/**************************************************************************//** * @file epwm_reg.h * @version V1.00 * @brief EPWM register definition header file * * @copyright SPDX-License-Identifier: Apache-2.0 * @copyright Copyright (C) 2020 Nuvoton Technology Corp. All rights reserved. *****************************************************************************/ #ifndef __EPWM_REG_H__ #define __EPWM_REG_H__ /** @addtogroup REGISTER Control Register @{ */ /*---------------------- Enhanced Pulse Width Modulation Controller -------------------------*/ /** @addtogroup EPWM Enhanced Pulse Width Modulation Controller(EPWM) Memory Mapped Structure for EPWM Controller @{ */ typedef struct { /** * @var ECAPDAT_T::RCAPDAT * Offset: 0x20C EPWM Rising Capture Data Register 0~5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |RCAPDAT |EPWM Rising Capture Data (Read Only) * | | |When rising capture condition happened, the EPWM counter value will be saved in this register. * @var ECAPDAT_T::FCAPDAT * Offset: 0x210 EPWM Falling Capture Data Register 0~5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |FCAPDAT |EPWM Falling Capture Data (Read Only) * | | |When falling capture condition happened, the EPWM counter value will be saved in this register. */ __IO uint32_t RCAPDAT; /*!< [0x20C/0x214/0x21C/0x224/0x22C/0x234] EPWM Rising Capture Data Register 0~5 */ __IO uint32_t FCAPDAT; /*!< [0x210/0x218/0x220/0x228/0x230/0x238] EPWM Falling Capture Data Register 0~5 */ } ECAPDAT_T; typedef struct { /** * @var EPWM_T::CTL0 * Offset: 0x00 EPWM Control Register 0 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CTRLD0 |Center Re-load * | | |In up-down counter type, PERIOD0 register will load to PBUF0 register at the end point of each period. * | | |CMPDAT0 register will load to CMPBUF0 register at the center point of a period. * |[1] |CTRLD1 |Center Re-load * | | |In up-down counter type, PERIOD1 register will load to PBUF1 register at the end point of each period. * | | |CMPDAT1 register will load to CMPBUF1 register at the center point of a period. * |[2] |CTRLD2 |Center Re-load * | | |In up-down counter type, PERIOD2 register will load to PBUF2 register at the end point of each period. * | | |CMPDAT2 register will load to CMPBUF2 register at the center point of a period. * |[3] |CTRLD3 |Center Re-load * | | |In up-down counter type, PERIOD3 register will load to PBUF3 register at the end point of each period. * | | |CMPDAT3 register will load to CMPBUF3 register at the center point of a period. * |[4] |CTRLD4 |Center Re-load * | | |In up-down counter type, PERIOD4 register will load to PBUF4 register at the end point of each period. * | | |CMPDAT4 register will load to CMPBUF4 register at the center point of a period. * |[5] |CTRLD5 |Center Re-load * | | |In up-down counter type, PERIOD5 register will load to PBUF5 register at the end point of each period. * | | |CMPDAT5 register will load to CMPBUF5 register at the center point of a period. * |[8] |WINLDEN0 |Window Load Enable Bits * | | |0 = PERIOD0 register will load to PBUF0 register at the end point of each period. * | | |CMPDAT0 register will load to CMPBUF0 register at the end point or center point of each period by setting CTRLD0 bit. * | | |1 = PERIOD0 register will load to PBUF0 and CMPDAT0 registers will load to CMPBUF0 register at the end point of each period when valid reload window is set. * | | |The valid reload window is set by software write 1 to EPWM_LOAD register, and cleared by hardware after load success. * |[9] |WINLDEN1 |Window Load Enable Bits * | | |0 = PERIOD1 register will load to PBUF1 register at the end point of each period. * | | |CMPDAT1 register will load to CMPBUF1 register at the end point or center point of each period by setting CTRLD1 bit. * | | |1 = PERIOD1 register will load to PBUF1 and CMPDAT1 registers will load to CMPBUF1 register at the end point of each period when valid reload window is set. * | | |The valid reload window is set by software write 1 to EPWM_LOAD register, and cleared by hardware after load success. * |[10] |WINLDEN2 |Window Load Enable Bits * | | |0 = PERIOD2 register will load to PBUF2 register at the end point of each period. * | | |CMPDAT2 register will load to CMPBUF2 register at the end point or center point of each period by setting CTRLD2 bit. * | | |1 = PERIOD2 register will load to PBUF2 and CMPDAT2 registers will load to CMPBUF2 register at the end point of each period when valid reload window is set. * | | |The valid reload window is set by software write 1 to EPWM_LOAD register, and cleared by hardware after load success. * |[11] |WINLDEN3 |Window Load Enable Bits * | | |0 = PERIOD3 register will load to PBUF3 register at the end point of each period. * | | |CMPDAT3 register will load to CMPBUF3 register at the end point or center point of each period by setting CTRLD3 bit. * | | |1 = PERIOD3 register will load to PBUF3 and CMPDAT3 registers will load to CMPBUF3 register at the end point of each period when valid reload window is set. * | | |The valid reload window is set by software write 1 to EPWM_LOAD register, and cleared by hardware after load success. * |[12] |WINLDEN4 |Window Load Enable Bits * | | |0 = PERIOD4 register will load to PBUF4 register at the end point of each period. * | | |CMPDAT4 register will load to CMPBUF4 register at the end point or center point of each period by setting CTRLD4 bit. * | | |1 = PERIOD4 register will load to PBUF4 and CMPDAT4 registers will load to CMPBUF4 register at the end point of each period when valid reload window is set. * | | |The valid reload window is set by software write 1 to EPWM_LOAD register, and cleared by hardware after load success. * |[13] |WINLDEN5 |Window Load Enable Bits * | | |0 = PERIOD5 register will load to PBUF5 register at the end point of each period. * | | |CMPDAT5 register will load to CMPBUF5 register at the end point or center point of each period by setting CTRLD5 bit. * | | |1 = PERIOD5 register will load to PBUF5 and CMPDAT5 registers will load to CMPBUF5 register at the end point of each period when valid reload window is set. * | | |The valid reload window is set by software write 1 to EPWM_LOAD register, and cleared by hardware after load success. * |[16] |IMMLDEN0 |Immediately Load Enable Bits * | | |0 = PERIOD0 register will load to PBUF0 register at the end point of each period. * | | |CMPDAT0 register will load to CMPBUF0 register at the end point or center point of each period by setting CTRLD0 bit. * | | |1 = PERIOD0/CMPDAT0 registers will load to PBUF0 and CMPBUF0 register immediately when software update PERIOD0/CMPDAT0 register. * | | |Note: If IMMLDEN0 bit is enabled, WINLDEN0 bit and CTRLD0 bits will be invalid. * |[17] |IMMLDEN1 |Immediately Load Enable Bits * | | |0 = PERIOD1 register will load to PBUF1 register at the end point of each period. * | | |CMPDAT1 register will load to CMPBUF1 register at the end point or center point of each period by setting CTRLD1 bit. * | | |1 = PERIOD1/CMPDAT1 registers will load to PBUF1 and CMPBUF1 register immediately when software update PERIOD1/CMPDAT1 register. * | | |Note: If IMMLDEN1 bit is enabled, WINLDEN1 bit and CTRLD1 bits will be invalid. * |[18] |IMMLDEN2 |Immediately Load Enable Bits * | | |0 = PERIOD2 register will load to PBUF2 register at the end point of each period. * | | |CMPDAT2 register will load to CMPBUF2 register at the end point or center point of each period by setting CTRLD2 bit. * | | |1 = PERIOD2/CMPDAT2 registers will load to PBUF2 and CMPBUF2 register immediately when software update PERIOD2/CMPDAT2 register. * | | |Note: If IMMLDEN2 bit is enabled, WINLDEN2 bit and CTRLD2 bits will be invalid. * |[19] |IMMLDEN3 |Immediately Load Enable Bits * | | |0 = PERIOD3 register will load to PBUF3 register at the end point of each period. * | | |CMPDAT3 register will load to CMPBUF3 register at the end point or center point of each period by setting CTRLD3 bit. * | | |1 = PERIOD3/CMPDAT3 registers will load to PBUF3 and CMPBUF3 register immediately when software update PERIOD3/CMPDAT3 register. * | | |Note: If IMMLDEN3 bit is enabled, WINLDEN3 bit and CTRLD3 bits will be invalid. * |[20] |IMMLDEN4 |Immediately Load Enable Bits * | | |0 = PERIOD4 register will load to PBUF4 register at the end point of each period. * | | |CMPDAT4 register will load to CMPBUF4 register at the end point or center point of each period by setting CTRLD4 bit. * | | |1 = PERIOD4/CMPDAT4 registers will load to PBUF4 and CMPBUF4 register immediately when software update PERIOD4/CMPDAT4 register. * | | |Note: If IMMLDEN4 bit is enabled, WINLDEN4 bit and CTRLD4 bits will be invalid. * |[21] |IMMLDEN5 |Immediately Load Enable Bits * | | |0 = PERIOD5 register will load to PBUF5 register at the end point of each period. * | | |CMPDAT5 register will load to CMPBUF5 register at the end point or center point of each period by setting CTRLD5 bit. * | | |1 = PERIOD5/CMPDAT5 registers will load to PBUF5 and CMPBUF5 register immediately when software update PERIOD5/CMPDAT5 register. * | | |Note: If IMMLDEN5 bit is enabled, WINLDEN5 bit and CTRLD5 bits will be invalid. * |[24] |GROUPEN |Group Function Enable Bit * | | |0 = The output waveform of each EPWM channel are independent. * | | |1 = Unify the EPWMx_CH2 and EPWMx_CH4 to output the same waveform as EPWMx_CH0 and unify the EPWMx_CH3 and EPWMx_CH5 to output the same waveform as EPWMx_CH1. * |[30] |DBGHALT |ICE Debug Mode Counter Halt (Write Protect) * | | |If counter halt is enabled, EPWM all counters will keep current value until exit ICE debug mode. * | | |0 = ICE debug mode counter halt disable. * | | |1 = ICE debug mode counter halt enable. * | | |Note: This register is write protected. Refer toSYS_REGLCTL register. * |[31] |DBGTRIOFF |ICE Debug Mode Acknowledge Disable (Write Protect) * | | |0 = ICE debug mode acknowledgement effects EPWM output. * | | |EPWM pin will be forced as tri-state while ICE debug mode acknowledged. * | | |1 = ICE debug mode acknowledgement disabled. * | | |EPWM pin will keep output no matter ICE debug mode acknowledged or not. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * @var EPWM_T::CTL1 * Offset: 0x04 EPWM Control Register 1 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[1:0] |CNTTYPE0 |EPWM Counter Behavior Type * | | |00 = Up counter type (supports in capture mode). * | | |01 = Down count type (supports in capture mode). * | | |10 = Up-down counter type. * | | |11 = Reserved. * |[3:2] |CNTTYPE1 |EPWM Counter Behavior Type * | | |00 = Up counter type (supports in capture mode). * | | |01 = Down count type (supports in capture mode). * | | |10 = Up-down counter type. * | | |11 = Reserved. * |[5:4] |CNTTYPE2 |EPWM Counter Behavior Type * | | |00 = Up counter type (supports in capture mode). * | | |01 = Down count type (supports in capture mode). * | | |10 = Up-down counter type. * | | |11 = Reserved. * |[7:6] |CNTTYPE3 |EPWM Counter Behavior Type * | | |00 = Up counter type (supports in capture mode). * | | |01 = Down count type (supports in capture mode). * | | |10 = Up-down counter type. * | | |11 = Reserved. * |[9:8] |CNTTYPE4 |EPWM Counter Behavior Type * | | |00 = Up counter type (supports in capture mode). * | | |01 = Down count type (supports in capture mode). * | | |10 = Up-down counter type. * | | |11 = Reserved. * |[11:10] |CNTTYPE5 |EPWM Counter Behavior Type * | | |00 = Up counter type (supports in capture mode). * | | |01 = Down count type (supports in capture mode). * | | |10 = Up-down counter type. * | | |11 = Reserved. * |[16] |CNTMODE0 |EPWM Counter Mode * | | |0 = Auto-reload mode. * | | |1 = One-shot mode. * |[17] |CNTMODE1 |EPWM Counter Mode * | | |0 = Auto-reload mode. * | | |1 = One-shot mode. * |[18] |CNTMODE2 |EPWM Counter Mode * | | |0 = Auto-reload mode. * | | |1 = One-shot mode. * |[19] |CNTMODE3 |EPWM Counter Mode * | | |0 = Auto-reload mode. * | | |1 = One-shot mode. * |[20] |CNTMODE4 |EPWM Counter Mode * | | |0 = Auto-reload mode. * | | |1 = One-shot mode. * |[21] |CNTMODE5 |EPWM Counter Mode * | | |0 = Auto-reload mode. * | | |1 = One-shot mode. * |[24] |OUTMODE0 |EPWM Output Mode * | | |Each bit n controls the output mode of corresponding EPWM channel n. * | | |0 = EPWM independent mode. * | | |1 = EPWM complementary mode. * | | |Note: When operating in group function, these bits must all set to the same mode. * |[25] |OUTMODE2 |EPWM Output Mode * | | |Each bit n controls the output mode of corresponding EPWM channel n. * | | |0 = EPWM independent mode. * | | |1 = EPWM complementary mode. * | | |Note: When operating in group function, these bits must all set to the same mode. * |[26] |OUTMODE4 |EPWM Output Mode * | | |Each bit n controls the output mode of corresponding EPWM channel n. * | | |0 = EPWM independent mode. * | | |1 = EPWM complementary mode. * | | |Note: When operating in group function, these bits must all set to the same mode. * @var EPWM_T::SYNC * Offset: 0x08 EPWM Synchronization Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |PHSEN0 |SYNC Phase Enable Bits * | | |0 = EPWM counter disable to load PHS value. * | | |1 = EPWM counter enable to load PHS value. * |[1] |PHSEN2 |SYNC Phase Enable Bits * | | |0 = EPWM counter disable to load PHS value. * | | |1 = EPWM counter enable to load PHS value. * |[2] |PHSEN4 |SYNC Phase Enable Bits * | | |0 = EPWM counter disable to load PHS value. * | | |1 = EPWM counter enable to load PHS value. * |[9:8] |SINSRC0 |EPWM0_SYNC_IN Source Selection * | | |00 = Synchronize source from SYNC_IN or SWSYNC. * | | |01 = Counter equal to 0. * | | |10 = Counter equal to EPWM_CMPDATm, m denotes 1, 3, 5. * | | |11 = SYNC_OUT will not be generated. * |[11:10] |SINSRC2 |EPWM0_SYNC_IN Source Selection * | | |00 = Synchronize source from SYNC_IN or SWSYNC. * | | |01 = Counter equal to 0. * | | |10 = Counter equal to EPWM_CMPDATm, m denotes 1, 3, 5. * | | |11 = SYNC_OUT will not be generated. * |[13:12] |SINSRC4 |EPWM0_SYNC_IN Source Selection * | | |00 = Synchronize source from SYNC_IN or SWSYNC. * | | |01 = Counter equal to 0. * | | |10 = Counter equal to EPWM_CMPDATm, m denotes 1, 3, 5. * | | |11 = SYNC_OUT will not be generated. * |[16] |SNFLTEN |EPWM0_SYNC_IN Noise Filter Enable Bits * | | |0 = Noise filter of input pin EPWM0_SYNC_IN is Disabled. * | | |1 = Noise filter of input pin EPWM0_SYNC_IN is Enabled. * |[19:17] |SFLTCSEL |SYNC Edge Detector Filter Clock Selection * | | |000 = Filter clock = HCLK. * | | |001 = Filter clock = HCLK/2. * | | |010 = Filter clock = HCLK/4. * | | |011 = Filter clock = HCLK/8. * | | |100 = Filter clock = HCLK/16. * | | |101 = Filter clock = HCLK/32. * | | |110 = Filter clock = HCLK/64. * | | |111 = Filter clock = HCLK/128. * |[22:20] |SFLTCNT |SYNC Edge Detector Filter Count * | | |The register bits control the counter number of edge detector. * |[23] |SINPINV |SYNC Input Pin Inverse * | | |0 = The state of pin EPWM0_SYNC_IN is passed to the negative edge detector. * | | |1 = The inverse state of pin EPWM0_SYNC_IN is passed to the negative edge detector. * |[24] |PHSDIR0 |EPWM Phase Direction Control * | | |0 = Control EPWM counter count decrement after synchronizing. * | | |1 = Control EPWM counter count increment after synchronizing. * |[25] |PHSDIR2 |EPWM Phase Direction Control * | | |0 = Control EPWM counter count decrement after synchronizing. * | | |1 = Control EPWM counter count increment after synchronizing. * |[26] |PHSDIR4 |EPWM Phase Direction Control * | | |0 = Control EPWM counter count decrement after synchronizing. * | | |1 = Control EPWM counter count increment after synchronizing. * @var EPWM_T::SWSYNC * Offset: 0x0C EPWM Software Control Synchronization Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |SWSYNC0 |Software SYNC Function * | | |When SINSRCn (EPWM_SYNC[13:8]) is selected to 0, SYNC_OUT source is come from SYNC_IN or this bit. * |[1] |SWSYNC2 |Software SYNC Function * | | |When SINSRCn (EPWM_SYNC[13:8]) is selected to 0, SYNC_OUT source is come from SYNC_IN or this bit. * |[2] |SWSYNC4 |Software SYNC Function * | | |When SINSRCn (EPWM_SYNC[13:8]) is selected to 0, SYNC_OUT source is come from SYNC_IN or this bit. * @var EPWM_T::CLKSRC * Offset: 0x10 EPWM Clock Source Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[2:0] |ECLKSRC0 |EPWM_CH01 External Clock Source Select * | | |000 = EPWMx_CLK, x denotes 0 or 1. * | | |001 = TIMER0 overflow. * | | |010 = TIMER1 overflow. * | | |011 = TIMER2 overflow. * | | |100 = TIMER3 overflow. * | | |Others = Reserved. * |[10:8] |ECLKSRC2 |EPWM_CH23 External Clock Source Select * | | |000 = EPWMx_CLK, x denotes 0 or 1. * | | |001 = TIMER0 overflow. * | | |010 = TIMER1 overflow. * | | |011 = TIMER2 overflow. * | | |100 = TIMER3 overflow. * | | |Others = Reserved. * |[18:16] |ECLKSRC4 |EPWM_CH45 External Clock Source Select * | | |000 = EPWMx_CLK, x denotes 0 or 1. * | | |001 = TIMER0 overflow. * | | |010 = TIMER1 overflow. * | | |011 = TIMER2 overflow. * | | |100 = TIMER3 overflow. * | | |Others = Reserved. * @var EPWM_T::CLKPSC[3] * Offset: 0x14 EPWM Clock Prescale Register 0/1, 2/3, 4/5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[11:0] |CLKPSC |EPWM Counter Clock Prescale * | | |The clock of EPWM counter is decided by clock prescaler * | | |Each EPWM pair share one EPWM counter clock prescaler * | | |The clock of EPWM counter is divided by (CLKPSC+ 1) * @var EPWM_T::CNTEN * Offset: 0x20 EPWM Counter Enable Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CNTEN0 |EPWM Counter Enable Bits * | | |0 = EPWM Counter and clock prescaler Stop Running. * | | |1 = EPWM Counter and clock prescaler Start Running. * |[1] |CNTEN1 |EPWM Counter Enable Bits * | | |0 = EPWM Counter and clock prescaler Stop Running. * | | |1 = EPWM Counter and clock prescaler Start Running. * |[2] |CNTEN2 |EPWM Counter Enable Bits * | | |0 = EPWM Counter and clock prescaler Stop Running. * | | |1 = EPWM Counter and clock prescaler Start Running. * |[3] |CNTEN3 |EPWM Counter Enable Bits * | | |0 = EPWM Counter and clock prescaler Stop Running. * | | |1 = EPWM Counter and clock prescaler Start Running. * |[4] |CNTEN4 |EPWM Counter Enable Bits * | | |0 = EPWM Counter and clock prescaler Stop Running. * | | |1 = EPWM Counter and clock prescaler Start Running. * |[5] |CNTEN5 |EPWM Counter Enable Bits * | | |0 = EPWM Counter and clock prescaler Stop Running. * | | |1 = EPWM Counter and clock prescaler Start Running. * @var EPWM_T::CNTCLR * Offset: 0x24 EPWM Clear Counter Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CNTCLR0 |Clear EPWM Counter Control Bit * | | |It is automatically cleared by hardware. * | | |0 = No effect. * | | |1 = Clear 16-bit EPWM counter to 0000H. * |[1] |CNTCLR1 |Clear EPWM Counter Control Bit * | | |It is automatically cleared by hardware. * | | |0 = No effect. * | | |1 = Clear 16-bit EPWM counter to 0000H. * |[2] |CNTCLR2 |Clear EPWM Counter Control Bit * | | |It is automatically cleared by hardware. * | | |0 = No effect. * | | |1 = Clear 16-bit EPWM counter to 0000H. * |[3] |CNTCLR3 |Clear EPWM Counter Control Bit * | | |It is automatically cleared by hardware. * | | |0 = No effect. * | | |1 = Clear 16-bit EPWM counter to 0000H. * |[4] |CNTCLR4 |Clear EPWM Counter Control Bit * | | |It is automatically cleared by hardware. * | | |0 = No effect. * | | |1 = Clear 16-bit EPWM counter to 0000H. * |[5] |CNTCLR5 |Clear EPWM Counter Control Bit * | | |It is automatically cleared by hardware. * | | |0 = No effect. * | | |1 = Clear 16-bit EPWM counter to 0000H. * @var EPWM_T::LOAD * Offset: 0x28 EPWM Load Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |LOAD0 |Re-load EPWM Comparator Register (CMPDAT) Control Bit * | | |This bit is software write, hardware clear when current EPWM period end. * | | |Write Operation: * | | |0 = No effect. * | | |1 = Set load window of window loading mode. * | | |Read Operation: * | | |0 = No load window is set. * | | |1 = Load window is set. * | | |Note: This bit only use in window loading mode, WINLDEN0(EPWM_CTL0[13:8]) = 1. * |[1] |LOAD1 |Re-load EPWM Comparator Register (CMPDAT) Control Bit * | | |This bit is software write, hardware clear when current EPWM period end. * | | |Write Operation: * | | |0 = No effect. * | | |1 = Set load window of window loading mode. * | | |Read Operation: * | | |0 = No load window is set. * | | |1 = Load window is set. * | | |Note: This bit only use in window loading mode, WINLDEN1(EPWM_CTL0[13:8]) = 1. * |[2] |LOAD2 |Re-load EPWM Comparator Register (CMPDAT) Control Bit * | | |This bit is software write, hardware clear when current EPWM period end. * | | |Write Operation: * | | |0 = No effect. * | | |1 = Set load window of window loading mode. * | | |Read Operation: * | | |0 = No load window is set. * | | |1 = Load window is set. * | | |Note: This bit only use in window loading mode, WINLDEN2(EPWM_CTL0[13:8]) = 1. * |[3] |LOAD3 |Re-load EPWM Comparator Register (CMPDAT) Control Bit * | | |This bit is software write, hardware clear when current EPWM period end. * | | |Write Operation: * | | |0 = No effect. * | | |1 = Set load window of window loading mode. * | | |Read Operation: * | | |0 = No load window is set. * | | |1 = Load window is set. * | | |Note: This bit only use in window loading mode, WINLDEN3(EPWM_CTL0[13:8]) = 1. * |[4] |LOAD4 |Re-load EPWM Comparator Register (CMPDAT) Control Bit * | | |This bit is software write, hardware clear when current EPWM period end. * | | |Write Operation: * | | |0 = No effect. * | | |1 = Set load window of window loading mode. * | | |Read Operation: * | | |0 = No load window is set. * | | |1 = Load window is set. * | | |Note: This bit only use in window loading mode, WINLDEN4(EPWM_CTL0[13:8]) = 1. * |[5] |LOAD5 |Re-load EPWM Comparator Register (CMPDAT) Control Bit * | | |This bit is software write, hardware clear when current EPWM period end. * | | |Write Operation: * | | |0 = No effect. * | | |1 = Set load window of window loading mode. * | | |Read Operation: * | | |0 = No load window is set. * | | |1 = Load window is set. * | | |Note: This bit only use in window loading mode, WINLDENn(EPWM_CTL0[13:8]) = 1. * @var EPWM_T::PERIOD[6] * Offset: 0x30 EPWM Period Register 0~5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |PERIOD |EPWM Period Register * | | |Up-Count mode: In this mode, EPWM counter counts from 0 to PERIOD, and restarts from 0. * | | |Down-Count mode: In this mode, EPWM counter counts from PERIOD to 0, and restarts from PERIOD. * | | |EPWM period time = (PERIOD+1) * EPWM_CLK period. * | | |Up-Down-Count mode: In this mode, EPWM counter counts from 0 to PERIOD, then decrements to 0 and repeats again. * | | |EPWM period time = 2 * PERIOD * EPWM_CLK period. * @var EPWM_T::CMPDAT[6] * Offset: 0x50 EPWM Comparator Register 0 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |CMP |EPWM Comparator Register * | | |CMP use to compare with CNTR to generate EPWM waveform, interrupt and trigger EADC/DAC. * | | |In independent mode, CMPDAT0~5 denote as 6 independent EPWM_CH0~5 compared point. * | | |In complementary mode, CMPDAT0, 2, 4 denote as first compared point, and CMPDAT1, 3, 5 denote as second compared point for the corresponding 3 complementary pairs EPWM_CH0 and EPWM_CH1, EPWM_CH2 and EPWM_CH3, EPWM_CH4 and EPWM_CH5. * @var EPWM_T::DTCTL[3] * Offset: 0x70 EPWM Dead-Time Control Register 0/1,2/3,4/5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[11:0] |DTCNT |Dead-time Counter (Write Protect) * | | |The dead-time can be calculated from the following formula: * | | |Dead-time = (DTCNT[11:0]+1) * EPWM_CLK period. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[16] |DTEN |Enable Dead-time Insertion for EPWM Pair (EPWM_CH0, EPWM_CH1) (EPWM_CH2, EPWM_CH3) (EPWM_CH4, EPWM_CH5) (Write Protect) * | | |Dead-time insertion is only active when this pair of complementary EPWM is enabled * | | |If dead- time insertion is inactive, the outputs of pin pair are complementary without any delay. * | | |0 = Dead-time insertion Disabled on the pin pair. * | | |1 = Dead-time insertion Enabled on the pin pair. * | | |Note: This register is write protected. Refer toSYS_REGLCTL register. * |[24] |DTCKSEL |Dead-time Clock Select (Write Protect) * | | |0 = Dead-time clock source from EPWM_CLK. * | | |1 = Dead-time clock source from prescaler output. * | | |Note: This register is write protected. Refer toREGWRPROT register. * @var EPWM_T::PHS[3] * Offset: 0x80 EPWM Counter Phase Register 0/1,2/3,4/5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |PHS |EPWM Synchronous Start Phase Bits * | | |PHS determines the EPWM synchronous start phase value. These bits only use in synchronous function. * @var EPWM_T::CNT[6] * Offset: 0x90 EPWM Counter Register 0~5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |CNT |EPWM Data Register (Read Only) * | | |User can monitor CNTR to know the current value in 16-bit period counter. * |[16] |DIRF |EPWM Direction Indicator Flag (Read Only) * | | |0 = Counter is Down count. * | | |1 = Counter is UP count. * @var EPWM_T::WGCTL0 * Offset: 0xB0 EPWM Generation Register 0 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[1:0] |ZPCTL0 |EPWM Zero Point Control * | | |00 = Do nothing. * | | |01 = EPWM zero point output Low. * | | |10 = EPWM zero point output High. * | | |11 = EPWM zero point output Toggle. * | | |EPWM can control output level when EPWM counter count to zero. * |[3:2] |ZPCTL1 |EPWM Zero Point Control * | | |00 = Do nothing. * | | |01 = EPWM zero point output Low. * | | |10 = EPWM zero point output High. * | | |11 = EPWM zero point output Toggle. * | | |EPWM can control output level when EPWM counter count to zero. * |[5:4] |ZPCTL2 |EPWM Zero Point Control * | | |00 = Do nothing. * | | |01 = EPWM zero point output Low. * | | |10 = EPWM zero point output High. * | | |11 = EPWM zero point output Toggle. * | | |EPWM can control output level when EPWM counter count to zero. * |[7:6] |ZPCTL3 |EPWM Zero Point Control * | | |00 = Do nothing. * | | |01 = EPWM zero point output Low. * | | |10 = EPWM zero point output High. * | | |11 = EPWM zero point output Toggle. * | | |EPWM can control output level when EPWM counter count to zero. * |[9:8] |ZPCTL4 |EPWM Zero Point Control * | | |00 = Do nothing. * | | |01 = EPWM zero point output Low. * | | |10 = EPWM zero point output High. * | | |11 = EPWM zero point output Toggle. * | | |EPWM can control output level when EPWM counter count to zero. * |[11:10] |ZPCTL5 |EPWM Zero Point Control * | | |00 = Do nothing. * | | |01 = EPWM zero point output Low. * | | |10 = EPWM zero point output High. * | | |11 = EPWM zero point output Toggle. * | | |EPWM can control output level when EPWM counter count to zero. * |[17:16] |PRDPCTL0 |EPWM Period (Center) Point Control * | | |00 = Do nothing. * | | |01 = EPWM period (center) point output Low. * | | |10 = EPWM period (center) point output High. * | | |11 = EPWM period (center) point output Toggle. * | | |EPWM can control output level when EPWM counter count to (PERIOD0+1). * | | |Note: This bit is center point control when EPWM counter operating in up-down counter type. * |[19:18] |PRDPCTL1 |EPWM Period (Center) Point Control * | | |00 = Do nothing. * | | |01 = EPWM period (center) point output Low. * | | |10 = EPWM period (center) point output High. * | | |11 = EPWM period (center) point output Toggle. * | | |EPWM can control output level when EPWM counter count to (PERIOD1+1). * | | |Note: This bit is center point control when EPWM counter operating in up-down counter type. * |[21:20] |PRDPCTL2 |EPWM Period (Center) Point Control * | | |00 = Do nothing. * | | |01 = EPWM period (center) point output Low. * | | |10 = EPWM period (center) point output High. * | | |11 = EPWM period (center) point output Toggle. * | | |EPWM can control output level when EPWM counter count to (PERIOD2+1). * | | |Note: This bit is center point control when EPWM counter operating in up-down counter type. * |[23:22] |PRDPCTL3 |EPWM Period (Center) Point Control * | | |00 = Do nothing. * | | |01 = EPWM period (center) point output Low. * | | |10 = EPWM period (center) point output High. * | | |11 = EPWM period (center) point output Toggle. * | | |EPWM can control output level when EPWM counter count to (PERIOD3+1). * | | |Note: This bit is center point control when EPWM counter operating in up-down counter type. * |[25:24] |PRDPCTL4 |EPWM Period (Center) Point Control * | | |00 = Do nothing. * | | |01 = EPWM period (center) point output Low. * | | |10 = EPWM period (center) point output High. * | | |11 = EPWM period (center) point output Toggle. * | | |EPWM can control output level when EPWM counter count to (PERIOD4+1). * | | |Note: This bit is center point control when EPWM counter operating in up-down counter type. * |[27:26] |PRDPCTL5 |EPWM Period (Center) Point Control * | | |00 = Do nothing. * | | |01 = EPWM period (center) point output