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nest-open-source / nest-detect / 1.0 / freertos / cbaab1db4b0e15ed6334aaae5e20f6bc3acd730f / . / FreeRTOSV8.0.1 / FreeRTOS / Demo / ARM7_STR75x_IAR / STLibrary / src / 75x_pwm.c
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/******************** (C) COPYRIGHT 2006 STMicroelectronics ********************
* File Name : 75x_pwm.c
* Author : MCD Application Team
* Date First Issued : 03/10/2006
* Description : This file provides all the PWM software functions.
********************************************************************************
* History:
* 07/17/2006 : V1.0
* 03/10/2006 : V0.1
********************************************************************************
* THE PRESENT SOFTWARE WHICH IS FOR GUIDANCE ONLY AIMS AT PROVIDING CUSTOMERS
* WITH CODING INFORMATION REGARDING THEIR PRODUCTS IN ORDER FOR THEM TO SAVE TIME.
* AS A RESULT, STMICROELECTRONICS SHALL NOT BE HELD LIABLE FOR ANY DIRECT,
* INDIRECT OR CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING FROM THE
* CONTENT OF SUCH SOFTWARE AND/OR THE USE MADE BY CUSTOMERS OF THE CODING
* INFORMATION CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS.
*******************************************************************************/
/* Includes ------------------------------------------------------------------*/
#include "75x_pwm.h"
#include "75x_mrcc.h"
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/* Private macro -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* PWM interrupt masks */
#define PWM_IT_Clear_Mask 0x7FFF
#define PWM_IT_Enable_Mask 0xEFFF
/* PWM_CR Masks bit */
#define PWM_CounterMode_Mask 0xFF8F
#define PWM_DBASE_Mask 0x077F
#define PWM_MasterModeSelection_Mask 0xFC7F
/* PWM Update flag selection Set/Reset value */
#define PWM_UFS_Reset 0xFFFE
#define PWM_UFS_Set 0x0001
/* PWM Counter value */
#define PWM_COUNTER_Reset 0x0002
#define PWM_COUNTER_Start 0x0004
#define PWM_COUNTER_Stop 0xFFFB
/* PWM Debug Mode Set/Reset value */
#define PWM_DBGC_Set 0x0400
#define PWM_DBGC_Reset 0xFBFF
/* PWM Output Compare Polarity Set/Reset value */
#define PWM_OC1P_Set 0x0020
#define PWM_OC1P_Reset 0xFFDF
#define PWM_OC1NP_Set 0x0080
#define PWM_OC1NP_Reset 0xFF7F
#define PWM_OC2P_Set 0x2000
#define PWM_OC2P_Reset 0xDFFF
#define PWM_OC2NP_Set 0x8000
#define PWM_OC2NP_Reset 0x7FFF
#define PWM_OC3P_Set 0x0020
#define PWM_OC3P_Reset 0xFFDF
#define PWM_OC3NP_Set 0x0080
#define PWM_OC3NP_Reset 0xFF7F
/* PWM Output Compare control mode constant */
#define PWM_OCControl_PWM 0x000C
#define PWM_OCControl_OCToggle 0x0006
#define PWM_OCControl_OCInactive 0x0004
#define PWM_OCControl_OCActive 0x0002
#define PWM_OCControl_OCTiming 0x0000
/* PWM Output Compare mode Enable value */
#define PWM_OC1_Enable 0x0010
#define PWM_OC2_Enable 0x1000
#define PWM_OC3_Enable 0x0010
#define PWM_OC1_Disable 0xFFEF
#define PWM_OC2_Disable 0xEFFF
#define PWM_OC3_Disable 0xFFEF
#define PWM_OC1N_Enable 0x0040
#define PWM_OC2N_Enable 0x4000
#define PWM_OC3N_Enable 0x0040
#define PWM_OC1N_Disable 0xFFBF
#define PWM_OC2N_Disable 0xBFFF
#define PWM_OC3N_Disable 0xFFBF
/* PWM Output Compare mode Mask value */
#define PWM_OC1C_Mask 0xFFF1
#define PWM_OC2C_Mask 0xF1FF
#define PWM_OC3C_Mask 0xFFF1
/* PWM Preload bit Set/Reset value */
#define PWM_PLD1_Set 0x0001
#define PWM_PLD2_Set 0x0100
#define PWM_PLD3_Set 0x0001
/* PWM OCRM Set/Reset value */
#define PWM_OCMR_Set 0x0080
#define PWM_OCMR_Reset 0xFF7F
/* PWM_DTR bit Masks value */
#define PWM_DTR_Mask 0xFC00
#define PWM_LOCK_Mask 0xF3FF
/* PWM MOE Set value */
#define PWM_MOE_Set 0x8000
#define PWM_MOE_Reset 0x7FFF
/* PWM OSSR bit Set/Reset value */
#define PWM_OSSR_Set 0x4000
#define PWM_OSSR_Reset 0xBFFF
/* Reset Register Masks */
#define PWM_Prescaler_Reset_Mask 0x0000
#define PWM_Pulse1_Reset_Mask 0x0000
#define PWM_Pulse2_Reset_Mask 0x0000
#define PWM_Pulse3_Reset_Mask 0x0000
#define PWM_Period_Reset_Mask 0xFFFF
#define PWM_RepetitionCounter_Reset_Mask 0x0000
#define PWM_DeadTime_Reset_Mask 0x0000
/* Private function prototypes -----------------------------------------------*/
static void OCM_ModuleConfig(PWM_InitTypeDef* PWM_InitStruct);
/* Private functions ---------------------------------------------------------*/
/******************************************************************************
* Function Name : PWM_DeInit
* Description : Deinitializes PWM peripheral registers to their default reset
* values.
