);
CLK_enableAdcClock(myClk);
(*Device_cal)();
CLK_disableAdcClock(myClk);
//Select the internal oscillator 1 as the clock source
CLK_setOscSrc(myClk, CLK_OscSrc_Internal);
// Setup the PLL for x12 /2 which will yield 60Mhz = 10Mhz * 12 / 2
PLL_setup(myPll, PLL_Multiplier_12, PLL_DivideSelect_ClkIn_by_2);
// Disable the PIE and all interrupts
PIE_disable(myPie);
PIE_disableAllInts(myPie);
CPU_disableGlobalInts(myCpu);
CPU_clearIntFlags(myCpu);
// If running from flash copy RAM only functions to RAM
#ifdef _FLASH
memcpy(&RamfuncsRunStart, &RamfuncsLoadStart, (size_t)&RamfuncsLoadSize);
#endif
// Step 1. Initialize System Control:
// PLL, WatchDog, enable Peripheral Clocks
// This example function is found in the f2802x_SysCtrl.c file.
// InitSysCtrl();
// Step 2. Initialize GPIO:
// This example function is found in the f2802x_Gpio.c file and
// illustrates how to set the GPIO to it's default state.
// InitGpio(); // Skipped for this example
// InitEPwmGpio();
// Step 3. Clear all interrupts and initialize PIE vector table:
// Disable CPU interrupts
// DINT;
// Initialize the PIE control registers to their default state.
// The default state is all PIE interrupts disabled and flags
// are cleared.
// This function is found in the f2802x_PieCtrl.c file.
// InitPieCtrl();
// Disable CPU interrupts and clear all CPU interrupt flags:
// IER = 0x0000;
// IFR = 0x0000;
// Initialize the PIE vector table with pointers to the shell Interrupt
// Service Routines (ISR).
// This will populate the entire table, even if the interrupt
// is not used in this example. This is useful for debug purposes.
// The shell ISR routines are found in f2802x_DefaultIsr.c.
// This function is found in f2802x_PieVect.c.
// InitPieVectTable();
// For this case just init GPIO pins for EPwm1, EPwm2, EPwm3, EPwm4
GPIO_setPullUp(myGpio, GPIO_Number_0, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_1, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_0, GPIO_0_Mode_EPWM1A);
GPIO_setMode(myGpio, GPIO_Number_1, GPIO_1_Mode_EPWM1B);
GPIO_setPullUp(myGpio, GPIO_Number_2, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_3, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_2, GPIO_2_Mode_EPWM2A);
GPIO_setMode(myGpio, GPIO_Number_3, GPIO_3_Mode_EPWM2B);
GPIO_setPullUp(myGpio, GPIO_Number_4, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_5, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_4, GPIO_4_Mode_EPWM3A);
GPIO_setMode(myGpio, GPIO_Number_5, GPIO_5_Mode_EPWM3B);
GPIO_setPullUp(myGpio, GPIO_Number_6, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_7, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_6, GPIO_6_Mode_EPWM4A);
GPIO_setMode(myGpio, GPIO_Number_7, GPIO_7_Mode_EPWM4B);
// Setup a debug vector table and enable the PIE
PIE_setDebugIntVectorTable(myPie);
PIE_enable(myPie);
CLK_enablePwmClock(myClk, PWM_Number_1);
CLK_enablePwmClock(myClk, PWM_Number_2);
CLK_enablePwmClock(myClk, PWM_Number_3);
CLK_enablePwmClock(myClk, PWM_Number_4);
CLK_enableHrPwmClock(myClk);
// For this example, only initialize the ePWM
// Step 4. User specific code, enable interrupts:
UpdateFine = 1;
PeriodFine = 0;
status = SFO_INCOMPLETE;
// Calling SFO() updates the HRMSTEP register with calibrated MEP_ScaleFactor.
// HRMSTEP must be populated with a scale factor value prior to enabling
// high resolution period control.
while (status== SFO_INCOMPLETE) // Call until complete
{
status = SFO();
if (status == SFO_ERROR)
{
error(); // SFO function returns 2 if an error occurs & # of MEP steps/coarse step
} // exceeds maximum of 255.
