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mbed-os/targets/TARGET_NUVOTON/TARGET_NUC472/device/StdDriver/nuc472_pwm.c

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/**************************************************************************//**
* @file PWM.c
* @version V1.00
* $Revision: 26 $
* $Date: 15/11/18 2:34p $
* @brief NUC472/NUC442 PWM driver source file
*
* @note
* Copyright (C) 2014 Nuvoton Technology Corp. All rights reserved.
*****************************************************************************/
#include "NUC472_442.h"
/** @addtogroup NUC472_442_Device_Driver NUC472/NUC442 Device Driver
@{
*/
/** @addtogroup NUC472_442_PWM_Driver PWM Driver
@{
*/
/** @addtogroup NUC472_442_PWM_EXPORTED_FUNCTIONS PWM Exported Functions
@{
*/
/**
* @brief This function config PWM generator and get the nearest frequency in edge aligned auto-reload mode
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32Frequency Target generator frequency
* @param[in] u32DutyCycle Target generator duty cycle percentage. Valid range are between 0 ~ 100. 10 means 10%, 20 means 20%...
* @return Nearest frequency clock in nano second
* @note Since every two channels, (0 & 1), (2 & 3), (4 & 5), shares a prescaler. Call this API to configure PWM frequency may affect
* existing frequency of other channel.
*/
uint32_t PWM_ConfigOutputChannel (PWM_T *pwm,
uint32_t u32ChannelNum,
uint32_t u32Frequency,
uint32_t u32DutyCycle)
{
return PWM_ConfigOutputChannel2(pwm, u32ChannelNum, u32Frequency, u32DutyCycle, 1);
}
/**
* @brief This function config PWM generator and get the nearest frequency in edge aligned auto-reload mode
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32Frequency Target generator frequency = u32Frequency / u32Frequency2
* @param[in] u32DutyCycle Target generator duty cycle percentage. Valid range are between 0 ~ 100. 10 means 10%, 20 means 20%...
* @param[in] u32Frequency2 Target generator frequency = u32Frequency / u32Frequency2
* @return Nearest frequency clock in nano second
* @note Since every two channels, (0 & 1), (2 & 3), (4 & 5), shares a prescaler. Call this API to configure PWM frequency may affect
* existing frequency of other channel.
*/
uint32_t PWM_ConfigOutputChannel2 (PWM_T *pwm,
uint32_t u32ChannelNum,
uint32_t u32Frequency,
uint32_t u32DutyCycle,
uint32_t u32Frequency2)
{
uint32_t i;
uint32_t u32PWM_CLock = __HIRC;
uint8_t u8Divider = 1, u8Prescale = 0xFF;
uint16_t u16CNR = 0xFFFF;
if (pwm == PWM0) {
if (u32ChannelNum < 2) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 0)
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 1)
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 2)
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 3)
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 4)
u32PWM_CLock = __LIRC;
} else if (u32ChannelNum < 4) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (0 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (1 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (2 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (3 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (4 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = __LIRC;
} else if (u32ChannelNum < 6) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (0 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (1 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (2 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (3 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (4 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = __LIRC;
}
} else if (pwm == PWM1) {
if (u32ChannelNum < 2) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (0 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (1 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (2 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (3 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (4 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = __LIRC;
} else if (u32ChannelNum < 4) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (0 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (1 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (2 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (3 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (4 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = __LIRC;
} else if (u32ChannelNum < 6) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (0 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (1 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (2 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (3 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (4 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = __LIRC;
}
}
for(; u8Divider < 17; u8Divider <<= 1) { // clk divider could only be 1, 2, 4, 8, 16
// Note: Support frequency < 1
i = (uint64_t) u32PWM_CLock * u32Frequency2 / u32Frequency / u8Divider;
// If target value is larger than CNR * prescale, need to use a larger divider
if(i > (0x10000 * 0x100))
continue;
// CNR = 0xFFFF + 1, get a prescaler that CNR value is below 0xFFFF
u8Prescale = (i + 0xFFFF)/ 0x10000;
// u8Prescale must at least be 2, otherwise the output stop
if(u8Prescale < 3)
u8Prescale = 2;
i /= u8Prescale;
if(i <= 0x10000) {
if(i == 1)
u16CNR = 1; // Too fast, and PWM cannot generate expected frequency...