Low. * | | |10 = EPWM period (center) point output High. * | | |11 = EPWM period (center) point output Toggle. * | | |EPWM can control output level when EPWM counter count to (PERIOD5+1). * | | |Note: This bit is center point control when EPWM counter operating in up-down counter type. * @var EPWM_T::WGCTL1 * Offset: 0xB4 EPWM Generation Register 1 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[1:0] |CMPUCTL0 |EPWM Compare Up Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare up point output Low. * | | |10 = EPWM compare up point output High. * | | |11 = EPWM compare up point output Toggle. * | | |EPWM can control output level when EPWM counter up count to CMPDAT. * | | |Note: In complementary mode, CMPUCTL1, 3, 5 use as another CMPUCTL for channel 0, 2, 4. * |[3:2] |CMPUCTL1 |EPWM Compare Up Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare up point output Low. * | | |10 = EPWM compare up point output High. * | | |11 = EPWM compare up point output Toggle. * | | |EPWM can control output level when EPWM counter up count to CMPDAT. * | | |Note: In complementary mode, CMPUCTL1, 3, 5 use as another CMPUCTL for channel 0, 2, 4. * |[5:4] |CMPUCTL2 |EPWM Compare Up Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare up point output Low. * | | |10 = EPWM compare up point output High. * | | |11 = EPWM compare up point output Toggle. * | | |EPWM can control output level when EPWM counter up count to CMPDAT. * | | |Note: In complementary mode, CMPUCTL1, 3, 5 use as another CMPUCTL for channel 0, 2, 4. * |[7:6] |CMPUCTL3 |EPWM Compare Up Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare up point output Low. * | | |10 = EPWM compare up point output High. * | | |11 = EPWM compare up point output Toggle. * | | |EPWM can control output level when EPWM counter up count to CMPDAT. * | | |Note: In complementary mode, CMPUCTL1, 3, 5 use as another CMPUCTL for channel 0, 2, 4. * |[9:8] |CMPUCTL4 |EPWM Compare Up Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare up point output Low. * | | |10 = EPWM compare up point output High. * | | |11 = EPWM compare up point output Toggle. * | | |EPWM can control output level when EPWM counter up count to CMPDAT. * | | |Note: In complementary mode, CMPUCTL1, 3, 5 use as another CMPUCTL for channel 0, 2, 4. * |[11:10] |CMPUCTL5 |EPWM Compare Up Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare up point output Low. * | | |10 = EPWM compare up point output High. * | | |11 = EPWM compare up point output Toggle. * | | |EPWM can control output level when EPWM counter up count to CMPDAT. * | | |Note: In complementary mode, CMPUCTL1, 3, 5 use as another CMPUCTL for channel 0, 2, 4. * |[17:16] |CMPDCTL0 |EPWM Compare Down Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare down point output Low. * | | |10 = EPWM compare down point output High. * | | |11 = EPWM compare down point output Toggle. * | | |EPWM can control output level when EPWM counter down count to CMPDAT. * | | |Note: In complementary mode, CMPDCTL1, 3, 5 use as another CMPDCTL for channel 0, 2, 4. * |[19:18] |CMPDCTL1 |EPWM Compare Down Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare down point output Low. * | | |10 = EPWM compare down point output High. * | | |11 = EPWM compare down point output Toggle. * | | |EPWM can control output level when EPWM counter down count to CMPDAT. * | | |Note: In complementary mode, CMPDCTL1, 3, 5 use as another CMPDCTL for channel 0, 2, 4. * |[21:20] |CMPDCTL2 |EPWM Compare Down Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare down point output Low. * | | |10 = EPWM compare down point output High. * | | |11 = EPWM compare down point output Toggle. * | | |EPWM can control output level when EPWM counter down count to CMPDAT. * | | |Note: In complementary mode, CMPDCTL1, 3, 5 use as another CMPDCTL for channel 0, 2, 4. * |[23:22] |CMPDCTL3 |EPWM Compare Down Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare down point output Low. * | | |10 = EPWM compare down point output High. * | | |11 = EPWM compare down point output Toggle. * | | |EPWM can control output level when EPWM counter down count to CMPDAT. * | | |Note: In complementary mode, CMPDCTL1, 3, 5 use as another CMPDCTL for channel 0, 2, 4. * |[25:24] |CMPDCTL4 |EPWM Compare Down Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare down point output Low. * | | |10 = EPWM compare down point output High. * | | |11 = EPWM compare down point output Toggle. * | | |EPWM can control output level when EPWM counter down count to CMPDAT. * | | |Note: In complementary mode, CMPDCTL1, 3, 5 use as another CMPDCTL for channel 0, 2, 4. * |[27:26] |CMPDCTL5 |EPWM Compare Down Point Control * | | |00 = Do nothing. * | | |01 = EPWM compare down point output Low. * | | |10 = EPWM compare down point output High. * | | |11 = EPWM compare down point output Toggle. * | | |EPWM can control output level when EPWM counter down count to CMPDAT. * | | |Note: In complementary mode, CMPDCTL1, 3, 5 use as another CMPDCTL for channel 0, 2, 4. * @var EPWM_T::MSKEN * Offset: 0xB8 EPWM Mask Enable Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |MSKEN0 |EPWM Mask Enable Bits * | | |The EPWM output signal will be masked when this bit is enabled. * | | |The corresponding EPWM channel 0 will output MSKDAT0 (EPWM_MSK[5:0]) data. * | | |0 = EPWM output signal is non-masked. * | | |1 = EPWM output signal is masked and output MSKDAT0 data. * |[1] |MSKEN1 |EPWM Mask Enable Bits * | | |The EPWM output signal will be masked when this bit is enabled. * | | |The corresponding EPWM channel 1 will output MSKDAT1 (EPWM_MSK[5:0]) data. * | | |0 = EPWM output signal is non-masked. * | | |1 = EPWM output signal is masked and output MSKDAT1 data. * |[2] |MSKEN2 |EPWM Mask Enable Bits * | | |The EPWM output signal will be masked when this bit is enabled. * | | |The corresponding EPWM channel 2 will output MSKDAT2 (EPWM_MSK[5:0]) data. * | | |0 = EPWM output signal is non-masked. * | | |1 = EPWM output signal is masked and output MSKDAT2 data. * |[3] |MSKEN3 |EPWM Mask Enable Bits * | | |The EPWM output signal will be masked when this bit is enabled. * | | |The corresponding EPWM channel 3 will output MSKDAT3 (EPWM_MSK[5:0]) data. * | | |0 = EPWM output signal is non-masked. * | | |1 = EPWM output signal is masked and output MSKDAT3 data. * |[4] |MSKEN4 |EPWM Mask Enable Bits * | | |The EPWM output signal will be masked when this bit is enabled. * | | |The corresponding EPWM channel 4 will output MSKDAT4 (EPWM_MSK[5:0]) data. * | | |0 = EPWM output signal is non-masked. * | | |1 = EPWM output signal is masked and output MSKDAT4 data. * |[5] |MSKEN5 |EPWM Mask Enable Bits * | | |The EPWM output signal will be masked when this bit is enabled. * | | |The corresponding EPWM channel 5 will output MSKDAT5 (EPWM_MSK[5:0]) data. * | | |0 = EPWM output signal is non-masked. * | | |1 = EPWM output signal is masked and output MSKDAT5 data. * @var EPWM_T::MSK * Offset: 0xBC EPWM Mask Data Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |MSKDAT0 |EPWM Mask Data Bit * | | |This data bit control the state of EPWM_CH0 output pin, if corresponding mask function is enabled. * | | |0 = Output logic low to EPWM_CH0. * | | |1 = Output logic high to EPWM_CH0. * |[1] |MSKDAT1 |EPWM Mask Data Bit * | | |This data bit control the state of EPWM_CH1 output pin, if corresponding mask function is enabled. * | | |0 = Output logic low to EPWM_CH1. * | | |1 = Output logic high to EPWM_CH1. * |[2] |MSKDAT2 |EPWM Mask Data Bit * | | |This data bit control the state of EPWM_CH2 output pin, if corresponding mask function is enabled. * | | |0 = Output logic low to EPWM_CH2. * | | |1 = Output logic high to EPWM_CH2. * |[3] |MSKDAT3 |EPWM Mask Data Bit * | | |This data bit control the state of EPWM_CH3 output pin, if corresponding mask function is enabled. * | | |0 = Output logic low to EPWM_CH3. * | | |1 = Output logic high to EPWM_CH3. * |[4] |MSKDAT4 |EPWM Mask Data Bit * | | |This data bit control the state of EPWM_CH4 output pin, if corresponding mask function is enabled. * | | |0 = Output logic low to EPWM_CH4. * | | |1 = Output logic high to EPWM_CH4. * |[5] |MSKDAT5 |EPWM Mask Data Bit * | | |This data bit control the state of EPWM_CH5 output pin, if corresponding mask function is enabled. * | | |0 = Output logic low to EPWM_CH5. * | | |1 = Output logic high to EPWM_CH5. * @var EPWM_T::BNF * Offset: 0xC0 EPWM Brake Noise Filter Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |BRK0NFEN |EPWM Brake 0 Noise Filter Enable Bit * | | |0 = Noise filter of EPWM Brake 0 Disabled. * | | |1 = Noise filter of EPWM Brake 0 Enabled. * |[3:1] |BRK0NFSEL |Brake 0 Edge Detector Filter Clock Selection * | | |000 = Filter clock = HCLK. * | | |001 = Filter clock = HCLK/2. * | | |010 = Filter clock = HCLK/4. * | | |011 = Filter clock = HCLK/8. * | | |100 = Filter clock = HCLK/16. * | | |101 = Filter clock = HCLK/32. * | | |110 = Filter clock = HCLK/64. * | | |111 = Filter clock = HCLK/128. * |[6:4] |BRK0FCNT |Brake 0 Edge Detector Filter Count * | | |The register bits control the Brake0 filter counter to count from 0 to BRK0FCNT. * |[7] |BRK0PINV |Brake 0 Pin Inverse * | | |0 = The state of pin EPWMx_BRAKE0 is passed to the negative edge detector. * | | |1 = The inversed state of pin EPWMx_BRAKE0 is passed to the negative edge detector. * |[8] |BRK1NFEN |EPWM Brake 1 Noise Filter Enable Bit * | | |0 = Noise filter of EPWM Brake 1 Disabled. * | | |1 = Noise filter of EPWM Brake 1 Enabled. * |[11:9] |BRK1NFSEL |Brake 1 Edge Detector Filter Clock Selection * | | |000 = Filter clock = HCLK. * | | |001 = Filter clock = HCLK/2. * | | |010 = Filter clock = HCLK/4. * | | |011 = Filter clock = HCLK/8. * | | |100 = Filter clock = HCLK/16. * | | |101 = Filter clock = HCLK/32. * | | |110 = Filter clock = HCLK/64. * | | |111 = Filter clock = HCLK/128. * |[14:12] |BRK1FCNT |Brake 1 Edge Detector Filter Count * | | |The register bits control the Brake1 filter counter to count from 0 to BRK1FCNT. * |[15] |BRK1PINV |Brake 1 Pin Inverse * | | |0 = The state of pin EPWMx_BRAKE1 is passed to the negative edge detector. * | | |1 = The inversed state of pin EPWMx_BRAKE1 is passed to the negative edge detector. * |[16] |BK0SRC |Brake 0 Pin Source Select * | | |For EPWM0 setting: * | | |0 = Brake 0 pin source come from EPWM0_BRAKE0. * | | |1 = Brake 0 pin source come from EPWM1_BRAKE0. * | | |For EPWM1 setting: * | | |0 = Brake 0 pin source come from EPWM1_BRAKE0. * | | |1 = Brake 0 pin source come from EPWM0_BRAKE0. * |[24] |BK1SRC |Brake 1 Pin Source Select * | | |For EPWM0 setting: * | | |0 = Brake 1 pin source come from EPWM0_BRAKE1. * | | |1 = Brake 1 pin source come from EPWM1_BRAKE1. * | | |For EPWM1 setting: * | | |0 = Brake 1 pin source come from EPWM1_BRAKE1. * | | |1 = Brake 1 pin source come from EPWM0_BRAKE1. * @var EPWM_T::FAILBRK * Offset: 0xC4 EPWM System Fail Brake Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CSSBRKEN |Clock Security System Detection Trigger EPWM Brake Function 0 Enable Bit * | | |0 = Brake Function triggered by CSS detection Disabled. * | | |1 = Brake Function triggered by CSS detection Enabled. * |[1] |BODBRKEN |Brown-out Detection Trigger EPWM Brake Function 0 Enable Bit * | | |0 = Brake Function triggered by BOD Disabled. * | | |1 = Brake Function triggered by BOD Enabled. * |[2] |RAMBRKEN |SRAM Parity Error Detection Trigger EPWM Brake Function 0 Enable Bit * | | |0 = Brake Function triggered by SRAM parity error detection Disabled. * | | |1 = Brake Function triggered by SRAM parity error detection Enabled. * |[3] |CORBRKEN |Core Lockup Detection Trigger EPWM Brake Function 0 Enable Bit * | | |0 = Brake Function triggered by Core lockup detection Disabled. * | | |1 = Brake Function triggered by Core lockup detection Enabled. * @var EPWM_T::BRKCTL[3] * Offset: 0xC8 EPWM Brake Edge Detect Control Register 0/1,2/3,4/5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CPO0EBEN |Enable ACMP0_O Digital Output As Edge-detect Brake Source (Write Protect) * | | |0 = ACMP0_O as edge-detect brake source Disabled. * | | |1 = ACMP0_O as edge-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[1] |CPO1EBEN |Enable ACMP1_O Digital Output As Edge-detect Brake Source (Write Protect) * | | |0 = ACMP1_O as edge-detect brake source Disabled. * | | |1 = ACMP1_O as edge-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[4] |BRKP0EEN |Enable EPWMx_BRAKE0 Pin As Edge-detect Brake Source (Write Protect) * | | |0 = EPWMx_BRAKE0 pin as edge-detect brake source Disabled. * | | |1 = EPWMx_BRAKE0 pin as edge-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[5] |BRKP1EEN |Enable EPWMx_BRAKE1 Pin As Edge-detect Brake Source (Write Protect) * | | |0 = EPWMx_BRAKE1 pin as edge-detect brake source Disabled. * | | |1 = EPWMx_BRAKE1 pin as edge-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[7] |SYSEBEN |Enable System Fail As Edge-detect Brake Source (Write Protect) * | | |0 = System Fail condition as edge-detect brake source Disabled. * | | |1 = System Fail condition as edge-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[8] |CPO0LBEN |Enable ACMP0_O Digital Output As Level-detect Brake Source (Write Protect) * | | |0 = ACMP0_O as level-detect brake source Disabled. * | | |1 = ACMP0_O as level-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[9] |CPO1LBEN |Enable ACMP1_O Digital Output As Level-detect Brake Source (Write Protect) * | | |0 = ACMP1_O as level-detect brake source Disabled. * | | |1 = ACMP1_O as level-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[12] |BRKP0LEN |Enable BKP0 Pin As Level-detect Brake Source (Write Protect) * | | |0 = EPWMx_BRAKE0 pin as level-detect brake source Disabled. * | | |1 = EPWMx_BRAKE0 pin as level-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[13] |BRKP1LEN |Enable BKP1 Pin As Level-detect Brake Source (Write Protect) * | | |0 = EPWMx_BRAKE1 pin as level-detect brake source Disabled. * | | |1 = EPWMx_BRAKE1 pin as level-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[15] |SYSLBEN |Enable System Fail As Level-detect Brake Source (Write Protect) * | | |0 = System Fail condition as level-detect brake source Disabled. * | | |1 = System Fail condition as level-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[17:16] |BRKAEVEN |EPWM Brake Action Select for Even Channel (Write Protect) * | | |00 = EPWMx brake event will not affect even channels output. * | | |01 = EPWM even channel output tri-state when EPWMx brake event happened. * | | |10 = EPWM even channel output low level when EPWMx brake event happened. * | | |11 = EPWM even channel output high level when EPWMx brake event happened. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[19:18] |BRKAODD |EPWM Brake Action Select for Odd Channel (Write Protect) * | | |00 = EPWMx brake event will not affect odd channels output. * | | |01 = EPWM odd channel output tri-state when EPWMx brake event happened. * | | |10 = EPWM odd channel output low level when EPWMx brake event happened. * | | |11 = EPWM odd channel output high level when EPWMx brake event happened. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[20] |EADCEBEN |Enable EADC Result Monitor (EADCRM) As Edge-detect Brake Source (Write Protect) * | | |0 = EADCRM as edge-detect brake source Disabled. * | | |1 = EADCRM as edge-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[28] |EADCLBEN |Enable EADC Result Monitor (EADCRM) As Level-detect Brake Source (Write Protect) * | | |0 = EADCRM as level-detect brake source Disabled. * | | |1 = EADCRM as level-detect brake source Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * @var EPWM_T::POLCTL * Offset: 0xD4 EPWM Pin Polar Inverse Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |PINV0 |EPWM_CH0 PIN Polar Inverse Control * | | |The register controls polarity state of EPWM_CH0 output. * | | |0 = EPWM_CH0 output polar inverse Disabled. * | | |1 = EPWM_CH0 output polar inverse Enabled. * |[1] |PINV1 |EPWM_CH1 PIN Polar Inverse Control * | | |The register controls polarity state of EPWM_CH1 output. * | | |0 = EPWM_CH1 output polar inverse Disabled. * | | |1 = EPWM_CH1 output polar inverse Enabled. * |[2] |PINV2 |EPWM_CH2 PIN Polar Inverse Control * | | |The register controls polarity state of EPWM_CH2 output. * | | |0 = EPWM_CH2 output polar inverse Disabled. * | | |1 = EPWM_CH2 output polar inverse Enabled. * |[3] |PINV3 |EPWM_CH3 PIN Polar Inverse Control * | | |The register controls polarity state of EPWM_CH3 output. * | | |0 = EPWM_CH3 output polar inverse Disabled. * | | |1 = EPWM_CH3 output polar inverse Enabled. * |[4] |PINV4 |EPWM_CH4 PIN Polar Inverse Control * | | |The register controls polarity state of EPWM_CH4 output. * | | |0 = EPWM_CH4 output polar inverse Disabled. * | | |1 = EPWM_CH4 output polar inverse Enabled. * |[5] |PINV5 |EPWM_CH5 PIN Polar Inverse Control * | | |The register controls polarity state of EPWM_CH5 output. * | | |0 = EPWM_CH5 output polar inverse Disabled. * | | |1 = EPWM_CH5 output polar inverse Enabled. * @var EPWM_T::POEN * Offset: 0xD8 EPWM Output Enable Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |POEN0 |EPWM_CH0 Pin Output Enable Bits * | | |0 = EPWM_CH0 pin at tri-state. * | | |1 = EPWM_CH0 pin in output mode. * |[1] |POEN1 |EPWM_CH1 Pin Output Enable Bits * | | |0 = EPWM_CH1 pin at tri-state. * | | |1 = EPWM_CH1 pin in output mode. * |[2] |POEN2 |EPWM_CH2 Pin Output Enable Bits * | | |0 = EPWM_CH2 pin at tri-state. * | | |1 = EPWM_CH2 pin in output mode. * |[3] |POEN3 |EPWM_CH3 Pin Output Enable Bits * | | |0 = EPWM_CH3 pin at tri-state. * | | |1 = EPWM_CH3 pin in output mode. * |[4] |POEN4 |EPWM_CH4 Pin Output Enable Bits * | | |0 = EPWM_CH4 pin at tri-state. * | | |1 = EPWM_CH4 pin in output mode. * |[5] |POEN5 |EPWM_CH5 Pin Output Enable Bits * | | |0 = EPWM_CH5 pin at tri-state. * | | |1 = EPWM_CH5 pin in output mode. * @var EPWM_T::SWBRK * Offset: 0xDC EPWM Software Brake Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |BRKETRG0 |EPWM Edge Brake Software Trigger (Write Only) (Write Protect) * | | |Write 1 to this bit will trigger edge brake, and set BRKEIF0 to 1 in EPWM_INTSTS1 register. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[1] |BRKETRG2 |EPWM Edge Brake Software Trigger (Write Only) (Write Protect) * | | |Write 1 to this bit will trigger edge brake, and set BRKEIF2 to 1 in EPWM_INTSTS1 register. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[2] |BRKETRG4 |EPWM Edge Brake Software Trigger (Write Only) (Write Protect) * | | |Write 1 to this bit will trigger edge brake, and set BRKEIF4 to 1 in EPWM_INTSTS1 register. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[8] |BRKLTRG0 |EPWM Level Brake Software Trigger (Write Only) (Write Protect) * | | |Write 1 to this bit will trigger level brake, and set BRKLIF0 to 1 in EPWM_INTSTS1 register. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[9] |BRKLTRG2 |EPWM Level Brake Software Trigger (Write Only) (Write Protect) * | | |Write 1 to this bit will trigger level brake, and set BRKLIF2 to 1 in EPWM_INTSTS1 register. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[10] |BRKLTRG4 |EPWM Level Brake Software Trigger (Write Only) (Write Protect) * | | |Write 1 to this bit will trigger level brake, and set BRKLIF4 to 1 in EPWM_INTSTS1 register. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * @var EPWM_T::INTEN0 * Offset: 0xE0 EPWM Interrupt Enable Register 0 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |ZIEN0 |EPWM Zero Point Interrupt Enable Bits * | | |0 = Zero point interrupt Disabled. * | | |1 = Zero point interrupt Enabled. * | | |Note: Odd channels will read always 0 at complementary mode. * |[1] |ZIEN1 |EPWM Zero Point Interrupt Enable Bits * | | |0 = Zero point interrupt Disabled. * | | |1 = Zero point interrupt Enabled. * | | |Note: Odd channels will read always 0 at complementary mode. * |[2] |ZIEN2 |EPWM Zero Point Interrupt Enable Bits * | | |0 = Zero point interrupt Disabled. * | | |1 = Zero point interrupt Enabled. * | | |Note: Odd channels will read always 0 at complementary mode. * |[3] |ZIEN3 |EPWM Zero Point Interrupt Enable Bits * | | |0 = Zero point interrupt Disabled. * | | |1 = Zero point interrupt Enabled. * | | |Note: Odd channels will read always 0 at complementary mode. * |[4] |ZIEN4 |EPWM Zero Point Interrupt Enable Bits * | | |0 = Zero point interrupt Disabled. * | | |1 = Zero point interrupt Enabled. * | | |Note: Odd channels will read always 0 at complementary mode. * |[5] |ZIEN5 |EPWM Zero Point Interrupt Enable Bits * | | |0 = Zero point interrupt Disabled. * | | |1 = Zero point interrupt Enabled. * | | |Note: Odd channels will read always 0 at complementary mode. * |[8] |PIEN0 |EPWM Period Point Interrupt Enable Bits * | | |0 = Period point interrupt Disabled. * | | |1 = Period point interrupt Enabled. * | | |Note1: When up-down counter type period point means center point. * | | |Note2: Odd channels will read always 0 at complementary mode. * |[9] |PIEN1 |EPWM Period Point Interrupt Enable Bits * | | |0 = Period point interrupt Disabled. * | | |1 = Period point interrupt Enabled. * | | |Note1: When up-down counter type period point means center point. * | | |Note2: Odd channels will read always 0 at complementary mode. * |[10] |PIEN2 |EPWM Period Point Interrupt Enable Bits * | | |0 = Period point interrupt Disabled. * | | |1 = Period point interrupt Enabled. * | | |Note1: When up-down counter type period point means center point. * | | |Note2: Odd channels will read always 0 at complementary mode. * |[11] |PIEN3 |EPWM Period Point Interrupt Enable Bits * | | |0 = Period point interrupt Disabled. * | | |1 = Period point interrupt Enabled. * | | |Note1: When up-down counter type period point means center point. * | | |Note2: Odd channels will read always 0 at complementary mode. * |[12] |PIEN4 |EPWM Period Point Interrupt Enable Bits * | | |0 = Period point interrupt Disabled. * | | |1 = Period point interrupt Enabled. * | | |Note1: When up-down counter type period point means center point. * | | |Note2: Odd channels will read always 0 at complementary mode. * |[13] |PIEN5 |EPWM Period Point Interrupt Enable Bits * | | |0 = Period point interrupt Disabled. * | | |1 = Period point interrupt Enabled. * | | |Note1: When up-down counter type period point means center point. * | | |Note2: Odd channels will read always 0 at complementary mode. * |[16] |CMPUIEN0 |EPWM Compare Up Count Interrupt Enable Bits * | | |0 = Compare up count interrupt Disabled. * | | |1 = Compare up count interrupt Enabled. * | | |Note: In complementary mode, CMPUIEN1, 3, 5 use as another CMPUIEN for channel 0, 2, 4. * |[17] |CMPUIEN1 |EPWM Compare Up Count Interrupt Enable Bits * | | |0 = Compare up count interrupt Disabled. * | | |1 = Compare up count interrupt Enabled. * | | |Note: In complementary mode, CMPUIEN1, 3, 5 use as another CMPUIEN for channel 0, 2, 4. * |[18] |CMPUIEN2 |EPWM Compare Up Count Interrupt Enable Bits * | | |0 = Compare up count interrupt Disabled. * | | |1 = Compare up count interrupt Enabled. * | | |Note: In complementary mode, CMPUIEN1, 3, 5 use as another CMPUIEN for channel 0, 2, 4. * |[19] |CMPUIEN3 |EPWM Compare Up Count Interrupt Enable Bits * | | |0 = Compare up count interrupt Disabled. * | | |1 = Compare up count interrupt Enabled. * | | |Note: In complementary mode, CMPUIEN1, 3, 5 use as another CMPUIEN for channel 0, 2, 4. * |[20] |CMPUIEN4 |EPWM Compare Up Count Interrupt Enable Bits * | | |0 = Compare up count interrupt Disabled. * | | |1 = Compare up count interrupt Enabled. * | | |Note: In complementary mode, CMPUIEN1, 3, 5 use as another CMPUIEN for channel 0, 2, 4. * |[21] |CMPUIEN5 |EPWM Compare Up Count Interrupt Enable Bits * | | |0 = Compare up count interrupt Disabled. * | | |1 = Compare up count interrupt Enabled. * | | |Note: In complementary mode, CMPUIEN1, 3, 5 use as another CMPUIEN for channel 0, 2, 4. * |[24] |CMPDIEN0 |EPWM Compare Down Count Interrupt Enable Bits * | | |0 = Compare down count interrupt Disabled. * | | |1 = Compare down count interrupt Enabled. * | | |Note: In complementary mode, CMPDIEN1, 3, 5 use as another CMPDIEN for channel 0, 2, 4. * |[25] |CMPDIEN1 |EPWM Compare Down Count Interrupt Enable Bits * | | |0 = Compare down count interrupt Disabled. * | | |1 = Compare down count interrupt Enabled. * | | |Note: In complementary mode, CMPDIEN1, 3, 5 use as another CMPDIEN for channel 0, 2, 4. * |[26] |CMPDIEN2 |EPWM Compare Down Count Interrupt Enable Bits * | | |0 = Compare down count interrupt Disabled. * | | |1 = Compare down count interrupt Enabled. * | | |Note: In complementary mode, CMPDIEN1, 3, 5 use as another CMPDIEN for channel 0, 2, 4. * |[27] |CMPDIEN3 |EPWM Compare Down Count Interrupt Enable Bits * | | |0 = Compare down count interrupt Disabled. * | | |1 = Compare down count interrupt Enabled. * | | |Note: In complementary mode, CMPDIEN1, 3, 5 use as another CMPDIEN for channel 0, 2, 4. * |[28] |CMPDIEN4 |EPWM Compare Down Count Interrupt Enable Bits * | | |0 = Compare down count interrupt Disabled. * | | |1 = Compare down count interrupt Enabled. * | | |Note: In complementary mode, CMPDIEN1, 3, 5 use as another CMPDIEN for channel 0, 2, 4. * |[29] |CMPDIEN5 |EPWM Compare Down Count Interrupt Enable Bits * | | |0 = Compare down count interrupt Disabled. * | | |1 = Compare down count interrupt Enabled. * | | |Note: In complementary mode, CMPDIEN1, 3, 5 use as another CMPDIEN for channel 0, 2, 4. * @var EPWM_T::INTEN1 * Offset: 0xE4 EPWM Interrupt Enable Register 1 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |BRKEIEN0_1|EPWM Edge-detect Brake Interrupt Enable for Channel0/1 (Write Protect) * | | |0 = Edge-detect Brake interrupt for channel0/1 Disabled. * | | |1 = Edge-detect Brake interrupt for channel0/1 Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[1] |BRKEIEN2_3|EPWM Edge-detect Brake Interrupt Enable for Channel2/3 (Write Protect) * | | |0 = Edge-detect Brake interrupt for channel2/3 Disabled. * | | |1 = Edge-detect Brake interrupt for channel2/3 Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[2] |BRKEIEN4_5|EPWM Edge-detect Brake Interrupt Enable for Channel4/5 (Write Protect) * | | |0 = Edge-detect Brake interrupt for channel4/5 Disabled. * | | |1 = Edge-detect Brake interrupt for channel4/5 Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[8] |BRKLIEN0_1|EPWM Level-detect Brake Interrupt Enable for Channel0/1 (Write Protect) * | | |0 = Level-detect Brake interrupt for channel0/1 Disabled. * | | |1 = Level-detect Brake interrupt for channel0/1 Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[9] |BRKLIEN2_3|EPWM Level-detect Brake Interrupt Enable for Channel2/3 (Write Protect) * | | |0 = Level-detect Brake interrupt for channel2/3 Disabled. * | | |1 = Level-detect Brake interrupt for channel2/3 Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[10] |BRKLIEN4_5|EPWM Level-detect Brake Interrupt Enable for Channel4/5 (Write Protect) * | | |0 = Level-detect Brake interrupt for channel4/5 Disabled. * | | |1 = Level-detect Brake interrupt for channel4/5 Enabled. