/* ===================================================================*/
LDD_TDeviceData* ExtIntLdd1_Init(LDD_TUserData *UserDataPtr)
{
/* Allocate LDD device structure */
ExtIntLdd1_TDeviceData *DeviceDataPrv;
/* {FreeRTOS RTOS Adapter} Driver memory allocation: Dynamic allocation is simulated by a pointer to the static object */
DeviceDataPrv = &DeviceDataPrv__DEFAULT_RTOS_ALLOC;
/* Store the UserData pointer */
DeviceDataPrv->UserData = UserDataPtr;
/* Interrupt vector(s) allocation */
/* {FreeRTOS RTOS Adapter} Set interrupt vector: IVT is static, ISR parameter is passed by the global variable */
INT_PORTD__BAREBOARD_RTOS_ISRPARAM = DeviceDataPrv;
/* Initialization of Port Control registers */
/* PORTD_PCR4: ISF=0,MUX=1 */
PORTD_PCR4 = (uint32_t)((PORTD_PCR4 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK |
PORT_PCR_MUX(0x06)
)) | (uint32_t)(
PORT_PCR_MUX(0x01)
));
/* PORTD_PCR4: ISF=1,IRQC=9 */
PORTD_PCR4 = (uint32_t)((PORTD_PCR4 & (uint32_t)~(uint32_t)(
PORT_PCR_IRQC(0x06)
)) | (uint32_t)(
PORT_PCR_ISF_MASK |
PORT_PCR_IRQC(0x09)
));
/* NVIC_IPR7: PRI_31=0 */
NVIC_IPR7 &= (uint32_t)~(uint32_t)(NVIC_IP_PRI_31(0xFF));
/* NVIC_ISER: SETENA|=0x80000000 */
NVIC_ISER |= NVIC_ISER_SETENA(0x80000000);
/* Registration of the device structure */
PE_LDD_RegisterDeviceStructure(PE_LDD_COMPONENT_ExtIntLdd1_ID,DeviceDataPrv);
return ((LDD_TDeviceData *)DeviceDataPrv);
}
/*
** ===================================================================
** Method : ExtIntLdd7_Init (component ExtInt_LDD)
**
** Description :
** This method initializes the associated peripheral(s) and the
** component internal variables. The method is called
** automatically as a part of the application initialization
** code.
** Parameters :
** NAME - DESCRIPTION
** * UserDataPtr - Pointer to the RTOS device
** structure. This pointer will be passed to
** all events as parameter.
** Returns :
** --- - Pointer to the dynamically allocated
** private structure or NULL if there was an
** error.
** ===================================================================
*/
LDD_TDeviceData* ExtIntLdd7_Init(LDD_TUserData *UserDataPtr)
{
/* Allocate LDD device structure */
ExtIntLdd7_TDeviceData *DeviceDataPrv;
/* {Default RTOS Adapter} Driver memory allocation: Dynamic allocation is simulated by a pointer to the static object */
DeviceDataPrv = &DeviceDataPrv__DEFAULT_RTOS_ALLOC;
/* Store the UserData pointer */
DeviceDataPrv->UserData = UserDataPtr;
/* Set device as Disable */
DeviceDataPrv->UserEnabled = FALSE;
/* Interrupt vector(s) allocation */
/* {Default RTOS Adapter} Set interrupt vector: IVT is static, ISR parameter is passed by the global variable */
INT_PORTD__DEFAULT_RTOS_ISRPARAM = DeviceDataPrv;
/* Clear interrupt status flag - w1c */
PORTD_ISFR = PORT_ISFR_ISF(0x80);
/* Initialization of Port Control registers */
/* PORTD_PCR7: ISF=0,IRQC=0,MUX=1 */
PORTD_PCR7 = (uint32_t)((PORTD_PCR7 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK |
PORT_PCR_IRQC(0x0F) |
PORT_PCR_MUX(0x06)
)) | (uint32_t)(
PORT_PCR_MUX(0x01)
));
/* NVIC_IPR7: PRI_31=0x80 */
NVIC_IPR7 = (uint32_t)((NVIC_IPR7 & (uint32_t)~(uint32_t)(
NVIC_IP_PRI_31(0x7F)
)) | (uint32_t)(
NVIC_IP_PRI_31(0x80)
));
/* NVIC_ISER: SETENA|=0x80000000 */
NVIC_ISER |= NVIC_ISER_SETENA(0x80000000);
/* Registration of the device structure */
PE_LDD_RegisterDeviceStructure(PE_LDD_COMPONENT_ExtIntLdd7_ID,DeviceDataPrv);
return ((LDD_TDeviceData *)DeviceDataPrv);
