/*
* Copyright (c) 2015, Freescale Semiconductor, Inc.
* Copyright 2016-2020 NXP
* All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include "fsl_flexcan.h"
/*******************************************************************************
* Definitions
******************************************************************************/
/* Component ID definition, used by tools. */
#ifndef FSL_COMPONENT_ID
#define FSL_COMPONENT_ID "platform.drivers.flexcan"
#endif
#if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_6032) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_6032)
#define RXINTERMISSION (CAN_DBG1_CFSM(0x2f))
#define TXINTERMISSION (CAN_DBG1_CFSM(0x14))
#define BUSIDLE (CAN_DBG1_CFSM(0x02))
#define CBN_VALUE3 (CAN_DBG1_CBN(0x03))
#define DELAY_BUSIDLE (200)
#endif
#define IDEAL_SP_LOW (750U)
#define IDEAL_SP_MID (800U)
#define IDEAL_SP_HIGH (875U)
#define IDEAL_SP_FACTOR (1000U)
#define MAX_PROPSEG (CAN_CTRL1_PROPSEG_MASK >> CAN_CTRL1_PROPSEG_SHIFT)
#define MAX_PSEG1 (CAN_CTRL1_PSEG1_MASK >> CAN_CTRL1_PSEG1_SHIFT)
#define MAX_PSEG2 (CAN_CTRL1_PSEG2_MASK >> CAN_CTRL1_PSEG2_SHIFT)
#define MAX_RJW (CAN_CTRL1_RJW_MASK >> CAN_CTRL1_RJW_SHIFT)
#define MAX_PRESDIV (CAN_CTRL1_PRESDIV_MASK >> CAN_CTRL1_PRESDIV_SHIFT)
#define CTRL1_MAX_TIME_QUANTA (1U + MAX_PROPSEG + 1U + MAX_PSEG1 + 1U + MAX_PSEG2 + 1U)
#define CTRL1_MIN_TIME_QUANTA (8U)
#define MAX_EPROPSEG (CAN_CBT_EPROPSEG_MASK >> CAN_CBT_EPROPSEG_SHIFT)
#define MAX_EPSEG1 (CAN_CBT_EPSEG1_MASK >> CAN_CBT_EPSEG1_SHIFT)
#define MAX_EPSEG2 (CAN_CBT_EPSEG2_MASK >> CAN_CBT_EPSEG2_SHIFT)
#define MAX_ERJW (CAN_CBT_ERJW_MASK >> CAN_CBT_ERJW_SHIFT)
#define MAX_EPRESDIV (CAN_CBT_EPRESDIV_MASK >> CAN_CBT_EPRESDIV_SHIFT)
#define CBT_MAX_TIME_QUANTA (1U + MAX_EPROPSEG + 1U + MAX_EPSEG1 + 1U + MAX_EPSEG2 + 1U)
#define CBT_MIN_TIME_QUANTA (8U)
#define MAX_FPROPSEG (CAN_FDCBT_FPROPSEG_MASK >> CAN_FDCBT_FPROPSEG_SHIFT)
#define MAX_FPSEG1 (CAN_FDCBT_FPSEG1_MASK >> CAN_FDCBT_FPSEG1_SHIFT)
#define MAX_FPSEG2 (CAN_FDCBT_FPSEG2_MASK >> CAN_FDCBT_FPSEG2_SHIFT)
#define MAX_FRJW (CAN_FDCBT_FRJW_MASK >> CAN_FDCBT_FRJW_SHIFT)
#define MAX_FPRESDIV (CAN_FDCBT_FPRESDIV_MASK >> CAN_FDCBT_FPRESDIV_SHIFT)
#define FDCBT_MAX_TIME_QUANTA (1U + MAX_FPROPSEG + 0U + MAX_FPSEG1 + 1U + MAX_FPSEG2 + 1U)
#define FDCBT_MIN_TIME_QUANTA (5U)
#define MAX_CANFD_BAUDRATE (8000000U)
#define MAX_CAN_BAUDRATE (1000000U)
#if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_9595) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_9595)
#define CAN_ESR1_FLTCONF_BUSOFF CAN_ESR1_FLTCONF(2U)
#endif
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
#ifndef CAN_CLOCK_CHECK_NO_AFFECTS
/* If no define such MACRO, it mean that the CAN in current device have no clock affect issue. */
#define CAN_CLOCK_CHECK_NO_AFFECTS (true)
#endif /* CAN_CLOCK_CHECK_NO_AFFECTS */
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
/*! @brief FlexCAN Internal State. */
enum _flexcan_state
{
kFLEXCAN_StateIdle = 0x0, /*!< MB/RxFIFO idle.*/
kFLEXCAN_StateRxData = 0x1, /*!< MB receiving.*/
kFLEXCAN_StateRxRemote = 0x2, /*!< MB receiving remote reply.*/
kFLEXCAN_StateTxData = 0x3, /*!< MB transmitting.*/
kFLEXCAN_StateTxRemote = 0x4, /*!< MB transmitting remote request.*/
kFLEXCAN_StateRxFifo = 0x5, /*!< RxFIFO receiving.*/
};
/*! @brief FlexCAN message buffer CODE for Rx buffers. */
enum _flexcan_mb_code_rx
{
kFLEXCAN_RxMbInactive = 0x0, /*!< MB is not active.*/
kFLEXCAN_RxMbFull = 0x2, /*!< MB is full.*/
kFLEXCAN_RxMbEmpty = 0x4, /*!< MB is active and empty.*/
kFLEXCAN_RxMbOverrun = 0x6, /*!< MB is overwritten into a full buffer.*/
kFLEXCAN_RxMbBusy = 0x8, /*!< FlexCAN is updating the contents of the MB.*/
/*! The CPU must not access the MB.*/
kFLEXCAN_RxMbRanswer = 0xA, /*!< A frame was configured to recognize a Remote Request Frame */
/*! and transmit a Response Frame in return.*/
kFLEXCAN_RxMbNotUsed = 0xF, /*!< Not used.*/
};
/*! @brief FlexCAN message buffer CODE FOR Tx buffers. */
enum _flexcan_mb_code_tx
{
kFLEXCAN_TxMbInactive = 0x8, /*!< MB is not active.*/
kFLEXCAN_TxMbAbort = 0x9, /*!< MB is aborted.*/
kFLEXCAN_TxMbDataOrRemote = 0xC, /*!< MB is a TX Data Frame(when MB RTR = 0) or */
/*!< MB is a TX Remote Request Frame (when MB RTR = 1).*/
kFLEXCAN_TxMbTanswer = 0xE, /*!< MB is a TX Response Request Frame from */
/*! an incoming Remote Request Frame.*/
kFLEXCAN_TxMbNotUsed = 0xF, /*!< Not used.*/
};
/* Typedef for interrupt handler. */
typedef void (*flexcan_isr_t)(CAN_Type *base, flexcan_handle_t *handle);
/*******************************************************************************
* Prototypes
******************************************************************************/
#if !defined(NDEBUG)
/*!
* @brief Check if Message Buffer is occupied by Rx FIFO.
*
* This function check if Message Buffer is occupied by Rx FIFO.
*
* @param base FlexCAN peripheral base address.
* @param mbIdx The FlexCAN Message Buffer index.
*/
static bool FLEXCAN_IsMbOccupied(CAN_Type *base, uint8_t mbIdx);
#endif
#if ((defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) || \
(defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829))
/*!
* @brief Get the first valid Message buffer ID of give FlexCAN instance.
*
* This function is a helper function for Errata 5641 workaround.
*
* @param base FlexCAN peripheral base address.
* @return The first valid Message Buffer Number.
*/
static uint8_t FLEXCAN_GetFirstValidMb(CAN_Type *base);
#endif
/*!
* @brief Check if Message Buffer interrupt is enabled.
*
* This function check if Message Buffer interrupt is enabled.
*
* @param base FlexCAN peripheral base address.
* @param mbIdx The FlexCAN Message Buffer index.
* @return TRUE if the index MB interrupt mask enabled, FALSE if the index MB interrupt mask disabled.
*
*/
static bool FLEXCAN_IsMbIntEnabled(CAN_Type *base, uint8_t mbIdx);
/*!
* @brief Reset the FlexCAN Instance.
*
* Restores the FlexCAN module to reset state, notice that this function
* will set all the registers to reset state so the FlexCAN module can not work
* after calling this API.
*
* @param base FlexCAN peripheral base address.
*/
static void FLEXCAN_Reset(CAN_Type *base);
/*!
* @brief Set Baud Rate of FlexCAN.
*
* This function set the baud rate of FlexCAN.
*
* @param base FlexCAN peripheral base address.
* @param sourceClock_Hz Source Clock in Hz.
* @param baudRate_Bps Baud Rate in Bps.
* @param timingConfig FlexCAN timingConfig.
*/
static void FLEXCAN_SetBaudRate(CAN_Type *base,
uint32_t sourceClock_Hz,
uint32_t baudRate_Bps,
flexcan_timing_config_t timingConfig);
/*!