else
u16CNR = i;
break;
}
}
// Store return value here 'cos we're gonna change u8Divider & u8Prescale & u16CNR to the real value to fill into register
i = u32PWM_CLock / (u8Prescale * u8Divider * u16CNR);
u8Prescale -= 1;
u16CNR -= 1;
// convert to real register value
if(u8Divider == 1)
u8Divider = 4;
else if (u8Divider == 2)
u8Divider = 0;
else if (u8Divider == 4)
u8Divider = 1;
else if (u8Divider == 8)
u8Divider = 2;
else // 16
u8Divider = 3;
// every two channels share a prescaler
while((pwm->SBS[u32ChannelNum] & 1) == 1);
pwm->CLKPSC = (pwm->CLKPSC & ~(PWM_CLKPSC_CLKPSC01_Msk << ((u32ChannelNum >> 1) * 8))) | (u8Prescale << ((u32ChannelNum >> 1) * 8));
pwm->CLKDIV = (pwm->CLKDIV & ~(PWM_CLKDIV_CLKDIV0_Msk << (4 * u32ChannelNum))) | (u8Divider << (4 * u32ChannelNum));
pwm->CTL |= 1 << (PWM_CTL_CNTMODE_Pos + u32ChannelNum);
if(u32DutyCycle == 0)
pwm->CMPDAT[u32ChannelNum] = 0;
else
pwm->CMPDAT[u32ChannelNum] = u32DutyCycle * (u16CNR + 1) / 100 - 1;
pwm->PERIOD[u32ChannelNum] = u16CNR;
return(i);
}
/**
* @brief This function config PWM capture and get the nearest unit time
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32UnitTimeNsec Unit time of counter
* @param[in] u32CaptureEdge Condition to latch the counter
* @return Nearest unit time in nano second
* @note Since every two channels, (0 & 1), (2 & 3), (4 & 5), shares a prescaler. Call this API to configure PWM frequency may affect
* existing frequency of other channel.
*/
uint32_t PWM_ConfigCaptureChannel (PWM_T *pwm,
uint32_t u32ChannelNum,
uint32_t u32UnitTimeNsec,
uint32_t u32CaptureEdge)
{
uint32_t i;
uint32_t u32PWM_CLock = __HIRC;
uint8_t u8Divider = 1, u8Prescale = 0xFF;
uint16_t u16CNR = 0xFFFF;
if (pwm == PWM0) {
if (u32ChannelNum < 2) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 0)
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 1)
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 2)
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 3)
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH01SEL_Msk) == 4)
u32PWM_CLock = __LIRC;
} else if (u32ChannelNum < 4) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (0 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (1 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (2 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (3 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH23SEL_Msk) == (4 << CLK_CLKSEL2_PWM0CH23SEL_Pos))
u32PWM_CLock = __LIRC;
} else if (u32ChannelNum < 6) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (0 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (1 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (2 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (3 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM0CH45SEL_Msk) == (4 << CLK_CLKSEL2_PWM0CH45SEL_Pos))
u32PWM_CLock = __LIRC;
}
} else if (pwm == PWM1) {
if (u32ChannelNum < 2) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (0 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (1 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (2 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (3 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH01SEL_Msk) == (4 << CLK_CLKSEL2_PWM1CH01SEL_Pos))
u32PWM_CLock = __LIRC;