}
// Some useful Period vs Frequency values
// SYSCLKOUT = 60 MHz 40 MHz
// --------------------------------------
// Period Frequency Frequency
// 1000 60 kHz 40 kHz
// 800 75 kHz 50 kHz
// 600 100 kHz 67 kHz
// 500 120 kHz 80 kHz
// 250 240 kHz 160 kHz
// 200 300 kHz 200 kHz
// 100 600 kHz 400 kHz
// 50 1.2 Mhz 800 kHz
// 25 2.4 Mhz 1.6 MHz
// 20 3.0 Mhz 2.0 MHz
// 12 5.0 MHz 3.3 MHz
// 10 6.0 MHz 4.0 MHz
// 9 6.7 MHz 4.4 MHz
// 8 7.5 MHz 5.0 MHz
// 7 8.6 MHz 5.7 MHz
// 6 10.0 MHz 6.6 MHz
// 5 12.0 MHz 8.0 MHz
//====================================================================
// ePWM and HRPWM register initialization
//====================================================================
CLK_disableTbClockSync(myClk);
HRPWM_Config(myPwm1, 30); // ePWMx target
HRPWM_Config(myPwm2, 30); // ePWMx target
HRPWM_Config(myPwm3, 30); // ePWMx target
HRPWM_Config(myPwm4, 30); // ePWMx target
CLK_enableTbClockSync(myClk);
PWM_forceSync(myPwm1);
PWM_forceSync(myPwm2);
PWM_forceSync(myPwm3);
PWM_forceSync(myPwm4);
for(;;)
{
// Sweep PeriodFine as a Q16 number from 0.2 - 0.999
for(PeriodFine = 0x3333; PeriodFine < 0xFFBF; PeriodFine++)
{
if(UpdateFine)
{
/*
// Because auto-conversion is enabled, the desired
// fractional period must be written directly to the
// TBPRDHR (or TBPRDHRM) register in Q16 format
// (lower 8-bits are ignored)
EPwm1Regs.TBPRDHR = PeriodFine;
// The hardware will automatically scale
// the fractional period by the MEP_ScaleFactor
// in the HRMSTEP register (which is updated
// by the SFO calibration software).
// Hardware conversion:
// MEP delay movement = ((TBPRDHR(15:0) >> 8) * HRMSTEP(7:0) + 0x80) >> 8
*/
// for(i=1;i<PWM_CH;i++)
// {
// (*ePWM[i]).TBPRDHR = PeriodFine; //In Q16 format
// }
PWM_setPeriodHr(myPwm1, PeriodFine);
PWM_setPeriodHr(myPwm2, PeriodFine);
PWM_setPeriodHr(myPwm3, PeriodFine);
PWM_setPeriodHr(myPwm4, PeriodFine);
}
else
{
// No high-resolution movement on TBPRDHR.
// for(i=1;i<PWM_CH;i++)
// {
// (*ePWM[i]).TBPRDHR = 0;
// }
PWM_setPeriodHr(myPwm1, 0);
PWM_setPeriodHr(myPwm2, 0);
PWM_setPeriodHr(myPwm3, 0);
PWM_setPeriodHr(myPwm4, 0);
}
// Call the scale factor optimizer lib function SFO()
// periodically to track for any change due to temp/voltage.
// This function generates MEP_ScaleFactor by running the
// MEP calibration module in the HRPWM logic. This scale
// factor can be used for all HRPWM channels. HRMSTEP
// register is automatically updated by the SFO function.
status = SFO(); // in background, MEP calibration module continuously updates MEP_ScaleFactor
if (status == SFO_ERROR) {
error(); // SFO function returns 2 if an error occurs & # of MEP steps/coarse step
} // exceeds maximum of 255.