* @brief Calculates the segment values for a single bit time for classical CAN
*
* @param baudRate The data speed in bps
* @param tqNum Number of time quantas per bit
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if Calculates the segment success, FALSE if Calculates the segment success
*/
static bool FLEXCAN_GetSegments(uint32_t baudRate, uint32_t tqNum, flexcan_timing_config_t *pTimingConfig);
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/*!
* @brief Set Baud Rate of FlexCAN FD frame.
*
* This function set the baud rate of FlexCAN FD frame.
*
* @param base FlexCAN peripheral base address.
* @param sourceClock_Hz Source Clock in Hz.
* @param baudRateFD_Bps FD frame Baud Rate in Bps.
* @param timingConfig FlexCAN timingConfig.
*/
static void FLEXCAN_SetFDBaudRate(CAN_Type *base,
uint32_t sourceClock_Hz,
uint32_t baudRateFD_Bps,
flexcan_timing_config_t timingConfig);
/*!
* @brief Get Mailbox offset number by dword.
*
* This function gets the offset number of the specified mailbox.
* Mailbox is not consecutive between memory regions when payload is not 8 bytes
* so need to calculate the specified mailbox address.
* For example, in the first memory region, MB[0].CS address is 0x4002_4080. For 32 bytes
* payload frame, the second mailbox is ((1/12)*512 + 1%12*40)/4 = 10, meaning 10 dword
* after the 0x4002_4080, which is actually the address of mailbox MB[1].CS.
*
* @param base FlexCAN peripheral base address.
* @param mbIdx Mailbox index.
*/
static uint32_t FLEXCAN_GetFDMailboxOffset(CAN_Type *base, uint8_t mbIdx);
/*!
* @brief Calculates the segment values for a single bit time for CANFD bus control baud Rate
*
* @param baudRate The canfd bus control speed in bps
* @param tqNum Number of time quanta per bit
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if Calculates the segment success, FALSE if Calculates the segment success
*/
static bool FLEXCAN_FDGetSegments(uint32_t baudRate, uint32_t tqNum, flexcan_timing_config_t *pTimingConfig);
/*!
* @brief Calculates the segment values for a single bit time for CANFD bus data baud Rate
*
* @param baudRatebrs The canfd bus data speed in bps
* @param tqNum Number of time quanta per bit
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if Calculates the segment success, FALSE if Calculates the segment success
*/
static bool FLEXCAN_FDGetSegmentswithBRS(uint32_t baudRatebrs, uint32_t tqNum, flexcan_timing_config_t *pTimingConfig);
/*!
* @brief Calculates the improved timing values by specific baudrates for CAN by CBT register
*
* @param baudRate The classical CAN speed in bps defined by user
* @param sourceClock_Hz The Source clock data speed in bps. Zero to disable baudrate switching
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if timing configuration found, FALSE if failed to find configuration
*/
static bool FLEXCAN_CalculateImprovedTimingValuesByCBT(uint32_t baudRate,
uint32_t sourceClock_Hz,
flexcan_timing_config_t *pTimingConfig);
#endif
/*!
* @brief Check unhandle interrupt events
*
* @param base FlexCAN peripheral base address.
* @return TRUE if unhandled interrupt action exist, FALSE if no unhandlered interrupt action exist.
*/
static bool FLEXCAN_CheckUnhandleInterruptEvents(CAN_Type *base);
/*!
* @brief Sub Handler Data Trasfered Events
*
* @param base FlexCAN peripheral base address.
* @param handle FlexCAN handle pointer.
* @param pResult Pointer to the Handle result.
* @return the status after handle each data transfered event.
*/
static status_t FLEXCAN_SubHandlerForDataTransfered(CAN_Type *base, flexcan_handle_t *handle, uint32_t *pResult);
/*******************************************************************************
* Variables
******************************************************************************/
/* Array of FlexCAN peripheral base address. */
static CAN_Type *const s_flexcanBases[] = CAN_BASE_PTRS;
/* Array of FlexCAN IRQ number. */
static const IRQn_Type s_flexcanRxWarningIRQ[] = CAN_Rx_Warning_IRQS;
static const IRQn_Type s_flexcanTxWarningIRQ[] = CAN_Tx_Warning_IRQS;
static const IRQn_Type s_flexcanWakeUpIRQ[] = CAN_Wake_Up_IRQS;
static const IRQn_Type s_flexcanErrorIRQ[] = CAN_Error_IRQS;
static const IRQn_Type s_flexcanBusOffIRQ[] = CAN_Bus_Off_IRQS;
static const IRQn_Type s_flexcanMbIRQ[] = CAN_ORed_Message_buffer_IRQS;
/* Array of FlexCAN handle. */
static flexcan_handle_t *s_flexcanHandle[ARRAY_SIZE(s_flexcanBases)];
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/* Array of FlexCAN clock name. */
static const clock_ip_name_t s_flexcanClock[] = FLEXCAN_CLOCKS;
#if defined(FLEXCAN_PERIPH_CLOCKS)
/* Array of FlexCAN serial clock name. */
static const clock_ip_name_t s_flexcanPeriphClock[] = FLEXCAN_PERIPH_CLOCKS;
#endif /* FLEXCAN_PERIPH_CLOCKS */
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
/* FlexCAN ISR for transactional APIs. */
#if defined(__ARMCC_VERSION) && (__ARMCC_VERSION >= 6010050)
static flexcan_isr_t s_flexcanIsr = (flexcan_isr_t)DefaultISR;
#else
static flexcan_isr_t s_flexcanIsr;
#endif
/*******************************************************************************
* Code
******************************************************************************/
/*!
* brief Get the FlexCAN instance from peripheral base address.
*
* param base FlexCAN peripheral base address.
* return FlexCAN instance.
*/
uint32_t FLEXCAN_GetInstance(CAN_Type *base)
{
uint32_t instance;
/* Find the instance index from base address mappings. */
for (instance = 0; instance < ARRAY_SIZE(s_flexcanBases); instance++)
{
if (s_flexcanBases[instance] == base)
{
break;
}
}
assert(instance < ARRAY_SIZE(s_flexcanBases));
return instance;
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_9595) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_9595)
void FLEXCAN_EnterFreezeMode(CAN_Type *base)
{
uint32_t u32TimeoutCount = 0U;
uint32_t u32TempMCR = 0U;
uint32_t u32TempIMASK1 = 0U;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint32_t u32TempIMASK2 = 0U;
#endif
/* Step1: set FRZ enable in MCR. */
base->MCR |= CAN_MCR_FRZ_MASK;
/* Step2: to check if MDIS bit set in MCR. if yes, clear it. */
if (0U != (base->MCR & CAN_MCR_MDIS_MASK))
{
base->MCR &= ~CAN_MCR_MDIS_MASK;
}
/* Step3: polling LPMACK. */
u32TimeoutCount = (uint32_t)FLEXCAN_WAIT_TIMEOUT;
while ((0U == (base->MCR & CAN_MCR_LPMACK_MASK)) && (u32TimeoutCount > 0U))
{
u32TimeoutCount--;
}
/* Step4: to check FLTCONF in ESR1 register */
if (0U == (base->ESR1 & CAN_ESR1_FLTCONF_BUSOFF))
{
/* Step5B: Set Halt bits. */
base->MCR |= CAN_MCR_HALT_MASK;
/* Step6B: Poll the MCR register until the Freeze Acknowledge (FRZACK) bit is set, timeout need more than 178
* CAN bit length, so 20 multiply timeout is enough. */
u32TimeoutCount = (uint32_t)FLEXCAN_WAIT_TIMEOUT * 20U;
while ((0U == (base->MCR & CAN_MCR_FRZACK_MASK)) && (u32TimeoutCount > 0U))
{
u32TimeoutCount--;
}
}
else
{
/* backup MCR and IMASK register. Errata document not descript it, but we need backup for step 8A and 9A. */
u32TempMCR = base->MCR;
u32TempIMASK1 = base->IMASK1;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
u32TempIMASK2 = base->IMASK2;
#endif
/* Step5A: Set the Soft Reset bit ((SOFTRST) in the MCR.*/
base->MCR |= CAN_MCR_SOFTRST_MASK;
/* Step6A: Poll the MCR register until the Soft Reset (SOFTRST) bit is cleared. */
u32TimeoutCount = (uint32_t)FLEXCAN_WAIT_TIMEOUT;
while ((CAN_MCR_SOFTRST_MASK == (base->MCR & CAN_MCR_SOFTRST_MASK)) && (u32TimeoutCount > 0U))
{
u32TimeoutCount--;
}
/* Step7A: Poll the MCR register until the Freeze Acknowledge (FRZACK) bit is set. */
u32TimeoutCount = (uint32_t)FLEXCAN_WAIT_TIMEOUT;
while ((0U == (base->MCR & CAN_MCR_FRZACK_MASK)) && (u32TimeoutCount > 0U))
{
u32TimeoutCount--;
}
/* Step8A: reconfig MCR. */
base->MCR = u32TempMCR;
/* Step9A: reconfig IMASK. */
base->IMASK1 = u32TempIMASK1;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
base->IMASK2 = u32TempIMASK2;
#endif
}
}
#elif (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_8341) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_8341)
void FLEXCAN_EnterFreezeMode(CAN_Type *base)
{
uint32_t u32TimeoutCount = 0U;