* Input : None
* Output : None
* Return : None
*******************************************************************************/
void PWM_DeInit(void)
{
/* Enters and exits the PWM peripheral to and from reset */
MRCC_PeripheralSWResetConfig(MRCC_Peripheral_PWM,ENABLE);
MRCC_PeripheralSWResetConfig(MRCC_Peripheral_PWM,DISABLE);
}
/*******************************************************************************
* Function Name : PWM_Init
* Description : Initializes the PWM peripheral according to the specified
* parameters in the PWM_InitStruct .
* Input : PWM_InitStruct: pointer to a PWM_InitTypeDef structure that
* contains the configuration information for the PWM peripheral.
* Output : None
* Return : None
*******************************************************************************/
void PWM_Init(PWM_InitTypeDef* PWM_InitStruct)
{
/* Sets the prescaler value */
PWM->PSC = PWM_InitStruct->PWM_Prescaler;
/* Selects the counter mode */
PWM->CR &= PWM_CounterMode_Mask;
PWM->CR |= PWM_InitStruct->PWM_CounterMode;
/* Sets the period value */
PWM->ARR = PWM_InitStruct->PWM_Period;
/* Sets the repetition counter */
PWM->RCR &= PWM_RepetitionCounter_Reset_Mask;
PWM->RCR |= PWM_InitStruct->PWM_RepetitionCounter;
/* Configures the PWM according to the PWM_InitTypeDef structure parameters */
OCM_ModuleConfig(PWM_InitStruct);
}
/*******************************************************************************
* Function Name : PWM_StructInit
* Description : Fills each PWM_InitStruct member with its default value.
* Input : PWM_InitStruct : pointer to a PWM_InitTypeDef structure which
* will be initialized.
* Output : None
* Return : None.
*******************************************************************************/
void PWM_StructInit(PWM_InitTypeDef *PWM_InitStruct)
{
/* Sets the default configuration */
PWM_InitStruct->PWM_Mode = PWM_Mode_OCTiming;
PWM_InitStruct->PWM_Prescaler = PWM_Prescaler_Reset_Mask;
PWM_InitStruct->PWM_CounterMode = PWM_CounterMode_Up;
PWM_InitStruct->PWM_Period = PWM_Period_Reset_Mask;
PWM_InitStruct->PWM_Complementary = PWM_Complementary_Disable;
PWM_InitStruct->PWM_OCState = PWM_OCState_Disable;
PWM_InitStruct->PWM_OCNState = PWM_OCNState_Disable;
PWM_InitStruct->PWM_Channel = PWM_Channel_1;
PWM_InitStruct->PWM_Pulse1 = PWM_Pulse1_Reset_Mask;
PWM_InitStruct->PWM_Pulse2 = PWM_Pulse2_Reset_Mask;
PWM_InitStruct->PWM_Pulse3 = PWM_Pulse3_Reset_Mask;
PWM_InitStruct->PWM_Polarity1 = PWM_Polarity1_High;
PWM_InitStruct->PWM_Polarity2 = PWM_Polarity2_High;
PWM_InitStruct->PWM_Polarity3 = PWM_Polarity3_High;
PWM_InitStruct->PWM_Polarity1N = PWM_Polarity1N_High;
PWM_InitStruct->PWM_Polarity2N = PWM_Polarity2N_High;
PWM_InitStruct->PWM_Polarity3N = PWM_Polarity3N_High;
PWM_InitStruct->PWM_DTRAccess = PWM_DTRAccess_Disable;
PWM_InitStruct->PWM_DeadTime = PWM_DeadTime_Reset_Mask;
PWM_InitStruct->PWM_Emergency = PWM_Emergency_Disable;
PWM_InitStruct->PWM_LOCKLevel = PWM_LOCKLevel_OFF;
PWM_InitStruct->PWM_OSSIState = PWM_OSSIState_Disable;
PWM_InitStruct->PWM_RepetitionCounter = PWM_RepetitionCounter_Reset_Mask;
}
/*******************************************************************************
* Function Name : PWM_Cmd
* Description : Enables or disables the PWM peripheral.
* Input : Newstate: new state of the PWM peripheral.
* This parameter can be: ENABLE or DISABLE.
* Output : None
* Return : None
*******************************************************************************/
void PWM_Cmd(FunctionalState Newstate)
{
if(Newstate == ENABLE)
{
PWM->CR |= PWM_COUNTER_Start;
}
else
{
PWM->CR &= PWM_COUNTER_Stop;
}
}
/*******************************************************************************
* Function Name : PWM_CtrlPWMOutputs
* Description : Enables or disables PWM peripheral Main Outputs.
* Input : Newstate: new state of the PWM peripheral Main Outputs.
* This parameter can be: ENABLE or DISABLE.