} // end PeriodFine for loop
} // end infinite for loop
} // end main
void main(void)
{
CPU_Handle myCpu;
PLL_Handle myPll;
WDOG_Handle myWDog;
// Initialize all the handles needed for this application
myClk = CLK_init((void *)CLK_BASE_ADDR, sizeof(CLK_Obj));
myCpu = CPU_init((void *)NULL, sizeof(CPU_Obj));
myFlash = FLASH_init((void *)FLASH_BASE_ADDR, sizeof(FLASH_Obj));
myGpio = GPIO_init((void *)GPIO_BASE_ADDR, sizeof(GPIO_Obj));
myPie = PIE_init((void *)PIE_BASE_ADDR, sizeof(PIE_Obj));
myPll = PLL_init((void *)PLL_BASE_ADDR, sizeof(PLL_Obj));
myPwm1 = PWM_init((void *)PWM_ePWM1_BASE_ADDR, sizeof(PWM_Obj));
myPwm2 = PWM_init((void *)PWM_ePWM2_BASE_ADDR, sizeof(PWM_Obj));
myPwm3 = PWM_init((void *)PWM_ePWM3_BASE_ADDR, sizeof(PWM_Obj));
myPwm4 = PWM_init((void *)PWM_ePWM4_BASE_ADDR, sizeof(PWM_Obj));
myWDog = WDOG_init((void *)WDOG_BASE_ADDR, sizeof(WDOG_Obj));
// Perform basic system initialization
WDOG_disable(myWDog);
CLK_enableAdcClock(myClk);
(*Device_cal)();
CLK_disableAdcClock(myClk);
//Select the internal oscillator 1 as the clock source
CLK_setOscSrc(myClk, CLK_OscSrc_Internal);
// Setup the PLL for x12 /2 which will yield 60Mhz = 10Mhz * 12 / 2
PLL_setup(myPll, PLL_Multiplier_12, PLL_DivideSelect_ClkIn_by_2);
// Disable the PIE and all interrupts
PIE_disable(myPie);
PIE_disableAllInts(myPie);
CPU_disableGlobalInts(myCpu);
CPU_clearIntFlags(myCpu);
// If running from flash copy RAM only functions to RAM
#ifdef _FLASH
memcpy(&RamfuncsRunStart, &RamfuncsLoadStart, (size_t)&RamfuncsLoadSize);
#endif
// Step 1. Initialize System Control:
// PLL, WatchDog, enable Peripheral Clocks
// This example function is found in the f2802x_SysCtrl.c file.
// InitSysCtrl();
// Step 2. Initialize GPIO:
// This example function is found in the f2802x_Gpio.c file and
// illustrates how to set the GPIO to it's default state.
// InitGpio(); // Skipped for this example
// For this case, just init GPIO for EPwm1-EPwm4
// For this case just init GPIO pins for EPwm1, EPwm2, EPwm3, EPwm4
// These functions are in the f2802x_EPwm.c file
// InitEPwm1Gpio();
// InitEPwm2Gpio();
// InitEPwm3Gpio();
// InitEPwm4Gpio();
// Step 3. Clear all interrupts and initialize PIE vector table:
// Disable CPU interrupts
// DINT;
// Initialize the PIE control registers to their default state.
// The default state is all PIE interrupts disabled and flags
// are cleared.
// This function is found in the f2802x_PieCtrl.c file.
// InitPieCtrl();
// Disable CPU interrupts and clear all CPU interrupt flags:
// IER = 0x0000;
// IFR = 0x0000;
// Initialize the PIE vector table with pointers to the shell Interrupt
// Service Routines (ISR).
// This will populate the entire table, even if the interrupt
// is not used in this example. This is useful for debug purposes.
// The shell ISR routines are found in f2802x_DefaultIsr.c.
// This function is found in f2802x_PieVect.c.