uint32_t u32TempMCR = 0U;
uint32_t u32TempIMASK1 = 0U;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint32_t u32TempIMASK2 = 0U;
#endif
/* Step1: set FRZ and HALT bit enable in MCR. */
base->MCR |= CAN_MCR_FRZ_MASK;
base->MCR |= CAN_MCR_HALT_MASK;
/* Step2: to check if MDIS bit set in MCR. if yes, clear it. */
if (0U != (base->MCR & CAN_MCR_MDIS_MASK))
{
base->MCR &= ~CAN_MCR_MDIS_MASK;
}
/* Step3: Poll the MCR register until the Freeze Acknowledge (FRZACK) bit is set. */
u32TimeoutCount = (uint32_t)FLEXCAN_WAIT_TIMEOUT * 100U;
while ((0U == (base->MCR & CAN_MCR_FRZACK_MASK)) && (u32TimeoutCount > 0U))
{
u32TimeoutCount--;
}
/* Step4: check whether the timeout reached. if no skip step5 to step8. */
if (0U == u32TimeoutCount)
{
/* backup MCR and IMASK register. Errata document not descript it, but we need backup for step 8A and 9A. */
u32TempMCR = base->MCR;
u32TempIMASK1 = base->IMASK1;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
u32TempIMASK2 = base->IMASK2;
#endif
/* Step5: Set the Soft Reset bit ((SOFTRST) in the MCR.*/
base->MCR |= CAN_MCR_SOFTRST_MASK;
/* Step6: Poll the MCR register until the Soft Reset (SOFTRST) bit is cleared. */
while (CAN_MCR_SOFTRST_MASK == (base->MCR & CAN_MCR_SOFTRST_MASK))
{
}
/* Step7: reconfig MCR. */
base->MCR = u32TempMCR;
/* Step8: reconfig IMASK. */
base->IMASK1 = u32TempIMASK1;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
base->IMASK2 = u32TempIMASK2;
#endif
}
}
#else
void FLEXCAN_EnterFreezeMode(CAN_Type *base)
{
/* Set Freeze, Halt bits. */
base->MCR |= CAN_MCR_FRZ_MASK;
base->MCR |= CAN_MCR_HALT_MASK;
while (0U == (base->MCR & CAN_MCR_FRZACK_MASK))
{
}
}
#endif
void FLEXCAN_ExitFreezeMode(CAN_Type *base)
{
#if (defined(FSL_FEATURE_FLEXCAN_HAS_MEMORY_ERROR_CONTROL) && FSL_FEATURE_FLEXCAN_HAS_MEMORY_ERROR_CONTROL)
/* Enable to update in MCER. */
base->CTRL2 |= CAN_CTRL2_ECRWRE_MASK;
base->MECR &= ~CAN_MECR_ECRWRDIS_MASK;
#endif
/* Clear Freeze, Halt bits. */
base->MCR &= ~CAN_MCR_HALT_MASK;
base->MCR &= ~CAN_MCR_FRZ_MASK;
/* Wait until the FlexCAN Module exit freeze mode. */
while (0U != (base->MCR & CAN_MCR_FRZACK_MASK))
{
}
}
#if !defined(NDEBUG)
static bool FLEXCAN_IsMbOccupied(CAN_Type *base, uint8_t mbIdx)
{
uint8_t lastOccupiedMb;
bool fgRet;
/* Is Rx FIFO enabled? */
if (0U != (base->MCR & CAN_MCR_RFEN_MASK))
{
/* Get RFFN value. */
lastOccupiedMb = (uint8_t)((base->CTRL2 & CAN_CTRL2_RFFN_MASK) >> CAN_CTRL2_RFFN_SHIFT);
/* Calculate the number of last Message Buffer occupied by Rx FIFO. */
lastOccupiedMb = ((lastOccupiedMb + 1U) * 2U) + 5U;
#if ((defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) || \
(defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829))
/* the first valid MB should be occupied by ERRATA 5461 or 5829. */
lastOccupiedMb += 1U;
#endif
fgRet = (mbIdx <= lastOccupiedMb);
}
else
{
#if ((defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) || \
(defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829))
if (0U == mbIdx)
{
fgRet = true;
}
else
#endif
{
fgRet = false;
}
}
return fgRet;
}
#endif
#if ((defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) || \
(defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829))
static uint8_t FLEXCAN_GetFirstValidMb(CAN_Type *base)
{
uint8_t firstValidMbNum;
if (0U != (base->MCR & CAN_MCR_RFEN_MASK))
{
firstValidMbNum = (uint8_t)((base->CTRL2 & CAN_CTRL2_RFFN_MASK) >> CAN_CTRL2_RFFN_SHIFT);
firstValidMbNum = ((firstValidMbNum + 1U) * 2U) + 6U;
}
else
{
firstValidMbNum = 0U;
}
return firstValidMbNum;
}
#endif
static bool FLEXCAN_IsMbIntEnabled(CAN_Type *base, uint8_t mbIdx)
{
/* Assertion. */
assert(mbIdx < (uint8_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base));
uint32_t flag = 1U;
bool fgRet = false;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
if (mbIdx >= 32U)
{
fgRet = (0U != (base->IMASK2 & (flag << (mbIdx - 32U))));
}
else
#endif
{
fgRet = (0U != (base->IMASK1 & (flag << mbIdx)));
}
return fgRet;
}
static void FLEXCAN_Reset(CAN_Type *base)
{
/* The module must should be first exit from low power
* mode, and then soft reset can be applied.
*/
assert(0U == (base->MCR & CAN_MCR_MDIS_MASK));
uint8_t i;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT) && FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT)
if (0 != (FSL_FEATURE_FLEXCAN_INSTANCE_HAS_DOZE_MODE_SUPPORTn(base)))
{
/* De-assert DOZE Enable Bit. */
base->MCR &= ~CAN_MCR_DOZE_MASK;
}
#endif
/* Wait until FlexCAN exit from any Low Power Mode. */
while (0U != (base->MCR & CAN_MCR_LPMACK_MASK))
{
}
/* Assert Soft Reset Signal. */
base->MCR |= CAN_MCR_SOFTRST_MASK;
/* Wait until FlexCAN reset completes. */
while (0U != (base->MCR & CAN_MCR_SOFTRST_MASK))
{
}
/* Reset MCR register. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_GLITCH_FILTER) && FSL_FEATURE_FLEXCAN_HAS_GLITCH_FILTER)
base->MCR |= CAN_MCR_WRNEN_MASK | CAN_MCR_WAKSRC_MASK |
CAN_MCR_MAXMB((uint32_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base) - 1U);
#else
base->MCR |=
CAN_MCR_WRNEN_MASK | CAN_MCR_MAXMB((uint32_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base) - 1U);
#endif
/* Reset CTRL1 and CTRL2 register. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/* SMP bit cannot be asserted when CAN FD is enabled */
if (0 != FSL_FEATURE_FLEXCAN_INSTANCE_HAS_FLEXIBLE_DATA_RATEn(base))
{
base->CTRL1 = 0x0;
}
else
{
base->CTRL1 = CAN_CTRL1_SMP_MASK;
}
#else
base->CTRL1 = CAN_CTRL1_SMP_MASK;
#endif
base->CTRL2 = CAN_CTRL2_TASD(0x16) | CAN_CTRL2_RRS_MASK | CAN_CTRL2_EACEN_MASK;
/* Clean all individual Rx Mask of Message Buffers. */
for (i = 0; i < (uint32_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base); i++)
{
base->RXIMR[i] = 0x3FFFFFFF;
}
/* Clean Global Mask of Message Buffers. */
base->RXMGMASK = 0x3FFFFFFF;
/* Clean Global Mask of Message Buffer 14. */
base->RX14MASK = 0x3FFFFFFF;
/* Clean Global Mask of Message Buffer 15. */
base->RX15MASK = 0x3FFFFFFF;
/* Clean Global Mask of Rx FIFO. */
base->RXFGMASK = 0x3FFFFFFF;
/* Clean all Message Buffer CS fields. */
for (i = 0; i < (uint32_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base); i++)
{
base->MB[i].CS = 0x0;
}
}
static void FLEXCAN_SetBaudRate(CAN_Type *base,
uint32_t sourceClock_Hz,
uint32_t baudRate_Bps,
flexcan_timing_config_t timingConfig)
{
/* FlexCAN timing setting formula:
* quantum = 1 + (PSEG1 + 1) + (PSEG2 + 1) + (PROPSEG + 1);
*/
uint32_t quantum = (1U + ((uint32_t)timingConfig.phaseSeg1 + 1U) + ((uint32_t)timingConfig.phaseSeg2 + 1U) +
((uint32_t)timingConfig.propSeg + 1U));
uint32_t priDiv = baudRate_Bps * quantum;
/* Assertion: Desired baud rate is too high. */
assert(baudRate_Bps <= 1000000U);
/* Assertion: Source clock should greater than baud rate * quantum. */
assert(priDiv <= sourceClock_Hz);
if (0U == priDiv)
{
priDiv = 1;
}
priDiv = (sourceClock_Hz / priDiv) - 1U;
/* Desired baud rate is too low. */
if (priDiv > 0xFFU)
{
priDiv = 0xFF;
}
timingConfig.preDivider = (uint16_t)priDiv;
/* Update actual timing characteristic. */
FLEXCAN_SetTimingConfig(base, (const flexcan_timing_config_t *)(uint32_t)&timingConfig);
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
static void FLEXCAN_SetFDBaudRate(CAN_Type *base,
uint32_t sourceClock_Hz,
uint32_t baudRateFD_Bps,
flexcan_timing_config_t timingConfig)
{
/* FlexCAN FD timing setting formula:
* quantum = 1 + (FPSEG1 + 1) + (FPSEG2 + 1) + FPROPSEG;
*/
uint32_t quantum = (1U + ((uint32_t)timingConfig.fphaseSeg1 + 1U) + ((uint32_t)timingConfig.fphaseSeg2 + 1U) +
(uint32_t)timingConfig.fpropSeg);
uint32_t priDiv = baudRateFD_Bps * quantum;
/* Assertion: Desired baud rate is too high. */
assert(baudRateFD_Bps <= 8000000U);
/* Assertion: Source clock should greater than baud rate * FLEXCAN_TIME_QUANTA_NUM. */
assert(priDiv <= sourceClock_Hz);
if (0U == priDiv)
{
priDiv = 1;
}
priDiv = (sourceClock_Hz / priDiv) - 1U;
/* Desired baud rate is too low. */
if (priDiv > 0xFFU)
{
priDiv = 0xFF;
}
timingConfig.fpreDivider = (uint16_t)priDiv;
/* Update actual timing characteristic. */
FLEXCAN_SetFDTimingConfig(base, (const flexcan_timing_config_t *)(uint32_t)&timingConfig);
}
#endif
/*!