}
/*
** ===================================================================
** Method : PE_low_level_init (component MKL26Z128FT4)
**
** Description :
** Initializes beans and provides common register initialization.
** The method is called automatically as a part of the
** application initialization code.
** This method is internal. It is used by Processor Expert only.
** ===================================================================
*/
void PE_low_level_init(void)
{
#ifdef PEX_RTOS_INIT
PEX_RTOS_INIT(); /* Initialization of the selected RTOS. Macro is defined by the RTOS component. */
#endif
/* Initialization of the SIM module */
/* PORTA_PCR4: ISF=0,MUX=7 */
PORTA_PCR4 = (uint32_t)((PORTA_PCR4 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK
)) | (uint32_t)(
PORT_PCR_MUX(0x07)
));
/* Initialization of the FTFL_FlashConfig module */
/* Initialization of the PMC module */
/* PMC_LVDSC1: LVDACK=1,LVDIE=0,LVDRE=1,LVDV=0 */
PMC_LVDSC1 = (uint8_t)((PMC_LVDSC1 & (uint8_t)~(uint8_t)(
PMC_LVDSC1_LVDIE_MASK |
PMC_LVDSC1_LVDV(0x03)
)) | (uint8_t)(
PMC_LVDSC1_LVDACK_MASK |
PMC_LVDSC1_LVDRE_MASK
));
/* PMC_LVDSC2: LVWACK=1,LVWIE=0,LVWV=0 */
PMC_LVDSC2 = (uint8_t)((PMC_LVDSC2 & (uint8_t)~(uint8_t)(
PMC_LVDSC2_LVWIE_MASK |
PMC_LVDSC2_LVWV(0x03)
)) | (uint8_t)(
PMC_LVDSC2_LVWACK_MASK
));
/* PMC_REGSC: BGEN=0,ACKISO=0,BGBE=0 */
PMC_REGSC &= (uint8_t)~(uint8_t)(
PMC_REGSC_BGEN_MASK |
PMC_REGSC_ACKISO_MASK |
PMC_REGSC_BGBE_MASK
);
/* SMC_PMPROT: ??=0,??=0,AVLP=0,??=0,ALLS=0,??=0,AVLLS=0,??=0 */
SMC_PMPROT = 0x00U; /* Setup Power mode protection register */
/* Common initialization of the CPU registers */
/* PORTD_ISFR: ISF=0xD2 */
PORTD_ISFR = PORT_ISFR_ISF(0xD2);
/* Common initialization of the CPU registers */
/* PORTD_PCR1: ISF=0,IRQC=0x0B,PE=1 */
PORTD_PCR1 = (uint32_t)((PORTD_PCR1 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK |
PORT_PCR_IRQC(0x04)
)) | (uint32_t)(
PORT_PCR_IRQC(0x0B) |
PORT_PCR_PE_MASK
));
/* PORTD_PCR2: ISF=0,PE=1,PS=1 */
PORTD_PCR2 = (uint32_t)((PORTD_PCR2 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK
)) | (uint32_t)(
PORT_PCR_PE_MASK |
PORT_PCR_PS_MASK
));
/* PORTD_PCR4: ISF=0,IRQC=0x0B,PE=1 */
PORTD_PCR4 = (uint32_t)((PORTD_PCR4 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK |
PORT_PCR_IRQC(0x04)
)) | (uint32_t)(
PORT_PCR_IRQC(0x0B) |
PORT_PCR_PE_MASK
));
/* PORTD_PCR5: ISF=0,PE=1 */
PORTD_PCR5 = (uint32_t)((PORTD_PCR5 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK
)) | (uint32_t)(
PORT_PCR_PE_MASK
));
/* PORTD_PCR6: ISF=0,IRQC=0x0B,DSE=0,PE=1 */
PORTD_PCR6 = (uint32_t)((PORTD_PCR6 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK |
PORT_PCR_IRQC(0x04) |
PORT_PCR_DSE_MASK
)) | (uint32_t)(
PORT_PCR_IRQC(0x0B) |
PORT_PCR_PE_MASK
));
/* PORTD_PCR7: ISF=0,IRQC=0x0B,DSE=0,PE=1 */