* Output : None
* Return : None
*******************************************************************************/
void PWM_CtrlPWMOutputs(FunctionalState Newstate)
{
if(Newstate == ENABLE)
{
PWM->DTR |= PWM_MOE_Set;
}
else
{
PWM->DTR &= PWM_MOE_Reset;
}
}
/*******************************************************************************
* Function Name : PWM_ITConfig
* Description : Enables or disables the PWM interrupts.
* Input : - PWM_IT: specifies the PWM interrupts sources to be enabled
* or disabled.
* This parameter can be any combination of the following values:
* - PWM_IT_OC1: PWM Output Compare 1 Interrupt source
* - PWM_IT_OC2: PWM Output Compare 2 Interrupt source
* - PWM_IT_OC3: PWM Output Compare 3 Interrupt source
* - PWM_IT_Update: PWM update Interrupt source
* - PWM_IT_Emergency: PWM Emergency interrupt source
* - PWM_IT_GlobalUpdate: PWM global update Interrupt
* source
* - Newstate: new state of PWM interrupts.
* This parameter can be: ENABLE or DISABLE.
* Output : None
* Return : None
*******************************************************************************/
void PWM_ITConfig(u16 PWM_IT, FunctionalState Newstate)
{
u16 PWM_IT_Enable = 0;
PWM_IT_Enable = PWM_IT & PWM_IT_Enable_Mask;
if(Newstate == ENABLE)
{
/* Update interrupt global source: overflow/undeflow, counter reset operation
or slave mode controller in reset mode */
if ((PWM_IT & PWM_IT_GlobalUpdate) == PWM_IT_GlobalUpdate)
{
PWM->CR &= PWM_UFS_Reset;
}
/* Update interrupt source: counter overflow/underflow */
else if ((PWM_IT & PWM_IT_Update) == PWM_IT_Update)
{
PWM->CR |= PWM_UFS_Set;
}
/* Select and enable the interrupts requests */
PWM->RSR |= PWM_IT_Enable;
PWM->RER |= PWM_IT_Enable;
}
/* Disable the interrupts requests */
else
{
PWM->RSR &= ~PWM_IT_Enable;
PWM->RER &= ~PWM_IT_Enable;
}
}
/*******************************************************************************
* Function Name : PWM_DMAConfig
* Description : Configures the PWMÂ’s DMA interface.
* Input : - PWM_DMASources: specifies the DMA Request sources.
* This parameter can be any combination of the following values:
* - PWM_DMASource_OC1: PWM Output Compare 1 DMA source
* - PWM_DMASource_OC2: PWM Output Compare 2 DMA source
* - PWM_DMASource_OC3: PWM Output Compare 3 DMA source
* - PWM_DMASource_Update: PWM Update DMA source
* - PWM_OCRMState: the state of output compare request mode.
* This parameter can be one of the following values:
* - PWM_OCRMState_Enable
* - PWM_OCRMState_Disable
* - PWM_DMABase:DMA Base address.
* This parameter can be one of the following values:
* PWM_DMABase_CR, PWM_DMABase_SCR, PWM_DMABase_OMR1,
* PWM_DMABase_OMR2, PWM_DMABase_RSR, PWM_DMABase_RER,
* PWM_DMABase_ISR, PWM_DMABase_CNT, PWM_DMABase_PSC,
* PWM_DMABase_RCR, PWM_DMABase_ARR, PWM_DMABase_OCR1,
* PWM_DMABase_OCR2, PWM_DMABase_OCR3 ,PWM_DMABase_DTR.
* Output : None
* Return : None
*******************************************************************************/
void PWM_DMAConfig(u16 PWM_DMASources, u16 PWM_OCRMState, u16 PWM_DMABase)
{
/* Select the DMA requests */
PWM->RSR &= ~PWM_DMASources;
/* Sets the OCRM state */
if(PWM_OCRMState == PWM_OCRMState_Enable)
{
PWM->RSR |= PWM_OCMR_Set;
}
else
{
PWM->RSR &= PWM_OCMR_Reset;
}
/* Sets the DMA Base address */
PWM->CR &= PWM_DBASE_Mask;
PWM->CR |= PWM_DMABase;
}
/*******************************************************************************
* Function Name : PWM_DMACmd
* Description : Enables or disables the PWMÂ’s DMA interface.
* Input : - PWM_DMASources: specifies the DMA Request sources.
* This parameter can be any combination of the following values:
* - PWM_DMASource_OC1: PWM Output Compare 1 DMA source
* - PWM_DMASource_OC2: PWM Output Compare 2 DMA source
* - PWM_DMASource_OC3: PWM Output Compare 3 DMA source
* - PWM_DMASource_Update: PWM Update DMA source
* - Newstate: new state of the DMA Request sources.
* This parameter can be: ENABLE or DISABLE.
* Output : None
* Return : None
*******************************************************************************/
void PWM_DMACmd(u16 PWM_DMASources, FunctionalState Newstate)
{
if(Newstate == ENABLE)
{
PWM->RER |= PWM_DMASources;
}
else
{
PWM->RER &= ~PWM_DMASources;
}
}
/*******************************************************************************
* Function Name : PWM_SetPrescaler
* Description : Sets the PWM prescaler value.
* Input : Prescaler: PWM prescaler new value.