* brief Initializes a FlexCAN instance.
*
* This function initializes the FlexCAN module with user-defined settings.
* This example shows how to set up the flexcan_config_t parameters and how
* to call the FLEXCAN_Init function by passing in these parameters.
* code
* flexcan_config_t flexcanConfig;
* flexcanConfig.clkSrc = kFLEXCAN_ClkSrc0;
* flexcanConfig.baudRate = 1000000U;
* flexcanConfig.maxMbNum = 16;
* flexcanConfig.enableLoopBack = false;
* flexcanConfig.enableSelfWakeup = false;
* flexcanConfig.enableIndividMask = false;
* flexcanConfig.disableSelfReception = false;
* flexcanConfig.enableListenOnlyMode = false;
* flexcanConfig.enableDoze = false;
* flexcanConfig.timingConfig = timingConfig;
* FLEXCAN_Init(CAN0, &flexcanConfig, 8000000UL);
* endcode
*
* param base FlexCAN peripheral base address.
* param pConfig Pointer to the user-defined configuration structure.
* param sourceClock_Hz FlexCAN Protocol Engine clock source frequency in Hz.
*/
void FLEXCAN_Init(CAN_Type *base, const flexcan_config_t *pConfig, uint32_t sourceClock_Hz)
{
/* Assertion. */
assert(NULL != pConfig);
assert((pConfig->maxMbNum > 0U) &&
(pConfig->maxMbNum <= (uint8_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base)));
uint32_t mcrTemp;
uint32_t ctrl1Temp;
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
uint32_t instance;
#endif
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
instance = FLEXCAN_GetInstance(base);
/* Enable FlexCAN clock. */
(void)CLOCK_EnableClock(s_flexcanClock[instance]);
/*
* Check the CAN clock in this device whether affected by Other clock gate
* If it affected, we'd better to change other clock source,
* If user insist on using that clock source, user need open these gate at same time,
* In this scene, User need to care the power consumption.
*/
assert(CAN_CLOCK_CHECK_NO_AFFECTS);
#if defined(FLEXCAN_PERIPH_CLOCKS)
/* Enable FlexCAN serial clock. */
(void)CLOCK_EnableClock(s_flexcanPeriphClock[instance]);
#endif /* FLEXCAN_PERIPH_CLOCKS */
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
#if defined(CAN_CTRL1_CLKSRC_MASK)
#if (defined(FSL_FEATURE_FLEXCAN_SUPPORT_ENGINE_CLK_SEL_REMOVE) && FSL_FEATURE_FLEXCAN_SUPPORT_ENGINE_CLK_SEL_REMOVE)
if (0 == FSL_FEATURE_FLEXCAN_INSTANCE_SUPPORT_ENGINE_CLK_SEL_REMOVEn(base))
#endif /* FSL_FEATURE_FLEXCAN_SUPPORT_ENGINE_CLK_SEL_REMOVE */
{
/* Disable FlexCAN Module. */
FLEXCAN_Enable(base, false);
/* Protocol-Engine clock source selection, This bit must be set
* when FlexCAN Module in Disable Mode.
*/
base->CTRL1 = (kFLEXCAN_ClkSrc0 == pConfig->clkSrc) ? (base->CTRL1 & ~CAN_CTRL1_CLKSRC_MASK) :
(base->CTRL1 | CAN_CTRL1_CLKSRC_MASK);
}
#endif /* CAN_CTRL1_CLKSRC_MASK */
/* Enable FlexCAN Module for configuration. */
FLEXCAN_Enable(base, true);
/* Reset to known status. */
FLEXCAN_Reset(base);
/* Save current CTRL1 value and enable to enter Freeze mode(enabled by default). */
ctrl1Temp = base->CTRL1;
/* Save current MCR value and enable to enter Freeze mode(enabled by default). */
mcrTemp = base->MCR;
/* Enable Loop Back Mode? */
ctrl1Temp = (pConfig->enableLoopBack) ? (ctrl1Temp | CAN_CTRL1_LPB_MASK) : (ctrl1Temp & ~CAN_CTRL1_LPB_MASK);
/* Enable Timer Sync? */
ctrl1Temp = (pConfig->enableTimerSync) ? (ctrl1Temp | CAN_CTRL1_TSYN_MASK) : (ctrl1Temp & ~CAN_CTRL1_TSYN_MASK);
/* Enable Listen Only Mode? */
ctrl1Temp = (pConfig->enableListenOnlyMode) ? ctrl1Temp | CAN_CTRL1_LOM_MASK : ctrl1Temp & ~CAN_CTRL1_LOM_MASK;
/* Set the maximum number of Message Buffers */
mcrTemp = (mcrTemp & ~CAN_MCR_MAXMB_MASK) | CAN_MCR_MAXMB((uint32_t)pConfig->maxMbNum - 1U);
/* Enable Self Wake Up Mode and configure the wake up source. */
mcrTemp = (pConfig->enableSelfWakeup) ? (mcrTemp | CAN_MCR_SLFWAK_MASK) : (mcrTemp & ~CAN_MCR_SLFWAK_MASK);
mcrTemp = (kFLEXCAN_WakeupSrcFiltered == pConfig->wakeupSrc) ? (mcrTemp | CAN_MCR_WAKSRC_MASK) :
(mcrTemp & ~CAN_MCR_WAKSRC_MASK);
/* Enable Individual Rx Masking? */
mcrTemp = (pConfig->enableIndividMask) ? (mcrTemp | CAN_MCR_IRMQ_MASK) : (mcrTemp & ~CAN_MCR_IRMQ_MASK);
/* Disable Self Reception? */
mcrTemp = (pConfig->disableSelfReception) ? mcrTemp | CAN_MCR_SRXDIS_MASK : mcrTemp & ~CAN_MCR_SRXDIS_MASK;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT) && FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT)
if (0 != FSL_FEATURE_FLEXCAN_INSTANCE_HAS_DOZE_MODE_SUPPORTn(base))
{
/* Enable Doze Mode? */
mcrTemp = (pConfig->enableDoze) ? (mcrTemp | CAN_MCR_DOZE_MASK) : (mcrTemp & ~CAN_MCR_DOZE_MASK);
}
#endif
/* Write back CTRL1 Configuration to register. */
base->CTRL1 = ctrl1Temp;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_MEMORY_ERROR_CONTROL) && FSL_FEATURE_FLEXCAN_HAS_MEMORY_ERROR_CONTROL)
/* Enable to update in MCER. */
base->CTRL2 |= CAN_CTRL2_ECRWRE_MASK;
base->MECR &= ~CAN_MECR_ECRWRDIS_MASK;
#endif
/* Write back MCR Configuration to register. */
base->MCR = mcrTemp;
/* Baud Rate Configuration.*/
FLEXCAN_SetBaudRate(base, sourceClock_Hz, pConfig->baudRate, pConfig->timingConfig);
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/*!
* brief Initializes a FlexCAN instance.
*
* This function initializes the FlexCAN module with user-defined settings.