PORTD_PCR7 = (uint32_t)((PORTD_PCR7 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK |
PORT_PCR_IRQC(0x04) |
PORT_PCR_DSE_MASK
)) | (uint32_t)(
PORT_PCR_IRQC(0x0B) |
PORT_PCR_PE_MASK
));
/* NVIC_ISER: SETENA|=0x80000040 */
NVIC_ISER |= NVIC_ISER_SETENA(0x80000040);
/* NVIC_IPR7: PRI_31=0 */
NVIC_IPR7 &= (uint32_t)~(uint32_t)(NVIC_IP_PRI_31(0xFF));
/* PORTC_PCR3: ISF=0,PE=1 */
PORTC_PCR3 = (uint32_t)((PORTC_PCR3 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK
)) | (uint32_t)(
PORT_PCR_PE_MASK
));
/* PORTC_PCR5: ISF=0,PE=1,PS=1 */
PORTC_PCR5 = (uint32_t)((PORTC_PCR5 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK
)) | (uint32_t)(
PORT_PCR_PE_MASK |
PORT_PCR_PS_MASK
));
/* NVIC_IPR5: PRI_21=0,PRI_20=0 */
NVIC_IPR5 &= (uint32_t)~(uint32_t)(
NVIC_IP_PRI_21(0xFF) |
NVIC_IP_PRI_20(0xFF)
);
/* PORTB_PCR0: ISF=0,PE=1,PS=1 */
PORTB_PCR0 = (uint32_t)((PORTB_PCR0 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK
)) | (uint32_t)(
PORT_PCR_PE_MASK |
PORT_PCR_PS_MASK
));
/* PORTB_PCR1: ISF=0,PE=1,PS=1 */
PORTB_PCR1 = (uint32_t)((PORTB_PCR1 & (uint32_t)~(uint32_t)(
PORT_PCR_ISF_MASK
)) | (uint32_t)(
PORT_PCR_PE_MASK |
PORT_PCR_PS_MASK
));
/* NVIC_IPR1: PRI_6=0 */
NVIC_IPR1 &= (uint32_t)~(uint32_t)(NVIC_IP_PRI_6(0xFF));
/* ### FreeRTOS "FRTOS1" init code ... */
#if configSYSTICK_USE_LOW_POWER_TIMER
/* enable clocking for low power timer, otherwise vPortStopTickTimer() will crash */
SIM_SCGC5 |= SIM_SCGC5_LPTMR_MASK; /* SIM_SCGC5: LPTMR=1 */
#endif
vPortStopTickTimer(); /* tick timer shall not run until the RTOS scheduler is started */
/* ### Serial_LDD "IO1" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)IO1_Init(NULL);
/* ### Init_GPIO "PTD" init code ... */
PTD_Init();
/* ### BitIO_LDD "StartStopButton" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)StartStopButton_Init(NULL);
/* ### BitIO_LDD "BitIoLdd1" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)BitIoLdd1_Init(NULL);
/* ### BitIO_LDD "BitIoLdd2" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)BitIoLdd2_Init(NULL);
/* ### BitIO_LDD "BitIoLdd3" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)BitIoLdd3_Init(NULL);
/* ### BitIO_LDD "BitIoLdd4" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)BitIoLdd4_Init(NULL);
/* ### BitIO_LDD "BitIoLdd5" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)BitIoLdd5_Init(NULL);
/* ### BitIO_LDD "ModeButton" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)ModeButton_Init(NULL);
/* ### Init_GPIO "PTC" init code ... */
PTC_Init();
/* ### BitIO_LDD "BitIoLdd6" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)BitIoLdd6_Init(NULL);
/* ### BitIO_LDD "EncoderA" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)EncoderA_Init(NULL);