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * @var EPWM_T::INTSTS0 * Offset: 0xE8 EPWM Interrupt Flag Register 0 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |ZIF0 |EPWM Zero Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches zero, software can write 1 to clear this bit to zero. * |[1] |ZIF1 |EPWM Zero Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches zero, software can write 1 to clear this bit to zero. * |[2] |ZIF2 |EPWM Zero Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches zero, software can write 1 to clear this bit to zero. * |[3] |ZIF3 |EPWM Zero Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches zero, software can write 1 to clear this bit to zero. * |[4] |ZIF4 |EPWM Zero Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches zero, software can write 1 to clear this bit to zero. * |[5] |ZIF5 |EPWM Zero Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches zero, software can write 1 to clear this bit to zero. * |[8] |PIF0 |EPWM Period Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches EPWM_PERIOD0, software can write 1 to clear this bit to zero * |[9] |PIF1 |EPWM Period Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches EPWM_PERIOD1, software can write 1 to clear this bit to zero * |[10] |PIF2 |EPWM Period Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches EPWM_PERIOD2, software can write 1 to clear this bit to zero * |[11] |PIF3 |EPWM Period Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches EPWM_PERIOD4, software can write 1 to clear this bit to zero * |[12] |PIF4 |EPWM Period Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches EPWM_PERIOD5, software can write 1 to clear this bit to zero * |[13] |PIF5 |EPWM Period Point Interrupt Flag * | | |This bit is set by hardware when EPWM counter reaches EPWM_PERIODn, software can write 1 to clear this bit to zero. * |[16] |CMPUIF0 |EPWM Compare Up Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter up count and reaches EPWM_CMPDAT0, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in up counter type selection. * | | |Note2: In complementary mode, CMPUIF1, 3, 5 use as another CMPUIF for channel 0, 2, 4. * |[17] |CMPUIF1 |EPWM Compare Up Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter up count and reaches EPWM_CMPDAT1, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in up counter type selection. * | | |Note2: In complementary mode, CMPUIF1, 3, 5 use as another CMPUIF for channel 0, 2, 4. * |[18] |CMPUIF2 |EPWM Compare Up Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter up count and reaches EPWM_CMPDAT2, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in up counter type selection. * | | |Note2: In complementary mode, CMPUIF1, 3, 5 use as another CMPUIF for channel 0, 2, 4. * |[19] |CMPUIF3 |EPWM Compare Up Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter up count and reaches EPWM_CMPDAT3, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in up counter type selection. * | | |Note2: In complementary mode, CMPUIF1, 3, 5 use as another CMPUIF for channel 0, 2, 4. * |[20] |CMPUIF4 |EPWM Compare Up Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter up count and reaches EPWM_CMPDAT4, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in up counter type selection. * | | |Note2: In complementary mode, CMPUIF1, 3, 5 use as another CMPUIF for channel 0, 2, 4. * |[21] |CMPUIF5 |EPWM Compare Up Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter up count and reaches EPWM_CMPDAT5, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in up counter type selection. * | | |Note2: In complementary mode, CMPUIF1, 3, 5 use as another CMPUIF for channel 0, 2, 4. * |[24] |CMPDIF0 |EPWM Compare Down Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter down count and reaches EPWM_CMPDAT0, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in down counter type selection. * | | |Note2: In complementary mode, CMPDIF1, 3, 5 use as another CMPDIF for channel 0, 2, 4. * |[25] |CMPDIF1 |EPWM Compare Down Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter down count and reaches EPWM_CMPDAT1, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in down counter type selection. * | | |Note2: In complementary mode, CMPDIF1, 3, 5 use as another CMPDIF for channel 0, 2, 4. * |[26] |CMPDIF2 |EPWM Compare Down Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter down count and reaches EPWM_CMPDAT2, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in down counter type selection. * | | |Note2: In complementary mode, CMPDIF1, 3, 5 use as another CMPDIF for channel 0, 2, 4. * |[27] |CMPDIF3 |EPWM Compare Down Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter down count and reaches EPWM_CMPDAT3, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in down counter type selection. * | | |Note2: In complementary mode, CMPDIF1, 3, 5 use as another CMPDIF for channel 0, 2, 4. * |[28] |CMPDIF4 |EPWM Compare Down Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter down count and reaches EPWM_CMPDAT4, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in down counter type selection. * | | |Note2: In complementary mode, CMPDIF1, 3, 5 use as another CMPDIF for channel 0, 2, 4. * |[29] |CMPDIF5 |EPWM Compare Down Count Interrupt Flag * | | |Flag is set by hardware when EPWM counter down count and reaches EPWM_CMPDAT5, software can clear this bit by writing 1 to it. * | | |Note1: If CMPDAT equal to PERIOD, this flag is not working in down counter type selection. * | | |Note2: In complementary mode, CMPDIF1, 3, 5 use as another CMPDIF for channel 0, 2, 4. * @var EPWM_T::INTSTS1 * Offset: 0xEC EPWM Interrupt Flag Register 1 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |BRKEIF0 |EPWM Channel0 Edge-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel0 edge-detect brake event do not happened. * | | |1 = When EPWM channel0 edge-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[1] |BRKEIF1 |EPWM Channel1 Edge-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel1 edge-detect brake event do not happened. * | | |1 = When EPWM channel1 edge-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[2] |BRKEIF2 |EPWM Channel2 Edge-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel2 edge-detect brake event do not happened. * | | |1 = When EPWM channel2 edge-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[3] |BRKEIF3 |EPWM Channel3 Edge-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel3 edge-detect brake event do not happened. * | | |1 = When EPWM channel3 edge-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[4] |BRKEIF4 |EPWM Channel4 Edge-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel4 edge-detect brake event do not happened. * | | |1 = When EPWM channel4 edge-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[5] |BRKEIF5 |EPWM Channel5 Edge-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel5 edge-detect brake event do not happened. * | | |1 = When EPWM channel5 edge-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[8] |BRKLIF0 |EPWM Channel0 Level-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel0 level-detect brake event do not happened. * | | |1 = When EPWM channel0 level-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[9] |BRKLIF1 |EPWM Channel1 Level-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel1 level-detect brake event do not happened. * | | |1 = When EPWM channel1 level-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[10] |BRKLIF2 |EPWM Channel2 Level-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel2 level-detect brake event do not happened. * | | |1 = When EPWM channel2 level-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[11] |BRKLIF3 |EPWM Channel3 Level-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel3 level-detect brake event do not happened. * | | |1 = When EPWM channel3 level-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[12] |BRKLIF4 |EPWM Channel4 Level-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel4 level-detect brake event do not happened. * | | |1 = When EPWM channel4 level-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[13] |BRKLIF5 |EPWM Channel5 Level-detect Brake Interrupt Flag (Write Protect) * | | |0 = EPWM channel5 level-detect brake event do not happened. * | | |1 = When EPWM channel5 level-detect brake event happened, this bit is set to 1, writing 1 to clear. * | | |Note: This register is write protected. Refer to SYS_REGLCTL register. * |[16] |BRKESTS0 |EPWM Channel0 Edge-detect Brake Status (Read Only) * | | |0 = EPWM channel0 edge-detect brake state is released. * | | |1 = When EPWM channel0 edge-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel0 at brake state, writing 1 to clear. * |[17] |BRKESTS1 |EPWM Channel1 Edge-detect Brake Status (Read Only) * | | |0 = EPWM channel1 edge-detect brake state is released. * | | |1 = When EPWM channel1 edge-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel1 at brake state, writing 1 to clear. * |[18] |BRKESTS2 |EPWM Channel2 Edge-detect Brake Status (Read Only) * | | |0 = EPWM channel2 edge-detect brake state is released. * | | |1 = When EPWM channel2 edge-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel2 at brake state, writing 1 to clear. * |[19] |BRKESTS3 |EPWM Channel3 Edge-detect Brake Status (Read Only) * | | |0 = EPWM channel3 edge-detect brake state is released. * | | |1 = When EPWM channel3 edge-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel3 at brake state, writing 1 to clear. * |[20] |BRKESTS4 |EPWM Channel4 Edge-detect Brake Status (Read Only) * | | |0 = EPWM channel4 edge-detect brake state is released. * | | |1 = When EPWM channel4 edge-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel4 at brake state, writing 1 to clear. * |[21] |BRKESTS5 |EPWM Channel5 Edge-detect Brake Status (Read Only) * | | |0 = EPWM channel5 edge-detect brake state is released. * | | |1 = When EPWM channel5 edge-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel5 at brake state, writing 1 to clear. * |[24] |BRKLSTS0 |EPWM Channel0 Level-detect Brake Status (Read Only) * | | |0 = EPWM channel0 level-detect brake state is released. * | | |1 = When EPWM channel0 level-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel0 at brake state. * | | |Note: This bit is read only and auto cleared by hardware * | | |When enabled brake source return to high level, EPWM will release brake state until current EPWM period finished * | | |The EPWM waveform will start output from next full EPWM period. * |[25] |BRKLSTS1 |EPWM Channel1 Level-detect Brake Status (Read Only) * | | |0 = EPWM channel1 level-detect brake state is released. * | | |1 = When EPWM channel1 level-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel1 at brake state. * | | |Note: This bit is read only and auto cleared by hardware * | | |When enabled brake source return to high level, EPWM will release brake state until current EPWM period finished * | | |The EPWM waveform will start output from next full EPWM period. * |[26] |BRKLSTS2 |EPWM Channel2 Level-detect Brake Status (Read Only) * | | |0 = EPWM channel2 level-detect brake state is released. * | | |1 = When EPWM channel2 level-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel2 at brake state. * | | |Note: This bit is read only and auto cleared by hardware * | | |When enabled brake source return to high level, EPWM will release brake state until current EPWM period finished * | | |The EPWM waveform will start output from next full EPWM period. * |[27] |BRKLSTS3 |EPWM Channel3 Level-detect Brake Status (Read Only) * | | |0 = EPWM channel3 level-detect brake state is released. * | | |1 = When EPWM channel3 level-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel3 at brake state. * | | |Note: This bit is read only and auto cleared by hardware * | | |When enabled brake source return to high level, EPWM will release brake state until current EPWM period finished * | | |The EPWM waveform will start output from next full EPWM period. * |[28] |BRKLSTS4 |EPWM Channel4 Level-detect Brake Status (Read Only) * | | |0 = EPWM channel4 level-detect brake state is released. * | | |1 = When EPWM channel4 level-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel4 at brake state. * | | |Note: This bit is read only and auto cleared by hardware * | | |When enabled brake source return to high level, EPWM will release brake state until current EPWM period finished * | | |The EPWM waveform will start output from next full EPWM period. * |[29] |BRKLSTS5 |EPWM Channel5 Level-detect Brake Status (Read Only) * | | |0 = EPWM channel5 level-detect brake state is released. * | | |1 = When EPWM channel5 level-detect brake detects a falling edge of any enabled brake source; this flag will be set to indicate the EPWM channel5 at brake state. * | | |Note: This bit is read only and auto cleared by hardware * | | |When enabled brake source return to high level, EPWM will release brake state until current EPWM period finished * | | |The EPWM waveform will start output from next full EPWM period. * @var EPWM_T::DACTRGEN * Offset: 0xF4 EPWM Trigger DAC Enable Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |ZTE0 |EPWM Zero Point Trigger DAC Enable Bits * | | |EPWM can trigger EADC/DAC/DMA to start action when EPWM counter down count to zero if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[1] |ZTE1 |EPWM Zero Point Trigger DAC Enable Bits * | | |EPWM can trigger EADC/DAC/DMA to start action when EPWM counter down count to zero if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[2] |ZTE2 |EPWM Zero Point Trigger DAC Enable Bits * | | |EPWM can trigger EADC/DAC/DMA to start action when EPWM counter down count to zero if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[3] |ZTE3 |EPWM Zero Point Trigger DAC Enable Bits * | | |EPWM can trigger EADC/DAC/DMA to start action when EPWM counter down count to zero if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[4] |ZTE4 |EPWM Zero Point Trigger DAC Enable Bits * | | |EPWM can trigger EADC/DAC/DMA to start action when EPWM counter down count to zero if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[5] |ZTE5 |EPWM Zero Point Trigger DAC Enable Bits * | | |EPWM can trigger EADC/DAC/DMA to start action when EPWM counter down count to zero if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[8] |PTE0 |EPWM Period Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to (PERIODn+1) if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[9] |PTE1 |EPWM Period Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to (PERIODn+1) if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[10] |PTE2 |EPWM Period Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to (PERIODn+1) if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[11] |PTE3 |EPWM Period Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to (PERIODn+1) if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[12] |PTE4 |EPWM Period Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to (PERIODn+1) if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[13] |PTE5 |EPWM Period Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to (PERIODn+1) if this bit is set to1. * | | |0 = EPWM period point trigger DAC function Disabled. * | | |1 = EPWM period point trigger DAC function Enabled. * |[16] |CUTRGE0 |EPWM Compare Up Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Up point trigger DAC function Disabled. * | | |1 = EPWM Compare Up point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in down counter type. * | | |Note2: In complementary mode, CUTRGE1, 3, 5 use as another CUTRGE for channel 0, 2, 4. * |[17] |CUTRGE1 |EPWM Compare Up Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Up point trigger DAC function Disabled. * | | |1 = EPWM Compare Up point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in down counter type. * | | |Note2: In complementary mode, CUTRGE1, 3, 5 use as another CUTRGE for channel 0, 2, 4. * |[18] |CUTRGE2 |EPWM Compare Up Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Up point trigger DAC function Disabled. * | | |1 = EPWM Compare Up point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in down counter type. * | | |Note2: In complementary mode, CUTRGE1, 3, 5 use as another CUTRGE for channel 0, 2, 4. * |[19] |CUTRGE3 |EPWM Compare Up Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Up point trigger DAC function Disabled. * | | |1 = EPWM Compare Up point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in down counter type. * | | |Note2: In complementary mode, CUTRGE1, 3, 5 use as another CUTRGE for channel 0, 2, 4. * |[20] |CUTRGE4 |EPWM Compare Up Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Up point trigger DAC function Disabled. * | | |1 = EPWM Compare Up point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in down counter type. * | | |Note2: In complementary mode, CUTRGE1, 3, 5 use as another CUTRGE for channel 0, 2, 4. * |[21] |CUTRGE5 |EPWM Compare Up Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter up count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Up point trigger DAC function Disabled. * | | |1 = EPWM Compare Up point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in down counter type. * | | |Note2: In complementary mode, CUTRGE1, 3, 5 use as another CUTRGE for channel 0, 2, 4. * |[24] |CDTRGE0 |EPWM Compare Down Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter down count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Down count point trigger DAC function Disabled. * | | |1 = EPWM Compare Down count point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in up counter type. * | | |Note2: In complementary mode, CDTRGE1, 3, 5 use as another CDTRGE for channel 0, 2, 4. * |[25] |CDTRGE1 |EPWM Compare Down Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter down count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Down count point trigger DAC function Disabled. * | | |1 = EPWM Compare Down count point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in up counter type. * | | |Note2: In complementary mode, CDTRGE1, 3, 5 use as another CDTRGE for channel 0, 2, 4. * |[26] |CDTRGE2 |EPWM Compare Down Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter down count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Down count point trigger DAC function Disabled. * | | |1 = EPWM Compare Down count point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in up counter type. * | | |Note2: In complementary mode, CDTRGE1, 3, 5 use as another CDTRGE for channel 0, 2, 4. * |[27] |CDTRGE3 |EPWM Compare Down Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter down count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Down count point trigger DAC function Disabled. * | | |1 = EPWM Compare Down count point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in up counter type. * | | |Note2: In complementary mode, CDTRGE1, 3, 5 use as another CDTRGE for channel 0, 2, 4. * |[28] |CDTRGE4 |EPWM Compare Down Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter down count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Down count point trigger DAC function Disabled. * | | |1 = EPWM Compare Down count point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in up counter type. * | | |Note2: In complementary mode, CDTRGE1, 3, 5 use as another CDTRGE for channel 0, 2, 4. * |[29] |CDTRGE5 |EPWM Compare Down Count Point Trigger DAC Enable Bits * | | |EPWM can trigger DAC to start action when EPWM counter down count to CMPDAT if this bit is set to1. * | | |0 = EPWM Compare Down count point trigger DAC function Disabled. * | | |1 = EPWM Compare Down count point trigger DAC function Enabled. * | | |Note1: This bit should keep at 0 when EPWM counter operating in up counter type. * | | |Note2: In complementary mode, CDTRGE1, 3, 5 use as another CDTRGE for channel 0, 2, 4. * @var EPWM_T::EADCTS0 * Offset: 0xF8 EPWM Trigger EADC Source Select Register 0 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[3:0] |TRGSEL0 |EPWM_CH0 Trigger EADC Source Select * | | |0000 = EPWM_CH0 zero point. * | | |0001 = EPWM_CH0 period point. * | | |0010 = EPWM_CH0 zero or period point. * | | |0011 = EPWM_CH0 up-count CMPDAT point. * | | |0100 = EPWM_CH0 down-count CMPDAT point. * | | |0101 = EPWM_CH1 zero point. * | | |0110 = EPWM_CH1 period point. * | | |0111 = EPWM_CH1 zero or period point. * | | |1000 = EPWM_CH1 up-count CMPDAT point. * | | |1001 = EPWM_CH1 down-count CMPDAT point. * | | |1010 = EPWM_CH0 up-count free CMPDAT point. * | | |1011 = EPWM_CH0 down-count free CMPDAT point. * | | |1100 = EPWM_CH2 up-count free CMPDAT point. * | | |1101 = EPWM_CH2 down-count free CMPDAT point. * | | |1110 = EPWM_CH4 up-count free CMPDAT point. * | | |1111 = EPWM_CH4 down-count free CMPDAT point. * |[7] |TRGEN0 |EPWM_CH0 Trigger EADC enable bit * |[11:8] |TRGSEL1 |EPWM_CH1 Trigger EADC Source Select * | | |0000 = EPWM_CH0 zero point. * | | |0001 = EPWM_CH0 period point. * | | |0010 = EPWM_CH0 zero or period point. * | | |0011 = EPWM_CH0 up-count CMPDAT point. * | | |0100 = EPWM_CH0 down-count CMPDAT point. * | | |0101 = EPWM_CH1 zero point. * | | |0110 = EPWM_CH1 period point. * | | |0111 = EPWM_CH1 zero or period point. * | | |1000 = EPWM_CH1 up-count CMPDAT point. * | | |1001 = EPWM_CH1 down-count CMPDAT point. * | | |1010 = EPWM_CH0 up-count free CMPDAT point. * | | |1011 = EPWM_CH0 down-count free CMPDAT point. * | | |1100 = EPWM_CH2 up-count free CMPDAT point. * | | |1101 = EPWM_CH2 down-count free CMPDAT point. * | | |1110 = EPWM_CH4 up-count free CMPDAT point. * | | |1111 = EPWM_CH4 down-count free CMPDAT point. * |[15] |TRGEN1 |EPWM_CH1 Trigger EADC enable bit * |[19:16] |TRGSEL2 |EPWM_CH2 Trigger EADC Source Select * | | |0000 = EPWM_CH2 zero point. * | | |0001 = EPWM_CH2 period point. * | | |0010 = EPWM_CH2 zero or period point. * | | |0011 = EPWM_CH2 up-count CMPDAT point. * | | |0100 = EPWM_CH2 down-count CMPDAT point. * | | |0101 = EPWM_CH3 zero point. * | | |0110 = EPWM_CH3 period point. * | | |0111 = EPWM_CH3 zero or period point. * | | |1000 = EPWM_CH3 up-count CMPDAT point. * | | |1001 = EPWM_CH3 down-count CMPDAT point. * | | |1010 = EPWM_CH0 up-count free CMPDAT point. * | | |1011 = EPWM_CH0 down-count free CMPDAT point. * | | |1100 = EPWM_CH2 up-count free CMPDAT point. * | | |1101 = EPWM_CH2 down-count free CMPDAT point. * | | |1110 = EPWM_CH4 up-count free CMPDAT point. * | | |1111 = EPWM_CH4 down-count free CMPDAT point. * |[23] |TRGEN2 |EPWM_CH2 Trigger EADC enable bit * |[27:24] |TRGSEL3 |EPWM_CH3 Trigger EADC Source Select * | | |0000 = EPWM_CH2 zero point. * | | |0001 = EPWM_CH2 period point. * | | |0010 = EPWM_CH2 zero or period point. * | | |0011 = EPWM_CH2 up-count CMPDAT point. * | | |0100 = EPWM_CH2 down-count CMPDAT point. * | | |0101 = EPWM_CH3 zero point. * | | |0110 = EPWM_CH3 period point. * | | |0111 = EPWM_CH3 zero or period point. * | | |1000 = EPWM_CH3 up-count CMPDAT point. * | | |1001 = EPWM_CH3 down-count CMPDAT point. * | | |1010 = EPWM_CH0 up-count free CMPDAT point. * | | |1011 = EPWM_CH0 down-count free CMPDAT point. * | | |1100 = EPWM_CH2 up-count free CMPDAT point. * | | |1101 = EPWM_CH2 down-count free CMPDAT point. * | | |1110 = EPWM_CH4 up-count free CMPDAT point. * | | |1111 = EPWM_CH4 down-count free CMPDAT point. * |[31] |TRGEN3 |EPWM_CH3 Trigger EADC enable bit * @var EPWM_T::EADCTS1 * Offset: 0xFC EPWM Trigger EADC Source Select Register 1 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[3:0] |TRGSEL4 |EPWM_CH4 Trigger EADC Source Select * | | |0000 = EPWM_CH4 zero point. * | | |0001 = EPWM_CH4 period point. * | | |0010 = EPWM_CH4 zero or period point. * | | |0011 = EPWM_CH4 up-count CMPDAT point. * | | |0100 = EPWM_CH4 down-count CMPDAT point. * | | |0101 = EPWM_CH5 zero point. * | | |0110 = EPWM_CH5 period point. * | | |0111 = EPWM_CH5 zero or period point. * | | |1000 = EPWM_CH5 up-count CMPDAT point. * | | |1001 = EPWM_CH5 down-count CMPDAT point. * | | |1010 = EPWM_CH0 up-count free CMPDAT point. * | | |1011 = EPWM_CH0 down-count free CMPDAT point. * | | |1100 = EPWM_CH2 up-count free CMPDAT point. * | | |1101 = EPWM_CH2 down-count free CMPDAT point. * | | |1110 = EPWM_CH4 up-count free CMPDAT point. * | | |1111 = EPWM_CH4 down-count free CMPDAT point. * |[7] |TRGEN4 |EPWM_CH4 Trigger EADC enable bit * |[11:8] |TRGSEL5 |EPWM_CH5 Trigger EADC Source Select * | | |0000 = EPWM_CH4 zero point. * | | |0001 = EPWM_CH4 period point. * | | |0010 = EPWM_CH4 zero or period point. * | | |0011 = EPWM_CH4 up-count CMPDAT point. * | | |0100 = EPWM_CH4 down-count CMPDAT point. * | | |0101 = EPWM_CH5 zero point. * | | |0110 = EPWM_CH5 period point. * | | |0111 = EPWM_CH5 zero or period point. * | | |1000 = EPWM_CH5 up-count CMPDAT point. * | | |1001 = EPWM_CH5 down-count CMPDAT point. * | | |1010 = EPWM_CH0 up-count free CMPDAT point. * | | |1011 = EPWM_CH0 down-count free CMPDAT point. * | | |1100 = EPWM_CH2 up-count free CMPDAT point. * | | |1101 = EPWM_CH2 down-count free CMPDAT point. * | | |1110 = EPWM_CH4 up-count free CMPDAT point. * | | |1111 = EPWM_CH4 down-count free CMPDAT point. * |[15] |TRGEN5 |EPWM_CH5 Trigger EADC enable bit * @var EPWM_T::FTCMPDAT[3] * Offset: 0x100 EPWM Free Trigger Compare Register 0/1,2/3,4/5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |FTCMP |EPWM Free Trigger Compare Register * | | |FTCMP use to compare with even CNTR to trigger EADC * | | |FTCMPDAT0, 2, 4 corresponding complementary pairs EPWM_CH0 and EPWM_CH1, EPWM_CH2 and EPWM_CH3, EPWM_CH4 and EPWM_CH5. * @var EPWM_T::SSCTL * Offset: 0x110 EPWM Synchronous Start Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |SSEN0 |EPWM Synchronous Start Function Enable Bits * | | |When synchronous start function is enabled, the EPWM counter enable register (EPWM_CNTEN) can be enabled by writing EPWM synchronous start trigger bit (CNTSEN). * | | |0 = EPWM synchronous start function Disabled. * | | |1 = EPWM synchronous start function Enabled. * |[1] |SSEN1 |EPWM Synchronous Start Function Enable Bits * | | |When synchronous start function is enabled, the EPWM counter enable register (EPWM_CNTEN) can be enabled by writing EPWM synchronous start trigger bit (CNTSEN). * | | |0 = EPWM synchronous start function Disabled. * | | |1 = EPWM synchronous start function Enabled. * |[2] |SSEN2 |EPWM Synchronous Start Function Enable Bits * | | |When synchronous start function is enabled, the EPWM counter enable register (EPWM_CNTEN) can be enabled by writing EPWM synchronous start trigger bit (CNTSEN). * | | |0 = EPWM synchronous start function Disabled. * | | |1 = EPWM synchronous start function Enabled. * |[3] |SSEN3 |EPWM Synchronous Start Function Enable Bits * | | |When synchronous start function is enabled, the EPWM counter enable register (EPWM_CNTEN) can be enabled by writing EPWM synchronous start trigger bit (CNTSEN). * | | |0 = EPWM synchronous start function Disabled. * | | |1 = EPWM synchronous start function Enabled. * |[4] |SSEN4 |EPWM Synchronous Start Function Enable Bits * | | |When synchronous start function is enabled, the EPWM counter enable register (EPWM_CNTEN) can be enabled by writing EPWM synchronous start trigger bit (CNTSEN). * | | |0 = EPWM synchronous start function Disabled. * | | |1 = EPWM synchronous start function Enabled. * |[5] |SSEN5 |EPWM Synchronous Start Function Enable Bits * | | |When synchronous start function is enabled, the EPWM counter enable register (EPWM_CNTEN) can be enabled by writing EPWM synchronous start trigger bit (CNTSEN). * | | |0 = EPWM synchronous start function Disabled. * | | |1 = EPWM synchronous start function Enabled. * |[9:8] |SSRC |EPWM Synchronous Start Source Select Bits * | | |00 = Synchronous start source come from EPWM0. * | | |01 = Synchronous start source come from EPWM1. * | | |10 = Synchronous start source come from BPWM0. * | | |11 = Synchronous start source come from BPWM1. * @var EPWM_T::SSTRG * Offset: 0x114 EPWM Synchronous Start Trigger Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CNTSEN |EPWM Counter Synchronous Start Enable (Write Only) * | | |PMW counter synchronous enable function is used to make selected EPWM channels (include EPWM0_CHx and EPWM1_CHx) start counting at the same time. * | | |Writing this bit to 1 will also set the counter enable bit (CNTENn, n denotes channel 0 to 5) if correlated EPWM channel counter synchronous start function is enabled. * @var EPWM_T::LEBCTL * Offset: 0x118 EPWM Leading Edge Blanking Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |LEBEN |EPWM Leading Edge Blanking Enable Bit * | | |0 = EPWM Leading Edge Blanking Disabled. * | | |1 = EPWM Leading Edge Blanking Enabled. * |[8] |SRCEN0 |EPWM Leading Edge Blanking Source From EPWM_CH0 Enable Bit * | | |0 = EPWM Leading Edge Blanking Source from EPWM_CH0 Disabled. * | | |1 = EPWM Leading Edge Blanking Source from EPWM_CH0 Enabled. * |[9] |SRCEN2 |EPWM Leading Edge Blanking Source From EPWM_CH2 Enable Bit * | | |0 = EPWM Leading Edge Blanking Source from EPWM_CH2 Disabled. * | | |1 = EPWM Leading Edge Blanking Source from EPWM_CH2 Enabled. * |[10] |SRCEN4 |EPWM Leading Edge Blanking Source From EPWM_CH4 Enable Bit * | | |0 = EPWM Leading Edge Blanking Source from EPWM_CH4 Disabled. * | | |1 = EPWM Leading Edge Blanking Source from EPWM_CH4 Enabled. * |[17:16] |TRGTYPE |EPWM Leading Edge Blanking Trigger Type * | | |0 = When detect leading edge blanking source rising edge, blanking counter start counting. * | | |1 = When detect leading edge blanking source falling edge, blanking counter start counting. * | | |2 = When detect leading edge blanking source rising or falling edge, blanking counter start counting. * | | |3 = Reserved. * @var EPWM_T::LEBCNT * Offset: 0x11C EPWM Leading Edge Blanking Counter Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[8:0] |LEBCNT |EPWM Leading Edge Blanking Counter * | | |This counter value decides leading edge blanking window size. * | | |Blanking window size = LEBCNT+1, and LEB counter clock base is ECLK. * @var EPWM_T::STATUS * Offset: 0x120 EPWM Status Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CNTMAXF0 |Time-base Counter Equal to 0xFFFF Latched Flag * | | |0 = indicates the time-base counter never reached its maximum value 0xFFFF. * | | |1 = indicates the time-base counter reached its maximum value, software can write 1 to clear this bit. * |[1] |CNTMAXF1 |Time-base Counter Equal to 0xFFFF Latched Flag * | | |0 = indicates the time-base counter never reached its maximum value 0xFFFF. * | | |1 = indicates the time-base counter reached its maximum value, software can write 1 to clear this bit. * |[2] |CNTMAXF2 |Time-base Counter Equal to 0xFFFF Latched