* This example shows how to set up the flexcan_config_t parameters and how
* to call the FLEXCAN_FDInit function by passing in these parameters.
* code
* flexcan_config_t flexcanConfig;
* flexcanConfig.clkSrc = kFLEXCAN_ClkSrc0;
* flexcanConfig.baudRate = 1000000U;
* flexcanConfig.baudRateFD = 2000000U;
* flexcanConfig.maxMbNum = 16;
* flexcanConfig.enableLoopBack = false;
* flexcanConfig.enableSelfWakeup = false;
* flexcanConfig.enableIndividMask = false;
* flexcanConfig.disableSelfReception = false;
* flexcanConfig.enableListenOnlyMode = false;
* flexcanConfig.enableDoze = false;
* flexcanConfig.timingConfig = timingConfig;
* FLEXCAN_FDInit(CAN0, &flexcanConfig, 8000000UL, kFLEXCAN_16BperMB, false);
* endcode
*
* param base FlexCAN peripheral base address.
* param pConfig Pointer to the user-defined configuration structure.
* param sourceClock_Hz FlexCAN Protocol Engine clock source frequency in Hz.
* param dataSize FlexCAN FD frame payload size.
* param brs If bitrate switch is enabled in FD mode.
*/
void FLEXCAN_FDInit(
CAN_Type *base, const flexcan_config_t *pConfig, uint32_t sourceClock_Hz, flexcan_mb_size_t dataSize, bool brs)
{
assert((uint32_t)dataSize <= 3U);
uint32_t fdctrl = 0U;
/* Initialization of classical CAN. */
FLEXCAN_Init(base, pConfig, sourceClock_Hz);
/* Extra bitrate setting for CANFD. */
FLEXCAN_SetFDBaudRate(base, sourceClock_Hz, pConfig->baudRateFD, pConfig->timingConfig);
/* read FDCTRL register. */
fdctrl = base->FDCTRL;
/* Enable FD operation and set bitrate switch. */
if (brs)
{
fdctrl |= CAN_FDCTRL_FDRATE_MASK;
}
else
{
fdctrl &= ~CAN_FDCTRL_FDRATE_MASK;
}
if (brs && !(pConfig->enableLoopBack))
{
/* Before use "|=" operation for multi-bits field, CPU should Clean previous Setting. */
fdctrl = (fdctrl & ~CAN_FDCTRL_TDCOFF_MASK) | CAN_FDCTRL_TDCOFF(0x2U);
}
/* Before use "|=" operation for multi-bits field, CPU should clean previous Setting. */
fdctrl = (fdctrl & ~CAN_FDCTRL_MBDSR0_MASK) | CAN_FDCTRL_MBDSR0(dataSize);
#if defined(CAN_FDCTRL_MBDSR1_MASK)
fdctrl = (fdctrl & ~CAN_FDCTRL_MBDSR1_MASK) | CAN_FDCTRL_MBDSR1(dataSize);
#endif
#if defined(CAN_FDCTRL_MBDSR2_MASK)
fdctrl = (fdctrl & ~CAN_FDCTRL_MBDSR2_MASK) | CAN_FDCTRL_MBDSR2(dataSize);
#endif
#if defined(CAN_FDCTRL_MBDSR3_MASK)
fdctrl = (fdctrl & ~CAN_FDCTRL_MBDSR3_MASK) | CAN_FDCTRL_MBDSR3(dataSize);
#endif
/* Enter Freeze Mode. */
FLEXCAN_EnterFreezeMode(base);
base->MCR |= CAN_MCR_FDEN_MASK;
/* update the FDCTL register. */
base->FDCTRL = fdctrl;
/* Exit Freeze Mode. */
FLEXCAN_ExitFreezeMode(base);
}
#endif
/*!
* brief De-initializes a FlexCAN instance.
*
* This function disables the FlexCAN module clock and sets all register values
* to the reset value.
*
* param base FlexCAN peripheral base address.
*/
void FLEXCAN_Deinit(CAN_Type *base)
{
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
uint32_t instance;
#endif
/* Reset all Register Contents. */
FLEXCAN_Reset(base);
/* Disable FlexCAN module. */
FLEXCAN_Enable(base, false);
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
instance = FLEXCAN_GetInstance(base);
#if defined(FLEXCAN_PERIPH_CLOCKS)
/* Disable FlexCAN serial clock. */
(void)CLOCK_DisableClock(s_flexcanPeriphClock[instance]);
#endif /* FLEXCAN_PERIPH_CLOCKS */
/* Disable FlexCAN clock. */
(void)CLOCK_DisableClock(s_flexcanClock[instance]);
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
}
/*!
* brief Gets the default configuration structure.
*
* This function initializes the FlexCAN configuration structure to default values. The default
* values are as follows.
* flexcanConfig->clkSrc = kFLEXCAN_ClkSrc0;
* flexcanConfig->baudRate = 1000000U;
* flexcanConfig->baudRateFD = 2000000U;
* flexcanConfig->maxMbNum = 16;
* flexcanConfig->enableLoopBack = false;
* flexcanConfig->enableSelfWakeup = false;
* flexcanConfig->enableIndividMask = false;
* flexcanConfig->disableSelfReception = false;
* flexcanConfig->enableListenOnlyMode = false;
* flexcanConfig->enableDoze = false;
* flexcanConfig.timingConfig = timingConfig;
*
* param pConfig Pointer to the FlexCAN configuration structure.
*/
void FLEXCAN_GetDefaultConfig(flexcan_config_t *pConfig)
{
/* Assertion. */
assert(NULL != pConfig);
/* Initializes the configure structure to zero. */
(void)memset(pConfig, 0, sizeof(*pConfig));
/* Initialize FlexCAN Module config struct with default value. */
pConfig->clkSrc = kFLEXCAN_ClkSrc0;
pConfig->baudRate = 1000000U;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
pConfig->baudRateFD = 2000000U;
#endif
pConfig->maxMbNum = 16;
pConfig->enableLoopBack = false;
pConfig->enableTimerSync = true;
pConfig->enableSelfWakeup = false;
pConfig->wakeupSrc = kFLEXCAN_WakeupSrcUnfiltered;
pConfig->enableIndividMask = false;
pConfig->disableSelfReception = false;
pConfig->enableListenOnlyMode = false;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT) && FSL_FEATURE_FLEXCAN_HAS_DOZE_MODE_SUPPORT)
pConfig->enableDoze = false;
#endif
/* Default protocol timing configuration, time quantum is 10. */
pConfig->timingConfig.phaseSeg1 = 3;
pConfig->timingConfig.phaseSeg2 = 2;
pConfig->timingConfig.propSeg = 1;
pConfig->timingConfig.rJumpwidth = 1;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
pConfig->timingConfig.fphaseSeg1 = 3;
pConfig->timingConfig.fphaseSeg2 = 3;
pConfig->timingConfig.fpropSeg = 1;
pConfig->timingConfig.frJumpwidth = 1;
#endif
}
/*!
* brief Sets the FlexCAN protocol timing characteristic.
*
* This function gives user settings to CAN bus timing characteristic.
* The function is for an experienced user. For less experienced users, call
* the FLEXCAN_Init() and fill the baud rate field with a desired value.
* This provides the default timing characteristics to the module.
*
* Note that calling FLEXCAN_SetTimingConfig() overrides the baud rate set
* in FLEXCAN_Init().
*
* param base FlexCAN peripheral base address.
* param pConfig Pointer to the timing configuration structure.
*/
void FLEXCAN_SetTimingConfig(CAN_Type *base, const flexcan_timing_config_t *pConfig)
{
/* Assertion. */
assert(NULL != pConfig);
/* Enter Freeze Mode. */
FLEXCAN_EnterFreezeMode(base);
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
if (0 != FSL_FEATURE_FLEXCAN_INSTANCE_HAS_FLEXIBLE_DATA_RATEn(base))
{
/* Cleaning previous Timing Setting. */
base->CBT &= ~(CAN_CBT_EPRESDIV_MASK | CAN_CBT_ERJW_MASK | CAN_CBT_EPSEG1_MASK | CAN_CBT_EPSEG2_MASK |
CAN_CBT_EPROPSEG_MASK);
/* Updating Timing Setting according to configuration structure. */
base->CBT |= (CAN_CBT_EPRESDIV(pConfig->preDivider) | CAN_CBT_ERJW(pConfig->rJumpwidth) |
CAN_CBT_EPSEG1(pConfig->phaseSeg1) | CAN_CBT_EPSEG2(pConfig->phaseSeg2) |
CAN_CBT_EPROPSEG(pConfig->propSeg));
}
else
{
/* Cleaning previous Timing Setting. */
base->CTRL1 &= ~(CAN_CTRL1_PRESDIV_MASK | CAN_CTRL1_RJW_MASK | CAN_CTRL1_PSEG1_MASK | CAN_CTRL1_PSEG2_MASK |
CAN_CTRL1_PROPSEG_MASK);
/* Updating Timing Setting according to configuration structure. */
base->CTRL1 |= (CAN_CTRL1_PRESDIV(pConfig->preDivider) | CAN_CTRL1_RJW(pConfig->rJumpwidth) |
CAN_CTRL1_PSEG1(pConfig->phaseSeg1) | CAN_CTRL1_PSEG2(pConfig->phaseSeg2) |
CAN_CTRL1_PROPSEG(pConfig->propSeg));
}
#else
/* Cleaning previous Timing Setting. */
base->CTRL1 &= ~(CAN_CTRL1_PRESDIV_MASK | CAN_CTRL1_RJW_MASK | CAN_CTRL1_PSEG1_MASK | CAN_CTRL1_PSEG2_MASK |
CAN_CTRL1_PROPSEG_MASK);
/* Updating Timing Setting according to configuration structure. */
base->CTRL1 |= (CAN_CTRL1_PRESDIV(pConfig->preDivider) | CAN_CTRL1_RJW(pConfig->rJumpwidth) |
CAN_CTRL1_PSEG1(pConfig->phaseSeg1) | CAN_CTRL1_PSEG2(pConfig->phaseSeg2) |
CAN_CTRL1_PROPSEG(pConfig->propSeg));
#endif
/* Exit Freeze Mode. */
FLEXCAN_ExitFreezeMode(base);
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/*!