// InitPieVectTable();
// For this case just init GPIO pins for EPwm1, EPwm2, EPwm3, EPwm4
GPIO_setPullUp(myGpio, GPIO_Number_0, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_1, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_0, GPIO_0_Mode_EPWM1A);
GPIO_setMode(myGpio, GPIO_Number_1, GPIO_1_Mode_EPWM1B);
GPIO_setPullUp(myGpio, GPIO_Number_2, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_3, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_2, GPIO_2_Mode_EPWM2A);
GPIO_setMode(myGpio, GPIO_Number_3, GPIO_3_Mode_EPWM2B);
GPIO_setPullUp(myGpio, GPIO_Number_4, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_5, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_4, GPIO_4_Mode_EPWM3A);
GPIO_setMode(myGpio, GPIO_Number_5, GPIO_5_Mode_EPWM3B);
GPIO_setPullUp(myGpio, GPIO_Number_6, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_7, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_6, GPIO_6_Mode_EPWM4A);
GPIO_setMode(myGpio, GPIO_Number_7, GPIO_7_Mode_EPWM4B);
// Setup a debug vector table and enable the PIE
PIE_setDebugIntVectorTable(myPie);
PIE_enable(myPie);
CLK_enablePwmClock(myClk, PWM_Number_1);
CLK_enablePwmClock(myClk, PWM_Number_2);
CLK_enablePwmClock(myClk, PWM_Number_3);
CLK_enablePwmClock(myClk, PWM_Number_4);
// For this example, only initialize the EPwm
// Step 4. User specific code, enable interrupts:
update =1;
DutyFine =0;
CLK_disableTbClockSync(myClk);
// Some useful Period vs Frequency values
// SYSCLKOUT = 60 MHz 40 MHz
// --------------------------------------
// Period Frequency Frequency
// 1000 60 kHz 40 kHz
// 800 75 kHz 50 kHz
// 600 100 kHz 67 kHz
// 500 120 kHz 80 kHz
// 250 240 kHz 160 kHz
// 200 300 kHz 200 kHz
// 100 600 kHz 400 kHz
// 50 1.2 Mhz 800 kHz
// 25 2.4 Mhz 1.6 MHz
// 20 3.0 Mhz 2.0 MHz
// 12 5.0 MHz 3.3 MHz
// 10 6.0 MHz 4.0 MHz
// 9 6.7 MHz 4.4 MHz
// 8 7.5 MHz 5.0 MHz
// 7 8.6 MHz 5.7 MHz
// 6 10.0 MHz 6.6 MHz
// 5 12.0 MHz 8.0 MHz
//====================================================================
// EPwm and HRPWM register initialization
//====================================================================
HRPWM1_Config(10); // EPwm1 target, Period = 10
HRPWM2_Config(20); // EPwm2 target, Period = 20
HRPWM3_Config(10); // EPwm3 target, Period = 10
HRPWM4_Config(20); // EPwm4 target, Period = 20
CLK_enableTbClockSync(myClk);
while (update ==1)
{
PWM_setCmpAHr(myPwm1, DutyFine << 8);
PWM_setCmpAHr(myPwm2, DutyFine << 8);
PWM_setCmpAHr(myPwm3, DutyFine << 8);
PWM_setCmpAHr(myPwm4, DutyFine << 8);
}
}
void InitEPwmTimer()
{
CLK_disableTbClockSync(myClk);
CLK_enablePwmClock(myClk, PWM_Number_1);
CLK_enablePwmClock(myClk, PWM_Number_2);
CLK_enablePwmClock(myClk, PWM_Number_3);
GPIO_setPullUp(myGpio, GPIO_Number_0, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_1, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_0, GPIO_0_Mode_EPWM1A);