Flag * | | |0 = indicates the time-base counter never reached its maximum value 0xFFFF. * | | |1 = indicates the time-base counter reached its maximum value, software can write 1 to clear this bit. * |[3] |CNTMAXF3 |Time-base Counter Equal to 0xFFFF Latched Flag * | | |0 = indicates the time-base counter never reached its maximum value 0xFFFF. * | | |1 = indicates the time-base counter reached its maximum value, software can write 1 to clear this bit. * |[4] |CNTMAXF4 |Time-base Counter Equal to 0xFFFF Latched Flag * | | |0 = indicates the time-base counter never reached its maximum value 0xFFFF. * | | |1 = indicates the time-base counter reached its maximum value, software can write 1 to clear this bit. * |[5] |CNTMAXF5 |Time-base Counter Equal to 0xFFFF Latched Flag * | | |0 = indicates the time-base counter never reached its maximum value 0xFFFF. * | | |1 = indicates the time-base counter reached its maximum value, software can write 1 to clear this bit. * |[8] |SYNCINF0 |Input Synchronization Latched Flag * | | |0 = Indicates no SYNC_IN event has occurred. * | | |1 = Indicates an SYNC_IN event has occurred, software can write 1 to clear this bit. * |[9] |SYNCINF2 |Input Synchronization Latched Flag * | | |0 = Indicates no SYNC_IN event has occurred. * | | |1 = Indicates an SYNC_IN event has occurred, software can write 1 to clear this bit. * |[10] |SYNCINF4 |Input Synchronization Latched Flag * | | |0 = Indicates no SYNC_IN event has occurred. * | | |1 = Indicates an SYNC_IN event has occurred, software can write 1 to clear this bit. * |[16] |EADCTRGF0 |EADC Start of Conversion Flag * | | |0 = Indicates no EADC start of conversion trigger event has occurred. * | | |1 = Indicates an EADC start of conversion trigger event has occurred, software can write 1 to clear this bit. * |[17] |EADCTRGF1 |EADC Start of Conversion Flag * | | |0 = Indicates no EADC start of conversion trigger event has occurred. * | | |1 = Indicates an EADC start of conversion trigger event has occurred, software can write 1 to clear this bit. * |[18] |EADCTRGF2 |EADC Start of Conversion Flag * | | |0 = Indicates no EADC start of conversion trigger event has occurred. * | | |1 = Indicates an EADC start of conversion trigger event has occurred, software can write 1 to clear this bit. * |[19] |EADCTRGF3 |EADC Start of Conversion Flag * | | |0 = Indicates no EADC start of conversion trigger event has occurred. * | | |1 = Indicates an EADC start of conversion trigger event has occurred, software can write 1 to clear this bit. * |[20] |EADCTRGF4 |EADC Start of Conversion Flag * | | |0 = Indicates no EADC start of conversion trigger event has occurred. * | | |1 = Indicates an EADC start of conversion trigger event has occurred, software can write 1 to clear this bit. * |[21] |EADCTRGF5 |EADC Start of Conversion Flag * | | |0 = Indicates no EADC start of conversion trigger event has occurred. * | | |1 = Indicates an EADC start of conversion trigger event has occurred, software can write 1 to clear this bit. * |[24] |DACTRGF |DAC Start of Conversion Flag * | | |0 = Indicates no DAC start of conversion trigger event has occurred. * | | |1 = Indicates an DAC start of conversion trigger event has occurred, software can write 1 to clear this bit * @var EPWM_T::IFA[6] * Offset: 0x130 EPWM Interrupt Flag Accumulator Register 0~5 * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |IFACNT |EPWM_CHn Interrupt Flag Counter * | | |The register sets the count number which defines how many times of EPWM_CHn period occurs to set bit IFAIFn to request the EPWM period interrupt. * | | |EPWM flag will be set in every IFACNT[15:0] times of EPWM period. * |[24] |STPMOD |EPWM_CHn Interrupt Flag Accumulator Stop Mode Enable Bits * | | |0 = EPWM_CHn interrupt flag accumulator stop mode disable. * | | |1 = EPWM_CHn interrupt flag accumulator stop mode enable. * |[29:28] |IFASEL |EPWM_CHn Interrupt Flag Accumulator Source Select * | | |00 = CNT equal to Zero in channel n. * | | |01 = CNT equal to PERIOD in channel n. * | | |10 = CNT equal to CMPU in channel n. * | | |11 = CNT equal to CMPD in channel n. * |[31] |IFAEN |EPWM_CHn Interrupt Flag Accumulator Enable Bits * | | |0 = EPWM_CHn interrupt flag accumulator disable. * | | |1 = EPWM_CHn interrupt flag accumulator enable. * @var EPWM_T::AINTSTS * Offset: 0x150 EPWM Accumulator Interrupt Flag Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |IFAIF0 |EPWM_CHn Interrupt Flag Accumulator Interrupt Flag * | | |Flag is set by hardware when condition match IFASEL in EPWM_IFAn register, software can clear this bit by writing 1 to it. * |[1] |IFAIF1 |EPWM_CHn Interrupt Flag Accumulator Interrupt Flag * | | |Flag is set by hardware when condition match IFASEL in EPWM_IFAn register, software can clear this bit by writing 1 to it. * |[2] |IFAIF2 |EPWM_CHn Interrupt Flag Accumulator Interrupt Flag * | | |Flag is set by hardware when condition match IFASEL in EPWM_IFAn register, software can clear this bit by writing 1 to it. * |[3] |IFAIF3 |EPWM_CHn Interrupt Flag Accumulator Interrupt Flag * | | |Flag is set by hardware when condition match IFASEL in EPWM_IFAn register, software can clear this bit by writing 1 to it. * |[4] |IFAIF4 |EPWM_CHn Interrupt Flag Accumulator Interrupt Flag * | | |Flag is set by hardware when condition match IFASEL in EPWM_IFAn register, software can clear this bit by writing 1 to it. * |[5] |IFAIF5 |EPWM_CHn Interrupt Flag Accumulator Interrupt Flag * | | |Flag is set by hardware when condition match IFASEL in EPWM_IFAn register, software can clear this bit by writing 1 to it. * @var EPWM_T::AINTEN * Offset: 0x154 EPWM Accumulator Interrupt Enable Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |IFAIEN0 |EPWM_CHn Interrupt Flag Accumulator Interrupt Enable Bits * | | |0 = Interrupt Flag accumulator interrupt Disabled. * | | |1 = Interrupt Flag accumulator interrupt Enabled. * |[1] |IFAIEN1 |EPWM_CHn Interrupt Flag Accumulator Interrupt Enable Bits * | | |0 = Interrupt Flag accumulator interrupt Disabled. * | | |1 = Interrupt Flag accumulator interrupt Enabled. * |[2] |IFAIEN2 |EPWM_CHn Interrupt Flag Accumulator Interrupt Enable Bits * | | |0 = Interrupt Flag accumulator interrupt Disabled. * | | |1 = Interrupt Flag accumulator interrupt Enabled. * |[3] |IFAIEN3 |EPWM_CHn Interrupt Flag Accumulator Interrupt Enable Bits * | | |0 = Interrupt Flag accumulator interrupt Disabled. * | | |1 = Interrupt Flag accumulator interrupt Enabled. * |[4] |IFAIEN4 |EPWM_CHn Interrupt Flag Accumulator Interrupt Enable Bits * | | |0 = Interrupt Flag accumulator interrupt Disabled. * | | |1 = Interrupt Flag accumulator interrupt Enabled. * |[5] |IFAIEN5 |EPWM_CHn Interrupt Flag Accumulator Interrupt Enable Bits * | | |0 = Interrupt Flag accumulator interrupt Disabled. * | | |1 = Interrupt Flag accumulator interrupt Enabled. * @var EPWM_T::APDMACTL * Offset: 0x158 EPWM Accumulator PDMA Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |APDMAEN0 |Channel N Accumulator PDMA Enable Bits * | | |0 = Channel n PDMA function Disabled. * | | |1 = Channel n PDMA function Enabled for the channel n to trigger PDMA to transfer memory data to register. * |[1] |APDMAEN1 |Channel N Accumulator PDMA Enable Bits * | | |0 = Channel n PDMA function Disabled. * | | |1 = Channel n PDMA function Enabled for the channel n to trigger PDMA to transfer memory data to register. * |[2] |APDMAEN2 |Channel N Accumulator PDMA Enable Bits * | | |0 = Channel n PDMA function Disabled. * | | |1 = Channel n PDMA function Enabled for the channel n to trigger PDMA to transfer memory data to register. * |[3] |APDMAEN3 |Channel N Accumulator PDMA Enable Bits * | | |0 = Channel n PDMA function Disabled. * | | |1 = Channel n PDMA function Enabled for the channel n to trigger PDMA to transfer memory data to register. * |[4] |APDMAEN4 |Channel N Accumulator PDMA Enable Bits * | | |0 = Channel n PDMA function Disabled. * | | |1 = Channel n PDMA function Enabled for the channel n to trigger PDMA to transfer memory data to register. * |[5] |APDMAEN5 |Channel N Accumulator PDMA Enable Bits * | | |0 = Channel n PDMA function Disabled. * | | |1 = Channel n PDMA function Enabled for the channel n to trigger PDMA to transfer memory data to register. * @var EPWM_T::CAPINEN * Offset: 0x200 EPWM Capture Input Enable Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CAPINEN0 |Capture Input Enable Bits * | | |0 = EPWM Channel capture input path Disabled * | | |The input of EPWM channel capture function is always regarded as 0. * | | |1 = EPWM Channel capture input path Enabled * | | |The input of EPWM channel capture function comes from correlative multifunction pin. * |[1] |CAPINEN1 |Capture Input Enable Bits * | | |0 = EPWM Channel capture input path Disabled * | | |The input of EPWM channel capture function is always regarded as 0. * | | |1 = EPWM Channel capture input path Enabled * | | |The input of EPWM channel capture function comes from correlative multifunction pin. * |[2] |CAPINEN2 |Capture Input Enable Bits * | | |0 = EPWM Channel capture input path Disabled * | | |The input of EPWM channel capture function is always regarded as 0. * | | |1 = EPWM Channel capture input path Enabled * | | |The input of EPWM channel capture function comes from correlative multifunction pin. * |[3] |CAPINEN3 |Capture Input Enable Bits * | | |0 = EPWM Channel capture input path Disabled * | | |The input of EPWM channel capture function is always regarded as 0. * | | |1 = EPWM Channel capture input path Enabled * | | |The input of EPWM channel capture function comes from correlative multifunction pin. * |[4] |CAPINEN4 |Capture Input Enable Bits * | | |0 = EPWM Channel capture input path Disabled * | | |The input of EPWM channel capture function is always regarded as 0. * | | |1 = EPWM Channel capture input path Enabled * | | |The input of EPWM channel capture function comes from correlative multifunction pin. * |[5] |CAPINEN5 |Capture Input Enable Bits * | | |0 = EPWM Channel capture input path Disabled * | | |The input of EPWM channel capture function is always regarded as 0. * | | |1 = EPWM Channel capture input path Enabled * | | |The input of EPWM channel capture function comes from correlative multifunction pin. * @var EPWM_T::CAPCTL * Offset: 0x204 EPWM Capture Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CAPEN0 |Capture Function Enable Bits * | | |0 = Capture function Disabled. RCAPDAT/FCAPDAT register will not be updated. * | | |1 = Capture function Enabled * | | |Capture latched the EPWM counter value when detected rising or falling edge of input signal and saved to RCAPDAT (Rising latch) and FCAPDAT (Falling latch). * |[1] |CAPEN1 |Capture Function Enable Bits * | | |0 = Capture function Disabled. RCAPDAT/FCAPDAT register will not be updated. * | | |1 = Capture function Enabled * | | |Capture latched the EPWM counter value when detected rising or falling edge of input signal and saved to RCAPDAT (Rising latch) and FCAPDAT (Falling latch). * |[2] |CAPEN2 |Capture Function Enable Bits * | | |0 = Capture function Disabled. RCAPDAT/FCAPDAT register will not be updated. * | | |1 = Capture function Enabled * | | |Capture latched the EPWM counter value when detected rising or falling edge of input signal and saved to RCAPDAT (Rising latch) and FCAPDAT (Falling latch). * |[3] |CAPEN3 |Capture Function Enable Bits * | | |0 = Capture function Disabled. RCAPDAT/FCAPDAT register will not be updated. * | | |1 = Capture function Enabled * | | |Capture latched the EPWM counter value when detected rising or falling edge of input signal and saved to RCAPDAT (Rising latch) and FCAPDAT (Falling latch). * |[4] |CAPEN4 |Capture Function Enable Bits * | | |0 = Capture function Disabled. RCAPDAT/FCAPDAT register will not be updated. * | | |1 = Capture function Enabled * | | |Capture latched the EPWM counter value when detected rising or falling edge of input signal and saved to RCAPDAT (Rising latch) and FCAPDAT (Falling latch). * |[5] |CAPEN5 |Capture Function Enable Bits * | | |0 = Capture function Disabled. RCAPDAT/FCAPDAT register will not be updated. * | | |1 = Capture function Enabled * | | |Capture latched the EPWM counter value when detected rising or falling edge of input signal and saved to RCAPDAT (Rising latch) and FCAPDAT (Falling latch). * |[8] |CAPINV0 |Capture Inverter Enable Bits * | | |0 = Capture source inverter Disabled. * | | |1 = Capture source inverter Enabled. Reverse the input signal from GPIO. * |[9] |CAPINV1 |Capture Inverter Enable Bits * | | |0 = Capture source inverter Disabled. * | | |1 = Capture source inverter Enabled. Reverse the input signal from GPIO. * |[10] |CAPINV2 |Capture Inverter Enable Bits * | | |0 = Capture source inverter Disabled. * | | |1 = Capture source inverter Enabled. Reverse the input signal from GPIO. * |[11] |CAPINV3 |Capture Inverter Enable Bits * | | |0 = Capture source inverter Disabled. * | | |1 = Capture source inverter Enabled. Reverse the input signal from GPIO. * |[12] |CAPINV4 |Capture Inverter Enable Bits * | | |0 = Capture source inverter Disabled. * | | |1 = Capture source inverter Enabled. Reverse the input signal from GPIO. * |[13] |CAPINV5 |Capture Inverter Enable Bits * | | |0 = Capture source inverter Disabled. * | | |1 = Capture source inverter Enabled. Reverse the input signal from GPIO. * |[16] |RCRLDEN0 |Rising Capture Reload Enable Bits * | | |0 = Rising capture reload counter Disabled. * | | |1 = Rising capture reload counter Enabled. * |[17] |RCRLDEN1 |Rising Capture Reload Enable Bits * | | |0 = Rising capture reload counter Disabled. * | | |1 = Rising capture reload counter Enabled. * |[18] |RCRLDEN2 |Rising Capture Reload Enable Bits * | | |0 = Rising capture reload counter Disabled. * | | |1 = Rising capture reload counter Enabled. * |[19] |RCRLDEN3 |Rising Capture Reload Enable Bits * | | |0 = Rising capture reload counter Disabled. * | | |1 = Rising capture reload counter Enabled. * |[20] |RCRLDEN4 |Rising Capture Reload Enable Bits * | | |0 = Rising capture reload counter Disabled. * | | |1 = Rising capture reload counter Enabled. * |[21] |RCRLDEN5 |Rising Capture Reload Enable Bits * | | |0 = Rising capture reload counter Disabled. * | | |1 = Rising capture reload counter Enabled. * |[24] |FCRLDEN0 |Falling Capture Reload Enable Bits * | | |0 = Falling capture reload counter Disabled. * | | |1 = Falling capture reload counter Enabled. * |[25] |FCRLDEN1 |Falling Capture Reload Enable Bits * | | |0 = Falling capture reload counter Disabled. * | | |1 = Falling capture reload counter Enabled. * |[26] |FCRLDEN2 |Falling Capture Reload Enable Bits * | | |0 = Falling capture reload counter Disabled. * | | |1 = Falling capture reload counter Enabled. * |[27] |FCRLDEN3 |Falling Capture Reload Enable Bits * | | |0 = Falling capture reload counter Disabled. * | | |1 = Falling capture reload counter Enabled. * |[28] |FCRLDEN4 |Falling Capture Reload Enable Bits * | | |0 = Falling capture reload counter Disabled. * | | |1 = Falling capture reload counter Enabled. * |[29] |FCRLDEN5 |Falling Capture Reload Enable Bits * | | |0 = Falling capture reload counter Disabled. * | | |1 = Falling capture reload counter Enabled. * @var EPWM_T::CAPSTS * Offset: 0x208 EPWM Capture Status Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CRLIFOV0 |Capture Rising Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if rising latch happened when the corresponding CRLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CRLIF. * |[1] |CRLIFOV1 |Capture Rising Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if rising latch happened when the corresponding CRLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CRLIF. * |[2] |CRLIFOV2 |Capture Rising Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if rising latch happened when the corresponding CRLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CRLIF. * |[3] |CRLIFOV3 |Capture Rising Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if rising latch happened when the corresponding CRLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CRLIF. * |[4] |CRLIFOV4 |Capture Rising Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if rising latch happened when the corresponding CRLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CRLIF. * |[5] |CRLIFOV5 |Capture Rising Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if rising latch happened when the corresponding CRLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CRLIF. * |[8] |CFLIFOV0 |Capture Falling Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if falling latch happened when the corresponding CFLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CFLIF. * |[9] |CFLIFOV1 |Capture Falling Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if falling latch happened when the corresponding CFLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CFLIF. * |[10] |CFLIFOV2 |Capture Falling Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if falling latch happened when the corresponding CFLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CFLIF. * |[11] |CFLIFOV3 |Capture Falling Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if falling latch happened when the corresponding CFLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CFLIF. * |[12] |CFLIFOV4 |Capture Falling Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if falling latch happened when the corresponding CFLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CFLIF. * |[13] |CFLIFOV5 |Capture Falling Latch Interrupt Flag Overrun Status (Read Only) * | | |This flag indicates if falling latch happened when the corresponding CFLIF is 1. * | | |Note: This bit will be cleared automatically when user clear corresponding CFLIF. * @var EPWM_T::PDMACTL * Offset: 0x23C EPWM PDMA Control Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CHEN0_1 |Channel 0/1 PDMA Enable * | | |0 = Channel 0/1 PDMA function Disabled. * | | |1 = Channel 0/1 PDMA function Enabled for the channel 0/1 captured data and transfer to memory. * |[2:1] |CAPMOD0_1 |Select EPWM_RCAPDAT0/1 or EPWM_FCAPDAT0/1 to Do PDMA Transfer * | | |00 = Reserved. * | | |01 = EPWM_RCAPDAT0/1 register. * | | |10 = EPWM_FCAPDAT0/1 register. * | | |11 = Both EPWM_RCAPDAT0/1 and EPWM_FCAPDAT0/1 registers. * |[3] |CAPORD0_1 |Capture Channel 0/1 Rising/Falling Order * | | |Set this bit to determine whether the EPWM_RCAPDAT0/1 or EPWM_FCAPDAT0/1 register is the first captured data transferred to memory through PDMA when CAPMOD0_1 bits are set to = 0x3. * | | |0 = EPWM_FCAPDAT0/1 register is the first captured data to memory. * | | |1 = EPWM_RCAPDAT0/1 register is the first captured data to memory. * |[4] |CHSEL0_1 |Select Channel 0/1 to Do PDMA Transfer * | | |0 = Channel0. * | | |1 = Channel1. * |[8] |CHEN2_3 |Channel 2/3 PDMA Enable * | | |0 = Channel 2/3 PDMA function Disabled. * | | |1 = Channel 2/3 PDMA function Enabled for the channel 2/3 captured data and transfer to memory. * |[10:9] |CAPMOD2_3 |Select EPWM_RCAPDAT2/3 or EPWM_FCAODAT2/3 to Do PDMA Transfer * | | |00 = Reserved. * | | |01 = EPWM_RCAPDAT2/3 register. * | | |10 = EPWM_FCAPDAT2/3 register. * | | |11 = Both EPWM_RCAPDAT2/3 and EPWM_FCAPDAT2/3 registers. * |[11] |CAPORD2_3 |Capture Channel 2/3 Rising/Falling Order * | | |Set this bit to determine whether the EPWM_RCAPDAT2/3 or EPWM_FCAPDAT2/3 register is the first captured data transferred to memory through PDMA when CAPMOD2_3 bits are set to =0x3. * | | |0 = EPWM_FCAPDAT2/3 register is the first captured data to memory. * | | |1 = EPWM_RCAPDAT2/3 register is the first captured data to memory. * |[12] |CHSEL2_3 |Select Channel 2/3 to Do PDMA Transfer * | | |0 = Channel2. * | | |1 = Channel3. * |[16] |CHEN4_5 |Channel 4/5 PDMA Enable * | | |0 = Channel 4/5 PDMA function Disabled. * | | |1 = Channel 4/5 PDMA function Enabled for the channel 4/5 captured data and transfer to memory. * |[18:17] |CAPMOD4_5 |Select EPWM_RCAPDAT4/5 or EPWM_FCAPDAT4/5 to Do PDMA Transfer * | | |00 = Reserved. * | | |01 = EPWM_RCAPDAT4/5 register. * | | |10 = EPWM_FCAPDAT4/5 register. * | | |11 = Both EPWM_RCAPDAT4/5 and EPWM_FCAPDAT4/5 registers. * |[19] |CAPORD4_5 |Capture Channel 4/5 Rising/Falling Order * | | |Set this bit to determine whether the EPWM_RCAPDAT4/5 or EPWM_FCAPDAT4/5 register is the first captured data transferred to memory through PDMA when CAPMOD4_5 bits =are set to 0x3. * | | |0 = EPWM_FCAPDAT4/5 register is the first captured data to memory. * | | |1 = EPWM_RCAPDAT4/5 register is the first captured data to memory. * |[20] |CHSEL4_5 |Select Channel 4/5 to Do PDMA Transfer * | | |0 = Channel4. * | | |1 = Channel5. * @var EPWM_T::PDMACAP[3] * Offset: 0x240 EPWM Capture Channel 01 PDMA Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |CAPBUF |EPWM Capture PDMA Register (Read Only) * | | |This register is use as a buffer to transfer EPWM capture rising or falling data to memory by PDMA. * @var EPWM_T::CAPIEN * Offset: 0x250 EPWM Capture Interrupt Enable Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CAPRIEN0 |EPWM Capture Rising Latch Interrupt Enable Bits * | | |0 = Capture rising edge latch interrupt Disabled. * | | |1 = Capture rising edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPRIEN0 bit must be disabled. * |[1] |CAPRIEN1 |EPWM Capture Rising Latch Interrupt Enable Bits * | | |0 = Capture rising edge latch interrupt Disabled. * | | |1 = Capture rising edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPRIEN1 bit must be disabled. * |[2] |CAPRIEN2 |EPWM Capture Rising Latch Interrupt Enable Bits * | | |0 = Capture rising edge latch interrupt Disabled. * | | |1 = Capture rising edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPRIEN2 bit must be disabled. * |[3] |CAPRIEN3 |EPWM Capture Rising Latch Interrupt Enable Bits * | | |0 = Capture rising edge latch interrupt Disabled. * | | |1 = Capture rising edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPRIEN3 bit must be disabled. * |[4] |CAPRIEN4 |EPWM Capture Rising Latch Interrupt Enable Bits * | | |0 = Capture rising edge latch interrupt Disabled. * | | |1 = Capture rising edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPRIEN4 bit must be disabled. * |[5] |CAPRIEN5 |EPWM Capture Rising Latch Interrupt Enable Bits * | | |0 = Capture rising edge latch interrupt Disabled. * | | |1 = Capture rising edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPRIEN5 bit must be disabled. * |[8] |CAPFIEN0 |EPWM Capture Falling Latch Interrupt Enable Bits * | | |0 = Capture falling edge latch interrupt Disabled. * | | |1 = Capture falling edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPFIEN0 bit must be disabled. * |[9] |CAPFIEN1 |EPWM Capture Falling Latch Interrupt Enable Bits * | | |0 = Capture falling edge latch interrupt Disabled. * | | |1 = Capture falling edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPFIEN1 bit must be disabled. * |[10] |CAPFIEN2 |EPWM Capture Falling Latch Interrupt Enable Bits * | | |0 = Capture falling edge latch interrupt Disabled. * | | |1 = Capture falling edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPFIEN2 bit must be disabled. * |[11] |CAPFIEN3 |EPWM Capture Falling Latch Interrupt Enable Bits * | | |0 = Capture falling edge latch interrupt Disabled. * | | |1 = Capture falling edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPFIEN3 bit must be disabled. * |[12] |CAPFIEN4 |EPWM Capture Falling Latch Interrupt Enable Bits * | | |0 = Capture falling edge latch interrupt Disabled. * | | |1 = Capture falling edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPFIEN4 bit must be disabled. * |[13] |CAPFIEN5 |EPWM Capture Falling Latch Interrupt Enable Bits * | | |0 = Capture falling edge latch interrupt Disabled. * | | |1 = Capture falling edge latch interrupt Enabled. * | | |Note: When Capture with PDMA operating, corresponding channel CAPFIEN5 bit must be disabled. * @var EPWM_T::CAPIF * Offset: 0x254 EPWM Capture Interrupt Flag Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |CRLIF0 |EPWM Capture Rising Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture rising latch condition happened. * | | |1 = Capture rising latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CRLIF0 bit will cleared by hardware after PDMA transfer data. * |[1] |CRLIF1 |EPWM Capture Rising Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture rising latch condition happened. * | | |1 = Capture rising latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CRLIF1 bit will cleared by hardware after PDMA transfer data. * |[2] |CRLIF2 |EPWM Capture Rising Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture rising latch condition happened. * | | |1 = Capture rising latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CRLIF2 bit will cleared by hardware after PDMA transfer data. * |[3] |CRLIF3 |EPWM Capture Rising Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture rising latch condition happened. * | | |1 = Capture rising latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CRLIF3 bit will cleared by hardware after PDMA transfer data. * |[4] |CRLIF4 |EPWM Capture Rising Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture rising latch condition happened. * | | |1 = Capture rising latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CRLIF4 bit will cleared by hardware after PDMA transfer data. * |[5] |CRLIF5 |EPWM Capture Rising Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture rising latch condition happened. * | | |1 = Capture rising latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CRLIF5 bit will cleared by hardware after PDMA transfer data. * |[8] |CFLIF0 |EPWM Capture Falling Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture falling latch condition happened. * | | |1 = Capture falling latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CFLIF0 bit will cleared by hardware after PDMA transfer data. * |[9] |CFLIF1 |EPWM Capture Falling Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture falling latch condition happened. * | | |1 = Capture falling latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CFLIF1 bit will cleared by hardware after PDMA transfer data. * |[10] |CFLIF2 |EPWM Capture Falling Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture falling latch condition happened. * | | |1 = Capture falling latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CFLIF2 bit will cleared by hardware after PDMA transfer data. * |[11] |CFLIF3 |EPWM Capture Falling Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture falling latch condition happened. * | | |1 = Capture falling latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CFLIF3 bit will cleared by hardware after PDMA transfer data. * |[12] |CFLIF4 |EPWM Capture Falling Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture falling latch condition happened. * | | |1 = Capture falling latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, corresponding channel CFLIF4 bit will cleared by hardware after PDMA transfer data. * |[13] |CFLIF5 |EPWM Capture Falling Latch Interrupt Flag * | | |This bit is writing 1 to clear. * | | |0 = No capture falling latch condition happened. * | | |1 = Capture falling latch condition happened, this flag will be set to high. * | | |Note: When Capture with PDMA operating, CAPIF corresponding channel CFLIF will cleared by hardware after PDMA transfer data. * @var EPWM_T::PBUF[6] * Offset: 0x304 EPWM PERIOD0~5 Buffer * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |PBUF |EPWM Period Register Buffer (Read Only) * | | |Used as PERIOD active register. * @var EPWM_T::CMPBUF[6] * Offset: 0x31C EPWM CMPDAT0~5 Buffer * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |CMPBUF |EPWM Comparator Register Buffer (Read Only) * | | |Used as CMP active register. * @var EPWM_T::CPSCBUF[3] * Offset: 0x334 EPWM CLKPSC0_1/2_3/4_5 Buffer * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[11:0] |CPSCBUF |EPWM Counter Clock Prescale Buffer * | | |Use as EPWM counter clock prescale active register. * @var EPWM_T::FTCBUF[3] * Offset: 0x340 EPWM FTCMPDAT0_1/2_3/4_5 Buffer * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[15:0] |FTCMPBUF |EPWM FTCMPDAT Buffer (Read Only) * | | |Used as FTCMPDAT active register. * @var EPWM_T::FTCI * Offset: 0x34C EPWM FTCMPDAT Indicator Register * --------------------------------------------------------------------------------------------------- * |Bits |Field |Descriptions * | :----: | :----: | :---- | * |[0] |FTCMU0 |EPWM FTCMPDAT Up Indicator * | | |Indicator will be set to high when FTCMPDATn equal to CNTn and DIRF=1, software can write 1 to clear this bit. * |[1] |FTCMU2 |EPWM FTCMPDAT Up Indicator * | | |Indicator will be set to high when FTCMPDATn equal to CNTn and DIRF=1, software can write 1 to clear this bit. * |[2] |FTCMU4 |EPWM FTCMPDAT Up Indicator * | | |Indicator will be set to high when FTCMPDATn equal to CNTn and DIRF=1, software can write 1 to clear this bit. * |[8] |FTCMD0 |EPWM FTCMPDAT Down Indicator * | | |Indicator will be set to high when FTCMPDATn equal to CNTn and DIRF=0, software can write 1 to clear this bit. * |[9] |FTCMD2 |EPWM FTCMPDAT Down Indicator * | | |Indicator will be set to high when FTCMPDATn equal to CNTn and DIRF=0, software can write 1 to clear this bit. * |[10] |FTCMD4 |EPWM FTCMPDAT Down Indicator * | | |Indicator will be set to high when FTCMPDATn equal to CNTn and DIRF=0, software can write 1 to clear this bit. */ __IO uint32_t CTL0; /*!