* brief Sets the FlexCAN FD protocol timing characteristic.
*
* This function gives user settings to CAN bus timing characteristic.
* The function is for an experienced user. For less experienced users, call
* the FLEXCAN_Init() and fill the baud rate field with a desired value.
* This provides the default timing characteristics to the module.
*
* Note that calling FLEXCAN_SetFDTimingConfig() overrides the baud rate set
* in FLEXCAN_Init().
*
* param base FlexCAN peripheral base address.
* param pConfig Pointer to the timing configuration structure.
*/
void FLEXCAN_SetFDTimingConfig(CAN_Type *base, const flexcan_timing_config_t *pConfig)
{
/* Assertion. */
assert(NULL != pConfig);
/* Enter Freeze Mode. */
FLEXCAN_EnterFreezeMode(base);
base->CBT |= CAN_CBT_BTF(1);
/* Cleaning previous Timing Setting. */
base->FDCBT &= ~(CAN_FDCBT_FPRESDIV_MASK | CAN_FDCBT_FRJW_MASK | CAN_FDCBT_FPSEG1_MASK | CAN_FDCBT_FPSEG2_MASK |
CAN_FDCBT_FPROPSEG_MASK);
/* Updating Timing Setting according to configuration structure. */
base->FDCBT |= (CAN_FDCBT_FPRESDIV(pConfig->fpreDivider) | CAN_FDCBT_FRJW(pConfig->frJumpwidth) |
CAN_FDCBT_FPSEG1(pConfig->fphaseSeg1) | CAN_FDCBT_FPSEG2(pConfig->fphaseSeg2) |
CAN_FDCBT_FPROPSEG(pConfig->fpropSeg));
/* Exit Freeze Mode. */
FLEXCAN_ExitFreezeMode(base);
}
#endif
/*!
* brief Sets the FlexCAN receive message buffer global mask.
*
* This function sets the global mask for the FlexCAN message buffer in a matching process.
* The configuration is only effective when the Rx individual mask is disabled in the FLEXCAN_Init().
*
* param base FlexCAN peripheral base address.
* param mask Rx Message Buffer Global Mask value.
*/
void FLEXCAN_SetRxMbGlobalMask(CAN_Type *base, uint32_t mask)
{
/* Enter Freeze Mode. */
FLEXCAN_EnterFreezeMode(base);
/* Setting Rx Message Buffer Global Mask value. */
base->RXMGMASK = mask;
base->RX14MASK = mask;
base->RX15MASK = mask;
/* Exit Freeze Mode. */
FLEXCAN_ExitFreezeMode(base);
}
/*!
* brief Sets the FlexCAN receive FIFO global mask.
*
* This function sets the global mask for FlexCAN FIFO in a matching process.
*
* param base FlexCAN peripheral base address.
* param mask Rx Fifo Global Mask value.
*/
void FLEXCAN_SetRxFifoGlobalMask(CAN_Type *base, uint32_t mask)
{
/* Enter Freeze Mode. */
FLEXCAN_EnterFreezeMode(base);
/* Setting Rx FIFO Global Mask value. */
base->RXFGMASK = mask;
/* Exit Freeze Mode. */
FLEXCAN_ExitFreezeMode(base);
}
/*!
* brief Sets the FlexCAN receive individual mask.
*
* This function sets the individual mask for the FlexCAN matching process.
* The configuration is only effective when the Rx individual mask is enabled in the FLEXCAN_Init().
* If the Rx FIFO is disabled, the individual mask is applied to the corresponding Message Buffer.
* If the Rx FIFO is enabled, the individual mask for Rx FIFO occupied Message Buffer is applied to
* the Rx Filter with the same index. Note that only the first 32
* individual masks can be used as the Rx FIFO filter mask.
*
* param base FlexCAN peripheral base address.
* param maskIdx The Index of individual Mask.
* param mask Rx Individual Mask value.
*/
void FLEXCAN_SetRxIndividualMask(CAN_Type *base, uint8_t maskIdx, uint32_t mask)
{
assert(maskIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
/* Enter Freeze Mode. */
FLEXCAN_EnterFreezeMode(base);
/* Setting Rx Individual Mask value. */
base->RXIMR[maskIdx] = mask;
/* Exit Freeze Mode. */
FLEXCAN_ExitFreezeMode(base);
}
/*!
* brief Configures a FlexCAN transmit message buffer.
*
* This function aborts the previous transmission, cleans the Message Buffer, and
* configures it as a Transmit Message Buffer.
*
* param base FlexCAN peripheral base address.
* param mbIdx The Message Buffer index.
* param enable Enable/disable Tx Message Buffer.
* - true: Enable Tx Message Buffer.
* - false: Disable Tx Message Buffer.
*/
void FLEXCAN_SetTxMbConfig(CAN_Type *base, uint8_t mbIdx, bool enable)
{
/* Assertion. */
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
/* Inactivate Message Buffer. */
if (enable)
{
base->MB[mbIdx].CS = CAN_CS_CODE(kFLEXCAN_TxMbInactive);
}
else
{
base->MB[mbIdx].CS = 0;
}
/* Clean Message Buffer content. */
base->MB[mbIdx].ID = 0x0;
base->MB[mbIdx].WORD0 = 0x0;
base->MB[mbIdx].WORD1 = 0x0;
}
/*!
* @brief Calculates the segment values for a single bit time for classical CAN
*
* @param baudRate The data speed in bps
* @param tqNum Number of time quantas per bit
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if Calculates the segment success, FALSE if Calculates the segment success
*/
static bool FLEXCAN_GetSegments(uint32_t baudRate, uint32_t tqNum, flexcan_timing_config_t *pTimingConfig)
{
uint32_t ideal_sp;
uint32_t p1;
bool fgRet = false;
/* Get ideal sample point. For the Bit field in CTRL1 register can't calculate higher ideal SP, we set it as the
* lowest one(75%).*/
ideal_sp = IDEAL_SP_LOW;
/* distribute time quanta. */
p1 = tqNum * (uint32_t)ideal_sp;
pTimingConfig->propSeg = (uint8_t)(p1 / (uint32_t)IDEAL_SP_FACTOR - 2U);
if (pTimingConfig->propSeg <= (MAX_PSEG1 + MAX_PROPSEG))
{
if (pTimingConfig->propSeg > MAX_PROPSEG)
{
pTimingConfig->phaseSeg1 = pTimingConfig->propSeg - MAX_PROPSEG;
pTimingConfig->propSeg = MAX_PROPSEG;
}
else
{
pTimingConfig->phaseSeg1 = 0;
}
/* The value of prog Seg should be not larger than tqNum -4U. */
if ((pTimingConfig->propSeg + pTimingConfig->phaseSeg1) < ((uint8_t)tqNum - 4U))
{
pTimingConfig->phaseSeg2 = (uint8_t)tqNum - (pTimingConfig->phaseSeg1 + pTimingConfig->propSeg + 4U);
if (pTimingConfig->phaseSeg2 <= MAX_PSEG1)
{
if ((pTimingConfig->phaseSeg1 < pTimingConfig->phaseSeg2) &&
(pTimingConfig->propSeg > (pTimingConfig->phaseSeg2 - pTimingConfig->phaseSeg1)))
{
pTimingConfig->propSeg -= (pTimingConfig->phaseSeg2 - pTimingConfig->phaseSeg1);
pTimingConfig->phaseSeg1 = pTimingConfig->phaseSeg2;
}
/* subtract one TQ for sync seg. */
/* sjw is 20% of total TQ, rounded to nearest int. */
pTimingConfig->rJumpwidth = ((uint8_t)tqNum + 4U) / 5U - 1U;
/* The max tqNum for CBT will reach to 129, ERJW would not be larger than 26. */
/* Considering that max ERJW is 31, rJumpwidth will always be smaller than MAX_ERJW. */
if (pTimingConfig->rJumpwidth > MAX_RJW)
{
pTimingConfig->rJumpwidth = MAX_RJW;
}
fgRet = true;
}
}
}
return fgRet;
}
/*!