} else if (u32ChannelNum < 4) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (0 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (1 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (2 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (3 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH23SEL_Msk) == (4 << CLK_CLKSEL2_PWM1CH23SEL_Pos))
u32PWM_CLock = __LIRC;
} else if (u32ChannelNum < 6) {
if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (0 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = __HXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (1 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = __LXT;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (2 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = CLK_GetPCLKFreq();
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (3 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = __HIRC;
else if ((CLK->CLKSEL2 & CLK_CLKSEL2_PWM1CH45SEL_Msk) == (4 << CLK_CLKSEL2_PWM1CH45SEL_Pos))
u32PWM_CLock = __LIRC;
}
}
for(; u8Divider < 17; u8Divider <<= 1) { // clk divider could only be 1, 2, 4, 8, 16
i = ((u32PWM_CLock / u8Divider) * u32UnitTimeNsec) / 1000000000;
// If target value is larger than 0xFF, need to use a larger divider
if(i > (0xFF))
continue;
u8Prescale = i;
// u8Prescale must at least be 2, otherwise the output stop
if(u8Prescale < 3)
u8Prescale = 2;
break;
}
// Store return value here 'cos we're gonna change u8Divider & u8Prescale & u16CNR to the real value to fill into register
i = (u8Prescale * u8Divider) * 1000000000/ u32PWM_CLock;
u8Prescale -= 1;
u16CNR -= 1;
// convert to real register value
if(u8Divider == 1)
u8Divider = 4;
else if (u8Divider == 2)
u8Divider = 0;
else if (u8Divider == 4)
u8Divider = 1;
else if (u8Divider == 8)
u8Divider = 2;
else // 16
u8Divider = 3;
// every two channels share a prescaler
while((pwm->SBS[u32ChannelNum] & 1) == 1);
pwm->CLKPSC = (pwm->CLKPSC & ~(PWM_CLKPSC_CLKPSC01_Msk << ((u32ChannelNum >> 1) * 8))) | (u8Prescale << ((u32ChannelNum >> 1) * 8));
pwm->CLKDIV = (pwm->CLKDIV & ~(PWM_CLKDIV_CLKDIV0_Msk << (4 * u32ChannelNum))) | (u8Divider << (4 * u32ChannelNum));
pwm->CTL |= 1 << (PWM_CTL_CNTMODE_Pos + u32ChannelNum);
pwm->PERIOD[u32ChannelNum] = u16CNR;
return(i);
}
/**
* @brief This function start PWM module
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelMask Combination of enabled channels. Each bit corresponds to a channel.
* Bit 0 is channel 0, bit 1 is channel 1...
* @return None
*/
void PWM_Start (PWM_T *pwm, uint32_t u32ChannelMask)
{
pwm->CNTEN |= u32ChannelMask;
}
/**
* @brief This function stop PWM module
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelMask Combination of enabled channels. Each bit corresponds to a channel.
* Bit 0 is channel 0, bit 1 is channel 1...
* @return None
*/
void PWM_Stop (PWM_T *pwm, uint32_t u32ChannelMask)
{
uint32_t i;
for(i = 0; i < PWM_CHANNEL_NUM; i ++) {
if(u32ChannelMask & (1 << i)) {
*(__IO uint32_t *) (&pwm->CNTEN + 1 * i) = 0;
}
}
}
/**
* @brief This function stop PWM generation immediately by clear channel enable bit
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelMask Combination of enabled channels. Each bit corresponds to a channel.
* Bit 0 is channel 0, bit 1 is channel 1...