* Output : None
* Return : None
*******************************************************************************/
void PWM_SetPrescaler(u16 Prescaler)
{
PWM->PSC = Prescaler;
}
/*******************************************************************************
* Function Name : PWM_SetPeriod
* Description : Sets the PWM period value.
* Input : Period: PWM period new value.
* Output : None
* Return : None
*******************************************************************************/
void PWM_SetPeriod(u16 Period)
{
PWM->ARR = Period;
}
/*******************************************************************************
* Function Name : PWM_SetPulse
* Description : Sets the PWM pulse value.
* Input : - PWM_Channel: specifies the PWM channel to be used.
* This parameter can be one of the following values:
* - PWM_Channel_1: PWM Channel 1 is used
* - PWM_Channel_2: PWM Channel 2 is used
* - PWM_Channel_3: PWM Channel 3 is used
* - PWM_Channel_ALL: PWM Channel 1, Channel 2 and 3 are used
* - Pulse: PWM pulse new value.
* Output : None
* Return : None
*******************************************************************************/
void PWM_SetPulse(u16 PWM_Channel, u16 Pulse)
{
/* Sets Channel 1 pulse value */
if(PWM_Channel == PWM_Channel_1)
{
PWM->OCR1 = Pulse;
}
/* Sets Channel 2 pulse value */
else if(PWM_Channel == PWM_Channel_2)
{
PWM->OCR2 = Pulse;
}
/* Sets Channel 3 pulse value */
else if(PWM_Channel == PWM_Channel_3)
{
PWM->OCR3 = Pulse;
}
/* Sets Channel 1, Channel 2 and Channel 3 pulse values */
else if(PWM_Channel == PWM_Channel_ALL)
{
PWM->OCR1 = Pulse;
PWM->OCR2 = Pulse;
PWM->OCR3 = Pulse;
}
}
/*******************************************************************************
* Function Name : PWM_SetPulse1
* Description : Sets the PWM Channel 1 pulse value.
* Input : - Pulse: PWM Channel 1 pulse new value.
* Output : None
* Return : None
*******************************************************************************/
void PWM_SetPulse1(u16 Pulse)
{
PWM->OCR1 = Pulse;
}
/*******************************************************************************
* Function Name : PWM_SetPulse2
* Description : Sets the PWM Channel 2 pulse value.
* Input : - Pulse: PWM Channel 2 pulse new value.
* Output : None
* Return : None
*******************************************************************************/
void PWM_SetPulse2(u16 Pulse)
{
PWM->OCR2 = Pulse;
}
/*******************************************************************************
* Function Name : PWM_SetPulse3
* Description : Sets the PWM Channel 3 pulse value.
* Input : - Pulse: PWM Channel 3 pulse new value.
* Output : None
* Return : None
*******************************************************************************/
void PWM_SetPulse3(u16 Pulse)
{
PWM->OCR3 = Pulse;
}
/*******************************************************************************
* Function Name : PWM_DebugCmd
* Description : Enables or disables PWM peripheral Debug control.
* Input : Newstate: new state of the PWM Debug control.
* This parameter can be: ENABLE or DISABLE.
* Output : None
* Return : None
*******************************************************************************/
void PWM_DebugCmd(FunctionalState Newstate)
{
if(Newstate == ENABLE)
{
PWM->CR |= PWM_DBGC_Set;
}
else
{
PWM->CR &= PWM_DBGC_Reset;
}
}
/*******************************************************************************
* Function Name : PWM_CounterModeConfig
* Description : Specifies the Counter Mode to be used.
* Input : PWM_CounterMode: specifies the Counter Mode to be used
* This parameter can be one of the following values:
* - PWM_CounterMode_Up: PWM Up Counting Mode
* - PWM_CounterMode_Down: PWM Down Counting Mode
* - PWM_CounterMode_CenterAligned1: PWM Center Aligned1 Mode
* - PWM_CounterMode_CenterAligned2: PWM Center Aligned2 Mode
* - PWM_CounterMode_CenterAligned3: PWM Center Aligned3 Mode
* Output : None
* Return : None
*******************************************************************************/
void PWM_CounterModeConfig(u16 PWM_CounterMode)
{
/* Counter mode configuration */
PWM->CR &= PWM_CounterMode_Mask;
PWM->CR |= PWM_CounterMode;
}
/*******************************************************************************
* Function Name : PWM_ForcedOCConfig
* Description : Forces the PWM output waveform to active or inactive level.
* Input : - PWM_Channel: specifies the PWM channel to be used.
* This parameter can be one of the following values:
* - PWM_Channel_1: PWM Channel 1 is used
* - PWM_Channel_2: PWM Channel 2 is used
* - PWM_Channel_3: PWM Channel 3 is used
* - PWM_Channel_ALL: PWM Channel 1, Channel 2 and 3 are used
* - PWM_ForcedAction: specifies the forced Action to be set to the
* output waveform.