< [0x0000] EPWM Control Register 0 */ __IO uint32_t CTL1; /*!< [0x0004] EPWM Control Register 1 */ __IO uint32_t SYNC; /*!< [0x0008] EPWM Synchronization Register */ __IO uint32_t SWSYNC; /*!< [0x000c] EPWM Software Control Synchronization Register */ __IO uint32_t CLKSRC; /*!< [0x0010] EPWM Clock Source Register */ __IO uint32_t CLKPSC[3]; /*!< [0x0014~0x001c] EPWM Clock Prescale Register 0_1,2_3,4_5 */ __IO uint32_t CNTEN; /*!< [0x0020] EPWM Counter Enable Register */ __IO uint32_t CNTCLR; /*!< [0x0024] EPWM Clear Counter Register */ __IO uint32_t LOAD; /*!< [0x0028] EPWM Load Register */ __I uint32_t RESERVE0[1]; __IO uint32_t PERIOD[6]; /*!< [0x0030~0x0044] EPWM Period Register 0~5 */ __I uint32_t RESERVE1[2]; __IO uint32_t CMPDAT[6]; /*!< [0x0050~0x0064] EPWM Comparator Register 0~5 */ __I uint32_t RESERVE2[2]; __IO uint32_t DTCTL[3]; /*!< [0x0070~0x0078] EPWM Dead-Time Control Register 0_1,2_3,4_5 */ __I uint32_t RESERVE3[1]; __IO uint32_t PHS[3]; /*!< [0x0080~0x0088] EPWM Counter Phase Register 0_1,2_3,4_5 */ __I uint32_t RESERVE4[1]; __I uint32_t CNT[6]; /*!< [0x0090~0x00A4 EPWM Counter Register 0~5 */ __I uint32_t RESERVE5[2]; __IO uint32_t WGCTL0; /*!< [0x00b0] EPWM Generation Register 0 */ __IO uint32_t WGCTL1; /*!< [0x00b4] EPWM Generation Register 1 */ __IO uint32_t MSKEN; /*!< [0x00b8] EPWM Mask Enable Register */ __IO uint32_t MSK; /*!< [0x00bc] EPWM Mask Data Register */ __IO uint32_t BNF; /*!< [0x00c0] EPWM Brake Noise Filter Register */ __IO uint32_t FAILBRK; /*!< [0x00c4] EPWM System Fail Brake Control Register */ __IO uint32_t BRKCTL[3]; /*!< [0x00c8~0x00d0] EPWM Brake Edge Detect Control Register 0_1,2_3,4_5 */ __IO uint32_t POLCTL; /*!< [0x00d4] EPWM Pin Polar Inverse Register */ __IO uint32_t POEN; /*!< [0x00d8] EPWM Output Enable Register */ __O uint32_t SWBRK; /*!< [0x00dc] EPWM Software Brake Control Register */ __IO uint32_t INTEN0; /*!< [0x00e0] EPWM Interrupt Enable Register 0 */ __IO uint32_t INTEN1; /*!< [0x00e4] EPWM Interrupt Enable Register 1 */ __IO uint32_t INTSTS0; /*!< [0x00e8] EPWM Interrupt Flag Register 0 */ __IO uint32_t INTSTS1; /*!< [0x00ec] EPWM Interrupt Flag Register 1 */ __I uint32_t RESERVE6[1]; __IO uint32_t DACTRGEN; /*!< [0x00f4] EPWM Trigger DAC Enable Register */ __IO uint32_t EADCTS0; /*!< [0x00f8] EPWM Trigger EADC Source Select Register 0 */ __IO uint32_t EADCTS1; /*!< [0x00fc] EPWM Trigger EADC Source Select Register 1 */ __IO uint32_t FTCMPDAT[3]; /*!< [0x0100~0x108] EPWM Free Trigger Compare Register 0_1,2_3,4_5 */ __I uint32_t RESERVE7[1]; __IO uint32_t SSCTL; /*!< [0x0110] EPWM Synchronous Start Control Register */ __O uint32_t SSTRG; /*!< [0x0114] EPWM Synchronous Start Trigger Register */ __IO uint32_t LEBCTL; /*!< [0x0118] EPWM Leading Edge Blanking Control Register */ __IO uint32_t LEBCNT; /*!< [0x011c] EPWM Leading Edge Blanking Counter Register */ __IO uint32_t STATUS; /*!< [0x0120] EPWM Status Register */ __I uint32_t RESERVE8[3]; __IO uint32_t IFA[6]; /*!< [0x0130~0x144] EPWM Interrupt Flag Accumulator Register 0~5 */ __I uint32_t RESERVE9[2]; __IO uint32_t AINTSTS; /*!< [0x0150] EPWM Accumulator Interrupt Flag Register */ __IO uint32_t AINTEN; /*!< [0x0154] EPWM Accumulator Interrupt Enable Register */ __IO uint32_t APDMACTL; /*!< [0x0158] EPWM Accumulator PDMA Control Register */ __I uint32_t RESERVE10[1]; __IO uint32_t FDEN; /*!< [0x0160] EPWM Fault Detect Enable Register */ __IO uint32_t FDCTL[6]; /*!< [0x0164~0x178] EPWM Fault Detect Control Register 0~5 */ __IO uint32_t FDIEN; /*!< [0x017C] EPWM Fault Detect Interrupt Enable Register */ __IO uint32_t FDSTS; /*!< [0x0180] EPWM Fault Detect Interrupt Flag Register */ __IO uint32_t EADCPSCCTL; /*!< [0x0184] EPWM Trigger EADC Prescale Control Register */ __IO uint32_t EADCPSC0; /*!< [0x0188] EPWM Trigger EADC Prescale Register 0 */ __IO uint32_t EADCPSC1; /*!< [0x018C] EPWM Trigger EADC Prescale Register 1 */ __IO uint32_t EADCPSCNT0; /*!< [0x0190] EPWM Trigger EADC Prescale Counter Register 0 */ __IO uint32_t EADCPSCNT1; /*!< [0x0194] EPWM Trigger EADC Prescale Counter Register 1 */ __I uint32_t RESERVE11[26]; __IO uint32_t CAPINEN; /*!< [0x0200] EPWM Capture Input Enable Register */ __IO uint32_t CAPCTL; /*!< [0x0204] EPWM Capture Control Register */ __I uint32_t CAPSTS; /*!< [0x0208] EPWM Capture Status Register */ ECAPDAT_T CAPDAT[6]; /*!< [0x020c~0x0238] EPWM Rising and Falling Capture Data Register 0~5 */ __IO uint32_t PDMACTL; /*!< [0x023c] EPWM PDMA Control Register */ __I uint32_t PDMACAP[3]; /*!< [0x0240~0x248] EPWM Capture Channel 0_1,2_3,4_5 PDMA Register */ __I uint32_t RESERVE12[1]; __IO uint32_t CAPIEN; /*!< [0x0250] EPWM Capture Interrupt Enable Register */ __IO uint32_t CAPIF; /*!< [0x0254] EPWM Capture Interrupt Flag Register */ __I uint32_t RESERVE13[43]; __I uint32_t PBUF[6]; /*!< [0x0304~0x0318 EPWM PERIOD0~5 Buffer */ __I uint32_t CMPBUF[6]; /*!< [0x031C~0x0330 EPWM CMPDAT0~5 Buffer */ __I uint32_t CPSCBUF[3]; /*!< [0x0334~0x33c] EPWM CLKPSC0_1,2_3,4_5 Buffer */ __I uint32_t FTCBUF[3]; /*!< [0x0340~0x348] EPWM FTCMPDAT0_1,2_3,4_5 Buffer */ __IO uint32_t FTCI; /*!< [0x034c] EPWM FTCMPDAT Indicator Register */ } EPWM_T; /** @addtogroup EPWM_CONST EPWM Bit Field Definition Constant Definitions for EPWM Controller @{ */ #define EPWM_CTL0_CTRLD0_Pos (0) /*!< EPWM_T::CTL0: CTRLD0 Position */ #define EPWM_CTL0_CTRLD0_Msk (0x1ul << EPWM_CTL0_CTRLD0_Pos) /*!< EPWM_T::CTL0: CTRLD0 Mask */ #define EPWM_CTL0_CTRLD1_Pos (1) /*!< EPWM_T::CTL0: CTRLD1 Position */ #define EPWM_CTL0_CTRLD1_Msk (0x1ul << EPWM_CTL0_CTRLD1_Pos) /*!< EPWM_T::CTL0: CTRLD1 Mask */ #define EPWM_CTL0_CTRLD2_Pos (2) /*!< EPWM_T::CTL0: CTRLD2 Position */ #define EPWM_CTL0_CTRLD2_Msk (0x1ul << EPWM_CTL0_CTRLD2_Pos) /*!< EPWM_T::CTL0: CTRLD2 Mask */ #define EPWM_CTL0_CTRLD3_Pos (3) /*!< EPWM_T::CTL0: CTRLD3 Position */ #define EPWM_CTL0_CTRLD3_Msk (0x1ul << EPWM_CTL0_CTRLD3_Pos) /*!< EPWM_T::CTL0: CTRLD3 Mask */ #define EPWM_CTL0_CTRLD4_Pos (4) /*!< EPWM_T::CTL0: CTRLD4 Position */ #define EPWM_CTL0_CTRLD4_Msk (0x1ul << EPWM_CTL0_CTRLD4_Pos) /*!< EPWM_T::CTL0: CTRLD4 Mask */ #define EPWM_CTL0_CTRLD5_Pos (5) /*!< EPWM_T::CTL0: CTRLD5 Position */ #define EPWM_CTL0_CTRLD5_Msk (0x1ul << EPWM_CTL0_CTRLD5_Pos) /*!< EPWM_T::CTL0: CTRLD5 Mask */ #define EPWM_CTL0_WINLDEN0_Pos (8) /*!< EPWM_T::CTL0: WINLDEN0 Position */ #define EPWM_CTL0_WINLDEN0_Msk (0x1ul << EPWM_CTL0_WINLDEN0_Pos) /*!< EPWM_T::CTL0: WINLDEN0 Mask */ #define EPWM_CTL0_WINLDEN1_Pos (9) /*!< EPWM_T::CTL0: WINLDEN1 Position */ #define EPWM_CTL0_WINLDEN1_Msk (0x1ul << EPWM_CTL0_WINLDEN1_Pos) /*!< EPWM_T::CTL0: WINLDEN1 Mask */ #define EPWM_CTL0_WINLDEN2_Pos (10) /*!< EPWM_T::CTL0: WINLDEN2 Position */ #define EPWM_CTL0_WINLDEN2_Msk (0x1ul << EPWM_CTL0_WINLDEN2_Pos) /*!< EPWM_T::CTL0: WINLDEN2 Mask */ #define EPWM_CTL0_WINLDEN3_Pos (11) /*!< EPWM_T::CTL0: WINLDEN3 Position */ #define EPWM_CTL0_WINLDEN3_Msk (0x1ul << EPWM_CTL0_WINLDEN3_Pos) /*!< EPWM_T::CTL0: WINLDEN3 Mask */ #define EPWM_CTL0_WINLDEN4_Pos (12) /*!< EPWM_T::CTL0: WINLDEN4 Position */ #define EPWM_CTL0_WINLDEN4_Msk (0x1ul << EPWM_CTL0_WINLDEN4_Pos) /*!< EPWM_T::CTL0: WINLDEN4 Mask */ #define EPWM_CTL0_WINLDEN5_Pos (13) /*!< EPWM_T::CTL0: WINLDEN5 Position */ #define EPWM_CTL0_WINLDEN5_Msk (0x1ul << EPWM_CTL0_WINLDEN5_Pos) /*!< EPWM_T::CTL0: WINLDEN5 Mask */ #define EPWM_CTL0_IMMLDEN0_Pos (16) /*!< EPWM_T::CTL0: IMMLDEN0 Position */ #define EPWM_CTL0_IMMLDEN0_Msk (0x1ul << EPWM_CTL0_IMMLDEN0_Pos) /*!< EPWM_T::CTL0: IMMLDEN0 Mask */ #define EPWM_CTL0_IMMLDEN1_Pos (17) /*!< EPWM_T::CTL0: IMMLDEN1 Position */ #define EPWM_CTL0_IMMLDEN1_Msk (0x1ul << EPWM_CTL0_IMMLDEN1_Pos) /*!< EPWM_T::CTL0: IMMLDEN1 Mask */ #define EPWM_CTL0_IMMLDEN2_Pos (18) /*!< EPWM_T::CTL0: IMMLDEN2 Position */ #define EPWM_CTL0_IMMLDEN2_Msk (0x1ul << EPWM_CTL0_IMMLDEN2_Pos) /*!< EPWM_T::CTL0: IMMLDEN2 Mask */ #define EPWM_CTL0_IMMLDEN3_Pos (19) /*!< EPWM_T::CTL0: IMMLDEN3 Position */ #define EPWM_CTL0_IMMLDEN3_Msk (0x1ul << EPWM_CTL0_IMMLDEN3_Pos) /*!< EPWM_T::CTL0: IMMLDEN3 Mask */ #define EPWM_CTL0_IMMLDEN4_Pos (20) /*!< EPWM_T::CTL0: IMMLDEN4 Position */ #define EPWM_CTL0_IMMLDEN4_Msk (0x1ul << EPWM_CTL0_IMMLDEN4_Pos) /*!< EPWM_T::CTL0: IMMLDEN4 Mask */ #define EPWM_CTL0_IMMLDEN5_Pos (21) /*!< EPWM_T::CTL0: IMMLDEN5 Position */ #define EPWM_CTL0_IMMLDEN5_Msk (0x1ul << EPWM_CTL0_IMMLDEN5_Pos) /*!< EPWM_T::CTL0: IMMLDEN5 Mask */ #define EPWM_CTL0_GROUPEN_Pos (24) /*!< EPWM_T::CTL0: GROUPEN Position */ #define EPWM_CTL0_GROUPEN_Msk (0x1ul << EPWM_CTL0_GROUPEN_Pos) /*!< EPWM_T::CTL0: GROUPEN Mask */ #define EPWM_CTL0_DBGHALT_Pos (30) /*!< EPWM_T::CTL0: DBGHALT Position */ #define EPWM_CTL0_DBGHALT_Msk (0x1ul << EPWM_CTL0_DBGHALT_Pos) /*!< EPWM_T::CTL0: DBGHALT Mask */ #define EPWM_CTL0_DBGTRIOFF_Pos (31) /*!< EPWM_T::CTL0: DBGTRIOFF Position */ #define EPWM_CTL0_DBGTRIOFF_Msk (0x1ul << EPWM_CTL0_DBGTRIOFF_Pos) /*!< EPWM_T::CTL0: DBGTRIOFF Mask */ #define EPWM_CTL1_CNTTYPE0_Pos (0) /*!< EPWM_T::CTL1: CNTTYPE0 Position */ #define EPWM_CTL1_CNTTYPE0_Msk (0x3ul << EPWM_CTL1_CNTTYPE0_Pos) /*!< EPWM_T::CTL1: CNTTYPE0 Mask */ #define EPWM_CTL1_CNTTYPE1_Pos (2) /*!< EPWM_T::CTL1: CNTTYPE1 Position */ #define EPWM_CTL1_CNTTYPE1_Msk (0x3ul << EPWM_CTL1_CNTTYPE1_Pos) /*!< EPWM_T::CTL1: CNTTYPE1 Mask */ #define EPWM_CTL1_CNTTYPE2_Pos (4) /*!< EPWM_T::CTL1: CNTTYPE2 Position */ #define EPWM_CTL1_CNTTYPE2_Msk (0x3ul << EPWM_CTL1_CNTTYPE2_Pos) /*!< EPWM_T::CTL1: CNTTYPE2 Mask */ #define EPWM_CTL1_CNTTYPE3_Pos (6) /*!< EPWM_T::CTL1: CNTTYPE3 Position */ #define EPWM_CTL1_CNTTYPE3_Msk (0x3ul << EPWM_CTL1_CNTTYPE3_Pos) /*!< EPWM_T::CTL1: CNTTYPE3 Mask */ #define EPWM_CTL1_CNTTYPE4_Pos (8) /*!< EPWM_T::CTL1: CNTTYPE4 Position */ #define EPWM_CTL1_CNTTYPE4_Msk (0x3ul << EPWM_CTL1_CNTTYPE4_Pos) /*!< EPWM_T::CTL1: CNTTYPE4 Mask */ #define EPWM_CTL1_CNTTYPE5_Pos (10) /*!< EPWM_T::CTL1: CNTTYPE5 Position */ #define EPWM_CTL1_CNTTYPE5_Msk (0x3ul << EPWM_CTL1_CNTTYPE5_Pos) /*!< EPWM_T::CTL1: CNTTYPE5 Mask */ #define EPWM_CTL1_CNTMODE0_Pos (16) /*!< EPWM_T::CTL1: CNTMODE0 Position */ #define EPWM_CTL1_CNTMODE0_Msk (0x1ul << EPWM_CTL1_CNTMODE0_Pos) /*!< EPWM_T::CTL1: CNTMODE0 Mask */ #define EPWM_CTL1_CNTMODE1_Pos (17) /*!< EPWM_T::CTL1: CNTMODE1 Position */ #define EPWM_CTL1_CNTMODE1_Msk (0x1ul << EPWM_CTL1_CNTMODE1_Pos) /*!< EPWM_T::CTL1: CNTMODE1 Mask */ #define EPWM_CTL1_CNTMODE2_Pos (18) /*!< EPWM_T::CTL1: CNTMODE2 Position */ #define EPWM_CTL1_CNTMODE2_Msk (0x1ul << EPWM_CTL1_CNTMODE2_Pos) /*!< EPWM_T::CTL1: CNTMODE2 Mask */ #define EPWM_CTL1_CNTMODE3_Pos (19) /*!< EPWM_T::CTL1: CNTMODE3 Position */ #define EPWM_CTL1_CNTMODE3_Msk (0x1ul << EPWM_CTL1_CNTMODE3_Pos) /*!< EPWM_T::CTL1: CNTMODE3 Mask */ #define EPWM_CTL1_CNTMODE4_Pos (20) /*!< EPWM_T::CTL1: CNTMODE4 Position */ #define EPWM_CTL1_CNTMODE4_Msk (0x1ul << EPWM_CTL1_CNTMODE4_Pos) /*!< EPWM_T::CTL1: CNTMODE4 Mask */ #define EPWM_CTL1_CNTMODE5_Pos (21) /*!< EPWM_T::CTL1: CNTMODE5 Position */ #define EPWM_CTL1_CNTMODE5_Msk (0x1ul << EPWM_CTL1_CNTMODE5_Pos) /*!< EPWM_T::CTL1: CNTMODE5 Mask */ #define EPWM_CTL1_OUTMODE0_Pos (24) /*!< EPWM_T::CTL1: OUTMODE0 Position */ #define EPWM_CTL1_OUTMODE0_Msk (0x1ul << EPWM_CTL1_OUTMODE0_Pos) /*!< EPWM_T::CTL1: OUTMODE0 Mask */ #define EPWM_CTL1_OUTMODE2_Pos (25) /*!< EPWM_T::CTL1: OUTMODE2 Position */ #define EPWM_CTL1_OUTMODE2_Msk (0x1ul << EPWM_CTL1_OUTMODE2_Pos) /*!< EPWM_T::CTL1: OUTMODE2 Mask */ #define EPWM_CTL1_OUTMODE4_Pos (26) /*!< EPWM_T::CTL1: OUTMODE4 Position */ #define EPWM_CTL1_OUTMODE4_Msk (0x1ul << EPWM_CTL1_OUTMODE4_Pos) /*!< EPWM_T::CTL1: OUTMODE4 Mask */ #define EPWM_SYNC_PHSEN0_Pos (0) /*!< EPWM_T::SYNC: PHSEN0 Position */ #define EPWM_SYNC_PHSEN0_Msk (0x1ul << EPWM_SYNC_PHSEN0_Pos) /*!< EPWM_T::SYNC: PHSEN0 Mask */ #define EPWM_SYNC_PHSEN2_Pos (1) /*!< EPWM_T::SYNC: PHSEN2 Position */ #define EPWM_SYNC_PHSEN2_Msk (0x1ul << EPWM_SYNC_PHSEN2_Pos) /*!< EPWM_T::SYNC: PHSEN2 Mask */ #define EPWM_SYNC_PHSEN4_Pos (2) /*!< EPWM_T::SYNC: PHSEN4 Position */ #define EPWM_SYNC_PHSEN4_Msk (0x1ul << EPWM_SYNC_PHSEN4_Pos) /*!< EPWM_T::SYNC: PHSEN4 Mask */ #define EPWM_SYNC_SINSRC0_Pos (8) /*!< EPWM_T::SYNC: SINSRC0 Position */ #define EPWM_SYNC_SINSRC0_Msk (0x3ul << EPWM_SYNC_SINSRC0_Pos) /*!< EPWM_T::SYNC: SINSRC0 Mask */ #define EPWM_SYNC_SINSRC2_Pos (10) /*!< EPWM_T::SYNC: SINSRC2 Position */ #define EPWM_SYNC_SINSRC2_Msk (0x3ul << EPWM_SYNC_SINSRC2_Pos) /*!< EPWM_T::SYNC: SINSRC2 Mask */ #define EPWM_SYNC_SINSRC4_Pos (12) /*!< EPWM_T::SYNC: SINSRC4 Position */ #define EPWM_SYNC_SINSRC4_Msk (0x3ul << EPWM_SYNC_SINSRC4_Pos) /*!< EPWM_T::SYNC: SINSRC4 Mask */ #define EPWM_SYNC_SNFLTEN_Pos (16) /*!< EPWM_T::SYNC: SNFLTEN Position */ #define EPWM_SYNC_SNFLTEN_Msk (0x1ul << EPWM_SYNC_SNFLTEN_Pos) /*!< EPWM_T::SYNC: SNFLTEN Mask */ #define EPWM_SYNC_SFLTCSEL_Pos (17) /*!< EPWM_T::SYNC: SFLTCSEL Position */ #define EPWM_SYNC_SFLTCSEL_Msk (0x7ul << EPWM_SYNC_SFLTCSEL_Pos) /*!< EPWM_T::SYNC: SFLTCSEL Mask */ #define EPWM_SYNC_SFLTCNT_Pos (20) /*!< EPWM_T::SYNC: SFLTCNT Position */ #define EPWM_SYNC_SFLTCNT_Msk (0x7ul << EPWM_SYNC_SFLTCNT_Pos) /*!< EPWM_T::SYNC: SFLTCNT Mask */ #define EPWM_SYNC_SINPINV_Pos (23) /*!< EPWM_T::SYNC: SINPINV Position */ #define EPWM_SYNC_SINPINV_Msk (0x1ul << EPWM_SYNC_SINPINV_Pos) /*!< EPWM_T::SYNC: SINPINV Mask */ #define EPWM_SYNC_PHSDIR0_Pos (24) /*!< EPWM_T::SYNC: PHSDIR0 Position */ #define EPWM_SYNC_PHSDIR0_Msk (0x1ul << EPWM_SYNC_PHSDIR0_Pos) /*!< EPWM_T::SYNC: PHSDIR0 Mask */ #define EPWM_SYNC_PHSDIR2_Pos (25) /*!< EPWM_T::SYNC: PHSDIR2 Position */ #define EPWM_SYNC_PHSDIR2_Msk (0x1ul << EPWM_SYNC_PHSDIR2_Pos) /*!< EPWM_T::SYNC: PHSDIR2 Mask */ #define EPWM_SYNC_PHSDIR4_Pos (26) /*!< EPWM_T::SYNC: PHSDIR4 Position */ #define EPWM_SYNC_PHSDIR4_Msk (0x1ul << EPWM_SYNC_PHSDIR4_Pos) /*!< EPWM_T::SYNC: PHSDIR4 Mask */ #define EPWM_SWSYNC_SWSYNC0_Pos (0) /*!< EPWM_T::SWSYNC: SWSYNC0 Position */ #define EPWM_SWSYNC_SWSYNC0_Msk (0x1ul << EPWM_SWSYNC_SWSYNC0_Pos) /*!< EPWM_T::SWSYNC: SWSYNC0 Mask */ #define EPWM_SWSYNC_SWSYNC2_Pos (1) /*!< EPWM_T::SWSYNC: SWSYNC2 Position */ #define EPWM_SWSYNC_SWSYNC2_Msk (0x1ul << EPWM_SWSYNC_SWSYNC2_Pos) /*!< EPWM_T::SWSYNC: SWSYNC2 Mask */ #define EPWM_SWSYNC_SWSYNC4_Pos (2) /*!< EPWM_T::SWSYNC: SWSYNC4 Position */ #define EPWM_SWSYNC_SWSYNC4_Msk (0x1ul << EPWM_SWSYNC_SWSYNC4_Pos) /*!< EPWM_T::SWSYNC: SWSYNC4 Mask */ #define EPWM_CLKSRC_ECLKSRC0_Pos (0) /*!< EPWM_T::CLKSRC: ECLKSRC0 Position */ #define EPWM_CLKSRC_ECLKSRC0_Msk (0x7ul << EPWM_CLKSRC_ECLKSRC0_Pos) /*!< EPWM_T::CLKSRC: ECLKSRC0 Mask */ #define EPWM_CLKSRC_ECLKSRC2_Pos (8) /*!< EPWM_T::CLKSRC: ECLKSRC2 Position */ #define EPWM_CLKSRC_ECLKSRC2_Msk (0x7ul << EPWM_CLKSRC_ECLKSRC2_Pos) /*!< EPWM_T::CLKSRC: ECLKSRC2 Mask */ #define EPWM_CLKSRC_ECLKSRC4_Pos (16) /*!< EPWM_T::CLKSRC: ECLKSRC4 Position */ #define EPWM_CLKSRC_ECLKSRC4_Msk (0x7ul << EPWM_CLKSRC_ECLKSRC4_Pos) /*!< EPWM_T::CLKSRC: ECLKSRC4 Mask */ #define EPWM_CLKPSC0_1_CLKPSC_Pos (0) /*!< EPWM_T::CLKPSC0_1: CLKPSC Position */ #define EPWM_CLKPSC0_1_CLKPSC_Msk (0xffful << EPWM_CLKPSC0_1_CLKPSC_Pos) /*!< EPWM_T::CLKPSC0_1: CLKPSC Mask */ #define EPWM_CLKPSC2_3_CLKPSC_Pos (0) /*!< EPWM_T::CLKPSC2_3: CLKPSC Position */ #define EPWM_CLKPSC2_3_CLKPSC_Msk (0xffful << EPWM_CLKPSC2_3_CLKPSC_Pos) /*!< EPWM_T::CLKPSC2_3: CLKPSC Mask */ #define EPWM_CLKPSC4_5_CLKPSC_Pos (0) /*!< EPWM_T::CLKPSC4_5: CLKPSC Position */ #define EPWM_CLKPSC4_5_CLKPSC_Msk (0xffful << EPWM_CLKPSC4_5_CLKPSC_Pos) /*!< EPWM_T::CLKPSC4_5: CLKPSC Mask */ #define EPWM_CNTEN_CNTEN0_Pos (0) /*!< EPWM_T::CNTEN: CNTEN0 Position */ #define EPWM_CNTEN_CNTEN0_Msk (0x1ul << EPWM_CNTEN_CNTEN0_Pos) /*!< EPWM_T::CNTEN: CNTEN0 Mask */ #define EPWM_CNTEN_CNTEN1_Pos (1) /*!< EPWM_T::CNTEN: CNTEN1 Position */ #define EPWM_CNTEN_CNTEN1_Msk (0x1ul << EPWM_CNTEN_CNTEN1_Pos) /*!< EPWM_T::CNTEN: CNTEN1 Mask */ #define EPWM_CNTEN_CNTEN2_Pos (2) /*!< EPWM_T::CNTEN: CNTEN2 Position */ #define EPWM_CNTEN_CNTEN2_Msk (0x1ul << EPWM_CNTEN_CNTEN2_Pos) /*!< EPWM_T::CNTEN: CNTEN2 Mask */ #define EPWM_CNTEN_CNTEN3_Pos (3) /*!< EPWM_T::CNTEN: CNTEN3 Position */ #define EPWM_CNTEN_CNTEN3_Msk (0x1ul << EPWM_CNTEN_CNTEN3_Pos) /*!< EPWM_T::CNTEN: CNTEN3 Mask */ #define EPWM_CNTEN_CNTEN4_Pos (4) /*!< EPWM_T::CNTEN: CNTEN4 Position */ #define EPWM_CNTEN_CNTEN4_Msk (0x1ul << EPWM_CNTEN_CNTEN4_Pos) /*!< EPWM_T::CNTEN: CNTEN4 Mask */ #define EPWM_CNTEN_CNTEN5_Pos (5) /*!< EPWM_T::CNTEN: CNTEN5 Position */ #define EPWM_CNTEN_CNTEN5_Msk (0x1ul << EPWM_CNTEN_CNTEN5_Pos) /*!< EPWM_T::CNTEN: CNTEN5 Mask */ #define EPWM_CNTCLR_CNTCLR0_Pos (0) /*!< EPWM_T::CNTCLR: CNTCLR0 Position */ #define EPWM_CNTCLR_CNTCLR0_Msk (0x1ul << EPWM_CNTCLR_CNTCLR0_Pos) /*!< EPWM_T::CNTCLR: CNTCLR0 Mask */ #define EPWM_CNTCLR_CNTCLR1_Pos (1) /*!< EPWM_T::CNTCLR: CNTCLR1 Position */ #define EPWM_CNTCLR_CNTCLR1_Msk (0x1ul << EPWM_CNTCLR_CNTCLR1_Pos) /*!< EPWM_T::CNTCLR: CNTCLR1 Mask */ #define EPWM_CNTCLR_CNTCLR2_Pos (2) /*!< EPWM_T::CNTCLR: CNTCLR2 Position */ #define EPWM_CNTCLR_CNTCLR2_Msk (0x1ul << EPWM_CNTCLR_CNTCLR2_Pos) /*!< EPWM_T::CNTCLR: CNTCLR2 Mask */ #define EPWM_CNTCLR_CNTCLR3_Pos (3) /*!< EPWM_T::CNTCLR: CNTCLR3 Position */ #define EPWM_CNTCLR_CNTCLR3_Msk (0x1ul << EPWM_CNTCLR_CNTCLR3_Pos) /*!< EPWM_T::CNTCLR: CNTCLR3 Mask */ #define EPWM_CNTCLR_CNTCLR4_Pos (4) /*!< EPWM_T::CNTCLR: CNTCLR4 Position */ #define EPWM_CNTCLR_CNTCLR4_Msk (0x1ul << EPWM_CNTCLR_CNTCLR4_Pos) /*!< EPWM_T::CNTCLR: CNTCLR4 Mask */ #define EPWM_CNTCLR_CNTCLR5_Pos (5) /*!< EPWM_T::CNTCLR: CNTCLR5 Position */ #define EPWM_CNTCLR_CNTCLR5_Msk (0x1ul << EPWM_CNTCLR_CNTCLR5_Pos) /*!< EPWM_T::CNTCLR: CNTCLR5 Mask */ #define EPWM_LOAD_LOAD0_Pos (0) /*!< EPWM_T::LOAD: LOAD0 Position */ #define EPWM_LOAD_LOAD0_Msk (0x1ul << EPWM_LOAD_LOAD0_Pos) /*!< EPWM_T::LOAD: LOAD0 Mask */ #define EPWM_LOAD_LOAD1_Pos (1) /*!< EPWM_T::LOAD: LOAD1 Position */ #define EPWM_LOAD_LOAD1_Msk (0x1ul << EPWM_LOAD_LOAD1_Pos) /*!< EPWM_T::LOAD: LOAD1 Mask */ #define EPWM_LOAD_LOAD2_Pos (2) /*!< EPWM_T::LOAD: LOAD2 Position */ #define EPWM_LOAD_LOAD2_Msk (0x1ul << EPWM_LOAD_LOAD2_Pos) /*!< EPWM_T::LOAD: LOAD2 Mask */ #define EPWM_LOAD_LOAD3_Pos (3) /*!< EPWM_T::LOAD: LOAD3 Position */ #define EPWM_LOAD_LOAD3_Msk (0x1ul << EPWM_LOAD_LOAD3_Pos) /*!< EPWM_T::LOAD: LOAD3 Mask */ #define EPWM_LOAD_LOAD4_Pos (4) /*!< EPWM_T::LOAD: LOAD4 Position */ #define EPWM_LOAD_LOAD4_Msk (0x1ul << EPWM_LOAD_LOAD4_Pos) /*!< EPWM_T::LOAD: LOAD4 Mask */ #define EPWM_LOAD_LOAD5_Pos (5) /*!< EPWM_T::LOAD: LOAD5 Position */ #define EPWM_LOAD_LOAD5_Msk (0x1ul << EPWM_LOAD_LOAD5_Pos) /*!< EPWM_T::LOAD: LOAD5 Mask */ #define EPWM_PERIOD0_PERIOD_Pos (0) /*!< EPWM_T::PERIOD0: PERIOD Position */ #define EPWM_PERIOD0_PERIOD_Msk (0xfffful << EPWM_PERIOD0_PERIOD_Pos) /*!< EPWM_T::PERIOD0: PERIOD Mask */ #define EPWM_PERIOD1_PERIOD_Pos (0) /*!< EPWM_T::PERIOD1: PERIOD Position */ #define EPWM_PERIOD1_PERIOD_Msk (0xfffful << EPWM_PERIOD1_PERIOD_Pos) /*!< EPWM_T::PERIOD1: PERIOD Mask */ #define EPWM_PERIOD2_PERIOD_Pos (0) /*!< EPWM_T::PERIOD2: PERIOD Position */ #define EPWM_PERIOD2_PERIOD_Msk (0xfffful << EPWM_PERIOD2_PERIOD_Pos) /*!< EPWM_T::PERIOD2: PERIOD Mask */ #define EPWM_PERIOD3_PERIOD_Pos (0) /*!< EPWM_T::PERIOD3: PERIOD Position */ #define EPWM_PERIOD3_PERIOD_Msk (0xfffful << EPWM_PERIOD3_PERIOD_Pos) /*!< EPWM_T::PERIOD3: PERIOD Mask */ #define EPWM_PERIOD4_PERIOD_Pos (0) /*!< EPWM_T::PERIOD4: PERIOD Position */ #define EPWM_PERIOD4_PERIOD_Msk (0xfffful << EPWM_PERIOD4_PERIOD_Pos) /*!< EPWM_T::PERIOD4: PERIOD Mask */ #define EPWM_PERIOD5_PERIOD_Pos (0) /*!< EPWM_T::PERIOD5: PERIOD Position */ #define EPWM_PERIOD5_PERIOD_Msk (0xfffful << EPWM_PERIOD5_PERIOD_Pos) /*!< EPWM_T::PERIOD5: PERIOD Mask */ #define EPWM_CMPDAT0_CMP_Pos (0) /*!< EPWM_T::CMPDAT0: CMP Position */ #define EPWM_CMPDAT0_CMP_Msk (0xfffful << EPWM_CMPDAT0_CMP_Pos) /*!< EPWM_T::CMPDAT0: CMP Mask */ #define EPWM_CMPDAT1_CMP_Pos (0) /*!< EPWM_T::CMPDAT1: CMP Position */ #define EPWM_CMPDAT1_CMP_Msk (0xfffful << EPWM_CMPDAT1_CMP_Pos) /*!< EPWM_T::CMPDAT1: CMP Mask */ #define EPWM_CMPDAT2_CMP_Pos (0) /*!< EPWM_T::CMPDAT2: CMP Position */ #define EPWM_CMPDAT2_CMP_Msk (0xfffful << EPWM_CMPDAT2_CMP_Pos) /*!< EPWM_T::CMPDAT2: CMP Mask */ #define EPWM_CMPDAT3_CMP_Pos (0) /*!< EPWM_T::CMPDAT3: CMP Position */ #define EPWM_CMPDAT3_CMP_Msk (0xfffful << EPWM_CMPDAT3_CMP_Pos) /*!< EPWM_T::CMPDAT3: CMP Mask */ #define EPWM_CMPDAT4_CMP_Pos (0) /*!< EPWM_T::CMPDAT4: CMP Position */ #define EPWM_CMPDAT4_CMP_Msk (0xfffful << EPWM_CMPDAT4_CMP_Pos) /*!< EPWM_T::CMPDAT4: CMP Mask */ #define EPWM_CMPDAT5_CMP_Pos (0) /*!< EPWM_T::CMPDAT5: CMP Position */ #define EPWM_CMPDAT5_CMP_Msk (0xfffful << EPWM_CMPDAT5_CMP_Pos) /*!< EPWM_T::CMPDAT5: CMP Mask */ #define EPWM_DTCTL0_1_DTCNT_Pos (0) /*!< EPWM_T::DTCTL0_1: DTCNT Position */ #define EPWM_DTCTL0_1_DTCNT_Msk (0xffful << EPWM_DTCTL0_1_DTCNT_Pos) /*!< EPWM_T::DTCTL0_1: DTCNT Mask */ #define EPWM_DTCTL0_1_DTEN_Pos (16) /*!< EPWM_T::DTCTL0_1: DTEN Position */ #define EPWM_DTCTL0_1_DTEN_Msk (0x1ul << EPWM_DTCTL0_1_DTEN_Pos) /*!< EPWM_T::DTCTL0_1: DTEN Mask */ #define EPWM_DTCTL0_1_DTCKSEL_Pos (24) /*!< EPWM_T::DTCTL0_1: DTCKSEL Position */ #define EPWM_DTCTL0_1_DTCKSEL_Msk (0x1ul << EPWM_DTCTL0_1_DTCKSEL_Pos) /*!< EPWM_T::DTCTL0_1: DTCKSEL Mask */ #define EPWM_DTCTL2_3_DTCNT_Pos (0) /*!< EPWM_T::DTCTL2_3: DTCNT Position */ #define EPWM_DTCTL2_3_DTCNT_Msk (0xffful << EPWM_DTCTL2_3_DTCNT_Pos) /*!< EPWM_T::DTCTL2_3: DTCNT Mask */ #define EPWM_DTCTL2_3_DTEN_Pos (16) /*!< EPWM_T::DTCTL2_3: DTEN Position */ #define EPWM_DTCTL2_3_DTEN_Msk (0x1ul << EPWM_DTCTL2_3_DTEN_Pos) /*!< EPWM_T::DTCTL2_3: DTEN Mask */ #define EPWM_DTCTL2_3_DTCKSEL_Pos (24) /*!< EPWM_T::DTCTL2_3: DTCKSEL Position */ #define EPWM_DTCTL2_3_DTCKSEL_Msk (0x1ul << EPWM_DTCTL2_3_DTCKSEL_Pos) /*!< EPWM_T::DTCTL2_3: DTCKSEL Mask */ #define EPWM_DTCTL4_5_DTCNT_Pos (0) /*!< EPWM_T::DTCTL4_5: DTCNT Position */ #define EPWM_DTCTL4_5_DTCNT_Msk (0xffful << EPWM_DTCTL4_5_DTCNT_Pos) /*!< EPWM_T::DTCTL4_5: DTCNT Mask */ #define EPWM_DTCTL4_5_DTEN_Pos (16) /*!< EPWM_T::DTCTL4_5: DTEN Position */ #define EPWM_DTCTL4_5_DTEN_Msk (0x1ul << EPWM_DTCTL4_5_DTEN_Pos) /*!< EPWM_T::DTCTL4_5: DTEN Mask */ #define EPWM_DTCTL4_5_DTCKSEL_Pos (24) /*!< EPWM_T::DTCTL4_5: DTCKSEL Position */ #define EPWM_DTCTL4_5_DTCKSEL_Msk (0x1ul << EPWM_DTCTL4_5_DTCKSEL_Pos) /*!< EPWM_T::DTCTL4_5: DTCKSEL Mask */ #define EPWM_PHS0_1_PHS_Pos (0) /*!< EPWM_T::PHS0_1: PHS Position */ #define EPWM_PHS0_1_PHS_Msk (0xfffful << EPWM_PHS0_1_PHS_Pos) /*!< EPWM_T::PHS0_1: PHS Mask */ #define EPWM_PHS2_3_PHS_Pos (0) /*!< EPWM_T::PHS2_3: PHS Position */ #define EPWM_PHS2_3_PHS_Msk (0xfffful << EPWM_PHS2_3_PHS_Pos) /*!< EPWM_T::PHS2_3: PHS Mask */ #define EPWM_PHS4_5_PHS_Pos (0) /*!< EPWM_T::PHS4_5: PHS Position */ #define EPWM_PHS4_5_PHS_Msk (0xfffful << EPWM_PHS4_5_PHS_Pos) /*!< EPWM_T::PHS4_5: PHS Mask */ #define EPWM_CNT0_CNT_Pos (0) /*!< EPWM_T::CNT0: CNT Position */ #define EPWM_CNT0_CNT_Msk (0xfffful << EPWM_CNT0_CNT_Pos) /*!< EPWM_T::CNT0: CNT Mask */ #define EPWM_CNT0_DIRF_Pos (16) /*!< EPWM_T::CNT0: DIRF Position */ #define EPWM_CNT0_DIRF_Msk (0x1ul << EPWM_CNT0_DIRF_Pos) /*!< EPWM_T::CNT0: DIRF Mask */ #define EPWM_CNT1_CNT_Pos (0) /*!< EPWM_T::CNT1: CNT Position */ #define EPWM_CNT1_CNT_Msk (0xfffful << EPWM_CNT1_CNT_Pos) /*!< EPWM_T::CNT1: CNT Mask */ #define EPWM_CNT1_DIRF_Pos (16) /*!< EPWM_T::CNT1: DIRF Position */ #define EPWM_CNT1_DIRF_Msk (0x1ul << EPWM_CNT1_DIRF_Pos) /*!< EPWM_T::CNT1: DIRF Mask */ #define EPWM_CNT2_CNT_Pos (0) /*!< EPWM_T::CNT2: CNT Position */ #define EPWM_CNT2_CNT_Msk (0xfffful << EPWM_CNT2_CNT_Pos) /*!< EPWM_T::CNT2: CNT Mask */ #define EPWM_CNT2_DIRF_Pos (16) /*!< EPWM_T::CNT2: DIRF Position */ #define EPWM_CNT2_DIRF_Msk (0x1ul << EPWM_CNT2_DIRF_Pos) /*!< EPWM_T::CNT2: DIRF Mask */ #define EPWM_CNT3_CNT_Pos (0) /*!< EPWM_T::CNT3: CNT Position */ #define EPWM_CNT3_CNT_Msk (0xfffful << EPWM_CNT3_CNT_Pos) /*!< EPWM_T::CNT3: CNT Mask */ #define EPWM_CNT3_DIRF_Pos (16) /*!< EPWM_T::CNT3: DIRF Position */ #define EPWM_CNT3_DIRF_Msk (0x1ul << EPWM_CNT3_DIRF_Pos) /*!< EPWM_T::CNT3: DIRF Mask */ #define EPWM_CNT4_CNT_Pos (0) /*!< EPWM_T::CNT4: CNT Position */ #define EPWM_CNT4_CNT_Msk (0xfffful << EPWM_CNT4_CNT_Pos) /*!< EPWM_T::CNT4: CNT Mask */ #define EPWM_CNT4_DIRF_Pos (16) /*!< EPWM_T::CNT4: DIRF Position */ #define EPWM_CNT4_DIRF_Msk (0x1ul << EPWM_CNT4_DIRF_Pos) /*!< EPWM_T::CNT4: DIRF Mask */ #define EPWM_CNT5_CNT_Pos (0) /*!< EPWM_T::CNT5: CNT Position */ #define EPWM_CNT5_CNT_Msk (0xfffful << EPWM_CNT5_CNT_Pos) /*!< EPWM_T::CNT5: CNT Mask */ #define EPWM_CNT5_DIRF_Pos (16) /*!< EPWM_T::CNT5: DIRF Position */ #define EPWM_CNT5_DIRF_Msk (0x1ul << EPWM_CNT5_DIRF_Pos) /*!< EPWM_T::CNT5: DIRF Mask */ #define EPWM_WGCTL0_ZPCTL0_Pos (0) /*!< EPWM_T::WGCTL0: ZPCTL0 Position */ #define EPWM_WGCTL0_ZPCTL0_Msk (0x3ul << EPWM_WGCTL0_ZPCTL0_Pos) /*!< EPWM_T::WGCTL0: ZPCTL0 Mask */ #define EPWM_WGCTL0_ZPCTL1_Pos (2) /*!< EPWM_T::WGCTL0: ZPCTL1 Position */ #define EPWM_WGCTL0_ZPCTL1_Msk (0x3ul << EPWM_WGCTL0_ZPCTL1_Pos) /*!< EPWM_T::WGCTL0: ZPCTL1 Mask */ #define EPWM_WGCTL0_ZPCTL2_Pos (4) /*!< EPWM_T::WGCTL0: ZPCTL2 Position */ #define EPWM_WGCTL0_ZPCTL2_Msk (0x3ul << EPWM_WGCTL0_ZPCTL2_Pos) /*!< EPWM_T::WGCTL0: ZPCTL2 Mask */ #define EPWM_WGCTL0_ZPCTL3_Pos (6) /*!< EPWM_T::WGCTL0: ZPCTL3 Position */ #define EPWM_WGCTL0_ZPCTL3_Msk (0x3ul << EPWM_WGCTL0_ZPCTL3_Pos) /*!< EPWM_T::WGCTL0: ZPCTL3 Mask */ #define EPWM_WGCTL0_ZPCTL4_Pos (8) /*!< EPWM_T::WGCTL0: ZPCTL4 Position */ #define EPWM_WGCTL0_ZPCTL4_Msk (0x3ul << EPWM_WGCTL0_ZPCTL4_Pos) /*!< EPWM_T::WGCTL0: ZPCTL4 Mask */ #define EPWM_WGCTL0_ZPCTL5_Pos (10) /*!< EPWM_T::WGCTL0: ZPCTL5 Position */ #define EPWM_WGCTL0_ZPCTL5_Msk (0x3ul << EPWM_WGCTL0_ZPCTL5_Pos) /*!< EPWM_T::WGCTL0: ZPCTL5 Mask */ #define EPWM_WGCTL0_PRDPCTL0_Pos (16) /*!< EPWM_T::WGCTL0: PRDPCTL0 Position */ #define EPWM_WGCTL0_PRDPCTL0_Msk (0x3ul << EPWM_WGCTL0_PRDPCTL0_Pos) /*!< EPWM_T::WGCTL0: PRDPCTL0 Mask */ #define EPWM_WGCTL0_PRDPCTL1_Pos (18) /*!< EPWM_T::WGCTL0: PRDPCTL1 Position */ #define EPWM_WGCTL0_PRDPCTL1_Msk (0x3ul << EPWM_WGCTL0_PRDPCTL1_Pos) /*!< EPWM_T::WGCTL0: PRDPCTL1 Mask */ #define EPWM_WGCTL0_PRDPCTL2_Pos (20) /*!< EPWM_T::WGCTL0: PRDPCTL2 Position */ #define EPWM_WGCTL0_PRDPCTL2_Msk (0x3ul << EPWM_WGCTL0_PRDPCTL2_Pos) /*!< EPWM_T::WGCTL0: PRDPCTL2 Mask */ #define EPWM_WGCTL0_PRDPCTL3_Pos (22) /*!< EPWM_T::WGCTL0: PRDPCTL3 Position */ #define EPWM_WGCTL0_PRDPCTL3_Msk (0x3ul << EPWM_WGCTL0_PRDPCTL3_Pos) /*!< EPWM_T::WGCTL0: PRDPCTL3 Mask */ #define EPWM_WGCTL0_PRDPCTL4_Pos (24) /*!< EPWM_T::WGCTL0: PRDPCTL4 Position */ #define EPWM_WGCTL0_PRDPCTL4_Msk (0x3ul << EPWM_WGCTL0_PRDPCTL4_Pos) /*!< EPWM_T::WGCTL0: PRDPCTL4 Mask */ #define EPWM_WGCTL0_PRDPCTL5_Pos (26) /*!< EPWM_T::WGCTL0: PRDPCTL5 Position */ #define EPWM_WGCTL0_PRDPCTL5_Msk (0x3ul << EPWM_WGCTL0_PRDPCTL5_Pos) /*!< EPWM_T::WGCTL0: PRDPCTL5 Mask */ #define EPWM_WGCTL1_CMPUCTL0_Pos (0) /*!< EPWM_T::WGCTL1: CMPUCTL0 Position */ #define EPWM_WGCTL1_CMPUCTL0_Msk (0x3ul << EPWM_WGCTL1_CMPUCTL0_Pos) /*!< EPWM_T::WGCTL1: CMPUCTL0 Mask */ #define EPWM_WGCTL1_CMPUCTL1_Pos (2) /*!< EPWM_T::WGCTL1: CMPUCTL1 Position */ #define EPWM_WGCTL1_CMPUCTL1_Msk (0x3ul << EPWM_WGCTL1_CMPUCTL1_Pos) /*!< EPWM_T::WGCTL1: CMPUCTL1 Mask */ #define EPWM_WGCTL1_CMPUCTL2_Pos (4) /*!< EPWM_T::WGCTL1: CMPUCTL2 Position */ #define EPWM_WGCTL1_CMPUCTL2_Msk (0x3ul << EPWM_WGCTL1_CMPUCTL2_Pos) /*!< EPWM_T::WGCTL1: CMPUCTL2 Mask */ #define EPWM_WGCTL1_CMPUCTL3_Pos (6) /*!< EPWM_T::WGCTL1: CMPUCTL3 Position */ #define EPWM_WGCTL1_CMPUCTL3_Msk (0x3ul << EPWM_WGCTL1_CMPUCTL3_Pos) /*!< EPWM_T::WGCTL1: CMPUCTL3 Mask */ #define EPWM_WGCTL1_CMPUCTL4_Pos (8) /*!< EPWM_T::WGCTL1: CMPUCTL4 Position */ #define EPWM_WGCTL1_CMPUCTL4_Msk (0x3ul << EPWM_WGCTL1_CMPUCTL4_Pos) /*!< EPWM_T::WGCTL1: CMPUCTL4 Mask */ #define EPWM_WGCTL1_CMPUCTL5_Pos (10) /*!< EPWM_T::WGCTL1: CMPUCTL5 Position */ #define EPWM_WGCTL1_CMPUCTL5_Msk (0x3ul << EPWM_WGCTL1_CMPUCTL5_Pos) /*!< EPWM_T::WGCTL1: CMPUCTL5 Mask */ #define EPWM_WGCTL1_CMPDCTL0_Pos (16) /*!< EPWM_T::WGCTL1: CMPDCTL0 Position */ #define EPWM_WGCTL1_CMPDCTL0_Msk (0x3ul << EPWM_WGCTL1_CMPDCTL0_Pos) /*!< EPWM_T::WGCTL1: CMPDCTL0 Mask */ #define EPWM_WGCTL1_CMPDCTL1_Pos (18) /*!< EPWM_T::WGCTL1: CMPDCTL1 Position */ #define EPWM_WGCTL1_CMPDCTL1_Msk (0x3ul << EPWM_WGCTL1_CMPDCTL1_Pos) /*!< EPWM_T::WGCTL1: CMPDCTL1 Mask */ #define EPWM_WGCTL1_CMPDCTL2_Pos (20) /*!