/* ### BitIO_LDD "EncoderB" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)EncoderB_Init(NULL);
/* ### BitIO_LDD "PreampEnable" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)PreampEnable_Init(NULL);
/* ### Init_SRTC "RTC" init code ... */
RTC_Init();
/* ### Init_GPIO "PTB" init code ... */
PTB_Init();
/* ### DMATransfer_LDD "SSI1_TxDMA" component auto initialization. Auto initialization feature can be disabled by component's property "Auto initialization". */
(void)SSI1_TxDMA_Init(NULL);
/* ### BitIO_LDD "BitIoLdd7" component auto initialization. Auto initialization feature can be disabled by component property "Auto initialization". */
(void)BitIoLdd7_Init(NULL);
}
/* ===================================================================*/
LDD_TDeviceData* CAN1_Init(LDD_TUserData *UserDataPtr)
{
/* Allocate LDD device structure */
CAN1_TDeviceDataPtr DeviceDataPrv;
/* {Default RTOS Adapter} Driver memory allocation: Dynamic allocation is simulated by a pointer to the static object */
DeviceDataPrv = &DeviceDataPrv__DEFAULT_RTOS_ALLOC;
DeviceDataPrv->BaseAddr = MSCAN_BASE_PTR; /* Device base address*/
DeviceDataPrv->UserData = UserDataPtr; /* Store the RTOS device structure */
DeviceDataPrv->MaxDataLen = 0x08U; /* Max number of data to be sent in one frame */
DeviceDataPrv->MaxBufferIndex = (LDD_CAN_TMBIndex)(CAN1_CAN_MBUFFERS-1U); /* Number of max. message buffer index */
DeviceDataPrv->BuffersNumber = (LDD_CAN_TMBIndex)CAN1_CAN_MBUFFERS; /* Number of message buffers */
DeviceDataPrv->RxBufferMask = 0x01U; /* Bit mask for message buffers configured as receive */
DeviceDataPrv->TxBufferMask = 0x02U; /* Bit mask for message buffers configured as transmit */
DeviceDataPrv->BuffersIdxToHwPtr = (LDD_CAN_TMBIndex *)RemapBuffersIdxToHw; /* Set pointer to BuffersIdxToHwPtr remap table */
DeviceDataPrv->HwToRxBuffersIdxPtr = (LDD_CAN_TMBIndex *)RemapHwToRxBuffersIdx; /* Set pointer to HwToRxBuffersIdx remap table */
DeviceDataPrv->HwToTxBuffersIdxPtr = (LDD_CAN_TMBIndex *)RemapHwToTxBuffersIdx; /* Set pointer to HwToTxBuffersIdx remap table */
DeviceDataPrv->TxBuffersPendingMask = 0x00U; /* Initialize used Tx buffers mask variable */
DeviceDataPrv->Index = 0x00U; /* Set the component instance index */
/* Clock Gating initialization */
/* SIM_SCGC: MSCAN=1 */
SIM_SCGC |= SIM_SCGC_MSCAN_MASK;
/* Allocate interrupt vectors */
/* {Default RTOS Adapter} Set interrupt vector: IVT is static, ISR parameter is passed by the global variable */
INT_MSCAN_TX__DEFAULT_RTOS_ISRPARAM = DeviceDataPrv;
/* {Default RTOS Adapter} Set interrupt vector: IVT is static, ISR parameter is passed by the global variable */
INT_MSCAN_RX__DEFAULT_RTOS_ISRPARAM = DeviceDataPrv;
/* SIM_PINSEL1: MSCANPS=1 */
SIM_PINSEL1 |= SIM_PINSEL1_MSCANPS_MASK;
/* Interrupt priorities */