GPIO_setMode(myGpio, GPIO_Number_1, GPIO_1_Mode_EPWM1B);
GPIO_setPullUp(myGpio, GPIO_Number_2, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_3, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_2, GPIO_2_Mode_EPWM2A);
GPIO_setMode(myGpio, GPIO_Number_3, GPIO_3_Mode_EPWM2B);
GPIO_setPullUp(myGpio, GPIO_Number_4, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_5, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_4, GPIO_4_Mode_EPWM3A);
GPIO_setMode(myGpio, GPIO_Number_5, GPIO_5_Mode_EPWM3B);
// Setup Sync
PWM_setSyncMode(myPwm1, PWM_SyncMode_EPWMxSYNC);
PWM_setSyncMode(myPwm2, PWM_SyncMode_EPWMxSYNC);
PWM_setSyncMode(myPwm3, PWM_SyncMode_EPWMxSYNC);
// Allow each timer to be sync'ed
PWM_enableCounterLoad(myPwm1);
PWM_enableCounterLoad(myPwm2);
PWM_enableCounterLoad(myPwm3);
// Set the phase
PWM_setPhase(myPwm1, 100);
PWM_setPhase(myPwm1, 200);
PWM_setPhase(myPwm1, 300);
PWM_setPeriod(myPwm1, PWM1_TIMER_TBPRD);
PWM_setCounterMode(myPwm1, PWM_CounterMode_Up); // Count up
PWM_setIntMode(myPwm1, PWM_IntMode_CounterEqualZero); // Select INT on Zero event
PWM_enableInt(myPwm1); // Enable INT
PWM_setIntPeriod(myPwm1, PWM_IntPeriod_FirstEvent); // Generate INT on 1st event
PWM_setPeriod(myPwm2, PWM2_TIMER_TBPRD);
PWM_setCounterMode(myPwm2, PWM_CounterMode_Up); // Count up
PWM_setIntMode(myPwm2, PWM_IntMode_CounterEqualZero); // Enable INT on Zero event
PWM_enableInt(myPwm2); // Enable INT
PWM_setIntPeriod(myPwm2, PWM_IntPeriod_SecondEvent); // Generate INT on 2nd event
PWM_setPeriod(myPwm3, PWM3_TIMER_TBPRD);
PWM_setCounterMode(myPwm3, PWM_CounterMode_Up); // Count up
PWM_setIntMode(myPwm3, PWM_IntMode_CounterEqualZero); // Enable INT on Zero event
PWM_enableInt(myPwm3); // Enable INT
PWM_setIntPeriod(myPwm3, PWM_IntPeriod_ThirdEvent); // Generate INT on 3rd event
PWM_setCmpA(myPwm1, PWM1_TIMER_TBPRD / 2);
PWM_setActionQual_Period_PwmA(myPwm1, PWM_ActionQual_Set);
PWM_setActionQual_CntUp_CmpA_PwmA(myPwm1, PWM_ActionQual_Clear);
PWM_setActionQual_Period_PwmB(myPwm1, PWM_ActionQual_Set);
PWM_setActionQual_CntUp_CmpA_PwmB(myPwm1, PWM_ActionQual_Clear);
PWM_setCmpA(myPwm2, PWM2_TIMER_TBPRD / 2);
PWM_setActionQual_Period_PwmA(myPwm2, PWM_ActionQual_Set);
PWM_setActionQual_CntUp_CmpA_PwmA(myPwm2, PWM_ActionQual_Clear);
PWM_setActionQual_Period_PwmB(myPwm2, PWM_ActionQual_Set);
PWM_setActionQual_CntUp_CmpA_PwmB(myPwm2, PWM_ActionQual_Clear);
PWM_setCmpA(myPwm3, PWM3_TIMER_TBPRD / 2);
PWM_setActionQual_Period_PwmA(myPwm3, PWM_ActionQual_Set);
PWM_setActionQual_CntUp_CmpA_PwmA(myPwm3, PWM_ActionQual_Clear);
PWM_setActionQual_Period_PwmB(myPwm3, PWM_ActionQual_Set);
PWM_setActionQual_CntUp_CmpA_PwmB(myPwm3, PWM_ActionQual_Clear);
CLK_enableTbClockSync(myClk);
}
void main(void)
{
CPU_Handle myCpu;
PLL_Handle myPll;
WDOG_Handle myWDog;
// Initialize all the handles needed for this application
myClk = CLK_init((void *)CLK_BASE_ADDR, sizeof(CLK_Obj));