< EPWM_T::WGCTL1: CMPDCTL2 Position */ #define EPWM_WGCTL1_CMPDCTL2_Msk (0x3ul << EPWM_WGCTL1_CMPDCTL2_Pos) /*!< EPWM_T::WGCTL1: CMPDCTL2 Mask */ #define EPWM_WGCTL1_CMPDCTL3_Pos (22) /*!< EPWM_T::WGCTL1: CMPDCTL3 Position */ #define EPWM_WGCTL1_CMPDCTL3_Msk (0x3ul << EPWM_WGCTL1_CMPDCTL3_Pos) /*!< EPWM_T::WGCTL1: CMPDCTL3 Mask */ #define EPWM_WGCTL1_CMPDCTL4_Pos (24) /*!< EPWM_T::WGCTL1: CMPDCTL4 Position */ #define EPWM_WGCTL1_CMPDCTL4_Msk (0x3ul << EPWM_WGCTL1_CMPDCTL4_Pos) /*!< EPWM_T::WGCTL1: CMPDCTL4 Mask */ #define EPWM_WGCTL1_CMPDCTL5_Pos (26) /*!< EPWM_T::WGCTL1: CMPDCTL5 Position */ #define EPWM_WGCTL1_CMPDCTL5_Msk (0x3ul << EPWM_WGCTL1_CMPDCTL5_Pos) /*!< EPWM_T::WGCTL1: CMPDCTL5 Mask */ #define EPWM_MSKEN_MSKEN0_Pos (0) /*!< EPWM_T::MSKEN: MSKEN0 Position */ #define EPWM_MSKEN_MSKEN0_Msk (0x1ul << EPWM_MSKEN_MSKEN0_Pos) /*!< EPWM_T::MSKEN: MSKEN0 Mask */ #define EPWM_MSKEN_MSKEN1_Pos (1) /*!< EPWM_T::MSKEN: MSKEN1 Position */ #define EPWM_MSKEN_MSKEN1_Msk (0x1ul << EPWM_MSKEN_MSKEN1_Pos) /*!< EPWM_T::MSKEN: MSKEN1 Mask */ #define EPWM_MSKEN_MSKEN2_Pos (2) /*!< EPWM_T::MSKEN: MSKEN2 Position */ #define EPWM_MSKEN_MSKEN2_Msk (0x1ul << EPWM_MSKEN_MSKEN2_Pos) /*!< EPWM_T::MSKEN: MSKEN2 Mask */ #define EPWM_MSKEN_MSKEN3_Pos (3) /*!< EPWM_T::MSKEN: MSKEN3 Position */ #define EPWM_MSKEN_MSKEN3_Msk (0x1ul << EPWM_MSKEN_MSKEN3_Pos) /*!< EPWM_T::MSKEN: MSKEN3 Mask */ #define EPWM_MSKEN_MSKEN4_Pos (4) /*!< EPWM_T::MSKEN: MSKEN4 Position */ #define EPWM_MSKEN_MSKEN4_Msk (0x1ul << EPWM_MSKEN_MSKEN4_Pos) /*!< EPWM_T::MSKEN: MSKEN4 Mask */ #define EPWM_MSKEN_MSKEN5_Pos (5) /*!< EPWM_T::MSKEN: MSKEN5 Position */ #define EPWM_MSKEN_MSKEN5_Msk (0x1ul << EPWM_MSKEN_MSKEN5_Pos) /*!< EPWM_T::MSKEN: MSKEN5 Mask */ #define EPWM_MSK_MSKDAT0_Pos (0) /*!< EPWM_T::MSK: MSKDAT0 Position */ #define EPWM_MSK_MSKDAT0_Msk (0x1ul << EPWM_MSK_MSKDAT0_Pos) /*!< EPWM_T::MSK: MSKDAT0 Mask */ #define EPWM_MSK_MSKDAT1_Pos (1) /*!< EPWM_T::MSK: MSKDAT1 Position */ #define EPWM_MSK_MSKDAT1_Msk (0x1ul << EPWM_MSK_MSKDAT1_Pos) /*!< EPWM_T::MSK: MSKDAT1 Mask */ #define EPWM_MSK_MSKDAT2_Pos (2) /*!< EPWM_T::MSK: MSKDAT2 Position */ #define EPWM_MSK_MSKDAT2_Msk (0x1ul << EPWM_MSK_MSKDAT2_Pos) /*!< EPWM_T::MSK: MSKDAT2 Mask */ #define EPWM_MSK_MSKDAT3_Pos (3) /*!< EPWM_T::MSK: MSKDAT3 Position */ #define EPWM_MSK_MSKDAT3_Msk (0x1ul << EPWM_MSK_MSKDAT3_Pos) /*!< EPWM_T::MSK: MSKDAT3 Mask */ #define EPWM_MSK_MSKDAT4_Pos (4) /*!< EPWM_T::MSK: MSKDAT4 Position */ #define EPWM_MSK_MSKDAT4_Msk (0x1ul << EPWM_MSK_MSKDAT4_Pos) /*!< EPWM_T::MSK: MSKDAT4 Mask */ #define EPWM_MSK_MSKDAT5_Pos (5) /*!< EPWM_T::MSK: MSKDAT5 Position */ #define EPWM_MSK_MSKDAT5_Msk (0x1ul << EPWM_MSK_MSKDAT5_Pos) /*!< EPWM_T::MSK: MSKDAT5 Mask */ #define EPWM_BNF_BRK0NFEN_Pos (0) /*!< EPWM_T::BNF: BRK0NFEN Position */ #define EPWM_BNF_BRK0NFEN_Msk (0x1ul << EPWM_BNF_BRK0NFEN_Pos) /*!< EPWM_T::BNF: BRK0NFEN Mask */ #define EPWM_BNF_BRK0NFSEL_Pos (1) /*!< EPWM_T::BNF: BRK0NFSEL Position */ #define EPWM_BNF_BRK0NFSEL_Msk (0x7ul << EPWM_BNF_BRK0NFSEL_Pos) /*!< EPWM_T::BNF: BRK0NFSEL Mask */ #define EPWM_BNF_BRK0FCNT_Pos (4) /*!< EPWM_T::BNF: BRK0FCNT Position */ #define EPWM_BNF_BRK0FCNT_Msk (0x7ul << EPWM_BNF_BRK0FCNT_Pos) /*!< EPWM_T::BNF: BRK0FCNT Mask */ #define EPWM_BNF_BRK0PINV_Pos (7) /*!< EPWM_T::BNF: BRK0PINV Position */ #define EPWM_BNF_BRK0PINV_Msk (0x1ul << EPWM_BNF_BRK0PINV_Pos) /*!< EPWM_T::BNF: BRK0PINV Mask */ #define EPWM_BNF_BRK1NFEN_Pos (8) /*!< EPWM_T::BNF: BRK1NFEN Position */ #define EPWM_BNF_BRK1NFEN_Msk (0x1ul << EPWM_BNF_BRK1NFEN_Pos) /*!< EPWM_T::BNF: BRK1NFEN Mask */ #define EPWM_BNF_BRK1NFSEL_Pos (9) /*!< EPWM_T::BNF: BRK1NFSEL Position */ #define EPWM_BNF_BRK1NFSEL_Msk (0x7ul << EPWM_BNF_BRK1NFSEL_Pos) /*!< EPWM_T::BNF: BRK1NFSEL Mask */ #define EPWM_BNF_BRK1FCNT_Pos (12) /*!< EPWM_T::BNF: BRK1FCNT Position */ #define EPWM_BNF_BRK1FCNT_Msk (0x7ul << EPWM_BNF_BRK1FCNT_Pos) /*!< EPWM_T::BNF: BRK1FCNT Mask */ #define EPWM_BNF_BRK1PINV_Pos (15) /*!< EPWM_T::BNF: BRK1PINV Position */ #define EPWM_BNF_BRK1PINV_Msk (0x1ul << EPWM_BNF_BRK1PINV_Pos) /*!< EPWM_T::BNF: BRK1PINV Mask */ #define EPWM_BNF_BK0SRC_Pos (16) /*!< EPWM_T::BNF: BK0SRC Position */ #define EPWM_BNF_BK0SRC_Msk (0x1ul << EPWM_BNF_BK0SRC_Pos) /*!< EPWM_T::BNF: BK0SRC Mask */ #define EPWM_BNF_BK1SRC_Pos (24) /*!< EPWM_T::BNF: BK1SRC Position */ #define EPWM_BNF_BK1SRC_Msk (0x1ul << EPWM_BNF_BK1SRC_Pos) /*!< EPWM_T::BNF: BK1SRC Mask */ #define EPWM_FAILBRK_CSSBRKEN_Pos (0) /*!< EPWM_T::FAILBRK: CSSBRKEN Position */ #define EPWM_FAILBRK_CSSBRKEN_Msk (0x1ul << EPWM_FAILBRK_CSSBRKEN_Pos) /*!< EPWM_T::FAILBRK: CSSBRKEN Mask */ #define EPWM_FAILBRK_BODBRKEN_Pos (1) /*!< EPWM_T::FAILBRK: BODBRKEN Position */ #define EPWM_FAILBRK_BODBRKEN_Msk (0x1ul << EPWM_FAILBRK_BODBRKEN_Pos) /*!< EPWM_T::FAILBRK: BODBRKEN Mask */ #define EPWM_FAILBRK_RAMBRKEN_Pos (2) /*!< EPWM_T::FAILBRK: RAMBRKEN Position */ #define EPWM_FAILBRK_RAMBRKEN_Msk (0x1ul << EPWM_FAILBRK_RAMBRKEN_Pos) /*!< EPWM_T::FAILBRK: RAMBRKEN Mask */ #define EPWM_FAILBRK_CORBRKEN_Pos (3) /*!< EPWM_T::FAILBRK: CORBRKEN Position */ #define EPWM_FAILBRK_CORBRKEN_Msk (0x1ul << EPWM_FAILBRK_CORBRKEN_Pos) /*!< EPWM_T::FAILBRK: CORBRKEN Mask */ #define EPWM_BRKCTL0_1_CPO0EBEN_Pos (0) /*!< EPWM_T::BRKCTL0_1: CPO0EBEN Position */ #define EPWM_BRKCTL0_1_CPO0EBEN_Msk (0x1ul << EPWM_BRKCTL0_1_CPO0EBEN_Pos) /*!< EPWM_T::BRKCTL0_1: CPO0EBEN Mask */ #define EPWM_BRKCTL0_1_CPO1EBEN_Pos (1) /*!< EPWM_T::BRKCTL0_1: CPO1EBEN Position */ #define EPWM_BRKCTL0_1_CPO1EBEN_Msk (0x1ul << EPWM_BRKCTL0_1_CPO1EBEN_Pos) /*!< EPWM_T::BRKCTL0_1: CPO1EBEN Mask */ #define EPWM_BRKCTL0_1_BRKP0EEN_Pos (4) /*!< EPWM_T::BRKCTL0_1: BRKP0EEN Position */ #define EPWM_BRKCTL0_1_BRKP0EEN_Msk (0x1ul << EPWM_BRKCTL0_1_BRKP0EEN_Pos) /*!< EPWM_T::BRKCTL0_1: BRKP0EEN Mask */ #define EPWM_BRKCTL0_1_BRKP1EEN_Pos (5) /*!< EPWM_T::BRKCTL0_1: BRKP1EEN Position */ #define EPWM_BRKCTL0_1_BRKP1EEN_Msk (0x1ul << EPWM_BRKCTL0_1_BRKP1EEN_Pos) /*!< EPWM_T::BRKCTL0_1: BRKP1EEN Mask */ #define EPWM_BRKCTL0_1_SYSEBEN_Pos (7) /*!< EPWM_T::BRKCTL0_1: SYSEBEN Position */ #define EPWM_BRKCTL0_1_SYSEBEN_Msk (0x1ul << EPWM_BRKCTL0_1_SYSEBEN_Pos) /*!< EPWM_T::BRKCTL0_1: SYSEBEN Mask */ #define EPWM_BRKCTL0_1_CPO0LBEN_Pos (8) /*!< EPWM_T::BRKCTL0_1: CPO0LBEN Position */ #define EPWM_BRKCTL0_1_CPO0LBEN_Msk (0x1ul << EPWM_BRKCTL0_1_CPO0LBEN_Pos) /*!< EPWM_T::BRKCTL0_1: CPO0LBEN Mask */ #define EPWM_BRKCTL0_1_CPO1LBEN_Pos (9) /*!< EPWM_T::BRKCTL0_1: CPO1LBEN Position */ #define EPWM_BRKCTL0_1_CPO1LBEN_Msk (0x1ul << EPWM_BRKCTL0_1_CPO1LBEN_Pos) /*!< EPWM_T::BRKCTL0_1: CPO1LBEN Mask */ #define EPWM_BRKCTL0_1_BRKP0LEN_Pos (12) /*!< EPWM_T::BRKCTL0_1: BRKP0LEN Position */ #define EPWM_BRKCTL0_1_BRKP0LEN_Msk (0x1ul << EPWM_BRKCTL0_1_BRKP0LEN_Pos) /*!< EPWM_T::BRKCTL0_1: BRKP0LEN Mask */ #define EPWM_BRKCTL0_1_BRKP1LEN_Pos (13) /*!< EPWM_T::BRKCTL0_1: BRKP1LEN Position */ #define EPWM_BRKCTL0_1_BRKP1LEN_Msk (0x1ul << EPWM_BRKCTL0_1_BRKP1LEN_Pos) /*!< EPWM_T::BRKCTL0_1: BRKP1LEN Mask */ #define EPWM_BRKCTL0_1_SYSLBEN_Pos (15) /*!< EPWM_T::BRKCTL0_1: SYSLBEN Position */ #define EPWM_BRKCTL0_1_SYSLBEN_Msk (0x1ul << EPWM_BRKCTL0_1_SYSLBEN_Pos) /*!< EPWM_T::BRKCTL0_1: SYSLBEN Mask */ #define EPWM_BRKCTL0_1_BRKAEVEN_Pos (16) /*!< EPWM_T::BRKCTL0_1: BRKAEVEN Position */ #define EPWM_BRKCTL0_1_BRKAEVEN_Msk (0x3ul << EPWM_BRKCTL0_1_BRKAEVEN_Pos) /*!< EPWM_T::BRKCTL0_1: BRKAEVEN Mask */ #define EPWM_BRKCTL0_1_BRKAODD_Pos (18) /*!< EPWM_T::BRKCTL0_1: BRKAODD Position */ #define EPWM_BRKCTL0_1_BRKAODD_Msk (0x3ul << EPWM_BRKCTL0_1_BRKAODD_Pos) /*!< EPWM_T::BRKCTL0_1: BRKAODD Mask */ #define EPWM_BRKCTL0_1_EADCEBEN_Pos (20) /*!< EPWM_T::BRKCTL0_1: EADCEBEN Position */ #define EPWM_BRKCTL0_1_EADCEBEN_Msk (0x1ul << EPWM_BRKCTL0_1_EADCEBEN_Pos) /*!< EPWM_T::BRKCTL0_1: EADCEBEN Mask */ #define EPWM_BRKCTL0_1_EADCLBEN_Pos (28) /*!< EPWM_T::BRKCTL0_1: EADCLBEN Position */ #define EPWM_BRKCTL0_1_EADCLBEN_Msk (0x1ul << EPWM_BRKCTL0_1_EADCLBEN_Pos) /*!< EPWM_T::BRKCTL0_1: EADCLBEN Mask */ #define EPWM_BRKCTL2_3_CPO0EBEN_Pos (0) /*!< EPWM_T::BRKCTL2_3: CPO0EBEN Position */ #define EPWM_BRKCTL2_3_CPO0EBEN_Msk (0x1ul << EPWM_BRKCTL2_3_CPO0EBEN_Pos) /*!< EPWM_T::BRKCTL2_3: CPO0EBEN Mask */ #define EPWM_BRKCTL2_3_CPO1EBEN_Pos (1) /*!< EPWM_T::BRKCTL2_3: CPO1EBEN Position */ #define EPWM_BRKCTL2_3_CPO1EBEN_Msk (0x1ul << EPWM_BRKCTL2_3_CPO1EBEN_Pos) /*!< EPWM_T::BRKCTL2_3: CPO1EBEN Mask */ #define EPWM_BRKCTL2_3_BRKP0EEN_Pos (4) /*!< EPWM_T::BRKCTL2_3: BRKP0EEN Position */ #define EPWM_BRKCTL2_3_BRKP0EEN_Msk (0x1ul << EPWM_BRKCTL2_3_BRKP0EEN_Pos) /*!< EPWM_T::BRKCTL2_3: BRKP0EEN Mask */ #define EPWM_BRKCTL2_3_BRKP1EEN_Pos (5) /*!< EPWM_T::BRKCTL2_3: BRKP1EEN Position */ #define EPWM_BRKCTL2_3_BRKP1EEN_Msk (0x1ul << EPWM_BRKCTL2_3_BRKP1EEN_Pos) /*!< EPWM_T::BRKCTL2_3: BRKP1EEN Mask */ #define EPWM_BRKCTL2_3_SYSEBEN_Pos (7) /*!< EPWM_T::BRKCTL2_3: SYSEBEN Position */ #define EPWM_BRKCTL2_3_SYSEBEN_Msk (0x1ul << EPWM_BRKCTL2_3_SYSEBEN_Pos) /*!< EPWM_T::BRKCTL2_3: SYSEBEN Mask */ #define EPWM_BRKCTL2_3_CPO0LBEN_Pos (8) /*!< EPWM_T::BRKCTL2_3: CPO0LBEN Position */ #define EPWM_BRKCTL2_3_CPO0LBEN_Msk (0x1ul << EPWM_BRKCTL2_3_CPO0LBEN_Pos) /*!< EPWM_T::BRKCTL2_3: CPO0LBEN Mask */ #define EPWM_BRKCTL2_3_CPO1LBEN_Pos (9) /*!< EPWM_T::BRKCTL2_3: CPO1LBEN Position */ #define EPWM_BRKCTL2_3_CPO1LBEN_Msk (0x1ul << EPWM_BRKCTL2_3_CPO1LBEN_Pos) /*!< EPWM_T::BRKCTL2_3: CPO1LBEN Mask */ #define EPWM_BRKCTL2_3_BRKP0LEN_Pos (12) /*!< EPWM_T::BRKCTL2_3: BRKP0LEN Position */ #define EPWM_BRKCTL2_3_BRKP0LEN_Msk (0x1ul << EPWM_BRKCTL2_3_BRKP0LEN_Pos) /*!< EPWM_T::BRKCTL2_3: BRKP0LEN Mask */ #define EPWM_BRKCTL2_3_BRKP1LEN_Pos (13) /*!< EPWM_T::BRKCTL2_3: BRKP1LEN Position */ #define EPWM_BRKCTL2_3_BRKP1LEN_Msk (0x1ul << EPWM_BRKCTL2_3_BRKP1LEN_Pos) /*!< EPWM_T::BRKCTL2_3: BRKP1LEN Mask */ #define EPWM_BRKCTL2_3_SYSLBEN_Pos (15) /*!< EPWM_T::BRKCTL2_3: SYSLBEN Position */ #define EPWM_BRKCTL2_3_SYSLBEN_Msk (0x1ul << EPWM_BRKCTL2_3_SYSLBEN_Pos) /*!< EPWM_T::BRKCTL2_3: SYSLBEN Mask */ #define EPWM_BRKCTL2_3_BRKAEVEN_Pos (16) /*!< EPWM_T::BRKCTL2_3: BRKAEVEN Position */ #define EPWM_BRKCTL2_3_BRKAEVEN_Msk (0x3ul << EPWM_BRKCTL2_3_BRKAEVEN_Pos) /*!< EPWM_T::BRKCTL2_3: BRKAEVEN Mask */ #define EPWM_BRKCTL2_3_BRKAODD_Pos (18) /*!< EPWM_T::BRKCTL2_3: BRKAODD Position */ #define EPWM_BRKCTL2_3_BRKAODD_Msk (0x3ul << EPWM_BRKCTL2_3_BRKAODD_Pos) /*!< EPWM_T::BRKCTL2_3: BRKAODD Mask */ #define EPWM_BRKCTL2_3_EADCEBEN_Pos (20) /*!< EPWM_T::BRKCTL2_3: EADCEBEN Position */ #define EPWM_BRKCTL2_3_EADCEBEN_Msk (0x1ul << EPWM_BRKCTL2_3_EADCEBEN_Pos) /*!< EPWM_T::BRKCTL2_3: EADCEBEN Mask */ #define EPWM_BRKCTL2_3_EADCLBEN_Pos (28) /*!< EPWM_T::BRKCTL2_3: EADCLBEN Position */ #define EPWM_BRKCTL2_3_EADCLBEN_Msk (0x1ul << EPWM_BRKCTL2_3_EADCLBEN_Pos) /*!< EPWM_T::BRKCTL2_3: EADCLBEN Mask */ #define EPWM_BRKCTL4_5_CPO0EBEN_Pos (0) /*!< EPWM_T::BRKCTL4_5: CPO0EBEN Position */ #define EPWM_BRKCTL4_5_CPO0EBEN_Msk (0x1ul << EPWM_BRKCTL4_5_CPO0EBEN_Pos) /*!< EPWM_T::BRKCTL4_5: CPO0EBEN Mask */ #define EPWM_BRKCTL4_5_CPO1EBEN_Pos (1) /*!< EPWM_T::BRKCTL4_5: CPO1EBEN Position */ #define EPWM_BRKCTL4_5_CPO1EBEN_Msk (0x1ul << EPWM_BRKCTL4_5_CPO1EBEN_Pos) /*!< EPWM_T::BRKCTL4_5: CPO1EBEN Mask */ #define EPWM_BRKCTL4_5_BRKP0EEN_Pos (4) /*!< EPWM_T::BRKCTL4_5: BRKP0EEN Position */ #define EPWM_BRKCTL4_5_BRKP0EEN_Msk (0x1ul << EPWM_BRKCTL4_5_BRKP0EEN_Pos) /*!< EPWM_T::BRKCTL4_5: BRKP0EEN Mask */ #define EPWM_BRKCTL4_5_BRKP1EEN_Pos (5) /*!< EPWM_T::BRKCTL4_5: BRKP1EEN Position */ #define EPWM_BRKCTL4_5_BRKP1EEN_Msk (0x1ul << EPWM_BRKCTL4_5_BRKP1EEN_Pos) /*!< EPWM_T::BRKCTL4_5: BRKP1EEN Mask */ #define EPWM_BRKCTL4_5_SYSEBEN_Pos (7) /*!< EPWM_T::BRKCTL4_5: SYSEBEN Position */ #define EPWM_BRKCTL4_5_SYSEBEN_Msk (0x1ul << EPWM_BRKCTL4_5_SYSEBEN_Pos) /*!< EPWM_T::BRKCTL4_5: SYSEBEN Mask */ #define EPWM_BRKCTL4_5_CPO0LBEN_Pos (8) /*!< EPWM_T::BRKCTL4_5: CPO0LBEN Position */ #define EPWM_BRKCTL4_5_CPO0LBEN_Msk (0x1ul << EPWM_BRKCTL4_5_CPO0LBEN_Pos) /*!< EPWM_T::BRKCTL4_5: CPO0LBEN Mask */ #define EPWM_BRKCTL4_5_CPO1LBEN_Pos (9) /*!< EPWM_T::BRKCTL4_5: CPO1LBEN Position */ #define EPWM_BRKCTL4_5_CPO1LBEN_Msk (0x1ul << EPWM_BRKCTL4_5_CPO1LBEN_Pos) /*!< EPWM_T::BRKCTL4_5: CPO1LBEN Mask */ #define EPWM_BRKCTL4_5_BRKP0LEN_Pos (12) /*!< EPWM_T::BRKCTL4_5: BRKP0LEN Position */ #define EPWM_BRKCTL4_5_BRKP0LEN_Msk (0x1ul << EPWM_BRKCTL4_5_BRKP0LEN_Pos) /*!< EPWM_T::BRKCTL4_5: BRKP0LEN Mask */ #define EPWM_BRKCTL4_5_BRKP1LEN_Pos (13) /*!< EPWM_T::BRKCTL4_5: BRKP1LEN Position */ #define EPWM_BRKCTL4_5_BRKP1LEN_Msk (0x1ul << EPWM_BRKCTL4_5_BRKP1LEN_Pos) /*!< EPWM_T::BRKCTL4_5: BRKP1LEN Mask */ #define EPWM_BRKCTL4_5_SYSLBEN_Pos (15) /*!< EPWM_T::BRKCTL4_5: SYSLBEN Position */ #define EPWM_BRKCTL4_5_SYSLBEN_Msk (0x1ul << EPWM_BRKCTL4_5_SYSLBEN_Pos) /*!< EPWM_T::BRKCTL4_5: SYSLBEN Mask */ #define EPWM_BRKCTL4_5_BRKAEVEN_Pos (16) /*!< EPWM_T::BRKCTL4_5: BRKAEVEN Position */ #define EPWM_BRKCTL4_5_BRKAEVEN_Msk (0x3ul << EPWM_BRKCTL4_5_BRKAEVEN_Pos) /*!< EPWM_T::BRKCTL4_5: BRKAEVEN Mask */ #define EPWM_BRKCTL4_5_BRKAODD_Pos (18) /*!< EPWM_T::BRKCTL4_5: BRKAODD Position */ #define EPWM_BRKCTL4_5_BRKAODD_Msk (0x3ul << EPWM_BRKCTL4_5_BRKAODD_Pos) /*!< EPWM_T::BRKCTL4_5: BRKAODD Mask */ #define EPWM_BRKCTL4_5_EADCEBEN_Pos (20) /*!< EPWM_T::BRKCTL4_5: EADCEBEN Position */ #define EPWM_BRKCTL4_5_EADCEBEN_Msk (0x1ul << EPWM_BRKCTL4_5_EADCEBEN_Pos) /*!< EPWM_T::BRKCTL4_5: EADCEBEN Mask */ #define EPWM_BRKCTL4_5_EADCLBEN_Pos (28) /*!< EPWM_T::BRKCTL4_5: EADCLBEN Position */ #define EPWM_BRKCTL4_5_EADCLBEN_Msk (0x1ul << EPWM_BRKCTL4_5_EADCLBEN_Pos) /*!< EPWM_T::BRKCTL4_5: EADCLBEN Mask */ #define EPWM_POLCTL_PINV0_Pos (0) /*!< EPWM_T::POLCTL: PINV0 Position */ #define EPWM_POLCTL_PINV0_Msk (0x1ul << EPWM_POLCTL_PINV0_Pos) /*!< EPWM_T::POLCTL: PINV0 Mask */ #define EPWM_POLCTL_PINV1_Pos (1) /*!< EPWM_T::POLCTL: PINV1 Position */ #define EPWM_POLCTL_PINV1_Msk (0x1ul << EPWM_POLCTL_PINV1_Pos) /*!< EPWM_T::POLCTL: PINV1 Mask */ #define EPWM_POLCTL_PINV2_Pos (2) /*!< EPWM_T::POLCTL: PINV2 Position */ #define EPWM_POLCTL_PINV2_Msk (0x1ul << EPWM_POLCTL_PINV2_Pos) /*!< EPWM_T::POLCTL: PINV2 Mask */ #define EPWM_POLCTL_PINV3_Pos (3) /*!< EPWM_T::POLCTL: PINV3 Position */ #define EPWM_POLCTL_PINV3_Msk (0x1ul << EPWM_POLCTL_PINV3_Pos) /*!< EPWM_T::POLCTL: PINV3 Mask */ #define EPWM_POLCTL_PINV4_Pos (4) /*!< EPWM_T::POLCTL: PINV4 Position */ #define EPWM_POLCTL_PINV4_Msk (0x1ul << EPWM_POLCTL_PINV4_Pos) /*!< EPWM_T::POLCTL: PINV4 Mask */ #define EPWM_POLCTL_PINV5_Pos (5) /*!< EPWM_T::POLCTL: PINV5 Position */ #define EPWM_POLCTL_PINV5_Msk (0x1ul << EPWM_POLCTL_PINV5_Pos) /*!< EPWM_T::POLCTL: PINV5 Mask */ #define EPWM_POEN_POEN0_Pos (0) /*!< EPWM_T::POEN: POEN0 Position */ #define EPWM_POEN_POEN0_Msk (0x1ul << EPWM_POEN_POEN0_Pos) /*!< EPWM_T::POEN: POEN0 Mask */ #define EPWM_POEN_POEN1_Pos (1) /*!< EPWM_T::POEN: POEN1 Position */ #define EPWM_POEN_POEN1_Msk (0x1ul << EPWM_POEN_POEN1_Pos) /*!< EPWM_T::POEN: POEN1 Mask */ #define EPWM_POEN_POEN2_Pos (2) /*!< EPWM_T::POEN: POEN2 Position */ #define EPWM_POEN_POEN2_Msk (0x1ul << EPWM_POEN_POEN2_Pos) /*!< EPWM_T::POEN: POEN2 Mask */ #define EPWM_POEN_POEN3_Pos (3) /*!< EPWM_T::POEN: POEN3 Position */ #define EPWM_POEN_POEN3_Msk (0x1ul << EPWM_POEN_POEN3_Pos) /*!< EPWM_T::POEN: POEN3 Mask */ #define EPWM_POEN_POEN4_Pos (4) /*!< EPWM_T::POEN: POEN4 Position */ #define EPWM_POEN_POEN4_Msk (0x1ul << EPWM_POEN_POEN4_Pos) /*!< EPWM_T::POEN: POEN4 Mask */ #define EPWM_POEN_POEN5_Pos (5) /*!< EPWM_T::POEN: POEN5 Position */ #define EPWM_POEN_POEN5_Msk (0x1ul << EPWM_POEN_POEN5_Pos) /*!< EPWM_T::POEN: POEN5 Mask */ #define EPWM_SWBRK_BRKETRG0_Pos (0) /*!< EPWM_T::SWBRK: BRKETRG0 Position */ #define EPWM_SWBRK_BRKETRG0_Msk (0x1ul << EPWM_SWBRK_BRKETRG0_Pos) /*!< EPWM_T::SWBRK: BRKETRG0 Mask */ #define EPWM_SWBRK_BRKETRG2_Pos (1) /*!< EPWM_T::SWBRK: BRKETRG2 Position */ #define EPWM_SWBRK_BRKETRG2_Msk (0x1ul << EPWM_SWBRK_BRKETRG2_Pos) /*!< EPWM_T::SWBRK: BRKETRG2 Mask */ #define EPWM_SWBRK_BRKETRG4_Pos (2) /*!< EPWM_T::SWBRK: BRKETRG4 Position */ #define EPWM_SWBRK_BRKETRG4_Msk (0x1ul << EPWM_SWBRK_BRKETRG4_Pos) /*!< EPWM_T::SWBRK: BRKETRG4 Mask */ #define EPWM_SWBRK_BRKLTRG0_Pos (8) /*!< EPWM_T::SWBRK: BRKLTRG0 Position */ #define EPWM_SWBRK_BRKLTRG0_Msk (0x1ul << EPWM_SWBRK_BRKLTRG0_Pos) /*!< EPWM_T::SWBRK: BRKLTRG0 Mask */ #define EPWM_SWBRK_BRKLTRG2_Pos (9) /*!< EPWM_T::SWBRK: BRKLTRG2 Position */ #define EPWM_SWBRK_BRKLTRG2_Msk (0x1ul << EPWM_SWBRK_BRKLTRG2_Pos) /*!< EPWM_T::SWBRK: BRKLTRG2 Mask */ #define EPWM_SWBRK_BRKLTRG4_Pos (10) /*!< EPWM_T::SWBRK: BRKLTRG4 Position */ #define EPWM_SWBRK_BRKLTRG4_Msk (0x1ul << EPWM_SWBRK_BRKLTRG4_Pos) /*!< EPWM_T::SWBRK: BRKLTRG4 Mask */ #define EPWM_INTEN0_ZIEN0_Pos (0) /*!< EPWM_T::INTEN0: ZIEN0 Position */ #define EPWM_INTEN0_ZIEN0_Msk (0x1ul << EPWM_INTEN0_ZIEN0_Pos) /*!< EPWM_T::INTEN0: ZIEN0 Mask */ #define EPWM_INTEN0_ZIEN1_Pos (1) /*!< EPWM_T::INTEN0: ZIEN1 Position */ #define EPWM_INTEN0_ZIEN1_Msk (0x1ul << EPWM_INTEN0_ZIEN1_Pos) /*!< EPWM_T::INTEN0: ZIEN1 Mask */ #define EPWM_INTEN0_ZIEN2_Pos (2) /*!< EPWM_T::INTEN0: ZIEN2 Position */ #define EPWM_INTEN0_ZIEN2_Msk (0x1ul << EPWM_INTEN0_ZIEN2_Pos) /*!< EPWM_T::INTEN0: ZIEN2 Mask */ #define EPWM_INTEN0_ZIEN3_Pos (3) /*!< EPWM_T::INTEN0: ZIEN3 Position */ #define EPWM_INTEN0_ZIEN3_Msk (0x1ul << EPWM_INTEN0_ZIEN3_Pos) /*!< EPWM_T::INTEN0: ZIEN3 Mask */ #define EPWM_INTEN0_ZIEN4_Pos (4) /*!< EPWM_T::INTEN0: ZIEN4 Position */ #define EPWM_INTEN0_ZIEN4_Msk (0x1ul << EPWM_INTEN0_ZIEN4_Pos) /*!< EPWM_T::INTEN0: ZIEN4 Mask */ #define EPWM_INTEN0_ZIEN5_Pos (5) /*!< EPWM_T::INTEN0: ZIEN5 Position */ #define EPWM_INTEN0_ZIEN5_Msk (0x1ul << EPWM_INTEN0_ZIEN5_Pos) /*!< EPWM_T::INTEN0: ZIEN5 Mask */ #define EPWM_INTEN0_PIEN0_Pos (8) /*!< EPWM_T::INTEN0: PIEN0 Position */ #define EPWM_INTEN0_PIEN0_Msk (0x1ul << EPWM_INTEN0_PIEN0_Pos) /*!< EPWM_T::INTEN0: PIEN0 Mask */ #define EPWM_INTEN0_PIEN1_Pos (9) /*!< EPWM_T::INTEN0: PIEN1 Position */ #define EPWM_INTEN0_PIEN1_Msk (0x1ul << EPWM_INTEN0_PIEN1_Pos) /*!< EPWM_T::INTEN0: PIEN1 Mask */ #define EPWM_INTEN0_PIEN2_Pos (10) /*!< EPWM_T::INTEN0: PIEN2 Position */ #define EPWM_INTEN0_PIEN2_Msk (0x1ul << EPWM_INTEN0_PIEN2_Pos) /*!< EPWM_T::INTEN0: PIEN2 Mask */ #define EPWM_INTEN0_PIEN3_Pos (11) /*!< EPWM_T::INTEN0: PIEN3 Position */ #define EPWM_INTEN0_PIEN3_Msk (0x1ul << EPWM_INTEN0_PIEN3_Pos) /*!< EPWM_T::INTEN0: PIEN3 Mask */ #define EPWM_INTEN0_PIEN4_Pos (12) /*!< EPWM_T::INTEN0: PIEN4 Position */ #define EPWM_INTEN0_PIEN4_Msk (0x1ul << EPWM_INTEN0_PIEN4_Pos) /*!< EPWM_T::INTEN0: PIEN4 Mask */ #define EPWM_INTEN0_PIEN5_Pos (13) /*!< EPWM_T::INTEN0: PIEN5 Position */ #define EPWM_INTEN0_PIEN5_Msk (0x1ul << EPWM_INTEN0_PIEN5_Pos) /*!< EPWM_T::INTEN0: PIEN5 Mask */ #define EPWM_INTEN0_CMPUIEN0_Pos (16) /*!< EPWM_T::INTEN0: CMPUIEN0 Position */ #define EPWM_INTEN0_CMPUIEN0_Msk (0x1ul << EPWM_INTEN0_CMPUIEN0_Pos) /*!< EPWM_T::INTEN0: CMPUIEN0 Mask */ #define EPWM_INTEN0_CMPUIEN1_Pos (17) /*!< EPWM_T::INTEN0: CMPUIEN1 Position */ #define EPWM_INTEN0_CMPUIEN1_Msk (0x1ul << EPWM_INTEN0_CMPUIEN1_Pos) /*!< EPWM_T::INTEN0: CMPUIEN1 Mask */ #define EPWM_INTEN0_CMPUIEN2_Pos (18) /*!< EPWM_T::INTEN0: CMPUIEN2 Position */ #define EPWM_INTEN0_CMPUIEN2_Msk (0x1ul << EPWM_INTEN0_CMPUIEN2_Pos) /*!< EPWM_T::INTEN0: CMPUIEN2 Mask */ #define EPWM_INTEN0_CMPUIEN3_Pos (19) /*!< EPWM_T::INTEN0: CMPUIEN3 Position */ #define EPWM_INTEN0_CMPUIEN3_Msk (0x1ul << EPWM_INTEN0_CMPUIEN3_Pos) /*!< EPWM_T::INTEN0: CMPUIEN3 Mask */ #define EPWM_INTEN0_CMPUIEN4_Pos (20) /*!< EPWM_T::INTEN0: CMPUIEN4 Position */ #define EPWM_INTEN0_CMPUIEN4_Msk (0x1ul << EPWM_INTEN0_CMPUIEN4_Pos) /*!< EPWM_T::INTEN0: CMPUIEN4 Mask */ #define EPWM_INTEN0_CMPUIEN5_Pos (21) /*!< EPWM_T::INTEN0: CMPUIEN5 Position */ #define EPWM_INTEN0_CMPUIEN5_Msk (0x1ul << EPWM_INTEN0_CMPUIEN5_Pos) /*!< EPWM_T::INTEN0: CMPUIEN5 Mask */ #define EPWM_INTEN0_CMPDIEN0_Pos (24) /*!< EPWM_T::INTEN0: CMPDIEN0 Position */ #define EPWM_INTEN0_CMPDIEN0_Msk (0x1ul << EPWM_INTEN0_CMPDIEN0_Pos) /*!< EPWM_T::INTEN0: CMPDIEN0 Mask */ #define EPWM_INTEN0_CMPDIEN1_Pos (25) /*!< EPWM_T::INTEN0: CMPDIEN1 Position */ #define EPWM_INTEN0_CMPDIEN1_Msk (0x1ul << EPWM_INTEN0_CMPDIEN1_Pos) /*!< EPWM_T::INTEN0: CMPDIEN1 Mask */ #define EPWM_INTEN0_CMPDIEN2_Pos (26) /*!< EPWM_T::INTEN0: CMPDIEN2 Position */ #define EPWM_INTEN0_CMPDIEN2_Msk (0x1ul << EPWM_INTEN0_CMPDIEN2_Pos) /*!< EPWM_T::INTEN0: CMPDIEN2 Mask */ #define EPWM_INTEN0_CMPDIEN3_Pos (27) /*!< EPWM_T::INTEN0: CMPDIEN3 Position */ #define EPWM_INTEN0_CMPDIEN3_Msk (0x1ul << EPWM_INTEN0_CMPDIEN3_Pos) /*!< EPWM_T::INTEN0: CMPDIEN3 Mask */ #define EPWM_INTEN0_CMPDIEN4_Pos (28) /*!< EPWM_T::INTEN0: CMPDIEN4 Position */ #define EPWM_INTEN0_CMPDIEN4_Msk (0x1ul << EPWM_INTEN0_CMPDIEN4_Pos) /*!< EPWM_T::INTEN0: CMPDIEN4 Mask */ #define EPWM_INTEN0_CMPDIEN5_Pos (29) /*!< EPWM_T::INTEN0: CMPDIEN5 Position */ #define EPWM_INTEN0_CMPDIEN5_Msk (0x1ul << EPWM_INTEN0_CMPDIEN5_Pos) /*!< EPWM_T::INTEN0: CMPDIEN5 Mask */ #define EPWM_INTEN1_BRKEIEN0_1_Pos (0) /*!< EPWM_T::INTEN1: BRKEIEN0_1 Position */ #define EPWM_INTEN1_BRKEIEN0_1_Msk (0x1ul << EPWM_INTEN1_BRKEIEN0_1_Pos) /*!< EPWM_T::INTEN1: BRKEIEN0_1 Mask */ #define EPWM_INTEN1_BRKEIEN2_3_Pos (1) /*!< EPWM_T::INTEN1: BRKEIEN2_3 Position */ #define EPWM_INTEN1_BRKEIEN2_3_Msk (0x1ul << EPWM_INTEN1_BRKEIEN2_3_Pos) /*!< EPWM_T::INTEN1: BRKEIEN2_3 Mask */ #define EPWM_INTEN1_BRKEIEN4_5_Pos (2) /*!< EPWM_T::INTEN1: BRKEIEN4_5 Position */ #define EPWM_INTEN1_BRKEIEN4_5_Msk (0x1ul << EPWM_INTEN1_BRKEIEN4_5_Pos) /*!< EPWM_T::INTEN1: BRKEIEN4_5 Mask */ #define EPWM_INTEN1_BRKLIEN0_1_Pos (8) /*!< EPWM_T::INTEN1: BRKLIEN0_1 Position */ #define EPWM_INTEN1_BRKLIEN0_1_Msk (0x1ul << EPWM_INTEN1_BRKLIEN0_1_Pos) /*!< EPWM_T::INTEN1: BRKLIEN0_1 Mask */ #define EPWM_INTEN1_BRKLIEN2_3_Pos (9) /*!< EPWM_T::INTEN1: BRKLIEN2_3 Position */ #define EPWM_INTEN1_BRKLIEN2_3_Msk (0x1ul << EPWM_INTEN1_BRKLIEN2_3_Pos) /*!< EPWM_T::INTEN1: BRKLIEN2_3 Mask */ #define EPWM_INTEN1_BRKLIEN4_5_Pos (10) /*!< EPWM_T::INTEN1: BRKLIEN4_5 Position */ #define EPWM_INTEN1_BRKLIEN4_5_Msk (0x1ul << EPWM_INTEN1_BRKLIEN4_5_Pos) /*!< EPWM_T::INTEN1: BRKLIEN4_5 Mask */ #define EPWM_INTSTS0_ZIF0_Pos (0) /*!< EPWM_T::INTSTS0: ZIF0 Position */ #define EPWM_INTSTS0_ZIF0_Msk (0x1ul << EPWM_INTSTS0_ZIF0_Pos) /*!< EPWM_T::INTSTS0: ZIF0 Mask */ #define EPWM_INTSTS0_ZIF1_Pos (1) /*!< EPWM_T::INTSTS0: ZIF1 Position */ #define EPWM_INTSTS0_ZIF1_Msk (0x1ul << EPWM_INTSTS0_ZIF1_Pos) /*!< EPWM_T::INTSTS0: ZIF1 Mask */ #define EPWM_INTSTS0_ZIF2_Pos (2) /*!< EPWM_T::INTSTS0: ZIF2 Position */ #define EPWM_INTSTS0_ZIF2_Msk (0x1ul << EPWM_INTSTS0_ZIF2_Pos) /*!< EPWM_T::INTSTS0: ZIF2 Mask */ #define EPWM_INTSTS0_ZIF3_Pos (3) /*!< EPWM_T::INTSTS0: ZIF3 Position */ #define EPWM_INTSTS0_ZIF3_Msk (0x1ul << EPWM_INTSTS0_ZIF3_Pos) /*!< EPWM_T::INTSTS0: ZIF3 Mask */ #define EPWM_INTSTS0_ZIF4_Pos (4) /*!< EPWM_T::INTSTS0: ZIF4 Position */ #define EPWM_INTSTS0_ZIF4_Msk (0x1ul << EPWM_INTSTS0_ZIF4_Pos) /*!< EPWM_T::INTSTS0: ZIF4 Mask */ #define EPWM_INTSTS0_ZIF5_Pos (5) /*!< EPWM_T::INTSTS0: ZIF5 Position */ #define EPWM_INTSTS0_ZIF5_Msk (0x1ul << EPWM_INTSTS0_ZIF5_Pos) /*!< EPWM_T::INTSTS0: ZIF5 Mask */ #define EPWM_INTSTS0_PIF0_Pos (8) /*!< EPWM_T::INTSTS0: PIF0 Position */ #define EPWM_INTSTS0_PIF0_Msk (0x1ul << EPWM_INTSTS0_PIF0_Pos) /*!< EPWM_T::INTSTS0: PIF0 Mask */ #define EPWM_INTSTS0_PIF1_Pos (9) /*!< EPWM_T::INTSTS0: PIF1 Position */ #define EPWM_INTSTS0_PIF1_Msk (0x1ul << EPWM_INTSTS0_PIF1_Pos) /*!< EPWM_T::INTSTS0: PIF1 Mask */ #define EPWM_INTSTS0_PIF2_Pos (10) /*!< EPWM_T::INTSTS0: PIF2 Position */ #define EPWM_INTSTS0_PIF2_Msk (0x1ul << EPWM_INTSTS0_PIF2_Pos) /*!< EPWM_T::INTSTS0: PIF2 Mask */ #define EPWM_INTSTS0_PIF3_Pos (11) /*!< EPWM_T::INTSTS0: PIF3 Position */ #define EPWM_INTSTS0_PIF3_Msk (0x1ul << EPWM_INTSTS0_PIF3_Pos) /*!< EPWM_T::INTSTS0: PIF3 Mask */ #define EPWM_INTSTS0_PIF4_Pos (12) /*!< EPWM_T::INTSTS0: PIF4 Position */ #define EPWM_INTSTS0_PIF4_Msk (0x1ul << EPWM_INTSTS0_PIF4_Pos) /*!< EPWM_T::INTSTS0: PIF4 Mask */ #define EPWM_INTSTS0_PIF5_Pos (13) /*!< EPWM_T::INTSTS0: PIF5 Position */ #define EPWM_INTSTS0_PIF5_Msk (0x1ul << EPWM_INTSTS0_PIF5_Pos) /*!< EPWM_T::INTSTS0: PIF5 Mask */ #define EPWM_INTSTS0_CMPUIF0_Pos (16) /*!< EPWM_T::INTSTS0: CMPUIF0 Position */ #define EPWM_INTSTS0_CMPUIF0_Msk (0x1ul << EPWM_INTSTS0_CMPUIF0_Pos) /*!< EPWM_T::INTSTS0: CMPUIF0 Mask */ #define EPWM_INTSTS0_CMPUIF1_Pos (17) /*!< EPWM_T::INTSTS0: CMPUIF1 Position */ #define EPWM_INTSTS0_CMPUIF1_Msk (0x1ul << EPWM_INTSTS0_CMPUIF1_Pos) /*!< EPWM_T::INTSTS0: CMPUIF1 Mask */ #define EPWM_INTSTS0_CMPUIF2_Pos (18) /*!< EPWM_T::INTSTS0: CMPUIF2 Position */ #define EPWM_INTSTS0_CMPUIF2_Msk (0x1ul << EPWM_INTSTS0_CMPUIF2_Pos) /*!< EPWM_T::INTSTS0: CMPUIF2 Mask */ #define EPWM_INTSTS0_CMPUIF3_Pos (19) /*!< EPWM_T::INTSTS0: CMPUIF3 Position */ #define EPWM_INTSTS0_CMPUIF3_Msk (0x1ul << EPWM_INTSTS0_CMPUIF3_Pos) /*!< EPWM_T::INTSTS0: CMPUIF3 Mask */ #define EPWM_INTSTS0_CMPUIF4_Pos (20) /*!< EPWM_T::INTSTS0: CMPUIF4 Position */ #define EPWM_INTSTS0_CMPUIF4_Msk (0x1ul << EPWM_INTSTS0_CMPUIF4_Pos) /*!< EPWM_T::INTSTS0: CMPUIF4 Mask */ #define EPWM_INTSTS0_CMPUIF5_Pos (21) /*!< EPWM_T::INTSTS0: CMPUIF5 Position */ #define EPWM_INTSTS0_CMPUIF5_Msk (0x1ul << EPWM_INTSTS0_CMPUIF5_Pos) /*!< EPWM_T::INTSTS0: CMPUIF5 Mask */ #define EPWM_INTSTS0_CMPDIF0_Pos (24) /*!< EPWM_T::INTSTS0: CMPDIF0 Position */ #define EPWM_INTSTS0_CMPDIF0_Msk (0x1ul << EPWM_INTSTS0_CMPDIF0_Pos) /*!< EPWM_T::INTSTS0: CMPDIF0 Mask */ #define EPWM_INTSTS0_CMPDIF1_Pos (25) /*!< EPWM_T::INTSTS0: CMPDIF1 Position */ #define EPWM_INTSTS0_CMPDIF1_Msk (0x1ul << EPWM_INTSTS0_CMPDIF1_Pos) /*!< EPWM_T::INTSTS0: CMPDIF1 Mask */ #define EPWM_INTSTS0_CMPDIF2_Pos (26) /*!< EPWM_T::INTSTS0: CMPDIF2 Position */ #define EPWM_INTSTS0_CMPDIF2_Msk (0x1ul << EPWM_INTSTS0_CMPDIF2_Pos) /*!< EPWM_T::INTSTS0: CMPDIF2 Mask */ #define EPWM_INTSTS0_CMPDIF3_Pos (27) /*!< EPWM_T::INTSTS0: CMPDIF3 Position */ #define EPWM_INTSTS0_CMPDIF3_Msk (0x1ul << EPWM_INTSTS0_CMPDIF3_Pos) /*!< EPWM_T::INTSTS0: CMPDIF3 Mask */ #define EPWM_INTSTS0_CMPDIF4_Pos (28) /*!< EPWM_T::INTSTS0: CMPDIF4 Position */ #define EPWM_INTSTS0_CMPDIF4_Msk (0x1ul << EPWM_INTSTS0_CMPDIF4_Pos) /*!< EPWM_T::INTSTS0: CMPDIF4 Mask */ #define EPWM_INTSTS0_CMPDIF5_Pos (29) /*!< EPWM_T::INTSTS0: CMPDIF5 Position */ #define EPWM_INTSTS0_CMPDIF5_Msk (0x1ul << EPWM_INTSTS0_CMPDIF5_Pos) /*!< EPWM_T::INTSTS0: CMPDIF5 Mask */ #define EPWM_INTSTS1_BRKEIF0_Pos (0) /*!< EPWM_T::INTSTS1: BRKEIF0 Position */ #define EPWM_INTSTS1_BRKEIF0_Msk (0x1ul << EPWM_INTSTS1_BRKEIF0_Pos) /*!< EPWM_T::INTSTS1: BRKEIF0 Mask */ #define EPWM_INTSTS1_BRKEIF1_Pos (1) /*!< EPWM_T::INTSTS1: BRKEIF1 Position */ #define EPWM_INTSTS1_BRKEIF1_Msk (0x1ul << EPWM_INTSTS1_BRKEIF1_Pos) /*!< EPWM_T::INTSTS1: BRKEIF1 Mask */ #define EPWM_INTSTS1_BRKEIF2_Pos (2) /*!< EPWM_T::INTSTS1: BRKEIF2 Position */ #define EPWM_INTSTS1_BRKEIF2_Msk (0x1ul << EPWM_INTSTS1_BRKEIF2_Pos) /*!< EPWM_T::INTSTS1: BRKEIF2 Mask */ #define EPWM_INTSTS1_BRKEIF3_Pos (3) /*!< EPWM_T::INTSTS1: BRKEIF3 Position */ #define EPWM_INTSTS1_BRKEIF3_Msk (0x1ul << EPWM_INTSTS1_BRKEIF3_Pos) /*!< EPWM_T::INTSTS1: BRKEIF3 Mask */ #define EPWM_INTSTS1_BRKEIF4_Pos (4) /*!< EPWM_T::INTSTS1: BRKEIF4 Position */ #define EPWM_INTSTS1_BRKEIF4_Msk (0x1ul << EPWM_INTSTS1_BRKEIF4_Pos) /*!< EPWM_T::INTSTS1: BRKEIF4 Mask */ #define EPWM_INTSTS1_BRKEIF5_Pos (5) /*!< EPWM_T::INTSTS1: BRKEIF5 Position */ #define EPWM_INTSTS1_BRKEIF5_Msk (0x1ul << EPWM_INTSTS1_BRKEIF5_Pos) /*!< EPWM_T::INTSTS1: BRKEIF5 Mask */ #define EPWM_INTSTS1_BRKLIF0_Pos (8) /*!< EPWM_T::INTSTS1: BRKLIF0 Position */ #define EPWM_INTSTS1_BRKLIF0_Msk (0x1ul << EPWM_INTSTS1_BRKLIF0_Pos) /*!< EPWM_T::INTSTS1: BRKLIF0 Mask */ #define EPWM_INTSTS1_BRKLIF1_Pos (9) /*!< EPWM_T::INTSTS1: BRKLIF1 Position */ #define EPWM_INTSTS1_BRKLIF1_Msk (0x1ul << EPWM_INTSTS1_BRKLIF1_Pos) /*!< EPWM_T::INTSTS1: BRKLIF1 Mask */ #define EPWM_INTSTS1_BRKLIF2_Pos (10) /*!< EPWM_T::INTSTS1: BRKLIF2 Position */ #define EPWM_INTSTS1_BRKLIF2_Msk (0x1ul << EPWM_INTSTS1_BRKLIF2_Pos) /*!< EPWM_T::INTSTS1: BRKLIF2 Mask */ #define EPWM_INTSTS1_BRKLIF3_Pos (11) /*!< EPWM_T::INTSTS1: BRKLIF3 Position */ #define EPWM_INTSTS1_BRKLIF3_Msk (0x1ul << EPWM_INTSTS1_BRKLIF3_Pos) /*!< EPWM_T::INTSTS1: BRKLIF3 Mask */ #define EPWM_INTSTS1_BRKLIF4_Pos (12) /*!< EPWM_T::INTSTS1: BRKLIF4 Position */ #define EPWM_INTSTS1_BRKLIF4_Msk (0x1ul << EPWM_INTSTS1_BRKLIF4_Pos) /*!< EPWM_T::INTSTS1: BRKLIF4 Mask */ #define EPWM_INTSTS1_BRKLIF5_Pos (13) /*!< EPWM_T::INTSTS1: BRKLIF5 Position */ #define EPWM_INTSTS1_BRKLIF5_Msk (0x1ul << EPWM_INTSTS1_BRKLIF5_Pos) /*!< EPWM_T::INTSTS1: BRKLIF5 Mask */ #define EPWM_INTSTS1_BRKESTS0_Pos (16) /*!< EPWM_T::INTSTS1: BRKESTS0 Position */ #define EPWM_INTSTS1_BRKESTS0_Msk (0x1ul << EPWM_INTSTS1_BRKESTS0_Pos) /*!< EPWM_T::INTSTS1: BRKESTS0 Mask */ #define EPWM_INTSTS1_BRKESTS1_Pos (17) /*!