/* NVIC_IPR7: PRI_31=1 */
NVIC_IPR7 = (uint32_t)((NVIC_IPR7 & (uint32_t)~(uint32_t)(
NVIC_IP_PRI_31(0x02)
)) | (uint32_t)(
NVIC_IP_PRI_31(0x01)
));
/* NVIC_ISER: SETENA31=1,SETENA30=0,SETENA29=0,SETENA28=0,SETENA27=0,SETENA26=0,SETENA25=0,SETENA24=0,SETENA23=0,SETENA22=0,SETENA21=0,SETENA20=0,SETENA19=0,SETENA18=0,SETENA17=0,SETENA16=0,SETENA15=0,SETENA14=0,SETENA13=0,SETENA12=0,SETENA11=0,SETENA10=0,SETENA9=0,SETENA8=0,SETENA7=0,SETENA6=0,SETENA5=0,SETENA4=0,SETENA3=0,SETENA2=0,SETENA1=0,SETENA0=0 */
NVIC_ISER = NVIC_ISER_SETENA31_MASK;
/* NVIC_ICER: CLRENA31=0,CLRENA30=0,CLRENA29=0,CLRENA28=0,CLRENA27=0,CLRENA26=0,CLRENA25=0,CLRENA24=0,CLRENA23=0,CLRENA22=0,CLRENA21=0,CLRENA20=0,CLRENA19=0,CLRENA18=0,CLRENA17=0,CLRENA16=0,CLRENA15=0,CLRENA14=0,CLRENA13=0,CLRENA12=0,CLRENA11=0,CLRENA10=0,CLRENA9=0,CLRENA8=0,CLRENA7=0,CLRENA6=0,CLRENA5=0,CLRENA4=0,CLRENA3=0,CLRENA2=0,CLRENA1=0,CLRENA0=0 */
NVIC_ICER = 0x00U;
/* NVIC_IPR7: PRI_30=1 */
NVIC_IPR7 = (uint32_t)((NVIC_IPR7 & (uint32_t)~(uint32_t)(
NVIC_IP_PRI_30(0x02)
)) | (uint32_t)(
NVIC_IP_PRI_30(0x01)
));
/* NVIC_ISER: SETENA31=0,SETENA30=1,SETENA29=0,SETENA28=0,SETENA27=0,SETENA26=0,SETENA25=0,SETENA24=0,SETENA23=0,SETENA22=0,SETENA21=0,SETENA20=0,SETENA19=0,SETENA18=0,SETENA17=0,SETENA16=0,SETENA15=0,SETENA14=0,SETENA13=0,SETENA12=0,SETENA11=0,SETENA10=0,SETENA9=0,SETENA8=0,SETENA7=0,SETENA6=0,SETENA5=0,SETENA4=0,SETENA3=0,SETENA2=0,SETENA1=0,SETENA0=0 */
NVIC_ISER = NVIC_ISER_SETENA30_MASK;
/* NVIC_ICER: CLRENA31=0,CLRENA30=0,CLRENA29=0,CLRENA28=0,CLRENA27=0,CLRENA26=0,CLRENA25=0,CLRENA24=0,CLRENA23=0,CLRENA22=0,CLRENA21=0,CLRENA20=0,CLRENA19=0,CLRENA18=0,CLRENA17=0,CLRENA16=0,CLRENA15=0,CLRENA14=0,CLRENA13=0,CLRENA12=0,CLRENA11=0,CLRENA10=0,CLRENA9=0,CLRENA8=0,CLRENA7=0,CLRENA6=0,CLRENA5=0,CLRENA4=0,CLRENA3=0,CLRENA2=0,CLRENA1=0,CLRENA0=0 */
NVIC_ICER = 0x00U;
/* MSCAN_CANCTL1: CANE=1,CLKSRC=1,LOOPB=0,LISTEN=0,BORM=0,WUPM=0,SLPAK=0,INITAK=0 */
MSCAN_CANCTL1 = (MSCAN_CANCTL1_CANE_MASK | MSCAN_CANCTL1_CLKSRC_MASK); /* Set control 1 register */
/* MSCAN_CANCTL0: RXFRM=0,RXACT=0,CSWAI=0,SYNCH=0,TIME=0,WUPE=0,SLPRQ=0,INITRQ=1 */
MSCAN_CANCTL0 = MSCAN_CANCTL0_INITRQ_MASK; /* Set control 0 register */
/* MSCAN_CANIDAC: ??=0,??=0,IDAM=0,??=0,IDHIT=0 */
MSCAN_CANIDAC = (MSCAN_CANIDAC_IDAM(0x00) | MSCAN_CANIDAC_IDHIT(0x00)); /* Set identifier acceptance control register */
/* MSCAN_CANIDMR0: AM=0xFF */
MSCAN_CANIDMR0 = MSCAN_CANIDMR_BANK_1_AM(0xFF); /* Set the acceptance mask - register MSCAN_CANIDMR0 */
/* MSCAN_CANIDMR1: AM=0xFF */
MSCAN_CANIDMR1 = MSCAN_CANIDMR_BANK_1_AM(0xFF); /* Set the acceptance mask - register MSCAN_CANIDMR1 */
/* MSCAN_CANIDMR2: AM=0xFF */
MSCAN_CANIDMR2 = MSCAN_CANIDMR_BANK_1_AM(0xFF); /* Set the acceptance mask - register MSCAN_CANIDMR2 */
/* MSCAN_CANIDMR3: AM=0xFF */