myCpu = CPU_init((void *)NULL, sizeof(CPU_Obj));
myFlash = FLASH_init((void *)FLASH_BASE_ADDR, sizeof(FLASH_Obj));
myGpio = GPIO_init((void *)GPIO_BASE_ADDR, sizeof(GPIO_Obj));
myPie = PIE_init((void *)PIE_BASE_ADDR, sizeof(PIE_Obj));
myPll = PLL_init((void *)PLL_BASE_ADDR, sizeof(PLL_Obj));
myPwm1 = PWM_init((void *)PWM_ePWM1_BASE_ADDR, sizeof(PWM_Obj));
myPwm2 = PWM_init((void *)PWM_ePWM2_BASE_ADDR, sizeof(PWM_Obj));
myPwm3 = PWM_init((void *)PWM_ePWM3_BASE_ADDR, sizeof(PWM_Obj));
myWDog = WDOG_init((void *)WDOG_BASE_ADDR, sizeof(WDOG_Obj));
// Perform basic system initialization
WDOG_disable(myWDog);
CLK_enableAdcClock(myClk);
(*Device_cal)();
CLK_disableAdcClock(myClk);
//Select the internal oscillator 1 as the clock source
CLK_setOscSrc(myClk, CLK_OscSrc_Internal);
// Setup the PLL for x10 /2 which will yield 50Mhz = 10Mhz * 10 / 2
PLL_setup(myPll, PLL_Multiplier_10, PLL_DivideSelect_ClkIn_by_2);
// Disable the PIE and all interrupts
PIE_disable(myPie);
PIE_disableAllInts(myPie);
CPU_disableGlobalInts(myCpu);
CPU_clearIntFlags(myCpu);
// Setup a debug vector table and enable the PIE
PIE_setDebugIntVectorTable(myPie);
PIE_enable(myPie);
// Register interrupt handlers in the PIE vector table
PIE_registerPieIntHandler(myPie, PIE_GroupNumber_3, PIE_SubGroupNumber_1, (intVec_t)&EPwm1_timer_isr);
PIE_registerPieIntHandler(myPie, PIE_GroupNumber_3, PIE_SubGroupNumber_2, (intVec_t)&EPwm2_timer_isr);
PIE_registerPieIntHandler(myPie, PIE_GroupNumber_3, PIE_SubGroupNumber_3, (intVec_t)&EPwm3_timer_isr);
// Initialize the EPwm Timers used in this example
InitEPwmTimer();
#ifdef _FLASH
// Copy time critical code and Flash setup code to RAM
// This includes the following ISR functions: EPwm1_timer_isr(), EPwm2_timer_isr()
// and FLASH_setup();
// The RamfuncsLoadStart, RamfuncsLoadSize, and RamfuncsRunStart
// symbols are created by the linker. Refer to the F2280270.cmd file.
memcpy(&RamfuncsRunStart, &RamfuncsLoadStart, (size_t)&RamfuncsLoadSize);
// Call Flash Initialization to setup flash waitstates
// This function must reside in RAM
FLASH_setup(myFlash);
#endif // end #ifdef _FLASH
// Initalize counters:
EPwm1TimerIntCount = 0;
EPwm2TimerIntCount = 0;
EPwm3TimerIntCount = 0;
LoopCount = 0;
// Enable CPU INT3 which is connected to EPwm1-3 INT:
CPU_enableInt(myCpu, CPU_IntNumber_3);
// Enable EPwm INTn in the PIE: Group 3 interrupt 1-3.
PIE_enablePwmInt(myPie, PWM_Number_1);
PIE_enablePwmInt(myPie, PWM_Number_2);
PIE_enablePwmInt(myPie, PWM_Number_3);
// Enable global Interrupts and higher priority real-time debug events
CPU_enableGlobalInts(myCpu);
CPU_enableDebugInt(myCpu);
// Configure GPIO so it can toggle in the idle loop
GPIO_setMode(myGpio, GPIO_Number_34, GPIO_34_Mode_GeneralPurpose);
GPIO_setDirection(myGpio, GPIO_Number_34, GPIO_Direction_Output);
for(;;)
{
// This loop will be interrupted, so the overall
// delay between pin toggles will be longer.