* @return None
*/
void PWM_ForceStop (PWM_T *pwm, uint32_t u32ChannelMask)
{
pwm->CNTEN &= ~u32ChannelMask;
}
/**
* @brief This function enable selected channel to trigger ADC
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32Condition The condition to trigger ADC. Combination of following conditions:
* - \ref PWM_TRIGGER_ADC_PERIOD_POINT
* - \ref PWM_TRIGGER_ADC_CENTER_POINT
* - \ref PWM_TRIGGER_ADC_FALLING_EDGE_POINT
* - \ref PWM_TRIGGER_ADC_RISING_EDGE_POINT
* @return None
*/
void PWM_EnableADCTrigger (PWM_T *pwm, uint32_t u32ChannelNum, uint32_t u32Condition)
{
pwm->TRGADCTL = (pwm->TRGADCTL & ~((PWM_TRIGGER_ADC_PERIOD_POINT |
PWM_TRIGGER_ADC_CENTER_POINT |
PWM_TRIGGER_ADC_FALLING_EDGE_POINT |
PWM_TRIGGER_ADC_RISING_EDGE_POINT ) << (1 * u32ChannelNum))) | (u32Condition << (1 * u32ChannelNum));
}
/**
* @brief This function disable selected channel to trigger ADC
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return None
*/
void PWM_DisableADCTrigger (PWM_T *pwm, uint32_t u32ChannelNum)
{
pwm->TRGADCTL = (pwm->TRGADCTL & ~((PWM_TRIGGER_ADC_PERIOD_POINT |
PWM_TRIGGER_ADC_CENTER_POINT |
PWM_TRIGGER_ADC_FALLING_EDGE_POINT |
PWM_TRIGGER_ADC_RISING_EDGE_POINT ) << (1 * u32ChannelNum)));
}
/**
* @brief This function clear selected channel trigger ADC flag
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32Condition PWM triggered ADC flag to be cleared. A combination of following flags:
* - \ref PWM_TRIGGER_ADC_PERIOD_POINT
* - \ref PWM_TRIGGER_ADC_CENTER_POINT
* - \ref PWM_TRIGGER_ADC_FALLING_EDGE_POINT
* - \ref PWM_TRIGGER_ADC_RISING_EDGE_POINT
* @return None
*/
void PWM_ClearADCTriggerFlag (PWM_T *pwm, uint32_t u32ChannelNum, uint32_t u32Condition)
{
pwm->TRGADCSTS |= (u32Condition << (1 * u32ChannelNum));
}
/**
* @brief This function get selected channel trigger ADC flag
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return Combination of following trigger conditions which triggered ADC
* - \ref PWM_TRIGGER_ADC_PERIOD_POINT
* - \ref PWM_TRIGGER_ADC_CENTER_POINT
* - \ref PWM_TRIGGER_ADC_FALLING_EDGE_POINT
* - \ref PWM_TRIGGER_ADC_FALLING_EDGE_POINT
*/
uint32_t PWM_GetADCTriggerFlag (PWM_T *pwm, uint32_t u32ChannelNum)
{
uint32_t u32Ret;
u32Ret = pwm->TRGADCSTS >> u32ChannelNum;
return (u32Ret & (PWM_TRIGGER_ADC_PERIOD_POINT |
PWM_TRIGGER_ADC_CENTER_POINT |
PWM_TRIGGER_ADC_FALLING_EDGE_POINT |
PWM_TRIGGER_ADC_FALLING_EDGE_POINT));
}
/**
* @brief This function enable fault brake of selected channels
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelMask This parameter is not used
* @param[in] u32LevelMask Output high or low while fault brake occurs, each bit represent the level of a channel
* while fault brake occurs. Bit 0 represents channel 0, bit 1 represents channel 1...
* , bit 6 represent D6, and bit 7 represents D7
* @param[in] u32BrakeSource Fault brake source, could be one of following source
* - \ref PWM_BRK0_BKP0
* - \ref PWM_BRK0_CPO0
* - \ref PWM_BRK0_CPO1
* - \ref PWM_BRK0_CPO2
* - \ref PWM_BRK1_LVDBK
* - \ref PWM_BK1SEL_BKP1
* - \ref PWM_BK1SEL_CPO0
* - \ref PWM_BK1SEL_CPO1
* @return None
*/
void PWM_EnableFaultBrake (PWM_T *pwm,
uint32_t u32ChannelMask,
uint32_t u32LevelMask,
uint32_t u32BrakeSource)
{
if ((u32BrakeSource == PWM_BRK0_BKP0)||(u32BrakeSource == PWM_BRK0_CPO0)||(u32BrakeSource == PWM_BRK0_CPO1)||(u32BrakeSource == PWM_BRK0_CPO2))
pwm->BRKCTL |= (u32BrakeSource | PWM_BRKCTL_BRK0EN_Msk);
else if (u32BrakeSource == PWM_BRK1_LVDBK)
pwm->BRKCTL |= PWM_BRKCTL_LVDBKEN_Msk;
else
pwm->BRKCTL = (pwm->BRKCTL & ~PWM_BRKCTL_BK1SEL_Msk) | u32BrakeSource | PWM_BRKCTL_BRK1EN_Msk;
pwm->BRKCTL = (pwm->BRKCTL & ~PWM_BRKCTL_BKOD_Msk) | (u32LevelMask << PWM_BRKCTL_BKOD_Pos);
}
/**
* @brief This function clear fault brake flag
* @param[in] pwm The base address of PWM module
* @param[in] u32BrakeSource Fault brake source 0 or 1
* 0: brake 0, 1: brake 1
* @return None
* @note After fault brake occurred, application must clear fault brake source before re-enable PWM output
*/
void PWM_ClearFaultBrakeFlag (PWM_T *pwm, uint32_t u32BrakeSource)
{
if (u32BrakeSource == 0)
pwm->INTSTS = (PWM_INTSTS_BRKLK0_Msk | PWM_INTSTS_BRKIF0_Msk);
else
pwm->INTSTS = PWM_INTSTS_BRKIF1_Msk;
}
/**
* @brief This function enables PWM capture of selected channels
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelMask Combination of enabled channels. Each bit corresponds to a channel.