* This parameter can be one of the following values:
* - PWM_ForcedAction_Active: Force active level on OCxREF
* - PWM_ForcedAction_InActive: Force inactive level on
* OCxREF
* Output : None
* Return : None
*******************************************************************************/
void PWM_ForcedOCConfig(u16 PWM_Channel, u16 PWM_ForcedAction)
{
/* Channel 1 Forced Output Compare mode configuration */
if(PWM_Channel == PWM_Channel_1)
{
PWM->OMR1 &= PWM_OC1C_Mask;
PWM->OMR1 |= PWM_ForcedAction;
}
/* Channel 2 Forced Output Compare mode configuration */
else
{
if(PWM_Channel == PWM_Channel_2)
{
PWM->OMR1 &= PWM_OC2C_Mask;
PWM->OMR1 |= (PWM_ForcedAction<<8);
}
else
{
/* Channel 3 Forced Output Compare mode configuration */
if(PWM_Channel == PWM_Channel_3)
{
PWM->OMR2 &= PWM_OC3C_Mask;
PWM->OMR2 |= PWM_ForcedAction;
}
/* Channel 1, Channel 2 and Channel 3 Forced Output Compare mode
configuration */
else
{
PWM->OMR1 &= PWM_OC1C_Mask;
PWM->OMR1 |= PWM_ForcedAction;
PWM->OMR1 &= PWM_OC2C_Mask;
PWM->OMR1 |= (PWM_ForcedAction<<8);
PWM->OMR2 &= PWM_OC3C_Mask;
PWM->OMR2 |= PWM_ForcedAction;
}
}
}
}
/*******************************************************************************
* Function Name : PWM_SetDeadTime
* Description : Inserts dead time between the OCx and OCNx.
* Input : DeadTime: PWM Dead Time value.
* Output : None
* Return : None
*******************************************************************************/
void PWM_SetDeadTime(u16 DeadTime)
{
/* Sets the dead time value */
PWM->DTR &= PWM_DTR_Mask;
PWM->DTR |= DeadTime;
}
/*******************************************************************************
* Function Name : PWM_ResetCounter
* Description : Re-intializes the PWM counter and generates an update of the
* registers.
* Input : None
* Output : None
* Return : None
*******************************************************************************/
void PWM_ResetCounter(void)
{
/* Resets the PWM counter */
PWM->CR |= PWM_COUNTER_Reset;
}
/*******************************************************************************
* Function Name : PWM_TRGOSelection
* Description : Sets the PWM Master Mode selection bits.
* Input : PWM_TRGOMode: specifies the TRGO source.
* This parameter can be one of the following values:
* - PWM_TRGOMode_Enable: The CNT_EN bit is used as TRGO
* - PWM_TRGOMode_Update: The Update event is used as TRGO
* - PWM_TRGOMode_Reset: The CNT_RST bit is used as TRGO
* - PWM_TRGOMode_OC: The OC1 signal is used as TRGO
* Output : None
* Return : None
*******************************************************************************/
void PWM_TRGOSelection(u16 PWM_TRGOMode)
{
/* Sets the synchronization action */
PWM->CR &= PWM_MasterModeSelection_Mask;
PWM->CR |= PWM_TRGOMode;
}
/*******************************************************************************
* Function Name : PWM_GetFlagStatus
* Description : Checks whether the specified PWM flag is set or not.
* Input : PWM_FLAG: specifies the flag to check.
* This parameter can be one of the following values:
* - PWM_FLAG_OC1: Output Compare 1 Flag
* - PWM_FLAG_OC2: Output Compare 2 Flag
* - PWM_FLAG_OC3: Output Compare 3 Flag
* - PWM_FLAG_Update: PWM update Flag
* - PWM_FLAG_Emergency: PWM Emergency Flag
* Output : None
* Return : The new state of the PWM_FLAG(SET or RESET).
*******************************************************************************/
FlagStatus PWM_GetFlagStatus(u16 PWM_FLAG)
{
if((PWM->ISR & PWM_FLAG) != RESET )
{
return SET;
}
else
{
return RESET;
}
}
/*******************************************************************************
* Function Name : PWM_ClearFlag
* Description : Clears the PWMÂ’s pending flags.
* Input : PWM_FLAG: specifies the flag to clear.
* This parameter can be any combination of the following values:
* - PWM_FLAG_OC1: Output Compare 1 flag
* - PWM_FLAG_OC2: Output Compare 2 flag
* - PWM_FLAG_OC3: Output Compare 3 flag
* - PWM_FLAG_Update: PWM update flag
* - PWM_FLAG_Emergency: PWM Emergency flag
* Output : None
* Return : None
*******************************************************************************/
void PWM_ClearFlag(u16 PWM_FLAG)
{
/* Clears the flags */
PWM->ISR &= ~PWM_FLAG;
}
/*******************************************************************************
* Function Name : PWM_GetITStatus
* Description : Checks whether the PWM interrupt has occurred or not.
* Input : PWM_IT: specifies the PWM interrupt source to check.
* This parameter can be one of the following values:
* - PWM_IT_OC1: PWM Output Compare 1 Interrupt source
* - PWM_IT_OC2: PWM Output Compare 2 Interrupt source
* - PWM_IT_OC3: PWM Output Compare 3 Interrupt source
* - PWM_IT_Update: PWM update Interrupt source
* - PWM_IT_Emergency: PWM Emergency interrupt source
* - PWM_IT_GlobalUpdate: PWM global update Interrupt
* source
* Output : None
* Return : The new state of the PWM_IT(SET or RESET).