DELAY_US(DELAY);
LoopCount++;
// Toggle GPIO
GPIO_toggle(myGpio, GPIO_Number_34);
}
}
void main(void)
{
ADC_Handle myAdc;
CPU_Handle myCpu;
PLL_Handle myPll;
WDOG_Handle myWDog;
// Initialize all the handles needed for this application
myAdc = ADC_init((void *)ADC_BASE_ADDR, sizeof(ADC_Obj));
myClk = CLK_init((void *)CLK_BASE_ADDR, sizeof(CLK_Obj));
myComp = COMP_init((void *)COMP1_BASE_ADDR, sizeof(COMP_Obj));
myCpu = CPU_init((void *)NULL, sizeof(CPU_Obj));
myFlash = FLASH_init((void *)FLASH_BASE_ADDR, sizeof(FLASH_Obj));
myGpio = GPIO_init((void *)GPIO_BASE_ADDR, sizeof(GPIO_Obj));
myPie = PIE_init((void *)PIE_BASE_ADDR, sizeof(PIE_Obj));
myPll = PLL_init((void *)PLL_BASE_ADDR, sizeof(PLL_Obj));
myPwm1 = PWM_init((void *)PWM_ePWM1_BASE_ADDR, sizeof(PWM_Obj));
myWDog = WDOG_init((void *)WDOG_BASE_ADDR, sizeof(WDOG_Obj));
// Perform basic system initialization
WDOG_disable(myWDog);
CLK_enableAdcClock(myClk);
(*Device_cal)();
CLK_disableAdcClock(myClk);
//Select the internal oscillator 1 as the clock source
CLK_setOscSrc(myClk, CLK_OscSrc_Internal);
// Setup the PLL for x10 /2 which will yield 50Mhz = 10Mhz * 10 / 2
PLL_setup(myPll, PLL_Multiplier_10, PLL_DivideSelect_ClkIn_by_2);
// Disable the PIE and all interrupts
PIE_disable(myPie);
PIE_disableAllInts(myPie);
CPU_disableGlobalInts(myCpu);
CPU_clearIntFlags(myCpu);
// If running from flash copy RAM only functions to RAM
#ifdef _FLASH
memcpy(&RamfuncsRunStart, &RamfuncsLoadStart, (size_t)&RamfuncsLoadSize);
#endif
// For this case just init GPIO pins for ePWM1
GPIO_setPullUp(myGpio, GPIO_Number_0, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_1, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_0, GPIO_0_Mode_EPWM1A);
GPIO_setMode(myGpio, GPIO_Number_1, GPIO_1_Mode_EPWM1B);
// Setup a debug vector table and enable the PIE
PIE_setDebugIntVectorTable(myPie);
PIE_enable(myPie);
// Register interrupt handlers in the PIE vector table
PIE_registerPieIntHandler(myPie, PIE_GroupNumber_2, PIE_SubGroupNumber_1,
(intVec_t)&epwm1_tzint_isr);
// Enable Clock to the ADC
CLK_enableAdcClock(myClk);
// Comparator shares the internal BG reference of the ADC,
// must be powered even if ADC is unused
ADC_enableBandGap(myAdc);
// Delay to allow BG reference to settle.
DELAY_US(1000L);
// Enable clock to the Comparator 1 block
CLK_enableCompClock(myClk, CLK_CompNumber_1);
// Power up Comparator 1 locally
COMP_enable(myComp);
// Connect the inverting input to pin COMP1B
COMP_disableDac(myComp);
////////////////Uncomment following 4 lines to use DAC instead of pin COMP1B //////////////////
// // Connect the inverting input to the internal DAC
// COMP_enableDac(myComp);
// // Set DAC output to midpoint
// COMP_setDacValue(myComp, 512);
//////////////////////////////////////////////////////////////////////////////////////////////
CLK_disableTbClockSync(myClk);
InitEPwm1Example();
CLK_enableTbClockSync(myClk);
// Initialize counters
EPwm1TZIntCount = 0;
// Enable CPU INT3 which is connected to EPWM1-3 INT
CPU_enableInt(myCpu, CPU_IntNumber_2);
// Enable EPWM INTn in the PIE: Group 2 interrupt 1-3
PIE_enablePwmTzInt(myPie, PWM_Number_1);
// Enable global Interrupts and higher priority real-time debug events