* Set bit 0 to 1 enables channel 0 output, set bit 1 to 1 enables channel 1 output...
* @return None
*/
void PWM_EnableCapture (PWM_T *pwm, uint32_t u32ChannelMask)
{
pwm->CAPCTL |= u32ChannelMask;
pwm->CAPINEN |= u32ChannelMask;
pwm->CTL |= (u32ChannelMask << PWM_CTL_CNTMODE_Pos);
}
/**
* @brief This function disables PWM capture of selected channels
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelMask Combination of enabled channels. Each bit corresponds to a channel.
* Set bit 0 to 1 enables channel 0 output, set bit 1 to 1 enables channel 1 output...
* @return None
*/
void PWM_DisableCapture (PWM_T *pwm, uint32_t u32ChannelMask)
{
pwm->CAPCTL &= ~u32ChannelMask;
pwm->CAPINEN &= ~u32ChannelMask;
}
/**
* @brief This function enables PWM output generation of selected channels
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelMask Combination of enabled channels. Each bit corresponds to a channel.
* Set bit 0 to 1 enables channel 0 output, set bit 1 to 1 enables channel 1 output...
* @return None
*/
void PWM_EnableOutput (PWM_T *pwm, uint32_t u32ChannelMask)
{
pwm->POEN |= u32ChannelMask;
}
/**
* @brief This function disables PWM output generation of selected channels
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelMask Combination of enabled channels. Each bit corresponds to a channel
* Set bit 0 to 1 disables channel 0 output, set bit 1 to 1 disables channel 1 output...
* @return None
*/
void PWM_DisableOutput (PWM_T *pwm, uint32_t u32ChannelMask)
{
pwm->POEN &= ~u32ChannelMask;
}
/**
* @brief This function enable Dead zone of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32Duration Dead Zone length in PWM clock count, valid values are between 0~0xFF, but 0 means there is no
* dead zone.
* @return None
*/
void PWM_EnableDeadZone (PWM_T *pwm, uint32_t u32ChannelNum, uint32_t u32Duration)
{
// every two channels shares the same setting
u32ChannelNum >>= 1;
// set duration
pwm->DTCTL = (pwm->DTCTL & ~(PWM_DTCTL_DTCNT01_Msk << (8 * u32ChannelNum))) | (u32Duration << (8 * u32ChannelNum));
// enable dead zone
pwm->DTCTL |= (PWM_DTCTL_DTEN01_Msk << u32ChannelNum);
}
/**
* @brief This function disable Dead zone of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return None
*/
void PWM_DisableDeadZone (PWM_T *pwm, uint32_t u32ChannelNum)
{
// every two channels shares the same setting
u32ChannelNum >>= 1;
// enable dead zone
pwm->DTCTL &= ~(PWM_DTCTL_DTEN01_Msk << u32ChannelNum);
}
/**
* @brief This function enable capture interrupt of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32Edge Capture interrupt type. It could be either
* - \ref PWM_FALLING_LATCH_INT_ENABLE
* - \ref PWM_RISING_LATCH_INT_ENABLE
* - \ref PWM_RISING_FALLING_LATCH_INT_ENABLE
* @return None
*/
void PWM_EnableCaptureInt (PWM_T *pwm, uint32_t u32ChannelNum, uint32_t u32Edge)
{
// enable capture interrupt
pwm->INTEN |= (u32Edge << u32ChannelNum);
}
/**
* @brief This function disable capture interrupt of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32Edge Capture interrupt type. It could be either
* - \ref PWM_FALLING_LATCH_INT_ENABLE