*******************************************************************************/
ITStatus PWM_GetITStatus(u16 PWM_IT)
{
u16 PWM_IT_Check = 0;
/* Calculates the pending bits to be checked */
PWM_IT_Check = PWM_IT & PWM_IT_Clear_Mask;
if((PWM->ISR & PWM_IT_Check) != RESET )
{
return SET;
}
else
{
return RESET;
}
}
/*******************************************************************************
* Function Name : PWM_ClearITPendingBit
* Description : Clears the PWM's interrupt pending bits.
* Input : PWM_IT: specifies the pending bit to clear.
* This parameter can be any combination of the following values:
* - PWM_IT_OC1: PWM Output Compare 1 Interrupt source
* - PWM_IT_OC2: PWM Output Compare 2 Interrupt source
* - PWM_IT_OC3: PWM Output Compare 3 Interrupt source
* - PWM_IT_Update: PWM update Interrupt source
* - PWM_IT_Emergency: PWM Emergency interrupt source
* - PWM_IT_GlobalUpdate: PWM global update Interrupt
* source
* Output : None
* Return : None
*******************************************************************************/
void PWM_ClearITPendingBit(u16 PWM_IT)
{
u16 PWM_IT_Clear = 0;
/* Calculates the pending bits to be cleared */
PWM_IT_Clear = PWM_IT & PWM_IT_Clear_Mask;
/* Clears the pending bits */
PWM->ISR &= ~PWM_IT_Clear;
}
/*******************************************************************************
* Function Name : OCM_ModuleConfig
* Description : Output Compare Module configuration.
* Input : PWM_InitStruct: pointer to a PWM_InitTypeDef structure that
* contains the configuration information for the PWM peripheral.
* Output : None
* Return : None
*******************************************************************************/
static void OCM_ModuleConfig(PWM_InitTypeDef* PWM_InitStruct)
{
u16 PWM_OCControl = 0x0000;
u16 DTR_REG = 0x0000;
if(PWM_InitStruct->PWM_Mode == PWM_Mode_OCTiming)
{
PWM_OCControl = PWM_OCControl_OCTiming;
}
else
{
if(PWM_InitStruct->PWM_Mode == PWM_Mode_OCActive)
{
PWM_OCControl = PWM_OCControl_OCActive;
}
else
{
if(PWM_InitStruct->PWM_Mode == PWM_Mode_OCInactive)
{
PWM_OCControl = PWM_OCControl_OCInactive;
}
else
{
if(PWM_InitStruct->PWM_Mode == PWM_Mode_OCToggle)
{
PWM_OCControl = PWM_OCControl_OCToggle;
}
else
{
PWM_OCControl = PWM_OCControl_PWM;
}
}
}
}
/* Read DTR register */
DTR_REG = PWM->DTR & 0x8000;
/*Channel 1 Configuration-----------------------------------------------------*/
if(PWM_InitStruct->PWM_Channel == PWM_Channel_1)
{
/* PWM Output Complementary Configuration */
if(PWM_InitStruct->PWM_Complementary == PWM_Complementary_Enable)
{
/* Configures Channel 1 on Output Compare mode */
PWM->OMR1 &= PWM_OC1C_Mask;
PWM->OMR1 |= PWM_OCControl|PWM_OC1_Enable|PWM_OC1N_Enable|PWM_PLD1_Set;
PWM->OCR1 = PWM_InitStruct->PWM_Pulse1;
/* Sets the OC1 wave polarity */
if(PWM_InitStruct->PWM_Polarity1 == PWM_Polarity1_Low)
{
PWM->OMR1 |= PWM_OC1P_Set;
}
else
{
PWM->OMR1 &= PWM_OC1P_Reset;
}
/* Sets the OC1N wave polarity */
if(PWM_InitStruct->PWM_Polarity1N == PWM_Polarity1N_Low)
{
PWM->OMR1 |= PWM_OC1NP_Set;
}
else
{
PWM->OMR1 &= PWM_OC1NP_Reset;
}
}/* End complementary case */
/* Single PWM Output configuratuion */
else
{
switch(PWM_InitStruct->PWM_OCState)
{
case PWM_OCState_Enable:
{
/* Configures Channel 1 on Output Compare mode */
PWM->OMR1 &= PWM_OC1C_Mask;
PWM->OMR1 |= PWM_OCControl|PWM_OC1_Enable;
PWM->OMR1 |= PWM_PLD1_Set;
PWM->OCR1 = PWM_InitStruct->PWM_Pulse1;