< EPWM_T::INTSTS1: BRKESTS1 Position */ #define EPWM_INTSTS1_BRKESTS1_Msk (0x1ul << EPWM_INTSTS1_BRKESTS1_Pos) /*!< EPWM_T::INTSTS1: BRKESTS1 Mask */ #define EPWM_INTSTS1_BRKESTS2_Pos (18) /*!< EPWM_T::INTSTS1: BRKESTS2 Position */ #define EPWM_INTSTS1_BRKESTS2_Msk (0x1ul << EPWM_INTSTS1_BRKESTS2_Pos) /*!< EPWM_T::INTSTS1: BRKESTS2 Mask */ #define EPWM_INTSTS1_BRKESTS3_Pos (19) /*!< EPWM_T::INTSTS1: BRKESTS3 Position */ #define EPWM_INTSTS1_BRKESTS3_Msk (0x1ul << EPWM_INTSTS1_BRKESTS3_Pos) /*!< EPWM_T::INTSTS1: BRKESTS3 Mask */ #define EPWM_INTSTS1_BRKESTS4_Pos (20) /*!< EPWM_T::INTSTS1: BRKESTS4 Position */ #define EPWM_INTSTS1_BRKESTS4_Msk (0x1ul << EPWM_INTSTS1_BRKESTS4_Pos) /*!< EPWM_T::INTSTS1: BRKESTS4 Mask */ #define EPWM_INTSTS1_BRKESTS5_Pos (21) /*!< EPWM_T::INTSTS1: BRKESTS5 Position */ #define EPWM_INTSTS1_BRKESTS5_Msk (0x1ul << EPWM_INTSTS1_BRKESTS5_Pos) /*!< EPWM_T::INTSTS1: BRKESTS5 Mask */ #define EPWM_INTSTS1_BRKLSTS0_Pos (24) /*!< EPWM_T::INTSTS1: BRKLSTS0 Position */ #define EPWM_INTSTS1_BRKLSTS0_Msk (0x1ul << EPWM_INTSTS1_BRKLSTS0_Pos) /*!< EPWM_T::INTSTS1: BRKLSTS0 Mask */ #define EPWM_INTSTS1_BRKLSTS1_Pos (25) /*!< EPWM_T::INTSTS1: BRKLSTS1 Position */ #define EPWM_INTSTS1_BRKLSTS1_Msk (0x1ul << EPWM_INTSTS1_BRKLSTS1_Pos) /*!< EPWM_T::INTSTS1: BRKLSTS1 Mask */ #define EPWM_INTSTS1_BRKLSTS2_Pos (26) /*!< EPWM_T::INTSTS1: BRKLSTS2 Position */ #define EPWM_INTSTS1_BRKLSTS2_Msk (0x1ul << EPWM_INTSTS1_BRKLSTS2_Pos) /*!< EPWM_T::INTSTS1: BRKLSTS2 Mask */ #define EPWM_INTSTS1_BRKLSTS3_Pos (27) /*!< EPWM_T::INTSTS1: BRKLSTS3 Position */ #define EPWM_INTSTS1_BRKLSTS3_Msk (0x1ul << EPWM_INTSTS1_BRKLSTS3_Pos) /*!< EPWM_T::INTSTS1: BRKLSTS3 Mask */ #define EPWM_INTSTS1_BRKLSTS4_Pos (28) /*!< EPWM_T::INTSTS1: BRKLSTS4 Position */ #define EPWM_INTSTS1_BRKLSTS4_Msk (0x1ul << EPWM_INTSTS1_BRKLSTS4_Pos) /*!< EPWM_T::INTSTS1: BRKLSTS4 Mask */ #define EPWM_INTSTS1_BRKLSTS5_Pos (29) /*!< EPWM_T::INTSTS1: BRKLSTS5 Position */ #define EPWM_INTSTS1_BRKLSTS5_Msk (0x1ul << EPWM_INTSTS1_BRKLSTS5_Pos) /*!< EPWM_T::INTSTS1: BRKLSTS5 Mask */ #define EPWM_DACTRGEN_ZTE0_Pos (0) /*!< EPWM_T::DACTRGEN: ZTE0 Position */ #define EPWM_DACTRGEN_ZTE0_Msk (0x1ul << EPWM_DACTRGEN_ZTE0_Pos) /*!< EPWM_T::DACTRGEN: ZTE0 Mask */ #define EPWM_DACTRGEN_ZTE1_Pos (1) /*!< EPWM_T::DACTRGEN: ZTE1 Position */ #define EPWM_DACTRGEN_ZTE1_Msk (0x1ul << EPWM_DACTRGEN_ZTE1_Pos) /*!< EPWM_T::DACTRGEN: ZTE1 Mask */ #define EPWM_DACTRGEN_ZTE2_Pos (2) /*!< EPWM_T::DACTRGEN: ZTE2 Position */ #define EPWM_DACTRGEN_ZTE2_Msk (0x1ul << EPWM_DACTRGEN_ZTE2_Pos) /*!< EPWM_T::DACTRGEN: ZTE2 Mask */ #define EPWM_DACTRGEN_ZTE3_Pos (3) /*!< EPWM_T::DACTRGEN: ZTE3 Position */ #define EPWM_DACTRGEN_ZTE3_Msk (0x1ul << EPWM_DACTRGEN_ZTE3_Pos) /*!< EPWM_T::DACTRGEN: ZTE3 Mask */ #define EPWM_DACTRGEN_ZTE4_Pos (4) /*!< EPWM_T::DACTRGEN: ZTE4 Position */ #define EPWM_DACTRGEN_ZTE4_Msk (0x1ul << EPWM_DACTRGEN_ZTE4_Pos) /*!< EPWM_T::DACTRGEN: ZTE4 Mask */ #define EPWM_DACTRGEN_ZTE5_Pos (5) /*!< EPWM_T::DACTRGEN: ZTE5 Position */ #define EPWM_DACTRGEN_ZTE5_Msk (0x1ul << EPWM_DACTRGEN_ZTE5_Pos) /*!< EPWM_T::DACTRGEN: ZTE5 Mask */ #define EPWM_DACTRGEN_PTE0_Pos (8) /*!< EPWM_T::DACTRGEN: PTE0 Position */ #define EPWM_DACTRGEN_PTE0_Msk (0x1ul << EPWM_DACTRGEN_PTE0_Pos) /*!< EPWM_T::DACTRGEN: PTE0 Mask */ #define EPWM_DACTRGEN_PTE1_Pos (9) /*!< EPWM_T::DACTRGEN: PTE1 Position */ #define EPWM_DACTRGEN_PTE1_Msk (0x1ul << EPWM_DACTRGEN_PTE1_Pos) /*!< EPWM_T::DACTRGEN: PTE1 Mask */ #define EPWM_DACTRGEN_PTE2_Pos (10) /*!< EPWM_T::DACTRGEN: PTE2 Position */ #define EPWM_DACTRGEN_PTE2_Msk (0x1ul << EPWM_DACTRGEN_PTE2_Pos) /*!< EPWM_T::DACTRGEN: PTE2 Mask */ #define EPWM_DACTRGEN_PTE3_Pos (11) /*!< EPWM_T::DACTRGEN: PTE3 Position */ #define EPWM_DACTRGEN_PTE3_Msk (0x1ul << EPWM_DACTRGEN_PTE3_Pos) /*!< EPWM_T::DACTRGEN: PTE3 Mask */ #define EPWM_DACTRGEN_PTE4_Pos (12) /*!< EPWM_T::DACTRGEN: PTE4 Position */ #define EPWM_DACTRGEN_PTE4_Msk (0x1ul << EPWM_DACTRGEN_PTE4_Pos) /*!< EPWM_T::DACTRGEN: PTE4 Mask */ #define EPWM_DACTRGEN_PTE5_Pos (13) /*!< EPWM_T::DACTRGEN: PTE5 Position */ #define EPWM_DACTRGEN_PTE5_Msk (0x1ul << EPWM_DACTRGEN_PTE5_Pos) /*!< EPWM_T::DACTRGEN: PTE5 Mask */ #define EPWM_DACTRGEN_CUTRGE0_Pos (16) /*!< EPWM_T::DACTRGEN: CUTRGE0 Position */ #define EPWM_DACTRGEN_CUTRGE0_Msk (0x1ul << EPWM_DACTRGEN_CUTRGE0_Pos) /*!< EPWM_T::DACTRGEN: CUTRGE0 Mask */ #define EPWM_DACTRGEN_CUTRGE1_Pos (17) /*!< EPWM_T::DACTRGEN: CUTRGE1 Position */ #define EPWM_DACTRGEN_CUTRGE1_Msk (0x1ul << EPWM_DACTRGEN_CUTRGE1_Pos) /*!< EPWM_T::DACTRGEN: CUTRGE1 Mask */ #define EPWM_DACTRGEN_CUTRGE2_Pos (18) /*!< EPWM_T::DACTRGEN: CUTRGE2 Position */ #define EPWM_DACTRGEN_CUTRGE2_Msk (0x1ul << EPWM_DACTRGEN_CUTRGE2_Pos) /*!< EPWM_T::DACTRGEN: CUTRGE2 Mask */ #define EPWM_DACTRGEN_CUTRGE3_Pos (19) /*!< EPWM_T::DACTRGEN: CUTRGE3 Position */ #define EPWM_DACTRGEN_CUTRGE3_Msk (0x1ul << EPWM_DACTRGEN_CUTRGE3_Pos) /*!< EPWM_T::DACTRGEN: CUTRGE3 Mask */ #define EPWM_DACTRGEN_CUTRGE4_Pos (20) /*!< EPWM_T::DACTRGEN: CUTRGE4 Position */ #define EPWM_DACTRGEN_CUTRGE4_Msk (0x1ul << EPWM_DACTRGEN_CUTRGE4_Pos) /*!< EPWM_T::DACTRGEN: CUTRGE4 Mask */ #define EPWM_DACTRGEN_CUTRGE5_Pos (21) /*!< EPWM_T::DACTRGEN: CUTRGE5 Position */ #define EPWM_DACTRGEN_CUTRGE5_Msk (0x1ul << EPWM_DACTRGEN_CUTRGE5_Pos) /*!< EPWM_T::DACTRGEN: CUTRGE5 Mask */ #define EPWM_DACTRGEN_CDTRGE0_Pos (24) /*!< EPWM_T::DACTRGEN: CDTRGE0 Position */ #define EPWM_DACTRGEN_CDTRGE0_Msk (0x1ul << EPWM_DACTRGEN_CDTRGE0_Pos) /*!< EPWM_T::DACTRGEN: CDTRGE0 Mask */ #define EPWM_DACTRGEN_CDTRGE1_Pos (25) /*!< EPWM_T::DACTRGEN: CDTRGE1 Position */ #define EPWM_DACTRGEN_CDTRGE1_Msk (0x1ul << EPWM_DACTRGEN_CDTRGE1_Pos) /*!< EPWM_T::DACTRGEN: CDTRGE1 Mask */ #define EPWM_DACTRGEN_CDTRGE2_Pos (26) /*!< EPWM_T::DACTRGEN: CDTRGE2 Position */ #define EPWM_DACTRGEN_CDTRGE2_Msk (0x1ul << EPWM_DACTRGEN_CDTRGE2_Pos) /*!< EPWM_T::DACTRGEN: CDTRGE2 Mask */ #define EPWM_DACTRGEN_CDTRGE3_Pos (27) /*!< EPWM_T::DACTRGEN: CDTRGE3 Position */ #define EPWM_DACTRGEN_CDTRGE3_Msk (0x1ul << EPWM_DACTRGEN_CDTRGE3_Pos) /*!< EPWM_T::DACTRGEN: CDTRGE3 Mask */ #define EPWM_DACTRGEN_CDTRGE4_Pos (28) /*!< EPWM_T::DACTRGEN: CDTRGE4 Position */ #define EPWM_DACTRGEN_CDTRGE4_Msk (0x1ul << EPWM_DACTRGEN_CDTRGE4_Pos) /*!< EPWM_T::DACTRGEN: CDTRGE4 Mask */ #define EPWM_DACTRGEN_CDTRGE5_Pos (29) /*!< EPWM_T::DACTRGEN: CDTRGE5 Position */ #define EPWM_DACTRGEN_CDTRGE5_Msk (0x1ul << EPWM_DACTRGEN_CDTRGE5_Pos) /*!< EPWM_T::DACTRGEN: CDTRGE5 Mask */ #define EPWM_EADCTS0_TRGSEL0_Pos (0) /*!< EPWM_T::EADCTS0: TRGSEL0 Position */ #define EPWM_EADCTS0_TRGSEL0_Msk (0xful << EPWM_EADCTS0_TRGSEL0_Pos) /*!< EPWM_T::EADCTS0: TRGSEL0 Mask */ #define EPWM_EADCTS0_TRGEN0_Pos (7) /*!< EPWM_T::EADCTS0: TRGEN0 Position */ #define EPWM_EADCTS0_TRGEN0_Msk (0x1ul << EPWM_EADCTS0_TRGEN0_Pos) /*!< EPWM_T::EADCTS0: TRGEN0 Mask */ #define EPWM_EADCTS0_TRGSEL1_Pos (8) /*!< EPWM_T::EADCTS0: TRGSEL1 Position */ #define EPWM_EADCTS0_TRGSEL1_Msk (0xful << EPWM_EADCTS0_TRGSEL1_Pos) /*!< EPWM_T::EADCTS0: TRGSEL1 Mask */ #define EPWM_EADCTS0_TRGEN1_Pos (15) /*!< EPWM_T::EADCTS0: TRGEN1 Position */ #define EPWM_EADCTS0_TRGEN1_Msk (0x1ul << EPWM_EADCTS0_TRGEN1_Pos) /*!< EPWM_T::EADCTS0: TRGEN1 Mask */ #define EPWM_EADCTS0_TRGSEL2_Pos (16) /*!< EPWM_T::EADCTS0: TRGSEL2 Position */ #define EPWM_EADCTS0_TRGSEL2_Msk (0xful << EPWM_EADCTS0_TRGSEL2_Pos) /*!< EPWM_T::EADCTS0: TRGSEL2 Mask */ #define EPWM_EADCTS0_TRGEN2_Pos (23) /*!< EPWM_T::EADCTS0: TRGEN2 Position */ #define EPWM_EADCTS0_TRGEN2_Msk (0x1ul << EPWM_EADCTS0_TRGEN2_Pos) /*!< EPWM_T::EADCTS0: TRGEN2 Mask */ #define EPWM_EADCTS0_TRGSEL3_Pos (24) /*!< EPWM_T::EADCTS0: TRGSEL3 Position */ #define EPWM_EADCTS0_TRGSEL3_Msk (0xful << EPWM_EADCTS0_TRGSEL3_Pos) /*!< EPWM_T::EADCTS0: TRGSEL3 Mask */ #define EPWM_EADCTS0_TRGEN3_Pos (31) /*!< EPWM_T::EADCTS0: TRGEN3 Position */ #define EPWM_EADCTS0_TRGEN3_Msk (0x1ul << EPWM_EADCTS0_TRGEN3_Pos) /*!< EPWM_T::EADCTS0: TRGEN3 Mask */ #define EPWM_EADCTS1_TRGSEL4_Pos (0) /*!< EPWM_T::EADCTS1: TRGSEL4 Position */ #define EPWM_EADCTS1_TRGSEL4_Msk (0xful << EPWM_EADCTS1_TRGSEL4_Pos) /*!< EPWM_T::EADCTS1: TRGSEL4 Mask */ #define EPWM_EADCTS1_TRGEN4_Pos (7) /*!< EPWM_T::EADCTS1: TRGEN4 Position */ #define EPWM_EADCTS1_TRGEN4_Msk (0x1ul << EPWM_EADCTS1_TRGEN4_Pos) /*!< EPWM_T::EADCTS1: TRGEN4 Mask */ #define EPWM_EADCTS1_TRGSEL5_Pos (8) /*!< EPWM_T::EADCTS1: TRGSEL5 Position */ #define EPWM_EADCTS1_TRGSEL5_Msk (0xful << EPWM_EADCTS1_TRGSEL5_Pos) /*!< EPWM_T::EADCTS1: TRGSEL5 Mask */ #define EPWM_EADCTS1_TRGEN5_Pos (15) /*!< EPWM_T::EADCTS1: TRGEN5 Position */ #define EPWM_EADCTS1_TRGEN5_Msk (0x1ul << EPWM_EADCTS1_TRGEN5_Pos) /*!< EPWM_T::EADCTS1: TRGEN5 Mask */ #define EPWM_FTCMPDAT0_1_FTCMP_Pos (0) /*!< EPWM_T::FTCMPDAT0_1: FTCMP Position */ #define EPWM_FTCMPDAT0_1_FTCMP_Msk (0xfffful << EPWM_FTCMPDAT0_1_FTCMP_Pos) /*!< EPWM_T::FTCMPDAT0_1: FTCMP Mask */ #define EPWM_FTCMPDAT2_3_FTCMP_Pos (0) /*!< EPWM_T::FTCMPDAT2_3: FTCMP Position */ #define EPWM_FTCMPDAT2_3_FTCMP_Msk (0xfffful << EPWM_FTCMPDAT2_3_FTCMP_Pos) /*!< EPWM_T::FTCMPDAT2_3: FTCMP Mask */ #define EPWM_FTCMPDAT4_5_FTCMP_Pos (0) /*!< EPWM_T::FTCMPDAT4_5: FTCMP Position */ #define EPWM_FTCMPDAT4_5_FTCMP_Msk (0xfffful << EPWM_FTCMPDAT4_5_FTCMP_Pos) /*!< EPWM_T::FTCMPDAT4_5: FTCMP Mask */ #define EPWM_SSCTL_SSEN0_Pos (0) /*!< EPWM_T::SSCTL: SSEN0 Position */ #define EPWM_SSCTL_SSEN0_Msk (0x1ul << EPWM_SSCTL_SSEN0_Pos) /*!< EPWM_T::SSCTL: SSEN0 Mask */ #define EPWM_SSCTL_SSEN1_Pos (1) /*!< EPWM_T::SSCTL: SSEN1 Position */ #define EPWM_SSCTL_SSEN1_Msk (0x1ul << EPWM_SSCTL_SSEN1_Pos) /*!< EPWM_T::SSCTL: SSEN1 Mask */ #define EPWM_SSCTL_SSEN2_Pos (2) /*!< EPWM_T::SSCTL: SSEN2 Position */ #define EPWM_SSCTL_SSEN2_Msk (0x1ul << EPWM_SSCTL_SSEN2_Pos) /*!< EPWM_T::SSCTL: SSEN2 Mask */ #define EPWM_SSCTL_SSEN3_Pos (3) /*!< EPWM_T::SSCTL: SSEN3 Position */ #define EPWM_SSCTL_SSEN3_Msk (0x1ul << EPWM_SSCTL_SSEN3_Pos) /*!< EPWM_T::SSCTL: SSEN3 Mask */ #define EPWM_SSCTL_SSEN4_Pos (4) /*!< EPWM_T::SSCTL: SSEN4 Position */ #define EPWM_SSCTL_SSEN4_Msk (0x1ul << EPWM_SSCTL_SSEN4_Pos) /*!< EPWM_T::SSCTL: SSEN4 Mask */ #define EPWM_SSCTL_SSEN5_Pos (5) /*!< EPWM_T::SSCTL: SSEN5 Position */ #define EPWM_SSCTL_SSEN5_Msk (0x1ul << EPWM_SSCTL_SSEN5_Pos) /*!< EPWM_T::SSCTL: SSEN5 Mask */ #define EPWM_SSCTL_SSRC_Pos (8) /*!< EPWM_T::SSCTL: SSRC Position */ #define EPWM_SSCTL_SSRC_Msk (0x3ul << EPWM_SSCTL_SSRC_Pos) /*!< EPWM_T::SSCTL: SSRC Mask */ #define EPWM_SSTRG_CNTSEN_Pos (0) /*!< EPWM_T::SSTRG: CNTSEN Position */ #define EPWM_SSTRG_CNTSEN_Msk (0x1ul << EPWM_SSTRG_CNTSEN_Pos) /*!< EPWM_T::SSTRG: CNTSEN Mask */ #define EPWM_LEBCTL_LEBEN_Pos (0) /*!< EPWM_T::LEBCTL: LEBEN Position */ #define EPWM_LEBCTL_LEBEN_Msk (0x1ul << EPWM_LEBCTL_LEBEN_Pos) /*!< EPWM_T::LEBCTL: LEBEN Mask */ #define EPWM_LEBCTL_SRCEN0_Pos (8) /*!< EPWM_T::LEBCTL: SRCEN0 Position */ #define EPWM_LEBCTL_SRCEN0_Msk (0x1ul << EPWM_LEBCTL_SRCEN0_Pos) /*!< EPWM_T::LEBCTL: SRCEN0 Mask */ #define EPWM_LEBCTL_SRCEN2_Pos (9) /*!< EPWM_T::LEBCTL: SRCEN2 Position */ #define EPWM_LEBCTL_SRCEN2_Msk (0x1ul << EPWM_LEBCTL_SRCEN2_Pos) /*!< EPWM_T::LEBCTL: SRCEN2 Mask */ #define EPWM_LEBCTL_SRCEN4_Pos (10) /*!< EPWM_T::LEBCTL: SRCEN4 Position */ #define EPWM_LEBCTL_SRCEN4_Msk (0x1ul << EPWM_LEBCTL_SRCEN4_Pos) /*!< EPWM_T::LEBCTL: SRCEN4 Mask */ #define EPWM_LEBCTL_TRGTYPE_Pos (16) /*!< EPWM_T::LEBCTL: TRGTYPE Position */ #define EPWM_LEBCTL_TRGTYPE_Msk (0x3ul << EPWM_LEBCTL_TRGTYPE_Pos) /*!< EPWM_T::LEBCTL: TRGTYPE Mask */ #define EPWM_LEBCNT_LEBCNT_Pos (0) /*!< EPWM_T::LEBCNT: LEBCNT Position */ #define EPWM_LEBCNT_LEBCNT_Msk (0x1fful << EPWM_LEBCNT_LEBCNT_Pos) /*!< EPWM_T::LEBCNT: LEBCNT Mask */ #define EPWM_STATUS_CNTMAXF0_Pos (0) /*!< EPWM_T::STATUS: CNTMAXF0 Position */ #define EPWM_STATUS_CNTMAXF0_Msk (0x1ul << EPWM_STATUS_CNTMAXF0_Pos) /*!< EPWM_T::STATUS: CNTMAXF0 Mask */ #define EPWM_STATUS_CNTMAXF1_Pos (1) /*!< EPWM_T::STATUS: CNTMAXF1 Position */ #define EPWM_STATUS_CNTMAXF1_Msk (0x1ul << EPWM_STATUS_CNTMAXF1_Pos) /*!< EPWM_T::STATUS: CNTMAXF1 Mask */ #define EPWM_STATUS_CNTMAXF2_Pos (2) /*!< EPWM_T::STATUS: CNTMAXF2 Position */ #define EPWM_STATUS_CNTMAXF2_Msk (0x1ul << EPWM_STATUS_CNTMAXF2_Pos) /*!< EPWM_T::STATUS: CNTMAXF2 Mask */ #define EPWM_STATUS_CNTMAXF3_Pos (3) /*!< EPWM_T::STATUS: CNTMAXF3 Position */ #define EPWM_STATUS_CNTMAXF3_Msk (0x1ul << EPWM_STATUS_CNTMAXF3_Pos) /*!< EPWM_T::STATUS: CNTMAXF3 Mask */ #define EPWM_STATUS_CNTMAXF4_Pos (4) /*!< EPWM_T::STATUS: CNTMAXF4 Position */ #define EPWM_STATUS_CNTMAXF4_Msk (0x1ul << EPWM_STATUS_CNTMAXF4_Pos) /*!< EPWM_T::STATUS: CNTMAXF4 Mask */ #define EPWM_STATUS_CNTMAXF5_Pos (5) /*!< EPWM_T::STATUS: CNTMAXF5 Position */ #define EPWM_STATUS_CNTMAXF5_Msk (0x1ul << EPWM_STATUS_CNTMAXF5_Pos) /*!< EPWM_T::STATUS: CNTMAXF5 Mask */ #define EPWM_STATUS_SYNCINF0_Pos (8) /*!< EPWM_T::STATUS: SYNCINF0 Position */ #define EPWM_STATUS_SYNCINF0_Msk (0x1ul << EPWM_STATUS_SYNCINF0_Pos) /*!< EPWM_T::STATUS: SYNCINF0 Mask */ #define EPWM_STATUS_SYNCINF2_Pos (9) /*!< EPWM_T::STATUS: SYNCINF2 Position */ #define EPWM_STATUS_SYNCINF2_Msk (0x1ul << EPWM_STATUS_SYNCINF2_Pos) /*!< EPWM_T::STATUS: SYNCINF2 Mask */ #define EPWM_STATUS_SYNCINF4_Pos (10) /*!< EPWM_T::STATUS: SYNCINF4 Position */ #define EPWM_STATUS_SYNCINF4_Msk (0x1ul << EPWM_STATUS_SYNCINF4_Pos) /*!< EPWM_T::STATUS: SYNCINF4 Mask */ #define EPWM_STATUS_EADCTRGF0_Pos (16) /*!< EPWM_T::STATUS: EADCTRGF0 Position */ #define EPWM_STATUS_EADCTRGF0_Msk (0x1ul << EPWM_STATUS_EADCTRGF0_Pos) /*!< EPWM_T::STATUS: EADCTRGF0 Mask */ #define EPWM_STATUS_EADCTRGF1_Pos (17) /*!< EPWM_T::STATUS: EADCTRGF1 Position */ #define EPWM_STATUS_EADCTRGF1_Msk (0x1ul << EPWM_STATUS_EADCTRGF1_Pos) /*!< EPWM_T::STATUS: EADCTRGF1 Mask */ #define EPWM_STATUS_EADCTRGF2_Pos (18) /*!< EPWM_T::STATUS: EADCTRGF2 Position */ #define EPWM_STATUS_EADCTRGF2_Msk (0x1ul << EPWM_STATUS_EADCTRGF2_Pos) /*!< EPWM_T::STATUS: EADCTRGF2 Mask */ #define EPWM_STATUS_EADCTRGF3_Pos (19) /*!< EPWM_T::STATUS: EADCTRGF3 Position */ #define EPWM_STATUS_EADCTRGF3_Msk (0x1ul << EPWM_STATUS_EADCTRGF3_Pos) /*!< EPWM_T::STATUS: EADCTRGF3 Mask */ #define EPWM_STATUS_EADCTRGF4_Pos (20) /*!< EPWM_T::STATUS: EADCTRGF4 Position */ #define EPWM_STATUS_EADCTRGF4_Msk (0x1ul << EPWM_STATUS_EADCTRGF4_Pos) /*!< EPWM_T::STATUS: EADCTRGF4 Mask */ #define EPWM_STATUS_EADCTRGF5_Pos (21) /*!< EPWM_T::STATUS: EADCTRGF5 Position */ #define EPWM_STATUS_EADCTRGF5_Msk (0x1ul << EPWM_STATUS_EADCTRGF5_Pos) /*!< EPWM_T::STATUS: EADCTRGF5 Mask */ #define EPWM_STATUS_DACTRGF_Pos (24) /*!< EPWM_T::STATUS: DACTRGF Position */ #define EPWM_STATUS_DACTRGF_Msk (0x1ul << EPWM_STATUS_DACTRGF_Pos) /*!< EPWM_T::STATUS: DACTRGF Mask */ #define EPWM_IFA0_IFACNT_Pos (0) /*!< EPWM_T::IFA0: IFACNT Position */ #define EPWM_IFA0_IFACNT_Msk (0xfffful << EPWM_IFA0_IFACNT_Pos) /*!< EPWM_T::IFA0: IFACNT Mask */ #define EPWM_IFA0_STPMOD_Pos (24) /*!< EPWM_T::IFA0: STPMOD Position */ #define EPWM_IFA0_STPMOD_Msk (0x1ul << EPWM_IFA0_STPMOD_Pos) /*!< EPWM_T::IFA0: STPMOD Mask */ #define EPWM_IFA0_IFASEL_Pos (28) /*!< EPWM_T::IFA0: IFASEL Position */ #define EPWM_IFA0_IFASEL_Msk (0x3ul << EPWM_IFA0_IFASEL_Pos) /*!< EPWM_T::IFA0: IFASEL Mask */ #define EPWM_IFA0_IFAEN_Pos (31) /*!< EPWM_T::IFA0: IFAEN Position */ #define EPWM_IFA0_IFAEN_Msk (0x1ul << EPWM_IFA0_IFAEN_Pos) /*!< EPWM_T::IFA0: IFAEN Mask */ #define EPWM_IFA1_IFACNT_Pos (0) /*!< EPWM_T::IFA1: IFACNT Position */ #define EPWM_IFA1_IFACNT_Msk (0xfffful << EPWM_IFA1_IFACNT_Pos) /*!< EPWM_T::IFA1: IFACNT Mask */ #define EPWM_IFA1_STPMOD_Pos (24) /*!< EPWM_T::IFA1: STPMOD Position */ #define EPWM_IFA1_STPMOD_Msk (0x1ul << EPWM_IFA1_STPMOD_Pos) /*!< EPWM_T::IFA1: STPMOD Mask */ #define EPWM_IFA1_IFASEL_Pos (28) /*!< EPWM_T::IFA1: IFASEL Position */ #define EPWM_IFA1_IFASEL_Msk (0x3ul << EPWM_IFA1_IFASEL_Pos) /*!< EPWM_T::IFA1: IFASEL Mask */ #define EPWM_IFA1_IFAEN_Pos (31) /*!< EPWM_T::IFA1: IFAEN Position */ #define EPWM_IFA1_IFAEN_Msk (0x1ul << EPWM_IFA1_IFAEN_Pos) /*!< EPWM_T::IFA1: IFAEN Mask */ #define EPWM_IFA2_IFACNT_Pos (0) /*!< EPWM_T::IFA2: IFACNT Position */ #define EPWM_IFA2_IFACNT_Msk (0xfffful << EPWM_IFA2_IFACNT_Pos) /*!< EPWM_T::IFA2: IFACNT Mask */ #define EPWM_IFA2_STPMOD_Pos (24) /*!< EPWM_T::IFA2: STPMOD Position */ #define EPWM_IFA2_STPMOD_Msk (0x1ul << EPWM_IFA2_STPMOD_Pos) /*!< EPWM_T::IFA2: STPMOD Mask */ #define EPWM_IFA2_IFASEL_Pos (28) /*!< EPWM_T::IFA2: IFASEL Position */ #define EPWM_IFA2_IFASEL_Msk (0x3ul << EPWM_IFA2_IFASEL_Pos) /*!< EPWM_T::IFA2: IFASEL Mask */ #define EPWM_IFA2_IFAEN_Pos (31) /*!< EPWM_T::IFA2: IFAEN Position */ #define EPWM_IFA2_IFAEN_Msk (0x1ul << EPWM_IFA2_IFAEN_Pos) /*!< EPWM_T::IFA2: IFAEN Mask */ #define EPWM_IFA3_IFACNT_Pos (0) /*!< EPWM_T::IFA3: IFACNT Position */ #define EPWM_IFA3_IFACNT_Msk (0xfffful << EPWM_IFA3_IFACNT_Pos) /*!< EPWM_T::IFA3: IFACNT Mask */ #define EPWM_IFA3_STPMOD_Pos (24) /*!< EPWM_T::IFA3: STPMOD Position */ #define EPWM_IFA3_STPMOD_Msk (0x1ul << EPWM_IFA3_STPMOD_Pos) /*!< EPWM_T::IFA3: STPMOD Mask */ #define EPWM_IFA3_IFASEL_Pos (28) /*!< EPWM_T::IFA3: IFASEL Position */ #define EPWM_IFA3_IFASEL_Msk (0x3ul << EPWM_IFA3_IFASEL_Pos) /*!< EPWM_T::IFA3: IFASEL Mask */ #define EPWM_IFA3_IFAEN_Pos (31) /*!< EPWM_T::IFA3: IFAEN Position */ #define EPWM_IFA3_IFAEN_Msk (0x1ul << EPWM_IFA3_IFAEN_Pos) /*!< EPWM_T::IFA3: IFAEN Mask */ #define EPWM_IFA4_IFACNT_Pos (0) /*!< EPWM_T::IFA4: IFACNT Position */ #define EPWM_IFA4_IFACNT_Msk (0xfffful << EPWM_IFA4_IFACNT_Pos) /*!< EPWM_T::IFA4: IFACNT Mask */ #define EPWM_IFA4_STPMOD_Pos (24) /*!< EPWM_T::IFA4: STPMOD Position */ #define EPWM_IFA4_STPMOD_Msk (0x1ul << EPWM_IFA4_STPMOD_Pos) /*!< EPWM_T::IFA4: STPMOD Mask */ #define EPWM_IFA4_IFASEL_Pos (28) /*!< EPWM_T::IFA4: IFASEL Position */ #define EPWM_IFA4_IFASEL_Msk (0x3ul << EPWM_IFA4_IFASEL_Pos) /*!< EPWM_T::IFA4: IFASEL Mask */ #define EPWM_IFA4_IFAEN_Pos (31) /*!< EPWM_T::IFA4: IFAEN Position */ #define EPWM_IFA4_IFAEN_Msk (0x1ul << EPWM_IFA4_IFAEN_Pos) /*!< EPWM_T::IFA4: IFAEN Mask */ #define EPWM_IFA5_IFACNT_Pos (0) /*!< EPWM_T::IFA5: IFACNT Position */ #define EPWM_IFA5_IFACNT_Msk (0xfffful << EPWM_IFA5_IFACNT_Pos) /*!< EPWM_T::IFA5: IFACNT Mask */ #define EPWM_IFA5_STPMOD_Pos (24) /*!< EPWM_T::IFA5: STPMOD Position */ #define EPWM_IFA5_STPMOD_Msk (0x1ul << EPWM_IFA5_STPMOD_Pos) /*!< EPWM_T::IFA5: STPMOD Mask */ #define EPWM_IFA5_IFASEL_Pos (28) /*!< EPWM_T::IFA5: IFASEL Position */ #define EPWM_IFA5_IFASEL_Msk (0x3ul << EPWM_IFA5_IFASEL_Pos) /*!< EPWM_T::IFA5: IFASEL Mask */ #define EPWM_IFA5_IFAEN_Pos (31) /*!< EPWM_T::IFA5: IFAEN Position */ #define EPWM_IFA5_IFAEN_Msk (0x1ul << EPWM_IFA5_IFAEN_Pos) /*!< EPWM_T::IFA5: IFAEN Mask */ #define EPWM_AINTSTS_IFAIF0_Pos (0) /*!< EPWM_T::AINTSTS: IFAIF0 Position */ #define EPWM_AINTSTS_IFAIF0_Msk (0x1ul << EPWM_AINTSTS_IFAIF0_Pos) /*!< EPWM_T::AINTSTS: IFAIF0 Mask */ #define EPWM_AINTSTS_IFAIF1_Pos (1) /*!< EPWM_T::AINTSTS: IFAIF1 Position */ #define EPWM_AINTSTS_IFAIF1_Msk (0x1ul << EPWM_AINTSTS_IFAIF1_Pos) /*!< EPWM_T::AINTSTS: IFAIF1 Mask */ #define EPWM_AINTSTS_IFAIF2_Pos (2) /*!< EPWM_T::AINTSTS: IFAIF2 Position */ #define EPWM_AINTSTS_IFAIF2_Msk (0x1ul << EPWM_AINTSTS_IFAIF2_Pos) /*!< EPWM_T::AINTSTS: IFAIF2 Mask */ #define EPWM_AINTSTS_IFAIF3_Pos (3) /*!< EPWM_T::AINTSTS: IFAIF3 Position */ #define EPWM_AINTSTS_IFAIF3_Msk (0x1ul << EPWM_AINTSTS_IFAIF3_Pos) /*!< EPWM_T::AINTSTS: IFAIF3 Mask */ #define EPWM_AINTSTS_IFAIF4_Pos (4) /*!< EPWM_T::AINTSTS: IFAIF4 Position */ #define EPWM_AINTSTS_IFAIF4_Msk (0x1ul << EPWM_AINTSTS_IFAIF4_Pos) /*!< EPWM_T::AINTSTS: IFAIF4 Mask */ #define EPWM_AINTSTS_IFAIF5_Pos (5) /*!< EPWM_T::AINTSTS: IFAIF5 Position */ #define EPWM_AINTSTS_IFAIF5_Msk (0x1ul << EPWM_AINTSTS_IFAIF5_Pos) /*!< EPWM_T::AINTSTS: IFAIF5 Mask */ #define EPWM_AINTEN_IFAIEN0_Pos (0) /*!< EPWM_T::AINTEN: IFAIEN0 Position */ #define EPWM_AINTEN_IFAIEN0_Msk (0x1ul << EPWM_AINTEN_IFAIEN0_Pos) /*!< EPWM_T::AINTEN: IFAIEN0 Mask */ #define EPWM_AINTEN_IFAIEN1_Pos (1) /*!< EPWM_T::AINTEN: IFAIEN1 Position */ #define EPWM_AINTEN_IFAIEN1_Msk (0x1ul << EPWM_AINTEN_IFAIEN1_Pos) /*!< EPWM_T::AINTEN: IFAIEN1 Mask */ #define EPWM_AINTEN_IFAIEN2_Pos (2) /*!< EPWM_T::AINTEN: IFAIEN2 Position */ #define EPWM_AINTEN_IFAIEN2_Msk (0x1ul << EPWM_AINTEN_IFAIEN2_Pos) /*!< EPWM_T::AINTEN: IFAIEN2 Mask */ #define EPWM_AINTEN_IFAIEN3_Pos (3) /*!< EPWM_T::AINTEN: IFAIEN3 Position */ #define EPWM_AINTEN_IFAIEN3_Msk (0x1ul << EPWM_AINTEN_IFAIEN3_Pos) /*!< EPWM_T::AINTEN: IFAIEN3 Mask */ #define EPWM_AINTEN_IFAIEN4_Pos (4) /*!< EPWM_T::AINTEN: IFAIEN4 Position */ #define EPWM_AINTEN_IFAIEN4_Msk (0x1ul << EPWM_AINTEN_IFAIEN4_Pos) /*!< EPWM_T::AINTEN: IFAIEN4 Mask */ #define EPWM_AINTEN_IFAIEN5_Pos (5) /*!< EPWM_T::AINTEN: IFAIEN5 Position */ #define EPWM_AINTEN_IFAIEN5_Msk (0x1ul << EPWM_AINTEN_IFAIEN5_Pos) /*!< EPWM_T::AINTEN: IFAIEN5 Mask */ #define EPWM_APDMACTL_APDMAEN0_Pos (0) /*!< EPWM_T::APDMACTL: APDMAEN0 Position */ #define EPWM_APDMACTL_APDMAEN0_Msk (0x1ul << EPWM_APDMACTL_APDMAEN0_Pos) /*!< EPWM_T::APDMACTL: APDMAEN0 Mask */ #define EPWM_APDMACTL_APDMAEN1_Pos (1) /*!< EPWM_T::APDMACTL: APDMAEN1 Position */ #define EPWM_APDMACTL_APDMAEN1_Msk (0x1ul << EPWM_APDMACTL_APDMAEN1_Pos) /*!< EPWM_T::APDMACTL: APDMAEN1 Mask */ #define EPWM_APDMACTL_APDMAEN2_Pos (2) /*!< EPWM_T::APDMACTL: APDMAEN2 Position */ #define EPWM_APDMACTL_APDMAEN2_Msk (0x1ul << EPWM_APDMACTL_APDMAEN2_Pos) /*!< EPWM_T::APDMACTL: APDMAEN2 Mask */ #define EPWM_APDMACTL_APDMAEN3_Pos (3) /*!< EPWM_T::APDMACTL: APDMAEN3 Position */ #define EPWM_APDMACTL_APDMAEN3_Msk (0x1ul << EPWM_APDMACTL_APDMAEN3_Pos) /*!< EPWM_T::APDMACTL: APDMAEN3 Mask */ #define EPWM_APDMACTL_APDMAEN4_Pos (4) /*!< EPWM_T::APDMACTL: APDMAEN4 Position */ #define EPWM_APDMACTL_APDMAEN4_Msk (0x1ul << EPWM_APDMACTL_APDMAEN4_Pos) /*!< EPWM_T::APDMACTL: APDMAEN4 Mask */ #define EPWM_APDMACTL_APDMAEN5_Pos (5) /*!< EPWM_T::APDMACTL: APDMAEN5 Position */ #define EPWM_APDMACTL_APDMAEN5_Msk (0x1ul << EPWM_APDMACTL_APDMAEN5_Pos) /*!< EPWM_T::APDMACTL: APDMAEN5 Mask */ #define EPWM_FDEN_FDEN0_Pos (0) /*!< EPWM_T::FDEN: FDEN0 Position */ #define EPWM_FDEN_FDEN0_Msk (0x1ul << EPWM_FDEN_FDEN0_Pos) /*!< EPWM_T::FDEN: FDEN0 Mask */ #define EPWM_FDEN_FDEN1_Pos (1) /*!< EPWM_T::FDEN: FDEN1 Position */ #define EPWM_FDEN_FDEN1_Msk (0x1ul << EPWM_FDEN_FDEN1_Pos) /*!< EPWM_T::FDEN: FDEN1 Mask */ #define EPWM_FDEN_FDEN2_Pos (2) /*!< EPWM_T::FDEN: FDEN2 Position */ #define EPWM_FDEN_FDEN2_Msk (0x1ul << EPWM_FDEN_FDEN2_Pos) /*!< EPWM_T::FDEN: FDEN2 Mask */ #define EPWM_FDEN_FDEN3_Pos (3) /*!< EPWM_T::FDEN: FDEN3 Position */ #define EPWM_FDEN_FDEN3_Msk (0x1ul << EPWM_FDEN_FDEN3_Pos) /*!< EPWM_T::FDEN: FDEN3 Mask */ #define EPWM_FDEN_FDEN4_Pos (4) /*!< EPWM_T::FDEN: FDEN4 Position */ #define EPWM_FDEN_FDEN4_Msk (0x1ul << EPWM_FDEN_FDEN4_Pos) /*!< EPWM_T::FDEN: FDEN4 Mask */ #define EPWM_FDEN_FDEN5_Pos (5) /*!< EPWM_T::FDEN: FDEN5 Position */ #define EPWM_FDEN_FDEN5_Msk (0x1ul << EPWM_FDEN_FDEN5_Pos) /*!< EPWM_T::FDEN: FDEN5 Mask */ #define EPWM_FDEN_FDODIS0_Pos (8) /*!< EPWM_T::FDEN: FDODIS0 Position */ #define EPWM_FDEN_FDODIS0_Msk (0x1ul << EPWM_FDEN_FDODIS0_Pos) /*!< EPWM_T::FDEN: FDODIS0 Mask */ #define EPWM_FDEN_FDODIS1_Pos (9) /*!< EPWM_T::FDEN: FDODIS1 Position */ #define EPWM_FDEN_FDODIS1_Msk (0x1ul << EPWM_FDEN_FDODIS1_Pos) /*!< EPWM_T::FDEN: FDODIS1 Mask */ #define EPWM_FDEN_FDODIS2_Pos (10) /*!< EPWM_T::FDEN: FDODIS2 Position */ #define EPWM_FDEN_FDODIS2_Msk (0x1ul << EPWM_FDEN_FDODIS2_Pos) /*!< EPWM_T::FDEN: FDODIS2 Mask */ #define EPWM_FDEN_FDODIS3_Pos (11) /*!< EPWM_T::FDEN: FDODIS3 Position */ #define EPWM_FDEN_FDODIS3_Msk (0x1ul << EPWM_FDEN_FDODIS3_Pos) /*!< EPWM_T::FDEN: FDODIS3 Mask */ #define EPWM_FDEN_FDODIS4_Pos (12) /*!< EPWM_T::FDEN: FDODIS4 Position */ #define EPWM_FDEN_FDODIS4_Msk (0x1ul << EPWM_FDEN_FDODIS4_Pos) /*!< EPWM_T::FDEN: FDODIS4 Mask */ #define EPWM_FDEN_FDODIS5_Pos (13) /*!< EPWM_T::FDEN: FDODIS5 Position */ #define EPWM_FDEN_FDODIS5_Msk (0x1ul << EPWM_FDEN_FDODIS5_Pos) /*!< EPWM_T::FDEN: FDODIS5 Mask */ #define EPWM_FDEN_FDCKS0_Pos (16) /*!< EPWM_T::FDEN: FDCKS0 Position */ #define EPWM_FDEN_FDCKS0_Msk (0x1ul << EPWM_FDEN_FDCKS0_Pos) /*!< EPWM_T::FDEN: FDCKS0 Mask */ #define EPWM_FDEN_FDCKS1_Pos (17) /*!< EPWM_T::FDEN: FDCKS1 Position */ #define EPWM_FDEN_FDCKS1_Msk (0x1ul << EPWM_FDEN_FDCKS1_Pos) /*!< EPWM_T::FDEN: FDCKS1 Mask */ #define EPWM_FDEN_FDCKS2_Pos (18) /*!< EPWM_T::FDEN: FDCKS2 Position */ #define EPWM_FDEN_FDCKS2_Msk (0x1ul << EPWM_FDEN_FDCKS2_Pos) /*!< EPWM_T::FDEN: FDCKS2 Mask */ #define EPWM_FDEN_FDCKS3_Pos (19) /*!< EPWM_T::FDEN: FDCKS3 Position */ #define EPWM_FDEN_FDCKS3_Msk (0x1ul << EPWM_FDEN_FDCKS3_Pos) /*!< EPWM_T::FDEN: FDCKS3 Mask */ #define EPWM_FDEN_FDCKS4_Pos (20) /*!< EPWM_T::FDEN: FDCKS4 Position */ #define EPWM_FDEN_FDCKS4_Msk (0x1ul << EPWM_FDEN_FDCKS4_Pos) /*!< EPWM_T::FDEN: FDCKS4 Mask */ #define EPWM_FDEN_FDCKS5_Pos (21) /*!< EPWM_T::FDEN: FDCKS5 Position */ #define EPWM_FDEN_FDCKS5_Msk (0x1ul << EPWM_FDEN_FDCKS5_Pos) /*!< EPWM_T::FDEN: FDCKS5 Mask */ #define EPWM_FDCTL0_TRMSKCNT_Pos (0) /*!< EPWM_T::FDCTL0: TRMSKCNT Position */ #define EPWM_FDCTL0_TRMSKCNT_Msk (0x7ful << EPWM_FDCTL0_TRMSKCNT_Pos) /*!< EPWM_T::FDCTL0: TRMSKCNT Mask */ #define EPWM_FDCTL0_FDMSKEN_Pos (15) /*!< EPWM_T::FDCTL0: FDMSKEN Position */ #define EPWM_FDCTL0_FDMSKEN_Msk (0x1ul << EPWM_FDCTL0_FDMSKEN_Pos) /*!< EPWM_T::FDCTL0: FDMSKEN Mask */ #define EPWM_FDCTL0_DGSMPCYC_Pos (16) /*!< EPWM_T::FDCTL0: DGSMPCYC Position */ #define EPWM_FDCTL0_DGSMPCYC_Msk (0x7ul << EPWM_FDCTL0_DGSMPCYC_Pos) /*!< EPWM_T::FDCTL0: DGSMPCYC Mask */ #define EPWM_FDCTL0_FDCKSEL_Pos (28) /*!< EPWM_T::FDCTL0: FDCKSEL Position */ #define EPWM_FDCTL0_FDCKSEL_Msk (0x3ul << EPWM_FDCTL0_FDCKSEL_Pos) /*!< EPWM_T::FDCTL0: FDCKSEL Mask */ #define EPWM_FDCTL0_FDDGEN_Pos (31) /*!< EPWM_T::FDCTL0: FDDGEN Position */ #define EPWM_FDCTL0_FDDGEN_Msk (0x1ul << EPWM_FDCTL0_FDDGEN_Pos) /*!< EPWM_T::FDCTL0: FDDGEN Mask */ #define EPWM_FDCTL1_TRMSKCNT_Pos (0) /*!< EPWM_T::FDCTL1: TRMSKCNT Position */ #define EPWM_FDCTL1_TRMSKCNT_Msk (0x7ful << EPWM_FDCTL1_TRMSKCNT_Pos) /*!< EPWM_T::FDCTL1: TRMSKCNT Mask */ #define EPWM_FDCTL1_FDMSKEN_Pos (15) /*!< EPWM_T::FDCTL1: FDMSKEN Position */ #define EPWM_FDCTL1_FDMSKEN_Msk (0x1ul << EPWM_FDCTL1_FDMSKEN_Pos) /*!< EPWM_T::FDCTL1: FDMSKEN Mask */ #define EPWM_FDCTL1_DGSMPCYC_Pos (16) /*!< EPWM_T::FDCTL1: DGSMPCYC Position */ #define EPWM_FDCTL1_DGSMPCYC_Msk (0x7ul << EPWM_FDCTL1_DGSMPCYC_Pos) /*!< EPWM_T::FDCTL1: DGSMPCYC Mask */ #define EPWM_FDCTL1_FDCKSEL_Pos (28) /*!< EPWM_T::FDCTL1: FDCKSEL Position */ #define EPWM_FDCTL1_FDCKSEL_Msk (0x3ul << EPWM_FDCTL1_FDCKSEL_Pos) /*!< EPWM_T::FDCTL1: FDCKSEL Mask */ #define EPWM_FDCTL1_FDDGEN_Pos (31) /*!< EPWM_T::FDCTL1: FDDGEN Position */ #define EPWM_FDCTL1_FDDGEN_Msk (0x1ul << EPWM_FDCTL1_FDDGEN_Pos) /*!< EPWM_T::FDCTL1: FDDGEN Mask */ #define EPWM_FDCTL2_TRMSKCNT_Pos (0) /*!< EPWM_T::FDCTL2: TRMSKCNT Position */ #define EPWM_FDCTL2_TRMSKCNT_Msk (0x7ful << EPWM_FDCTL2_TRMSKCNT_Pos) /*!< EPWM_T::FDCTL2: TRMSKCNT Mask */ #define EPWM_FDCTL2_FDMSKEN_Pos (15) /*!< EPWM_T::FDCTL2: FDMSKEN Position */ #define EPWM_FDCTL2_FDMSKEN_Msk (0x1ul << EPWM_FDCTL2_FDMSKEN_Pos) /*!< EPWM_T::FDCTL2: FDMSKEN Mask */ #define EPWM_FDCTL2_DGSMPCYC_Pos (16) /*!< EPWM_T::FDCTL2: DGSMPCYC Position */ #define EPWM_FDCTL2_DGSMPCYC_Msk (0x7ul << EPWM_FDCTL2_DGSMPCYC_Pos) /*!< EPWM_T::FDCTL2: DGSMPCYC Mask */ #define EPWM_FDCTL2_FDCKSEL_Pos (28) /*!< EPWM_T::FDCTL2: FDCKSEL Position */ #define EPWM_FDCTL2_FDCKSEL_Msk (0x3ul << EPWM_FDCTL2_FDCKSEL_Pos) /*!< EPWM_T::FDCTL2: FDCKSEL Mask */ #define EPWM_FDCTL2_FDDGEN_Pos (31) /*!< EPWM_T::FDCTL2: FDDGEN Position */ #define EPWM_FDCTL2_FDDGEN_Msk (0x1ul << EPWM_FDCTL2_FDDGEN_Pos) /*!< EPWM_T::FDCTL2: FDDGEN Mask */ #define EPWM_FDCTL3_TRMSKCNT_Pos (0) /*!< EPWM_T::FDCTL3: TRMSKCNT Position */ #define EPWM_FDCTL3_TRMSKCNT_Msk (0x7ful << EPWM_FDCTL3_TRMSKCNT_Pos) /*!< EPWM_T::FDCTL3: TRMSKCNT Mask */ #define EPWM_FDCTL3_FDMSKEN_Pos (15) /*!< EPWM_T::FDCTL3: FDMSKEN Position */ #define EPWM_FDCTL3_FDMSKEN_Msk (0x1ul << EPWM_FDCTL3_FDMSKEN_Pos) /*!< EPWM_T::FDCTL3: FDMSKEN Mask */ #define EPWM_FDCTL3_DGSMPCYC_Pos (16) /*!< EPWM_T::FDCTL3: DGSMPCYC Position */ #define EPWM_FDCTL3_DGSMPCYC_Msk (0x7ul << EPWM_FDCTL3_DGSMPCYC_Pos) /*!< EPWM_T::FDCTL3: DGSMPCYC Mask */ #define EPWM_FDCTL3_FDCKSEL_Pos (28) /*!< EPWM_T::FDCTL3: FDCKSEL Position */ #define EPWM_FDCTL3_FDCKSEL_Msk (0x3ul << EPWM_FDCTL3_FDCKSEL_Pos) /*!< EPWM_T::FDCTL3: FDCKSEL Mask */ #define EPWM_FDCTL3_FDDGEN_Pos (31) /*!< EPWM_T::FDCTL3: FDDGEN Position */ #define EPWM_FDCTL3_FDDGEN_Msk (0x1ul << EPWM_FDCTL3_FDDGEN_Pos) /*!< EPWM_T::FDCTL3: FDDGEN Mask */ #define EPWM_FDCTL4_TRMSKCNT_Pos (0) /*!< EPWM_T::FDCTL4: TRMSKCNT Position */ #define EPWM_FDCTL4_TRMSKCNT_Msk (0x7ful << EPWM_FDCTL4_TRMSKCNT_Pos) /*!< EPWM_T::FDCTL4: TRMSKCNT Mask */ #define EPWM_FDCTL4_FDMSKEN_Pos (15) /*!