MSCAN_CANIDMR3 = MSCAN_CANIDMR_BANK_1_AM(0xFF); /* Set the acceptance mask - register MSCAN_CANIDMR3 */
/* MSCAN_CANIDMR4: AM=0xFF */
MSCAN_CANIDMR4 = MSCAN_CANIDMR_BANK_2_AM(0xFF); /* Set the acceptance mask - register MSCAN_CANIDMR4 */
/* MSCAN_CANIDMR5: AM=0xFF */
MSCAN_CANIDMR5 = MSCAN_CANIDMR_BANK_2_AM(0xFF); /* Set the acceptance mask - register MSCAN_CANIDMR5 */
/* MSCAN_CANIDMR6: AM=0xFF */
MSCAN_CANIDMR6 = MSCAN_CANIDMR_BANK_2_AM(0xFF); /* Set the acceptance mask - register MSCAN_CANIDMR6 */
/* MSCAN_CANIDMR7: AM=0xFF */
MSCAN_CANIDMR7 = MSCAN_CANIDMR_BANK_2_AM(0xFF); /* Set the acceptance mask - register MSCAN_CANIDMR7 */
/* MSCAN_CANIDAR0: AC=0xFF */
MSCAN_CANIDAR0 = MSCAN_CANIDAR_BANK_1_AC(0xFF); /* Set the acceptance code - register MSCAN_CANIDAR0 */
/* MSCAN_CANIDAR1: AC=0xFF */
MSCAN_CANIDAR1 = MSCAN_CANIDAR_BANK_1_AC(0xFF); /* Set the acceptance code - register MSCAN_CANIDAR1 */
/* MSCAN_CANIDAR2: AC=0xFF */
MSCAN_CANIDAR2 = MSCAN_CANIDAR_BANK_1_AC(0xFF); /* Set the acceptance code - register MSCAN_CANIDAR2 */
/* MSCAN_CANIDAR3: AC=0xFF */
MSCAN_CANIDAR3 = MSCAN_CANIDAR_BANK_1_AC(0xFF); /* Set the acceptance code - register MSCAN_CANIDAR3 */
/* MSCAN_CANIDAR4: AC=0xFF */
MSCAN_CANIDAR4 = MSCAN_CANIDAR_BANK_2_AC(0xFF); /* Set the acceptance code - register MSCAN_CANIDAR4 */
/* MSCAN_CANIDAR5: AC=0xFF */
MSCAN_CANIDAR5 = MSCAN_CANIDAR_BANK_2_AC(0xFF); /* Set the acceptance code - register MSCAN_CANIDAR5 */
/* MSCAN_CANIDAR6: AC=0xFF */
MSCAN_CANIDAR6 = MSCAN_CANIDAR_BANK_2_AC(0xFF); /* Set the acceptance code - register MSCAN_CANIDAR6 */
/* MSCAN_CANIDAR7: AC=0xFF */
MSCAN_CANIDAR7 = MSCAN_CANIDAR_BANK_2_AC(0xFF); /* Set the acceptance code - register MSCAN_CANIDAR7 */
/* MSCAN_CANBTR0: SJW=0,BRP=6 */
MSCAN_CANBTR0 = (MSCAN_CANBTR0_SJW(0x00) | MSCAN_CANBTR0_BRP(0x06)); /* Set the timing register 0 */
/* MSCAN_CANBTR1: SAMP=0,TSEG2=1,TSEG1=3 */
MSCAN_CANBTR1 = (MSCAN_CANBTR1_TSEG2(0x01) | MSCAN_CANBTR1_TSEG1(0x03)); /* Set the timing register 1 */
DeviceDataPrv->TxBuffersPendingMask = 0x00U; /* Clear Tx request pending message buffer mask */
MSCAN_PDD_EnableInitializationMode(MSCAN_BASE_PTR, PDD_DISABLE); /* Exit from initialization mode */
while(MSCAN_PDD_GetInitializationModeAcknowledgeFlag(MSCAN_BASE_PTR) != 0U) {} /* Wait for enable */
MSCAN_PDD_ClearRxStatusInterruptFlags(MSCAN_BASE_PTR, (MSCAN_PDD_WAKEUP_REQUESTED_FLAG | MSCAN_PDD_ERROR_COUNTER_CHANGE_FLAG | MSCAN_PDD_RX_BUFFER_OVERRUN_FLAG)); /* Reset interrupt flags */
MSCAN_PDD_EnableRxInterruptsMask(MSCAN_BASE_PTR, MSCAN_PDD_RX_BUFFER_FULL_INT); /* Enable/configure interrupt */
/* Registration of the device structure */
PE_LDD_RegisterDeviceStructure(PE_LDD_COMPONENT_CAN1_ID,DeviceDataPrv);
return ((LDD_TDeviceDataPtr)DeviceDataPrv);
}