* @brief Calculates the improved timing values by specific baudrates for classical CAN
*
* @param baudRate The classical CAN speed in bps defined by user
* @param sourceClock_Hz The Source clock data speed in bps. Zero to disable baudrate switching
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if timing configuration found, FALSE if failed to find configuration
*/
bool FLEXCAN_CalculateImprovedTimingValues(uint32_t baudRate,
uint32_t sourceClock_Hz,
flexcan_timing_config_t *pTimingConfig)
{
/* observe baud rate maximums. */
assert(baudRate <= MAX_CAN_BAUDRATE);
uint32_t clk; /* the clock is tqNumb x baudRateFD. */
uint32_t tqNum; /* Numbers of TQ. */
bool fgRet = false;
/* Auto Improved Protocal timing for CTRL1. */
tqNum = CTRL1_MAX_TIME_QUANTA;
do
{
clk = baudRate * tqNum;
if (clk > sourceClock_Hz)
{
continue; /* tqNum too large, clk has been exceed sourceClock_Hz. */
}
if ((sourceClock_Hz / clk * clk) != sourceClock_Hz)
{
continue; /* Non-supporting: the frequency of clock source is not divisible by target baud rate, the user
should change a divisible baud rate. */
}
pTimingConfig->preDivider = (uint16_t)(sourceClock_Hz / clk) - 1U;
if (pTimingConfig->preDivider > MAX_PRESDIV)
{
break; /* The frequency of source clock is too large or the baud rate is too small, the pre-divider could
not handle it. */
}
/* Try to get the best timing configuration. */
if (FLEXCAN_GetSegments(baudRate, tqNum, pTimingConfig))
{
fgRet = true;
break;
}
} while (--tqNum >= CTRL1_MIN_TIME_QUANTA);
return fgRet;
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
static uint32_t FLEXCAN_GetFDMailboxOffset(CAN_Type *base, uint8_t mbIdx)
{
uint32_t offset = 0;
uint32_t dataSize = (base->FDCTRL & CAN_FDCTRL_MBDSR0_MASK) >> CAN_FDCTRL_MBDSR0_SHIFT;
switch (dataSize)
{
case (uint32_t)kFLEXCAN_8BperMB:
offset = (((uint32_t)mbIdx / 32U) * 512U + ((uint32_t)mbIdx % 32U) * 16U);
break;
case (uint32_t)kFLEXCAN_16BperMB:
offset = (((uint32_t)mbIdx / 21U) * 512U + ((uint32_t)mbIdx % 21U) * 24U);
break;
case (uint32_t)kFLEXCAN_32BperMB:
offset = (((uint32_t)mbIdx / 12U) * 512U + ((uint32_t)mbIdx % 12U) * 40U);
break;
case (uint32_t)kFLEXCAN_64BperMB:
offset = (((uint32_t)mbIdx / 7U) * 512U + ((uint32_t)mbIdx % 7U) * 72U);
break;
default:
/* All the cases have been listed above, the default clause should not be reached. */
assert(false);
break;
}
/* To get the dword aligned offset, need to divide by 4. */
offset = offset / 4U;
return offset;
}
/*!
* @brief Calculates the segment values for a single bit time for CANFD bus control baud Rate
*
* @param baudRate The canfd bus control speed in bps
* @param tqNum Number of time quanta per bit
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if Calculates the segment success, FALSE if Calculates the segment success
*/
static bool FLEXCAN_FDGetSegments(uint32_t baudRate, uint32_t tqNum, flexcan_timing_config_t *pTimingConfig)
{
uint32_t ideal_sp;
uint32_t p1;
bool fgRet = false;
/* Get ideal sample point. */
if (baudRate >= 1000000U)
{
ideal_sp = IDEAL_SP_LOW;
}
else if (baudRate >= 800000U)
{
ideal_sp = IDEAL_SP_MID;
}
else
{
ideal_sp = IDEAL_SP_HIGH;
}
/* distribute time quanta. */
p1 = tqNum * (uint32_t)ideal_sp;
pTimingConfig->propSeg = (uint8_t)(p1 / (uint32_t)IDEAL_SP_FACTOR - 2U);
if (pTimingConfig->propSeg <= (MAX_EPSEG1 + MAX_EPROPSEG))
{
if (pTimingConfig->propSeg > MAX_EPROPSEG)
{
pTimingConfig->phaseSeg1 = pTimingConfig->propSeg - MAX_EPROPSEG;
pTimingConfig->propSeg = MAX_EPROPSEG;
}
else
{
pTimingConfig->phaseSeg1 = 0;
}
/* The value of prog Seg should be not larger than tqNum -4U. */
if ((pTimingConfig->propSeg + pTimingConfig->phaseSeg1) < ((uint8_t)tqNum - 4U))
{
pTimingConfig->phaseSeg2 = (uint8_t)tqNum - (pTimingConfig->phaseSeg1 + pTimingConfig->propSeg + 4U);
if (pTimingConfig->phaseSeg2 <= MAX_EPSEG2)
{
if ((pTimingConfig->phaseSeg1 < pTimingConfig->phaseSeg2) &&
(pTimingConfig->propSeg > (pTimingConfig->phaseSeg2 - pTimingConfig->phaseSeg1)))
{
pTimingConfig->propSeg -= (pTimingConfig->phaseSeg2 - pTimingConfig->phaseSeg1);
pTimingConfig->phaseSeg1 = pTimingConfig->phaseSeg2;
}
/* subtract one TQ for sync seg. */
/* sjw is 20% of total TQ, rounded to nearest int. */
pTimingConfig->rJumpwidth = ((uint8_t)tqNum + 4U) / 5U - 1U;
/* The max tqNum for CBT will reach to 129, ERJW would not be larger than 26. */
/* Considering that max ERJW is 31, rJumpwidth will always be smaller than MAX_ERJW. */
if (pTimingConfig->rJumpwidth > MAX_ERJW)
{
pTimingConfig->rJumpwidth = MAX_ERJW;
}
fgRet = true;
}
}
}
return fgRet;
}
/*!
* @brief Calculates the segment values for a single bit time for CANFD bus data baud Rate
*
* @param baudRatebrs The canfd bus data speed in bps
* @param tqNum Number of time quanta per bit
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if Calculates the segment success, FALSE if Calculates the segment success
*/
static bool FLEXCAN_FDGetSegmentswithBRS(uint32_t baudRatebrs, uint32_t tqNum, flexcan_timing_config_t *pTimingConfig)
{
uint32_t ideal_sp;
uint32_t p1;
bool fgRet = false;
/* get ideal sample point. */
if (baudRatebrs >= 1000000U)
{
ideal_sp = IDEAL_SP_LOW;
}
else if (baudRatebrs >= 800000U)
{
ideal_sp = IDEAL_SP_MID;
}
else
{
ideal_sp = IDEAL_SP_HIGH;
}
/* distribute time quanta. */
p1 = tqNum * (uint32_t)ideal_sp;
pTimingConfig->fpropSeg = (uint8_t)(p1 / (uint32_t)IDEAL_SP_FACTOR - 1U);
if (pTimingConfig->fpropSeg <= (MAX_FPSEG1 + MAX_FPROPSEG))
{
if (pTimingConfig->fpropSeg > MAX_FPROPSEG)
{
pTimingConfig->fphaseSeg1 = pTimingConfig->fpropSeg - MAX_FPROPSEG;
pTimingConfig->fpropSeg = MAX_FPROPSEG;
}
else
{
pTimingConfig->fphaseSeg1 = 0;
}
/* The value of prog Seg should be not larger than tqNum -3U. */
if ((pTimingConfig->fpropSeg + pTimingConfig->fphaseSeg1) < ((uint8_t)tqNum - 3U))
{
pTimingConfig->fphaseSeg2 = (uint8_t)tqNum - (pTimingConfig->fphaseSeg1 + pTimingConfig->fpropSeg + 3U);
if ((pTimingConfig->fphaseSeg1 < pTimingConfig->fphaseSeg2) &&
(pTimingConfig->fpropSeg > (pTimingConfig->fphaseSeg2 - pTimingConfig->fphaseSeg1)))
{
pTimingConfig->fpropSeg -= (pTimingConfig->fphaseSeg2 - pTimingConfig->fphaseSeg1);
pTimingConfig->fphaseSeg1 = pTimingConfig->fphaseSeg2;
}
/* subtract one TQ for sync seg. */
/* sjw is 20% of total TQ, rounded to nearest int. */
pTimingConfig->frJumpwidth = ((uint8_t)tqNum + 4U) / 5U - 1U;
if (pTimingConfig->frJumpwidth > MAX_FRJW)
{
pTimingConfig->frJumpwidth = MAX_FRJW;
}
fgRet = true;
}
}
return fgRet;
}
/*!