< EPWM_T::FDCTL4: FDMSKEN Position */ #define EPWM_FDCTL4_FDMSKEN_Msk (0x1ul << EPWM_FDCTL4_FDMSKEN_Pos) /*!< EPWM_T::FDCTL4: FDMSKEN Mask */ #define EPWM_FDCTL4_DGSMPCYC_Pos (16) /*!< EPWM_T::FDCTL4: DGSMPCYC Position */ #define EPWM_FDCTL4_DGSMPCYC_Msk (0x7ul << EPWM_FDCTL4_DGSMPCYC_Pos) /*!< EPWM_T::FDCTL4: DGSMPCYC Mask */ #define EPWM_FDCTL4_FDCKSEL_Pos (28) /*!< EPWM_T::FDCTL4: FDCKSEL Position */ #define EPWM_FDCTL4_FDCKSEL_Msk (0x3ul << EPWM_FDCTL4_FDCKSEL_Pos) /*!< EPWM_T::FDCTL4: FDCKSEL Mask */ #define EPWM_FDCTL4_FDDGEN_Pos (31) /*!< EPWM_T::FDCTL4: FDDGEN Position */ #define EPWM_FDCTL4_FDDGEN_Msk (0x1ul << EPWM_FDCTL4_FDDGEN_Pos) /*!< EPWM_T::FDCTL4: FDDGEN Mask */ #define EPWM_FDCTL5_TRMSKCNT_Pos (0) /*!< EPWM_T::FDCTL5: TRMSKCNT Position */ #define EPWM_FDCTL5_TRMSKCNT_Msk (0x7ful << EPWM_FDCTL5_TRMSKCNT_Pos) /*!< EPWM_T::FDCTL5: TRMSKCNT Mask */ #define EPWM_FDCTL5_FDMSKEN_Pos (15) /*!< EPWM_T::FDCTL5: FDMSKEN Position */ #define EPWM_FDCTL5_FDMSKEN_Msk (0x1ul << EPWM_FDCTL5_FDMSKEN_Pos) /*!< EPWM_T::FDCTL5: FDMSKEN Mask */ #define EPWM_FDCTL5_DGSMPCYC_Pos (16) /*!< EPWM_T::FDCTL5: DGSMPCYC Position */ #define EPWM_FDCTL5_DGSMPCYC_Msk (0x7ul << EPWM_FDCTL5_DGSMPCYC_Pos) /*!< EPWM_T::FDCTL5: DGSMPCYC Mask */ #define EPWM_FDCTL5_FDCKSEL_Pos (28) /*!< EPWM_T::FDCTL5: FDCKSEL Position */ #define EPWM_FDCTL5_FDCKSEL_Msk (0x3ul << EPWM_FDCTL5_FDCKSEL_Pos) /*!< EPWM_T::FDCTL5: FDCKSEL Mask */ #define EPWM_FDCTL5_FDDGEN_Pos (31) /*!< EPWM_T::FDCTL5: FDDGEN Position */ #define EPWM_FDCTL5_FDDGEN_Msk (0x1ul << EPWM_FDCTL5_FDDGEN_Pos) /*!< EPWM_T::FDCTL5: FDDGEN Mask */ #define EPWM_FDIEN_FDIEN0_Pos (0) /*!< EPWM_T::FDIEN: FDIEN0 Position */ #define EPWM_FDIEN_FDIEN0_Msk (0x1ul << EPWM_FDIEN_FDIEN0_Pos) /*!< EPWM_T::FDIEN: FDIEN0 Mask */ #define EPWM_FDIEN_FDIEN1_Pos (1) /*!< EPWM_T::FDIEN: FDIEN1 Position */ #define EPWM_FDIEN_FDIEN1_Msk (0x1ul << EPWM_FDIEN_FDIEN1_Pos) /*!< EPWM_T::FDIEN: FDIEN1 Mask */ #define EPWM_FDIEN_FDIEN2_Pos (2) /*!< EPWM_T::FDIEN: FDIEN2 Position */ #define EPWM_FDIEN_FDIEN2_Msk (0x1ul << EPWM_FDIEN_FDIEN2_Pos) /*!< EPWM_T::FDIEN: FDIEN2 Mask */ #define EPWM_FDIEN_FDIEN3_Pos (3) /*!< EPWM_T::FDIEN: FDIEN3 Position */ #define EPWM_FDIEN_FDIEN3_Msk (0x1ul << EPWM_FDIEN_FDIEN3_Pos) /*!< EPWM_T::FDIEN: FDIEN3 Mask */ #define EPWM_FDIEN_FDIEN4_Pos (4) /*!< EPWM_T::FDIEN: FDIEN4 Position */ #define EPWM_FDIEN_FDIEN4_Msk (0x1ul << EPWM_FDIEN_FDIEN4_Pos) /*!< EPWM_T::FDIEN: FDIEN4 Mask */ #define EPWM_FDIEN_FDIEN5_Pos (5) /*!< EPWM_T::FDIEN: FDIEN5 Position */ #define EPWM_FDIEN_FDIEN5_Msk (0x1ul << EPWM_FDIEN_FDIEN5_Pos) /*!< EPWM_T::FDIEN: FDIEN5 Mask */ #define EPWM_FDSTS_FDIF0_Pos (0) /*!< EPWM_T::FDSTS: FDIF0 Position */ #define EPWM_FDSTS_FDIF0_Msk (0x1ul << EPWM_FDSTS_FDIF0_Pos) /*!< EPWM_T::FDSTS: FDIF0 Mask */ #define EPWM_FDSTS_FDIF1_Pos (1) /*!< EPWM_T::FDSTS: FDIF1 Position */ #define EPWM_FDSTS_FDIF1_Msk (0x1ul << EPWM_FDSTS_FDIF1_Pos) /*!< EPWM_T::FDSTS: FDIF1 Mask */ #define EPWM_FDSTS_FDIF2_Pos (2) /*!< EPWM_T::FDSTS: FDIF2 Position */ #define EPWM_FDSTS_FDIF2_Msk (0x1ul << EPWM_FDSTS_FDIF2_Pos) /*!< EPWM_T::FDSTS: FDIF2 Mask */ #define EPWM_FDSTS_FDIF3_Pos (3) /*!< EPWM_T::FDSTS: FDIF3 Position */ #define EPWM_FDSTS_FDIF3_Msk (0x1ul << EPWM_FDSTS_FDIF3_Pos) /*!< EPWM_T::FDSTS: FDIF3 Mask */ #define EPWM_FDSTS_FDIF4_Pos (4) /*!< EPWM_T::FDSTS: FDIF4 Position */ #define EPWM_FDSTS_FDIF4_Msk (0x1ul << EPWM_FDSTS_FDIF4_Pos) /*!< EPWM_T::FDSTS: FDIF4 Mask */ #define EPWM_FDSTS_FDIF5_Pos (5) /*!< EPWM_T::FDSTS: FDIF5 Position */ #define EPWM_FDSTS_FDIF5_Msk (0x1ul << EPWM_FDSTS_FDIF5_Pos) /*!< EPWM_T::FDSTS: FDIF5 Mask */ #define EPWM_EADCPSCCTL_PSCEN0_Pos (0) /*!< EPWM_T::EADCPSCCTL: PSCEN0 Position */ #define EPWM_EADCPSCCTL_PSCEN0_Msk (0x1ul << EPWM_EADCPSCCTL_PSCEN0_Pos) /*!< EPWM_T::EADCPSCCTL: PSCEN0 Mask */ #define EPWM_EADCPSCCTL_PSCEN1_Pos (1) /*!< EPWM_T::EADCPSCCTL: PSCEN1 Position */ #define EPWM_EADCPSCCTL_PSCEN1_Msk (0x1ul << EPWM_EADCPSCCTL_PSCEN1_Pos) /*!< EPWM_T::EADCPSCCTL: PSCEN1 Mask */ #define EPWM_EADCPSCCTL_PSCEN2_Pos (2) /*!< EPWM_T::EADCPSCCTL: PSCEN2 Position */ #define EPWM_EADCPSCCTL_PSCEN2_Msk (0x1ul << EPWM_EADCPSCCTL_PSCEN2_Pos) /*!< EPWM_T::EADCPSCCTL: PSCEN2 Mask */ #define EPWM_EADCPSCCTL_PSCEN3_Pos (3) /*!< EPWM_T::EADCPSCCTL: PSCEN3 Position */ #define EPWM_EADCPSCCTL_PSCEN3_Msk (0x1ul << EPWM_EADCPSCCTL_PSCEN3_Pos) /*!< EPWM_T::EADCPSCCTL: PSCEN3 Mask */ #define EPWM_EADCPSCCTL_PSCEN4_Pos (4) /*!< EPWM_T::EADCPSCCTL: PSCEN4 Position */ #define EPWM_EADCPSCCTL_PSCEN4_Msk (0x1ul << EPWM_EADCPSCCTL_PSCEN4_Pos) /*!< EPWM_T::EADCPSCCTL: PSCEN4 Mask */ #define EPWM_EADCPSCCTL_PSCEN5_Pos (5) /*!< EPWM_T::EADCPSCCTL: PSCEN5 Position */ #define EPWM_EADCPSCCTL_PSCEN5_Msk (0x1ul << EPWM_EADCPSCCTL_PSCEN5_Pos) /*!< EPWM_T::EADCPSCCTL: PSCEN5 Mask */ #define EPWM_EADCPSC0_EADCPSC0_Pos (0) /*!< EPWM_T::EADCPSC0: EADCPSC0 Position */ #define EPWM_EADCPSC0_EADCPSC0_Msk (0xful << EPWM_EADCPSC0_EADCPSC0_Pos) /*!< EPWM_T::EADCPSC0: EADCPSC0 Mask */ #define EPWM_EADCPSC0_EADCPSC1_Pos (8) /*!< EPWM_T::EADCPSC0: EADCPSC1 Position */ #define EPWM_EADCPSC0_EADCPSC1_Msk (0xful << EPWM_EADCPSC0_EADCPSC1_Pos) /*!< EPWM_T::EADCPSC0: EADCPSC1 Mask */ #define EPWM_EADCPSC0_EADCPSC2_Pos (16) /*!< EPWM_T::EADCPSC0: EADCPSC2 Position */ #define EPWM_EADCPSC0_EADCPSC2_Msk (0xful << EPWM_EADCPSC0_EADCPSC2_Pos) /*!< EPWM_T::EADCPSC0: EADCPSC2 Mask */ #define EPWM_EADCPSC0_EADCPSC3_Pos (24) /*!< EPWM_T::EADCPSC0: EADCPSC3 Position */ #define EPWM_EADCPSC0_EADCPSC3_Msk (0xful << EPWM_EADCPSC0_EADCPSC3_Pos) /*!< EPWM_T::EADCPSC0: EADCPSC3 Mask */ #define EPWM_EADCPSC1_EADCPSC4_Pos (0) /*!< EPWM_T::EADCPSC1: EADCPSC4 Position */ #define EPWM_EADCPSC1_EADCPSC4_Msk (0xful << EPWM_EADCPSC1_EADCPSC4_Pos) /*!< EPWM_T::EADCPSC1: EADCPSC4 Mask */ #define EPWM_EADCPSC1_EADCPSC5_Pos (8) /*!< EPWM_T::EADCPSC1: EADCPSC5 Position */ #define EPWM_EADCPSC1_EADCPSC5_Msk (0xful << EPWM_EADCPSC1_EADCPSC5_Pos) /*!< EPWM_T::EADCPSC1: EADCPSC5 Mask */ #define EPWM_EADCPSCNT0_PSCNT0_Pos (0) /*!< EPWM_T::EADCPSCNT0: PSCNT0 Position */ #define EPWM_EADCPSCNT0_PSCNT0_Msk (0xful << EPWM_EADCPSCNT0_PSCNT0_Pos) /*!< EPWM_T::EADCPSCNT0: PSCNT0 Mask */ #define EPWM_EADCPSCNT0_PSCNT1_Pos (8) /*!< EPWM_T::EADCPSCNT0: PSCNT1 Position */ #define EPWM_EADCPSCNT0_PSCNT1_Msk (0xful << EPWM_EADCPSCNT0_PSCNT1_Pos) /*!< EPWM_T::EADCPSCNT0: PSCNT1 Mask */ #define EPWM_EADCPSCNT0_PSCNT2_Pos (16) /*!< EPWM_T::EADCPSCNT0: PSCNT2 Position */ #define EPWM_EADCPSCNT0_PSCNT2_Msk (0xful << EPWM_EADCPSCNT0_PSCNT2_Pos) /*!< EPWM_T::EADCPSCNT0: PSCNT2 Mask */ #define EPWM_EADCPSCNT0_PSCNT3_Pos (24) /*!< EPWM_T::EADCPSCNT0: PSCNT3 Position */ #define EPWM_EADCPSCNT0_PSCNT3_Msk (0xful << EPWM_EADCPSCNT0_PSCNT3_Pos) /*!< EPWM_T::EADCPSCNT0: PSCNT3 Mask */ #define EPWM_EADCPSCNT1_PSCNT4_Pos (0) /*!< EPWM_T::EADCPSCNT1: PSCNT4 Position */ #define EPWM_EADCPSCNT1_PSCNT4_Msk (0xful << EPWM_EADCPSCNT1_PSCNT4_Pos) /*!< EPWM_T::EADCPSCNT1: PSCNT4 Mask */ #define EPWM_EADCPSCNT1_PSCNT5_Pos (8) /*!< EPWM_T::EADCPSCNT1: PSCNT5 Position */ #define EPWM_EADCPSCNT1_PSCNT5_Msk (0xful << EPWM_EADCPSCNT1_PSCNT5_Pos) /*!< EPWM_T::EADCPSCNT1: PSCNT5 Mask */ #define EPWM_CAPINEN_CAPINEN0_Pos (0) /*!< EPWM_T::CAPINEN: CAPINEN0 Position */ #define EPWM_CAPINEN_CAPINEN0_Msk (0x1ul << EPWM_CAPINEN_CAPINEN0_Pos) /*!< EPWM_T::CAPINEN: CAPINEN0 Mask */ #define EPWM_CAPINEN_CAPINEN1_Pos (1) /*!< EPWM_T::CAPINEN: CAPINEN1 Position */ #define EPWM_CAPINEN_CAPINEN1_Msk (0x1ul << EPWM_CAPINEN_CAPINEN1_Pos) /*!< EPWM_T::CAPINEN: CAPINEN1 Mask */ #define EPWM_CAPINEN_CAPINEN2_Pos (2) /*!< EPWM_T::CAPINEN: CAPINEN2 Position */ #define EPWM_CAPINEN_CAPINEN2_Msk (0x1ul << EPWM_CAPINEN_CAPINEN2_Pos) /*!< EPWM_T::CAPINEN: CAPINEN2 Mask */ #define EPWM_CAPINEN_CAPINEN3_Pos (3) /*!< EPWM_T::CAPINEN: CAPINEN3 Position */ #define EPWM_CAPINEN_CAPINEN3_Msk (0x1ul << EPWM_CAPINEN_CAPINEN3_Pos) /*!< EPWM_T::CAPINEN: CAPINEN3 Mask */ #define EPWM_CAPINEN_CAPINEN4_Pos (4) /*!< EPWM_T::CAPINEN: CAPINEN4 Position */ #define EPWM_CAPINEN_CAPINEN4_Msk (0x1ul << EPWM_CAPINEN_CAPINEN4_Pos) /*!< EPWM_T::CAPINEN: CAPINEN4 Mask */ #define EPWM_CAPINEN_CAPINEN5_Pos (5) /*!< EPWM_T::CAPINEN: CAPINEN5 Position */ #define EPWM_CAPINEN_CAPINEN5_Msk (0x1ul << EPWM_CAPINEN_CAPINEN5_Pos) /*!< EPWM_T::CAPINEN: CAPINEN5 Mask */ #define EPWM_CAPCTL_CAPEN0_Pos (0) /*!< EPWM_T::CAPCTL: CAPEN0 Position */ #define EPWM_CAPCTL_CAPEN0_Msk (0x1ul << EPWM_CAPCTL_CAPEN0_Pos) /*!< EPWM_T::CAPCTL: CAPEN0 Mask */ #define EPWM_CAPCTL_CAPEN1_Pos (1) /*!< EPWM_T::CAPCTL: CAPEN1 Position */ #define EPWM_CAPCTL_CAPEN1_Msk (0x1ul << EPWM_CAPCTL_CAPEN1_Pos) /*!< EPWM_T::CAPCTL: CAPEN1 Mask */ #define EPWM_CAPCTL_CAPEN2_Pos (2) /*!< EPWM_T::CAPCTL: CAPEN2 Position */ #define EPWM_CAPCTL_CAPEN2_Msk (0x1ul << EPWM_CAPCTL_CAPEN2_Pos) /*!< EPWM_T::CAPCTL: CAPEN2 Mask */ #define EPWM_CAPCTL_CAPEN3_Pos (3) /*!< EPWM_T::CAPCTL: CAPEN3 Position */ #define EPWM_CAPCTL_CAPEN3_Msk (0x1ul << EPWM_CAPCTL_CAPEN3_Pos) /*!< EPWM_T::CAPCTL: CAPEN3 Mask */ #define EPWM_CAPCTL_CAPEN4_Pos (4) /*!< EPWM_T::CAPCTL: CAPEN4 Position */ #define EPWM_CAPCTL_CAPEN4_Msk (0x1ul << EPWM_CAPCTL_CAPEN4_Pos) /*!< EPWM_T::CAPCTL: CAPEN4 Mask */ #define EPWM_CAPCTL_CAPEN5_Pos (5) /*!< EPWM_T::CAPCTL: CAPEN5 Position */ #define EPWM_CAPCTL_CAPEN5_Msk (0x1ul << EPWM_CAPCTL_CAPEN5_Pos) /*!< EPWM_T::CAPCTL: CAPEN5 Mask */ #define EPWM_CAPCTL_CAPINV0_Pos (8) /*!< EPWM_T::CAPCTL: CAPINV0 Position */ #define EPWM_CAPCTL_CAPINV0_Msk (0x1ul << EPWM_CAPCTL_CAPINV0_Pos) /*!< EPWM_T::CAPCTL: CAPINV0 Mask */ #define EPWM_CAPCTL_CAPINV1_Pos (9) /*!< EPWM_T::CAPCTL: CAPINV1 Position */ #define EPWM_CAPCTL_CAPINV1_Msk (0x1ul << EPWM_CAPCTL_CAPINV1_Pos) /*!< EPWM_T::CAPCTL: CAPINV1 Mask */ #define EPWM_CAPCTL_CAPINV2_Pos (10) /*!< EPWM_T::CAPCTL: CAPINV2 Position */ #define EPWM_CAPCTL_CAPINV2_Msk (0x1ul << EPWM_CAPCTL_CAPINV2_Pos) /*!< EPWM_T::CAPCTL: CAPINV2 Mask */ #define EPWM_CAPCTL_CAPINV3_Pos (11) /*!< EPWM_T::CAPCTL: CAPINV3 Position */ #define EPWM_CAPCTL_CAPINV3_Msk (0x1ul << EPWM_CAPCTL_CAPINV3_Pos) /*!< EPWM_T::CAPCTL: CAPINV3 Mask */ #define EPWM_CAPCTL_CAPINV4_Pos (12) /*!< EPWM_T::CAPCTL: CAPINV4 Position */ #define EPWM_CAPCTL_CAPINV4_Msk (0x1ul << EPWM_CAPCTL_CAPINV4_Pos) /*!< EPWM_T::CAPCTL: CAPINV4 Mask */ #define EPWM_CAPCTL_CAPINV5_Pos (13) /*!< EPWM_T::CAPCTL: CAPINV5 Position */ #define EPWM_CAPCTL_CAPINV5_Msk (0x1ul << EPWM_CAPCTL_CAPINV5_Pos) /*!< EPWM_T::CAPCTL: CAPINV5 Mask */ #define EPWM_CAPCTL_RCRLDEN0_Pos (16) /*!< EPWM_T::CAPCTL: RCRLDEN0 Position */ #define EPWM_CAPCTL_RCRLDEN0_Msk (0x1ul << EPWM_CAPCTL_RCRLDEN0_Pos) /*!< EPWM_T::CAPCTL: RCRLDEN0 Mask */ #define EPWM_CAPCTL_RCRLDEN1_Pos (17) /*!< EPWM_T::CAPCTL: RCRLDEN1 Position */ #define EPWM_CAPCTL_RCRLDEN1_Msk (0x1ul << EPWM_CAPCTL_RCRLDEN1_Pos) /*!< EPWM_T::CAPCTL: RCRLDEN1 Mask */ #define EPWM_CAPCTL_RCRLDEN2_Pos (18) /*!< EPWM_T::CAPCTL: RCRLDEN2 Position */ #define EPWM_CAPCTL_RCRLDEN2_Msk (0x1ul << EPWM_CAPCTL_RCRLDEN2_Pos) /*!< EPWM_T::CAPCTL: RCRLDEN2 Mask */ #define EPWM_CAPCTL_RCRLDEN3_Pos (19) /*!< EPWM_T::CAPCTL: RCRLDEN3 Position */ #define EPWM_CAPCTL_RCRLDEN3_Msk (0x1ul << EPWM_CAPCTL_RCRLDEN3_Pos) /*!< EPWM_T::CAPCTL: RCRLDEN3 Mask */ #define EPWM_CAPCTL_RCRLDEN4_Pos (20) /*!< EPWM_T::CAPCTL: RCRLDEN4 Position */ #define EPWM_CAPCTL_RCRLDEN4_Msk (0x1ul << EPWM_CAPCTL_RCRLDEN4_Pos) /*!< EPWM_T::CAPCTL: RCRLDEN4 Mask */ #define EPWM_CAPCTL_RCRLDEN5_Pos (21) /*!< EPWM_T::CAPCTL: RCRLDEN5 Position */ #define EPWM_CAPCTL_RCRLDEN5_Msk (0x1ul << EPWM_CAPCTL_RCRLDEN5_Pos) /*!< EPWM_T::CAPCTL: RCRLDEN5 Mask */ #define EPWM_CAPCTL_FCRLDEN0_Pos (24) /*!< EPWM_T::CAPCTL: FCRLDEN0 Position */ #define EPWM_CAPCTL_FCRLDEN0_Msk (0x1ul << EPWM_CAPCTL_FCRLDEN0_Pos) /*!< EPWM_T::CAPCTL: FCRLDEN0 Mask */ #define EPWM_CAPCTL_FCRLDEN1_Pos (25) /*!< EPWM_T::CAPCTL: FCRLDEN1 Position */ #define EPWM_CAPCTL_FCRLDEN1_Msk (0x1ul << EPWM_CAPCTL_FCRLDEN1_Pos) /*!< EPWM_T::CAPCTL: FCRLDEN1 Mask */ #define EPWM_CAPCTL_FCRLDEN2_Pos (26) /*!< EPWM_T::CAPCTL: FCRLDEN2 Position */ #define EPWM_CAPCTL_FCRLDEN2_Msk (0x1ul << EPWM_CAPCTL_FCRLDEN2_Pos) /*!< EPWM_T::CAPCTL: FCRLDEN2 Mask */ #define EPWM_CAPCTL_FCRLDEN3_Pos (27) /*!< EPWM_T::CAPCTL: FCRLDEN3 Position */ #define EPWM_CAPCTL_FCRLDEN3_Msk (0x1ul << EPWM_CAPCTL_FCRLDEN3_Pos) /*!< EPWM_T::CAPCTL: FCRLDEN3 Mask */ #define EPWM_CAPCTL_FCRLDEN4_Pos (28) /*!< EPWM_T::CAPCTL: FCRLDEN4 Position */ #define EPWM_CAPCTL_FCRLDEN4_Msk (0x1ul << EPWM_CAPCTL_FCRLDEN4_Pos) /*!< EPWM_T::CAPCTL: FCRLDEN4 Mask */ #define EPWM_CAPCTL_FCRLDEN5_Pos (29) /*!< EPWM_T::CAPCTL: FCRLDEN5 Position */ #define EPWM_CAPCTL_FCRLDEN5_Msk (0x1ul << EPWM_CAPCTL_FCRLDEN5_Pos) /*!< EPWM_T::CAPCTL: FCRLDEN5 Mask */ #define EPWM_CAPSTS_CRLIFOV0_Pos (0) /*!< EPWM_T::CAPSTS: CRLIFOV0 Position */ #define EPWM_CAPSTS_CRLIFOV0_Msk (0x1ul << EPWM_CAPSTS_CRLIFOV0_Pos) /*!< EPWM_T::CAPSTS: CRLIFOV0 Mask */ #define EPWM_CAPSTS_CRLIFOV1_Pos (1) /*!< EPWM_T::CAPSTS: CRLIFOV1 Position */ #define EPWM_CAPSTS_CRLIFOV1_Msk (0x1ul << EPWM_CAPSTS_CRLIFOV1_Pos) /*!< EPWM_T::CAPSTS: CRLIFOV1 Mask */ #define EPWM_CAPSTS_CRLIFOV2_Pos (2) /*!< EPWM_T::CAPSTS: CRLIFOV2 Position */ #define EPWM_CAPSTS_CRLIFOV2_Msk (0x1ul << EPWM_CAPSTS_CRLIFOV2_Pos) /*!< EPWM_T::CAPSTS: CRLIFOV2 Mask */ #define EPWM_CAPSTS_CRLIFOV3_Pos (3) /*!< EPWM_T::CAPSTS: CRLIFOV3 Position */ #define EPWM_CAPSTS_CRLIFOV3_Msk (0x1ul << EPWM_CAPSTS_CRLIFOV3_Pos) /*!< EPWM_T::CAPSTS: CRLIFOV3 Mask */ #define EPWM_CAPSTS_CRLIFOV4_Pos (4) /*!< EPWM_T::CAPSTS: CRLIFOV4 Position */ #define EPWM_CAPSTS_CRLIFOV4_Msk (0x1ul << EPWM_CAPSTS_CRLIFOV4_Pos) /*!< EPWM_T::CAPSTS: CRLIFOV4 Mask */ #define EPWM_CAPSTS_CRLIFOV5_Pos (5) /*!< EPWM_T::CAPSTS: CRLIFOV5 Position */ #define EPWM_CAPSTS_CRLIFOV5_Msk (0x1ul << EPWM_CAPSTS_CRLIFOV5_Pos) /*!< EPWM_T::CAPSTS: CRLIFOV5 Mask */ #define EPWM_CAPSTS_CFLIFOV0_Pos (8) /*!< EPWM_T::CAPSTS: CFLIFOV0 Position */ #define EPWM_CAPSTS_CFLIFOV0_Msk (0x1ul << EPWM_CAPSTS_CFLIFOV0_Pos) /*!< EPWM_T::CAPSTS: CFLIFOV0 Mask */ #define EPWM_CAPSTS_CFLIFOV1_Pos (9) /*!< EPWM_T::CAPSTS: CFLIFOV1 Position */ #define EPWM_CAPSTS_CFLIFOV1_Msk (0x1ul << EPWM_CAPSTS_CFLIFOV1_Pos) /*!< EPWM_T::CAPSTS: CFLIFOV1 Mask */ #define EPWM_CAPSTS_CFLIFOV2_Pos (10) /*!< EPWM_T::CAPSTS: CFLIFOV2 Position */ #define EPWM_CAPSTS_CFLIFOV2_Msk (0x1ul << EPWM_CAPSTS_CFLIFOV2_Pos) /*!< EPWM_T::CAPSTS: CFLIFOV2 Mask */ #define EPWM_CAPSTS_CFLIFOV3_Pos (11) /*!< EPWM_T::CAPSTS: CFLIFOV3 Position */ #define EPWM_CAPSTS_CFLIFOV3_Msk (0x1ul << EPWM_CAPSTS_CFLIFOV3_Pos) /*!< EPWM_T::CAPSTS: CFLIFOV3 Mask */ #define EPWM_CAPSTS_CFLIFOV4_Pos (12) /*!< EPWM_T::CAPSTS: CFLIFOV4 Position */ #define EPWM_CAPSTS_CFLIFOV4_Msk (0x1ul << EPWM_CAPSTS_CFLIFOV4_Pos) /*!< EPWM_T::CAPSTS: CFLIFOV4 Mask */ #define EPWM_CAPSTS_CFLIFOV5_Pos (13) /*!< EPWM_T::CAPSTS: CFLIFOV5 Position */ #define EPWM_CAPSTS_CFLIFOV5_Msk (0x1ul << EPWM_CAPSTS_CFLIFOV5_Pos) /*!< EPWM_T::CAPSTS: CFLIFOV5 Mask */ #define EPWM_RCAPDAT0_RCAPDAT_Pos (0) /*!< EPWM_T::RCAPDAT0: RCAPDAT Position */ #define EPWM_RCAPDAT0_RCAPDAT_Msk (0xfffful << EPWM_RCAPDAT0_RCAPDAT_Pos) /*!< EPWM_T::RCAPDAT0: RCAPDAT Mask */ #define EPWM_FCAPDAT0_FCAPDAT_Pos (0) /*!< EPWM_T::FCAPDAT0: FCAPDAT Position */ #define EPWM_FCAPDAT0_FCAPDAT_Msk (0xfffful << EPWM_FCAPDAT0_FCAPDAT_Pos) /*!< EPWM_T::FCAPDAT0: FCAPDAT Mask */ #define EPWM_RCAPDAT1_RCAPDAT_Pos (0) /*!< EPWM_T::RCAPDAT1: RCAPDAT Position */ #define EPWM_RCAPDAT1_RCAPDAT_Msk (0xfffful << EPWM_RCAPDAT1_RCAPDAT_Pos) /*!< EPWM_T::RCAPDAT1: RCAPDAT Mask */ #define EPWM_FCAPDAT1_FCAPDAT_Pos (0) /*!< EPWM_T::FCAPDAT1: FCAPDAT Position */ #define EPWM_FCAPDAT1_FCAPDAT_Msk (0xfffful << EPWM_FCAPDAT1_FCAPDAT_Pos) /*!< EPWM_T::FCAPDAT1: FCAPDAT Mask */ #define EPWM_RCAPDAT2_RCAPDAT_Pos (0) /*!< EPWM_T::RCAPDAT2: RCAPDAT Position */ #define EPWM_RCAPDAT2_RCAPDAT_Msk (0xfffful << EPWM_RCAPDAT2_RCAPDAT_Pos) /*!< EPWM_T::RCAPDAT2: RCAPDAT Mask */ #define EPWM_FCAPDAT2_FCAPDAT_Pos (0) /*!< EPWM_T::FCAPDAT2: FCAPDAT Position */ #define EPWM_FCAPDAT2_FCAPDAT_Msk (0xfffful << EPWM_FCAPDAT2_FCAPDAT_Pos) /*!< EPWM_T::FCAPDAT2: FCAPDAT Mask */ #define EPWM_RCAPDAT3_RCAPDAT_Pos (0) /*!< EPWM_T::RCAPDAT3: RCAPDAT Position */ #define EPWM_RCAPDAT3_RCAPDAT_Msk (0xfffful << EPWM_RCAPDAT3_RCAPDAT_Pos) /*!< EPWM_T::RCAPDAT3: RCAPDAT Mask */ #define EPWM_FCAPDAT3_FCAPDAT_Pos (0) /*!< EPWM_T::FCAPDAT3: FCAPDAT Position */ #define EPWM_FCAPDAT3_FCAPDAT_Msk (0xfffful << EPWM_FCAPDAT3_FCAPDAT_Pos) /*!< EPWM_T::FCAPDAT3: FCAPDAT Mask */ #define EPWM_RCAPDAT4_RCAPDAT_Pos (0) /*!< EPWM_T::RCAPDAT4: RCAPDAT Position */ #define EPWM_RCAPDAT4_RCAPDAT_Msk (0xfffful << EPWM_RCAPDAT4_RCAPDAT_Pos) /*!< EPWM_T::RCAPDAT4: RCAPDAT Mask */ #define EPWM_FCAPDAT4_FCAPDAT_Pos (0) /*!< EPWM_T::FCAPDAT4: FCAPDAT Position */ #define EPWM_FCAPDAT4_FCAPDAT_Msk (0xfffful << EPWM_FCAPDAT4_FCAPDAT_Pos) /*!< EPWM_T::FCAPDAT4: FCAPDAT Mask */ #define EPWM_RCAPDAT5_RCAPDAT_Pos (0) /*!< EPWM_T::RCAPDAT5: RCAPDAT Position */ #define EPWM_RCAPDAT5_RCAPDAT_Msk (0xfffful << EPWM_RCAPDAT5_RCAPDAT_Pos) /*!< EPWM_T::RCAPDAT5: RCAPDAT Mask */ #define EPWM_FCAPDAT5_FCAPDAT_Pos (0) /*!< EPWM_T::FCAPDAT5: FCAPDAT Position */ #define EPWM_FCAPDAT5_FCAPDAT_Msk (0xfffful << EPWM_FCAPDAT5_FCAPDAT_Pos) /*!< EPWM_T::FCAPDAT5: FCAPDAT Mask */ #define EPWM_PDMACTL_CHEN0_1_Pos (0) /*!< EPWM_T::PDMACTL: CHEN0_1 Position */ #define EPWM_PDMACTL_CHEN0_1_Msk (0x1ul << EPWM_PDMACTL_CHEN0_1_Pos) /*!< EPWM_T::PDMACTL: CHEN0_1 Mask */ #define EPWM_PDMACTL_CAPMOD0_1_Pos (1) /*!< EPWM_T::PDMACTL: CAPMOD0_1 Position */ #define EPWM_PDMACTL_CAPMOD0_1_Msk (0x3ul << EPWM_PDMACTL_CAPMOD0_1_Pos) /*!< EPWM_T::PDMACTL: CAPMOD0_1 Mask */ #define EPWM_PDMACTL_CAPORD0_1_Pos (3) /*!< EPWM_T::PDMACTL: CAPORD0_1 Position */ #define EPWM_PDMACTL_CAPORD0_1_Msk (0x1ul << EPWM_PDMACTL_CAPORD0_1_Pos) /*!< EPWM_T::PDMACTL: CAPORD0_1 Mask */ #define EPWM_PDMACTL_CHSEL0_1_Pos (4) /*!< EPWM_T::PDMACTL: CHSEL0_1 Position */ #define EPWM_PDMACTL_CHSEL0_1_Msk (0x1ul << EPWM_PDMACTL_CHSEL0_1_Pos) /*!< EPWM_T::PDMACTL: CHSEL0_1 Mask */ #define EPWM_PDMACTL_CHEN2_3_Pos (8) /*!< EPWM_T::PDMACTL: CHEN2_3 Position */ #define EPWM_PDMACTL_CHEN2_3_Msk (0x1ul << EPWM_PDMACTL_CHEN2_3_Pos) /*!< EPWM_T::PDMACTL: CHEN2_3 Mask */ #define EPWM_PDMACTL_CAPMOD2_3_Pos (9) /*!< EPWM_T::PDMACTL: CAPMOD2_3 Position */ #define EPWM_PDMACTL_CAPMOD2_3_Msk (0x3ul << EPWM_PDMACTL_CAPMOD2_3_Pos) /*!< EPWM_T::PDMACTL: CAPMOD2_3 Mask */ #define EPWM_PDMACTL_CAPORD2_3_Pos (11) /*!< EPWM_T::PDMACTL: CAPORD2_3 Position */ #define EPWM_PDMACTL_CAPORD2_3_Msk (0x1ul << EPWM_PDMACTL_CAPORD2_3_Pos) /*!< EPWM_T::PDMACTL: CAPORD2_3 Mask */ #define EPWM_PDMACTL_CHSEL2_3_Pos (12) /*!< EPWM_T::PDMACTL: CHSEL2_3 Position */ #define EPWM_PDMACTL_CHSEL2_3_Msk (0x1ul << EPWM_PDMACTL_CHSEL2_3_Pos) /*!< EPWM_T::PDMACTL: CHSEL2_3 Mask */ #define EPWM_PDMACTL_CHEN4_5_Pos (16) /*!< EPWM_T::PDMACTL: CHEN4_5 Position */ #define EPWM_PDMACTL_CHEN4_5_Msk (0x1ul << EPWM_PDMACTL_CHEN4_5_Pos) /*!< EPWM_T::PDMACTL: CHEN4_5 Mask */ #define EPWM_PDMACTL_CAPMOD4_5_Pos (17) /*!< EPWM_T::PDMACTL: CAPMOD4_5 Position */ #define EPWM_PDMACTL_CAPMOD4_5_Msk (0x3ul << EPWM_PDMACTL_CAPMOD4_5_Pos) /*!< EPWM_T::PDMACTL: CAPMOD4_5 Mask */ #define EPWM_PDMACTL_CAPORD4_5_Pos (19) /*!< EPWM_T::PDMACTL: CAPORD4_5 Position */ #define EPWM_PDMACTL_CAPORD4_5_Msk (0x1ul << EPWM_PDMACTL_CAPORD4_5_Pos) /*!< EPWM_T::PDMACTL: CAPORD4_5 Mask */ #define EPWM_PDMACTL_CHSEL4_5_Pos (20) /*!< EPWM_T::PDMACTL: CHSEL4_5 Position */ #define EPWM_PDMACTL_CHSEL4_5_Msk (0x1ul << EPWM_PDMACTL_CHSEL4_5_Pos) /*!< EPWM_T::PDMACTL: CHSEL4_5 Mask */ #define EPWM_PDMACAP0_1_CAPBUF_Pos (0) /*!< EPWM_T::PDMACAP0_1: CAPBUF Position */ #define EPWM_PDMACAP0_1_CAPBUF_Msk (0xfffful << EPWM_PDMACAP0_1_CAPBUF_Pos) /*!< EPWM_T::PDMACAP0_1: CAPBUF Mask */ #define EPWM_PDMACAP2_3_CAPBUF_Pos (0) /*!< EPWM_T::PDMACAP2_3: CAPBUF Position */ #define EPWM_PDMACAP2_3_CAPBUF_Msk (0xfffful << EPWM_PDMACAP2_3_CAPBUF_Pos) /*!< EPWM_T::PDMACAP2_3: CAPBUF Mask */ #define EPWM_PDMACAP4_5_CAPBUF_Pos (0) /*!< EPWM_T::PDMACAP4_5: CAPBUF Position */ #define EPWM_PDMACAP4_5_CAPBUF_Msk (0xfffful << EPWM_PDMACAP4_5_CAPBUF_Pos) /*!< EPWM_T::PDMACAP4_5: CAPBUF Mask */ #define EPWM_CAPIEN_CAPRIEN0_Pos (0) /*!< EPWM_T::CAPIEN: CAPRIEN0 Position */ #define EPWM_CAPIEN_CAPRIEN0_Msk (0x1ul << EPWM_CAPIEN_CAPRIEN0_Pos) /*!< EPWM_T::CAPIEN: CAPRIEN0 Mask */ #define EPWM_CAPIEN_CAPRIEN1_Pos (1) /*!< EPWM_T::CAPIEN: CAPRIEN1 Position */ #define EPWM_CAPIEN_CAPRIEN1_Msk (0x1ul << EPWM_CAPIEN_CAPRIEN1_Pos) /*!< EPWM_T::CAPIEN: CAPRIEN1 Mask */ #define EPWM_CAPIEN_CAPRIEN2_Pos (2) /*!< EPWM_T::CAPIEN: CAPRIEN2 Position */ #define EPWM_CAPIEN_CAPRIEN2_Msk (0x1ul << EPWM_CAPIEN_CAPRIEN2_Pos) /*!< EPWM_T::CAPIEN: CAPRIEN2 Mask */ #define EPWM_CAPIEN_CAPRIEN3_Pos (3) /*!< EPWM_T::CAPIEN: CAPRIEN3 Position */ #define EPWM_CAPIEN_CAPRIEN3_Msk (0x1ul << EPWM_CAPIEN_CAPRIEN3_Pos) /*!< EPWM_T::CAPIEN: CAPRIEN3 Mask */ #define EPWM_CAPIEN_CAPRIEN4_Pos (4) /*!< EPWM_T::CAPIEN: CAPRIEN4 Position */ #define EPWM_CAPIEN_CAPRIEN4_Msk (0x1ul << EPWM_CAPIEN_CAPRIEN4_Pos) /*!< EPWM_T::CAPIEN: CAPRIEN4 Mask */ #define EPWM_CAPIEN_CAPRIEN5_Pos (5) /*!< EPWM_T::CAPIEN: CAPRIEN5 Position */ #define EPWM_CAPIEN_CAPRIEN5_Msk (0x1ul << EPWM_CAPIEN_CAPRIEN5_Pos) /*!< EPWM_T::CAPIEN: CAPRIEN5 Mask */ #define EPWM_CAPIEN_CAPFIEN0_Pos (8) /*!< EPWM_T::CAPIEN: CAPFIEN0 Position */ #define EPWM_CAPIEN_CAPFIEN0_Msk (0x1ul << EPWM_CAPIEN_CAPFIEN0_Pos) /*!< EPWM_T::CAPIEN: CAPFIEN0 Mask */ #define EPWM_CAPIEN_CAPFIEN1_Pos (9) /*!< EPWM_T::CAPIEN: CAPFIEN1 Position */ #define EPWM_CAPIEN_CAPFIEN1_Msk (0x1ul << EPWM_CAPIEN_CAPFIEN1_Pos) /*!< EPWM_T::CAPIEN: CAPFIEN1 Mask */ #define EPWM_CAPIEN_CAPFIEN2_Pos (10) /*!< EPWM_T::CAPIEN: CAPFIEN2 Position */ #define EPWM_CAPIEN_CAPFIEN2_Msk (0x1ul << EPWM_CAPIEN_CAPFIEN2_Pos) /*!< EPWM_T::CAPIEN: CAPFIEN2 Mask */ #define EPWM_CAPIEN_CAPFIEN3_Pos (11) /*!< EPWM_T::CAPIEN: CAPFIEN3 Position */ #define EPWM_CAPIEN_CAPFIEN3_Msk (0x1ul << EPWM_CAPIEN_CAPFIEN3_Pos) /*!< EPWM_T::CAPIEN: CAPFIEN3 Mask */ #define EPWM_CAPIEN_CAPFIEN4_Pos (12) /*!< EPWM_T::CAPIEN: CAPFIEN4 Position */ #define EPWM_CAPIEN_CAPFIEN4_Msk (0x1ul << EPWM_CAPIEN_CAPFIEN4_Pos) /*!< EPWM_T::CAPIEN: CAPFIEN4 Mask */ #define EPWM_CAPIEN_CAPFIEN5_Pos (13) /*!< EPWM_T::CAPIEN: CAPFIEN5 Position */ #define EPWM_CAPIEN_CAPFIEN5_Msk (0x1ul << EPWM_CAPIEN_CAPFIEN5_Pos) /*!< EPWM_T::CAPIEN: CAPFIEN5 Mask */ #define EPWM_CAPIF_CRLIF0_Pos (0) /*!< EPWM_T::CAPIF: CRLIF0 Position */ #define EPWM_CAPIF_CRLIF0_Msk (0x1ul << EPWM_CAPIF_CRLIF0_Pos) /*!< EPWM_T::CAPIF: CRLIF0 Mask */ #define EPWM_CAPIF_CRLIF1_Pos (1) /*!< EPWM_T::CAPIF: CRLIF1 Position */ #define EPWM_CAPIF_CRLIF1_Msk (0x1ul << EPWM_CAPIF_CRLIF1_Pos) /*!< EPWM_T::CAPIF: CRLIF1 Mask */ #define EPWM_CAPIF_CRLIF2_Pos (2) /*!< EPWM_T::CAPIF: CRLIF2 Position */ #define EPWM_CAPIF_CRLIF2_Msk (0x1ul << EPWM_CAPIF_CRLIF2_Pos) /*!< EPWM_T::CAPIF: CRLIF2 Mask */ #define EPWM_CAPIF_CRLIF3_Pos (3) /*!< EPWM_T::CAPIF: CRLIF3 Position */ #define EPWM_CAPIF_CRLIF3_Msk (0x1ul << EPWM_CAPIF_CRLIF3_Pos) /*!< EPWM_T::CAPIF: CRLIF3 Mask */ #define EPWM_CAPIF_CRLIF4_Pos (4) /*!< EPWM_T::CAPIF: CRLIF4 Position */ #define EPWM_CAPIF_CRLIF4_Msk (0x1ul << EPWM_CAPIF_CRLIF4_Pos) /*!< EPWM_T::CAPIF: CRLIF4 Mask */ #define EPWM_CAPIF_CRLIF5_Pos (5) /*!< EPWM_T::CAPIF: CRLIF5 Position */ #define EPWM_CAPIF_CRLIF5_Msk (0x1ul << EPWM_CAPIF_CRLIF5_Pos) /*!< EPWM_T::CAPIF: CRLIF5 Mask */ #define EPWM_CAPIF_CFLIF0_Pos (8) /*!< EPWM_T::CAPIF: CFLIF0 Position */ #define EPWM_CAPIF_CFLIF0_Msk (0x1ul << EPWM_CAPIF_CFLIF0_Pos) /*!< EPWM_T::CAPIF: CFLIF0 Mask */ #define EPWM_CAPIF_CFLIF1_Pos (9) /*!< EPWM_T::CAPIF: CFLIF1 Position */ #define EPWM_CAPIF_CFLIF1_Msk (0x1ul << EPWM_CAPIF_CFLIF1_Pos) /*!< EPWM_T::CAPIF: CFLIF1 Mask */ #define EPWM_CAPIF_CFLIF2_Pos (10) /*!< EPWM_T::CAPIF: CFLIF2 Position */ #define EPWM_CAPIF_CFLIF2_Msk (0x1ul << EPWM_CAPIF_CFLIF2_Pos) /*!< EPWM_T::CAPIF: CFLIF2 Mask */ #define EPWM_CAPIF_CFLIF3_Pos (11) /*!< EPWM_T::CAPIF: CFLIF3 Position */ #define EPWM_CAPIF_CFLIF3_Msk (0x1ul << EPWM_CAPIF_CFLIF3_Pos) /*!< EPWM_T::CAPIF: CFLIF3 Mask */ #define EPWM_CAPIF_CFLIF4_Pos (12) /*!< EPWM_T::CAPIF: CFLIF4 Position */ #define EPWM_CAPIF_CFLIF4_Msk (0x1ul << EPWM_CAPIF_CFLIF4_Pos) /*!< EPWM_T::CAPIF: CFLIF4 Mask */ #define EPWM_CAPIF_CFLIF5_Pos (13) /*!< EPWM_T::CAPIF: CFLIF5 Position */ #define EPWM_CAPIF_CFLIF5_Msk (0x1ul << EPWM_CAPIF_CFLIF5_Pos) /*!< EPWM_T::CAPIF: CFLIF5 Mask */ #define EPWM_PBUF0_PBUF_Pos (0) /*!< EPWM_T::PBUF0: PBUF Position */ #define EPWM_PBUF0_PBUF_Msk (0xfffful << EPWM_PBUF0_PBUF_Pos) /*!< EPWM_T::PBUF0: PBUF Mask */ #define EPWM_PBUF1_PBUF_Pos (0) /*!< EPWM_T::PBUF1: PBUF Position */ #define EPWM_PBUF1_PBUF_Msk (0xfffful << EPWM_PBUF1_PBUF_Pos) /*!< EPWM_T::PBUF1: PBUF Mask */ #define EPWM_PBUF2_PBUF_Pos (0) /*!< EPWM_T::PBUF2: PBUF Position */ #define EPWM_PBUF2_PBUF_Msk (0xfffful << EPWM_PBUF2_PBUF_Pos) /*!< EPWM_T::PBUF2: PBUF Mask */ #define EPWM_PBUF3_PBUF_Pos (0) /*!< EPWM_T::PBUF3: PBUF Position */ #define EPWM_PBUF3_PBUF_Msk (0xfffful << EPWM_PBUF3_PBUF_Pos) /*!< EPWM_T::PBUF3: PBUF Mask */ #define EPWM_PBUF4_PBUF_Pos (0) /*!< EPWM_T::PBUF4: PBUF Position */ #define EPWM_PBUF4_PBUF_Msk (0xfffful << EPWM_PBUF4_PBUF_Pos) /*!< EPWM_T::PBUF4: PBUF Mask */ #define EPWM_PBUF5_PBUF_Pos (0) /*!< EPWM_T::PBUF5: PBUF Position */ #define EPWM_PBUF5_PBUF_Msk (0xfffful << EPWM_PBUF5_PBUF_Pos) /*!< EPWM_T::PBUF5: PBUF Mask */ #define EPWM_CMPBUF0_CMPBUF_Pos (0) /*!< EPWM_T::CMPBUF0: CMPBUF Position */ #define EPWM_CMPBUF0_CMPBUF_Msk (0xfffful << EPWM_CMPBUF0_CMPBUF_Pos) /*!< EPWM_T::CMPBUF0: CMPBUF Mask */ #define EPWM_CMPBUF1_CMPBUF_Pos (0) /*!< EPWM_T::CMPBUF1: CMPBUF Position */ #define EPWM_CMPBUF1_CMPBUF_Msk (0xfffful << EPWM_CMPBUF1_CMPBUF_Pos) /*!< EPWM_T::CMPBUF1: CMPBUF Mask */ #define EPWM_CMPBUF2_CMPBUF_Pos (0) /*!< EPWM_T::CMPBUF2: CMPBUF Position */ #define EPWM_CMPBUF2_CMPBUF_Msk (0xfffful << EPWM_CMPBUF2_CMPBUF_Pos) /*!< EPWM_T::CMPBUF2: CMPBUF Mask */ #define EPWM_CMPBUF3_CMPBUF_Pos (0) /*!< EPWM_T::CMPBUF3: CMPBUF Position */ #define EPWM_CMPBUF3_CMPBUF_Msk (0xfffful << EPWM_CMPBUF3_CMPBUF_Pos) /*!< EPWM_T::CMPBUF3: CMPBUF Mask */ #define EPWM_CMPBUF4_CMPBUF_Pos (0) /*!< EPWM_T::CMPBUF4: CMPBUF Position */ #define EPWM_CMPBUF4_CMPBUF_Msk (0xfffful << EPWM_CMPBUF4_CMPBUF_Pos) /*!< EPWM_T::CMPBUF4: CMPBUF Mask */ #define EPWM_CMPBUF5_CMPBUF_Pos (0) /*!< EPWM_T::CMPBUF5: CMPBUF Position */ #define EPWM_CMPBUF5_CMPBUF_Msk (0xfffful << EPWM_CMPBUF5_CMPBUF_Pos) /*!< EPWM_T::CMPBUF5: CMPBUF Mask */ #define EPWM_CPSCBUF0_1_CPSCBUF_Pos (0) /*!< EPWM_T::CPSCBUF0_1: CPSCBUF Position */ #define EPWM_CPSCBUF0_1_CPSCBUF_Msk (0xffful << EPWM_CPSCBUF0_1_CPSCBUF_Pos) /*!< EPWM_T::CPSCBUF0_1: CPSCBUF Mask */ #define EPWM_CPSCBUF2_3_CPSCBUF_Pos (0) /*!< EPWM_T::CPSCBUF2_3: CPSCBUF Position */ #define EPWM_CPSCBUF2_3_CPSCBUF_Msk (0xffful << EPWM_CPSCBUF2_3_CPSCBUF_Pos) /*!< EPWM_T::CPSCBUF2_3: CPSCBUF Mask */ #define EPWM_CPSCBUF4_5_CPSCBUF_Pos (0) /*!< EPWM_T::CPSCBUF4_5: CPSCBUF Position */ #define EPWM_CPSCBUF4_5_CPSCBUF_Msk (0xffful << EPWM_CPSCBUF4_5_CPSCBUF_Pos) /*!< EPWM_T::CPSCBUF4_5: CPSCBUF Mask */ #define EPWM_FTCBUF0_1_FTCMPBUF_Pos (0) /*!< EPWM_T::FTCBUF0_1: FTCMPBUF Position */ #define EPWM_FTCBUF0_1_FTCMPBUF_Msk (0xfffful << EPWM_FTCBUF0_1_FTCMPBUF_Pos) /*!< EPWM_T::FTCBUF0_1: FTCMPBUF Mask */ #define EPWM_FTCBUF2_3_FTCMPBUF_Pos (0) /*!< EPWM_T::FTCBUF2_3: FTCMPBUF Position */ #define EPWM_FTCBUF2_3_FTCMPBUF_Msk (0xfffful << EPWM_FTCBUF2_3_FTCMPBUF_Pos) /*!< EPWM_T::FTCBUF2_3: FTCMPBUF Mask */ #define EPWM_FTCBUF4_5_FTCMPBUF_Pos (0) /*!< EPWM_T::FTCBUF4_5: FTCMPBUF Position */ #define EPWM_FTCBUF4_5_FTCMPBUF_Msk (0xfffful << EPWM_FTCBUF4_5_FTCMPBUF_Pos) /*!< EPWM_T::FTCBUF4_5: FTCMPBUF Mask */ #define EPWM_FTCI_FTCMU0_Pos (0) /*!< EPWM_T::FTCI: FTCMU0 Position */ #define EPWM_FTCI_FTCMU0_Msk (0x1ul << EPWM_FTCI_FTCMU0_Pos) /*!< EPWM_T::FTCI: FTCMU0 Mask */ #define EPWM_FTCI_FTCMU2_Pos (1) /*!< EPWM_T::FTCI: FTCMU2 Position */ #define EPWM_FTCI_FTCMU2_Msk (0x1ul << EPWM_FTCI_FTCMU2_Pos) /*!< EPWM_T::FTCI: FTCMU2 Mask */ #define EPWM_FTCI_FTCMU4_Pos (2) /*!< EPWM_T::FTCI: FTCMU4 Position */ #define EPWM_FTCI_FTCMU4_Msk (0x1ul << EPWM_FTCI_FTCMU4_Pos) /*!< EPWM_T::FTCI: FTCMU4 Mask */ #define EPWM_FTCI_FTCMD0_Pos (8) /*!< EPWM_T::FTCI: FTCMD0 Position */ #define EPWM_FTCI_FTCMD0_Msk (0x1ul << EPWM_FTCI_FTCMD0_Pos) /*!< EPWM_T::FTCI: FTCMD0 Mask */ #define EPWM_FTCI_FTCMD2_Pos (9) /*!< EPWM_T::FTCI: FTCMD2 Position */ #define EPWM_FTCI_FTCMD2_Msk (0x1ul << EPWM_FTCI_FTCMD2_Pos) /*!< EPWM_T::FTCI: FTCMD2 Mask */ #define EPWM_FTCI_FTCMD4_Pos (10) /*!< EPWM_T::FTCI: FTCMD4 Position */ #define EPWM_FTCI_FTCMD4_Msk (0x1ul << EPWM_FTCI_FTCMD4_Pos) /*!< EPWM_T::FTCI: FTCMD4 Mask */ /**@}*/ /* EPWM_CONST */ /**@}*/ /* end of EPWM register group */ /**@}*/ /* end of REGISTER group */ #endif /* __EPWM_REG_H__ */