/* Sets the OC1 wave polarity */
if(PWM_InitStruct->PWM_Polarity1 == PWM_Polarity1_Low)
{
PWM->OMR1 |= PWM_OC1P_Set;
}
else
{
PWM->OMR1 &= PWM_OC1P_Reset;
}
}
break;
case PWM_OCState_Disable:
{
/* OC1E = 0 and OSSR = 0 sets the polarity */
PWM->OMR1 &= PWM_OC1_Disable;
DTR_REG &= PWM_OSSR_Reset;
}
break;
case PWM_OCState_OffState:
{
/* OC1E = 0 and OSSR = 1 and sets the polarity */
PWM->OMR1 &= PWM_OC1_Disable;
DTR_REG |= PWM_OSSR_Set;
/* Sets the OC1 wave polarity */
if(PWM_InitStruct->PWM_Polarity1 == PWM_Polarity1_Low)
{
PWM->OMR1 |= PWM_OC1P_Set;
}
else
{
PWM->OMR1 &= PWM_OC1P_Reset;
}
}
break;
}
switch(PWM_InitStruct->PWM_OCNState)
{
case PWM_OCNState_Enable:
{
/* Configures Channel 1N on Output Compare mode */
PWM->OMR1 &= PWM_OC1C_Mask;
PWM->OMR1 |= PWM_OCControl |PWM_OC1N_Enable |PWM_PLD1_Set;
PWM->OCR1 = PWM_InitStruct->PWM_Pulse1;
/* Sets the OC1N wave polarity */
if(PWM_InitStruct->PWM_Polarity1N == PWM_Polarity1N_Low)
{
PWM->OMR1 |= PWM_OC1NP_Set;
}
else
{
PWM->OMR1 &= PWM_OC1NP_Reset;
}
}
break;
case PWM_OCNState_Disable:
{
/* OC1N = 0 OSSR = 0 */
PWM->OMR1 &= PWM_OC1N_Disable;
DTR_REG &= PWM_OSSR_Reset;
}
break;
case PWM_OCNState_OffState:
{
/* OC1N = 0 OSSR = 1 and sets the polarity */
PWM->OMR1 &= PWM_OC1N_Disable;
DTR_REG |= PWM_OSSR_Set;
if(PWM_InitStruct->PWM_Polarity1N == PWM_Polarity1N_Low)
{
PWM->OMR1 |= PWM_OC1NP_Set;
}
else
{
PWM->OMR1 &= PWM_OC1NP_Reset;
}
}
break;
}
} /* End not complementary case */
}/* end channel 1 */
/*Channel 2 Configuration-----------------------------------------------------*/
if(PWM_InitStruct->PWM_Channel == PWM_Channel_2)
{
/* PWM Output Complementary Configuration */
if(PWM_InitStruct->PWM_Complementary == PWM_Complementary_Enable)
{
/* Configures Channel 2 on Output Compare mode */
PWM->OMR1 &= PWM_OC2C_Mask;
PWM->OMR1 |= (PWM_OCControl<<8)|PWM_OC2_Enable|PWM_OC2N_Enable|PWM_PLD2_Set;
PWM->OCR2 = PWM_InitStruct->PWM_Pulse2;
/* Set the OC2 wave polarity */
if(PWM_InitStruct->PWM_Polarity2 == PWM_Polarity2_Low)
{
PWM->OMR1 |= PWM_OC2P_Set;
}
else
{
PWM->OMR1 &= PWM_OC2P_Reset;
}
/* Sets the OC2N wave polarity */
if(PWM_InitStruct->PWM_Polarity2N == PWM_Polarity2N_Low)
{
PWM->OMR1 |= PWM_OC2NP_Set;
}
else
{
PWM->OMR1 &= PWM_OC2NP_Reset;
}
}/* End complentary case */
else
/* Single PWM Output configuratuion */
{
switch(PWM_InitStruct->PWM_OCState)
{
case PWM_OCState_Enable:
{
/* Configures Channel 2 on Output Compare mode */
PWM->OMR1 &= PWM_OC2C_Mask;
PWM->OMR1 |= (PWM_OCControl<<8)|PWM_OC2_Enable|PWM_PLD2_Set;
PWM->OCR2 = PWM_InitStruct->PWM_Pulse2;
/* Sets the OC2 wave polarity */
if(PWM_InitStruct->PWM_Polarity2 == PWM_Polarity2_Low)
{
PWM->OMR1 |= PWM_OC2P_Set;
}
else
{
PWM->OMR1 &= PWM_OC2P_Reset;
}
}
break;
case PWM_OCState_Disable:
{
/* OC2E = 0 and OSSR = 0 */
PWM->OMR1 &= PWM_OC2_Disable;
DTR_REG &= PWM_OSSR_Reset;
}
break;
case PWM_OCState_OffState:
{
/* OC2E = 0 and OSSR = 1 sets the polarity */
PWM->OMR1 &= PWM_OC2_Disable;
DTR_REG |= PWM_OSSR_Set;
/* Sets the OC2 wave polarity */
if(PWM_InitStruct->PWM_Polarity2 == PWM_Polarity2_Low)
{
PWM->OMR1 |= PWM_OC2P_Set;
}
else
{
PWM->OMR1 &= PWM_OC2P_Reset;
}
}
break;
}
switch(PWM_InitStruct->PWM_OCNState)
{
case PWM_OCNState_Enable:
{
/* Configures Channel 2N on Output Compare mode */
PWM->OMR1 &= PWM_OC2C_Mask;
PWM->OMR1 |= (PWM_OCControl<<8)|PWM_OC2N_Enable|PWM_PLD2_Set;
PWM->OCR2 = PWM_InitStruct->PWM_Pulse2;