CPU_enableGlobalInts(myCpu);
CPU_enableDebugInt(myCpu);
for(;;)
{
__asm(" NOP");
}
}
void main(void)
{
CPU_Handle myCpu;
PLL_Handle myPll;
WDOG_Handle myWDog;
// Initialize all the handles needed for this application
myClk = CLK_init((void *)CLK_BASE_ADDR, sizeof(CLK_Obj));
myCpu = CPU_init((void *)NULL, sizeof(CPU_Obj));
myFlash = FLASH_init((void *)FLASH_BASE_ADDR, sizeof(FLASH_Obj));
myGpio = GPIO_init((void *)GPIO_BASE_ADDR, sizeof(GPIO_Obj));
myPie = PIE_init((void *)PIE_BASE_ADDR, sizeof(PIE_Obj));
myPll = PLL_init((void *)PLL_BASE_ADDR, sizeof(PLL_Obj));
myPwm1 = PWM_init((void *)PWM_ePWM1_BASE_ADDR, sizeof(PWM_Obj));
myPwm2 = PWM_init((void *)PWM_ePWM2_BASE_ADDR, sizeof(PWM_Obj));
myPwm3 = PWM_init((void *)PWM_ePWM3_BASE_ADDR, sizeof(PWM_Obj));
myWDog = WDOG_init((void *)WDOG_BASE_ADDR, sizeof(WDOG_Obj));
// Perform basic system initialization
WDOG_disable(myWDog);
CLK_enableAdcClock(myClk);
(*Device_cal)();
CLK_disableAdcClock(myClk);
//Select the internal oscillator 1 as the clock source
CLK_setOscSrc(myClk, CLK_OscSrc_Internal);
// Setup the PLL for x10 /2 which will yield 50Mhz = 10Mhz * 10 / 2
PLL_setup(myPll, PLL_Multiplier_10, PLL_DivideSelect_ClkIn_by_2);
// Disable the PIE and all interrupts
PIE_disable(myPie);
PIE_disableAllInts(myPie);
CPU_disableGlobalInts(myCpu);
CPU_clearIntFlags(myCpu);
// If running from flash copy RAM only functions to RAM
#ifdef _FLASH
memcpy(&RamfuncsRunStart, &RamfuncsLoadStart, (size_t)&RamfuncsLoadSize);
#endif
// Initialize GPIO
GPIO_setPullUp(myGpio, GPIO_Number_0, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_1, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_0, GPIO_0_Mode_EPWM1A);
GPIO_setMode(myGpio, GPIO_Number_1, GPIO_1_Mode_EPWM1B);
GPIO_setPullUp(myGpio, GPIO_Number_2, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_3, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_2, GPIO_2_Mode_EPWM2A);
GPIO_setMode(myGpio, GPIO_Number_3, GPIO_3_Mode_EPWM2B);
GPIO_setPullUp(myGpio, GPIO_Number_4, GPIO_PullUp_Disable);
GPIO_setPullUp(myGpio, GPIO_Number_5, GPIO_PullUp_Disable);
GPIO_setMode(myGpio, GPIO_Number_4, GPIO_4_Mode_EPWM3A);
GPIO_setMode(myGpio, GPIO_Number_5, GPIO_5_Mode_EPWM3B);
// Setup a debug vector table and enable the PIE
PIE_setDebugIntVectorTable(myPie);
PIE_enable(myPie);
// Register interrupt handlers in the PIE vector table
PIE_registerPieIntHandler(myPie, PIE_GroupNumber_3, PIE_SubGroupNumber_1,
(intVec_t)&epwm1_isr);
PIE_registerPieIntHandler(myPie, PIE_GroupNumber_3, PIE_SubGroupNumber_2,
(intVec_t)&epwm2_isr);
PIE_registerPieIntHandler(myPie, PIE_GroupNumber_3, PIE_SubGroupNumber_3,
(intVec_t)&epwm3_isr);
CLK_disableTbClockSync(myClk);
InitEPwm1Example();
InitEPwm2Example();
InitEPwm3Example();
CLK_enableTbClockSync(myClk);
// Enable CPU INT3 which is connected to EPWM1-3 INT:
CPU_enableInt(myCpu, CPU_IntNumber_3);
// Enable EPWM INTn in the PIE: Group 3 interrupt 1-3
PIE_enablePwmInt(myPie, PWM_Number_1);
PIE_enablePwmInt(myPie, PWM_Number_2);
PIE_enablePwmInt(myPie, PWM_Number_3);
// Enable global Interrupts and higher priority real-time debug events
CPU_enableGlobalInts(myCpu);
CPU_enableDebugInt(myCpu);
for(;;)
{
__asm(" NOP");
}
}