* - \ref PWM_RISING_LATCH_INT_ENABLE
* - \ref PWM_RISING_FALLING_LATCH_INT_ENABLE
* @return None
*/
void PWM_DisableCaptureInt (PWM_T *pwm, uint32_t u32ChannelNum, uint32_t u32Edge)
{
// disable capture interrupt
pwm->INTEN &= ~(u32Edge << u32ChannelNum);
}
/**
* @brief This function clear capture interrupt flag of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32Edge Capture interrupt type. It could be either
* - \ref PWM_FALLING_LATCH_INT_ENABLE
* - \ref PWM_RISING_LATCH_INT_ENABLE
* - \ref PWM_RISING_FALLING_LATCH_INT_ENABLE
* @return None
*/
void PWM_ClearCaptureIntFlag (PWM_T *pwm, uint32_t u32ChannelNum, uint32_t u32Edge)
{
// disable capture interrupt flag
pwm->INTSTS = (u32Edge << u32ChannelNum);
}
/**
* @brief This function get capture interrupt flag of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return Capture interrupt flag of specified channel
* @retval 0 Capture interrupt did not occurred
* @retval PWM_RISING_LATCH_INT_FLAG Rising edge latch interrupt occurred
* @retval PWM_FALLING_LATCH_INT_FLAG Falling edge latch interrupt occurred
* @retval PWM_RISING_FALLING_LATCH_INT_FLAG Rising and falling edge latch interrupt occurred
*/
uint32_t PWM_GetCaptureIntFlag (PWM_T *pwm, uint32_t u32ChannelNum)
{
return ((pwm->INTSTS >> u32ChannelNum) & PWM_RISING_FALLING_LATCH_INT_FLAG);
}
/**
* @brief This function enable duty interrupt of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32IntDutyType Duty interrupt type. It could be either
* - \ref PWM_DUTY_INT_MATCH_CMR_UP
* - \ref PWM_DUTY_INT_MATCH_CMR_DN
* @return None
*/
void PWM_EnableDutyInt (PWM_T *pwm, uint32_t u32ChannelNum, uint32_t u32IntDutyType)
{
// set duty interrupt type
pwm->INTCTL = (pwm->INTCTL & ~(PWM_DUTY_INT_MATCH_CMR_UP << u32ChannelNum)) | (u32IntDutyType << u32ChannelNum);
// enable duty interrupt
pwm->INTEN |= ((1 << PWM_INTEN_DIEN_Pos) << u32ChannelNum);
}
/**
* @brief This function disable duty interrupt of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return None
*/
void PWM_DisableDutyInt (PWM_T *pwm, uint32_t u32ChannelNum)
{
pwm->INTEN &= ~((1 << PWM_INTEN_DIEN_Pos) << u32ChannelNum);
}
/**
* @brief This function clears duty interrupt flag of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return None
*/
void PWM_ClearDutyIntFlag (PWM_T *pwm, uint32_t u32ChannelNum)
{
// write 1 clear
pwm->INTSTS = (1 << PWM_INTSTS_DIF_Pos) << u32ChannelNum;
}
/**
* @brief This function get duty interrupt flag of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return Duty interrupt flag of specified channel
* @retval 0 Duty interrupt did not occurred
* @retval 1 Duty interrupt occurred
*/
uint32_t PWM_GetDutyIntFlag (PWM_T *pwm, uint32_t u32ChannelNum)
{
return(pwm->INTSTS & ((1 << PWM_INTSTS_DIF_Pos) << u32ChannelNum) ? 1 : 0);
}
/**
* @brief This function enable fault brake interrupt
* @param[in] pwm The base address of PWM module
* @param[in] u32BrakeSource This parameter is not used
* @return None
*/
void PWM_EnableFaultBrakeInt (PWM_T *pwm, uint32_t u32BrakeSource)
{
pwm->INTEN |= PWM_INTEN_BRKIEN_Msk;
}
/**