/* Sets the OC2 wave polarity */
if(PWM_InitStruct->PWM_Polarity2N == PWM_Polarity2N_Low)
{
PWM->OMR1 |= PWM_OC2NP_Set;
}
else
{
PWM->OMR1 &= PWM_OC2NP_Reset;
}
}
break;
case PWM_OCNState_Disable:
{
/* OC2N = 0 OSSR = 0 */
PWM->OMR1 &= PWM_OC2N_Disable;
DTR_REG &= PWM_OSSR_Reset;
}
break;
case PWM_OCNState_OffState:
{
/* OC2N = 0 OSSR = 1 and sets the polarity */
PWM->OMR1 &= PWM_OC2N_Disable;
DTR_REG |= PWM_OSSR_Set;
if(PWM_InitStruct->PWM_Polarity2N == PWM_Polarity2N_Low)
{
PWM->OMR1 |= PWM_OC2NP_Set;
}
else
{
PWM->OMR1 &= PWM_OC2NP_Reset;
}
}
break;
}
} /* End not complementary case */
}/* end channel 2 */
/*Channel 3 Configuration-----------------------------------------------------*/
if(PWM_InitStruct->PWM_Channel == PWM_Channel_3)
{
/* PWM Output Complementary Configuration */
if(PWM_InitStruct->PWM_Complementary == PWM_Complementary_Enable)
{
/* Configures Channel 3 on Output Compare mode */
PWM->OMR2 &= PWM_OC3C_Mask;
PWM->OMR2 |= PWM_OCControl|PWM_OC3_Enable|PWM_OC3N_Enable|PWM_PLD3_Set;
PWM->OCR3 = PWM_InitStruct->PWM_Pulse3;
/* Sets the OC3 wave polarity */
if(PWM_InitStruct->PWM_Polarity3 == PWM_Polarity3_Low)
{
PWM->OMR2 |= PWM_OC3P_Set;
}
else
{
PWM->OMR2 &= PWM_OC3P_Reset;
}
/* Sets the OC3N wave polarity */
if(PWM_InitStruct->PWM_Polarity3N == PWM_Polarity3N_Low)
{
PWM->OMR2 |= PWM_OC3NP_Set;
}
else
{
PWM->OMR2 &= PWM_OC3NP_Reset;
}
}/* End complementary case */
else
/* Single PWM Output configuratuion */
{
switch(PWM_InitStruct->PWM_OCState)
{
case PWM_OCState_Enable:
{
/* Configures Channel 3 on Output Compare mode */
PWM->OMR2 &= PWM_OC3C_Mask;
PWM->OMR2 |= PWM_OCControl|PWM_OC3_Enable|PWM_PLD3_Set;
PWM->OCR3 = PWM_InitStruct->PWM_Pulse3;
/* Sets the OCC wave polarity */
if(PWM_InitStruct->PWM_Polarity3 == PWM_Polarity3_Low)
{
PWM->OMR2 |= PWM_OC3P_Set;
}
else
{
PWM->OMR2 &= PWM_OC3P_Reset;
}
}
break;
case PWM_OCState_Disable:
{
/* OC3E = 0 and OSSR = 0 */
PWM->OMR2 &= PWM_OC3_Disable;
DTR_REG &= PWM_OSSR_Reset;
}
break;
case PWM_OCState_OffState:
{
/* OC3E = 0 and OSSR = 1 sets the polarity */
PWM->OMR2 &= PWM_OC3_Disable;
DTR_REG |= PWM_OSSR_Set;
if(PWM_InitStruct->PWM_Polarity3 == PWM_Polarity3_Low)
{
PWM->OMR2 |= PWM_OC3P_Set;
}
else
{
PWM->OMR2 &= PWM_OC3P_Reset;
}
}
break;
}
switch(PWM_InitStruct->PWM_OCNState)
{
case PWM_OCNState_Enable:
{
/* Configures Channel 3N on Output Compare mode */
PWM->OMR2 &= PWM_OC3C_Mask;
PWM->OMR2 |= PWM_OCControl |PWM_OC3N_Enable|PWM_PLD3_Set;
PWM->OCR3 = PWM_InitStruct->PWM_Pulse3;
/* Sets the OC3 wave polarity */
if(PWM_InitStruct->PWM_Polarity3N == PWM_Polarity3N_Low)
{
PWM->OMR2 |= PWM_OC3NP_Set;
}
else
{
PWM->OMR2 &= PWM_OC3NP_Reset;
}
}
break;
case PWM_OCNState_Disable:
{
/* OC3N = 0 OSSR = 0 */
PWM->OMR2 &= PWM_OC3N_Disable;
DTR_REG &= PWM_OSSR_Reset;
}
break;
case PWM_OCNState_OffState:
{
/* OC3N = 0 OSSR = 1 and sets the polarity */
PWM->OMR2 &= PWM_OC3N_Disable;
DTR_REG |= PWM_OSSR_Set;
if(PWM_InitStruct->PWM_Polarity3N == PWM_Polarity3N_Low)
{
PWM->OMR2 |= PWM_OC3NP_Set;
}
else
{
PWM->OMR2 &= PWM_OC3NP_Reset;
}
}
break;
}
} /* End not complementary case */
}/* end channel 3 */
if(PWM_InitStruct->PWM_DTRAccess == PWM_DTRAccess_Enable)
{
DTR_REG |= PWM_InitStruct->PWM_LOCKLevel | PWM_InitStruct->PWM_Emergency |
PWM_InitStruct->PWM_DeadTime | PWM_InitStruct->PWM_OSSIState;
PWM->DTR = DTR_REG;
}
}
/******************* (C) COPYRIGHT 2006 STMicroelectronics *****END OF FILE****/