* @brief This function disable fault brake interrupt
* @param[in] pwm The base address of PWM module
* @param[in] u32BrakeSource This parameter is not used
* @return None
*/
void PWM_DisableFaultBrakeInt (PWM_T *pwm, uint32_t u32BrakeSource)
{
pwm->INTEN &= ~PWM_INTEN_BRKIEN_Msk;
}
/**
* @brief This function clear fault brake interrupt of selected source
* @param[in] pwm The base address of PWM module
* @param[in] u32BrakeSource Fault brake source, could be either
* - \ref PWM_INTSTS_BRKIF0_Msk, or
* - \ref PWM_INTSTS_BRKIF1_Msk
* @return None
*/
void PWM_ClearFaultBrakeIntFlag (PWM_T *pwm, uint32_t u32BrakeSource)
{
pwm->INTSTS = u32BrakeSource;
}
/**
* @brief This function get fault brake interrupt of selected source
* @param[in] pwm The base address of PWM module
* @param[in] u32BrakeSource Fault brake source, could be either
* - \ref PWM_INTSTS_BRKIF0_Msk, or
* - \ref PWM_INTSTS_BRKIF1_Msk
* @return Fault brake interrupt flag of specified source
* @retval 0 Fault brake interrupt did not occurred
* @retval 1 Fault brake interrupt occurred
*/
uint32_t PWM_GetFaultBrakeIntFlag (PWM_T *pwm, uint32_t u32BrakeSource)
{
return (pwm->INTSTS & u32BrakeSource ? 1 : 0);
}
/**
* @brief This function enable period interrupt of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @param[in] u32IntPeriodType Period interrupt type, could be either
* - \ref PWM_PERIOD_INT_UNDERFLOW
* - \ref PWM_PERIOD_INT_MATCH_CNR
* @return None
* @note All channels share the same period interrupt type setting.
*/
void PWM_EnablePeriodInt (PWM_T *pwm, uint32_t u32ChannelNum, uint32_t u32IntPeriodType)
{
// set period interrupt type
pwm->INTCTL = (pwm->INTCTL & ~(PWM_PERIOD_INT_MATCH_CNR << u32ChannelNum)) | (u32IntPeriodType << u32ChannelNum);
// enable period interrupt
pwm->INTEN |= ((1 << PWM_INTEN_PIEN_Pos) << u32ChannelNum);
}
/**
* @brief This function disable period interrupt of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return None
*/
void PWM_DisablePeriodInt (PWM_T *pwm, uint32_t u32ChannelNum)
{
pwm->INTEN &= ~((1 << PWM_INTEN_PIEN_Pos) << u32ChannelNum);
}
/**
* @brief This function clear period interrupt of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return None
*/
void PWM_ClearPeriodIntFlag (PWM_T *pwm, uint32_t u32ChannelNum)
{
// write 1 clear
pwm->INTSTS = ((1 << PWM_INTSTS_PIF_Pos) << u32ChannelNum);
}
/**
* @brief This function get period interrupt of selected channel
* @param[in] pwm The base address of PWM module
* @param[in] u32ChannelNum PWM channel number. Valid values are between 0~5
* @return Period interrupt flag of specified channel
* @retval 0 Period interrupt did not occurred
* @retval 1 Period interrupt occurred
*/
uint32_t PWM_GetPeriodIntFlag (PWM_T *pwm, uint32_t u32ChannelNum)
{
return(pwm->INTSTS & ((1 << PWM_INTSTS_PIF_Pos) << u32ChannelNum) ? 1 : 0);
}
/*@}*/ /* end of group NUC472_442_PWM_EXPORTED_FUNCTIONS */
/*@}*/ /* end of group NUC472_442_PWM_Driver */
/*@}*/ /* end of group NUC472_442_Device_Driver */
/*** (C) COPYRIGHT 2014 Nuvoton Technology Corp. ***/
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