* @brief Calculates the improved timing values by specific baudrates for CAN by CBT register
*
* @param baudRate The classical CAN speed in bps defined by user
* @param sourceClock_Hz The Source clock data speed in bps. Zero to disable baudrate switching
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if timing configuration found, FALSE if failed to find configuration
*/
static bool FLEXCAN_CalculateImprovedTimingValuesByCBT(uint32_t baudRate,
uint32_t sourceClock_Hz,
flexcan_timing_config_t *pTimingConfig)
{
/* observe baud rate maximums. */
assert(baudRate <= MAX_CAN_BAUDRATE);
uint32_t clk; /* the clock is tqNumb x baudRateFD. */
uint32_t tqNum; /* Numbers of TQ. */
bool fgRet = false;
tqNum = CBT_MAX_TIME_QUANTA;
/* Auto Improved Protocal timing. */
do
{
clk = baudRate * tqNum;
if (clk > sourceClock_Hz)
{
continue; /* tqNum too large, clk has been exceed sourceClock_Hz. */
}
if ((sourceClock_Hz / clk * clk) != sourceClock_Hz)
{
continue; /* Non-supporting: the frequency of clock source is not divisible by target baud rate, the user
should change a divisible baud rate. */
}
pTimingConfig->preDivider = (uint16_t)(sourceClock_Hz / clk) - 1U;
if (pTimingConfig->preDivider > MAX_EPRESDIV)
{
break; /* The frequency of source clock is too large or the baud rate is too small, the pre-divider could
not handle it. */
}
/* Try to get the best timing configuration. */
if (FLEXCAN_FDGetSegments(baudRate, tqNum, pTimingConfig))
{
fgRet = true;
break;
}
} while (--tqNum >= CBT_MIN_TIME_QUANTA);
return fgRet;
}
/*!
* @brief Calculates the improved timing values by specific baudrates for CANFD
*
* @param baudRate The CANFD bus control speed in bps defined by user
* @param baudRateFD The CANFD bus data speed in bps defined by user
* @param sourceClock_Hz The Source clock data speed in bps. Zero to disable baudrate switching
* @param pTimingConfig Pointer to the FlexCAN timing configuration structure.
*
* @return TRUE if timing configuration found, FALSE if failed to find configuration
*/
bool FLEXCAN_FDCalculateImprovedTimingValues(uint32_t baudRate,
uint32_t baudRateFD,
uint32_t sourceClock_Hz,
flexcan_timing_config_t *pTimingConfig)
{
/* observe baud rate maximums */
assert(baudRate <= MAX_CAN_BAUDRATE);
assert(baudRateFD <= MAX_CANFD_BAUDRATE);
uint32_t clk;
uint32_t tqNum; /* Numbers of TQ. */
bool fgRet = false;
if (FLEXCAN_CalculateImprovedTimingValuesByCBT(baudRate, sourceClock_Hz, pTimingConfig))
{
if (0U != baudRateFD)
{
/* Auto Improved Protocal timing for CBT. */
tqNum = FDCBT_MAX_TIME_QUANTA;
do
{
clk = baudRateFD * tqNum;
if (clk > sourceClock_Hz)
{
continue; /* tqNum too large, clk x tqNum has been exceed sourceClock_Hz. */
}
if ((sourceClock_Hz / clk * clk) != sourceClock_Hz)
{
continue; /* Non-supporting: the frequency of clock source is not divisible by target baud rate,
the user should change a divisible baud rate. */
}
pTimingConfig->fpreDivider = (uint16_t)(sourceClock_Hz / clk - 1U);
if (pTimingConfig->fpreDivider > MAX_FPRESDIV)
{
break; /* The frequency of source clock is too large or the baud rate is too small, the pre-divider
could not handle it. */
}
/* Get the best CANFD data bus timing configuration. */
if (FLEXCAN_FDGetSegmentswithBRS(baudRateFD, tqNum, pTimingConfig))
{
fgRet = true;
break;
}
} while (--tqNum >= FDCBT_MIN_TIME_QUANTA);
}
else
{
fgRet = true; /* User don't use Brs feature. */
}
}
return fgRet;
}
/*!
* brief Configures a FlexCAN transmit message buffer.
*
* This function aborts the previous transmission, cleans the Message Buffer, and
* configures it as a Transmit Message Buffer.
*
* param base FlexCAN peripheral base address.
* param mbIdx The Message Buffer index.
* param enable Enable/disable Tx Message Buffer.
* - true: Enable Tx Message Buffer.
* - false: Disable Tx Message Buffer.
*/
void FLEXCAN_SetFDTxMbConfig(CAN_Type *base, uint8_t mbIdx, bool enable)
{
/* Assertion. */
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
uint8_t cnt = 0;
uint8_t payload_dword = 1;
uint32_t dataSize;
dataSize = (base->FDCTRL & CAN_FDCTRL_MBDSR0_MASK) >> CAN_FDCTRL_MBDSR0_SHIFT;
volatile uint32_t *mbAddr = &(base->MB[0].CS);
uint32_t offset = FLEXCAN_GetFDMailboxOffset(base, mbIdx);
#if ((defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) || \
(defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829))
uint32_t availoffset = FLEXCAN_GetFDMailboxOffset(base, FLEXCAN_GetFirstValidMb(base));
#endif
/* Inactivate Message Buffer. */
if (enable)
{
/* Inactivate by writing CS. */
mbAddr[offset] = CAN_CS_CODE(kFLEXCAN_TxMbInactive);
}
else
{
mbAddr[offset] = 0x0;
}
/* Calculate the DWORD number, dataSize 0/1/2/3 corresponds to 8/16/32/64
Bytes payload. */
for (cnt = 0; cnt < (dataSize + 1U); cnt++)
{
payload_dword *= 2U;
}
/* Clean ID. */
mbAddr[offset + 1U] = 0x0U;
/* Clean Message Buffer content, DWORD by DWORD. */
for (cnt = 0; cnt < payload_dword; cnt++)
{
mbAddr[offset + 2U + cnt] = 0x0U;
}
#if ((defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) || \
(defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829))
mbAddr[availoffset] = CAN_CS_CODE(kFLEXCAN_TxMbInactive);
#endif
}
#endif /* FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE */
/*!
* brief Configures a FlexCAN Receive Message Buffer.
*
* This function cleans a FlexCAN build-in Message Buffer and configures it
* as a Receive Message Buffer.
*
* param base FlexCAN peripheral base address.
* param mbIdx The Message Buffer index.
* param pRxMbConfig Pointer to the FlexCAN Message Buffer configuration structure.
* param enable Enable/disable Rx Message Buffer.
* - true: Enable Rx Message Buffer.
* - false: Disable Rx Message Buffer.
*/
void FLEXCAN_SetRxMbConfig(CAN_Type *base, uint8_t mbIdx, const flexcan_rx_mb_config_t *pRxMbConfig, bool enable)
{
/* Assertion. */
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
assert(((NULL != pRxMbConfig) || (false == enable)));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
uint32_t cs_temp = 0;
/* Inactivate Message Buffer. */
base->MB[mbIdx].CS = 0;
/* Clean Message Buffer content. */
base->MB[mbIdx].ID = 0x0;
base->MB[mbIdx].WORD0 = 0x0;
base->MB[mbIdx].WORD1 = 0x0;
if (enable)
{
/* Setup Message Buffer ID. */
base->MB[mbIdx].ID = pRxMbConfig->id;
/* Setup Message Buffer format. */
if (kFLEXCAN_FrameFormatExtend == pRxMbConfig->format)
{
cs_temp |= CAN_CS_IDE_MASK;
}
/* Setup Message Buffer type. */
if (kFLEXCAN_FrameTypeRemote == pRxMbConfig->type)
{
cs_temp |= CAN_CS_RTR_MASK;
}
/* Activate Rx Message Buffer. */
cs_temp |= CAN_CS_CODE(kFLEXCAN_RxMbEmpty);
base->MB[mbIdx].CS = cs_temp;
}
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/*!
* brief Configures a FlexCAN Receive Message Buffer.
*
* This function cleans a FlexCAN build-in Message Buffer and configures it
* as a Receive Message Buffer.
*
* param base FlexCAN peripheral base address.
* param mbIdx The Message Buffer index.
* param pRxMbConfig Pointer to the FlexCAN Message Buffer configuration structure.
* param enable Enable/disable Rx Message Buffer.
* - true: Enable Rx Message Buffer.
* - false: Disable Rx Message Buffer.
*/
void FLEXCAN_SetFDRxMbConfig(CAN_Type *base, uint8_t mbIdx, const flexcan_rx_mb_config_t *pRxMbConfig, bool enable)
{
/* Assertion. */
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
assert(((NULL != pRxMbConfig) || (false == enable)));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
uint32_t cs_temp = 0;
uint8_t cnt = 0;
volatile uint32_t *mbAddr = &(base->MB[0].CS);
uint32_t offset = FLEXCAN_GetFDMailboxOffset(base, mbIdx);
uint8_t payload_dword;
uint32_t dataSize = (base->FDCTRL & CAN_FDCTRL_MBDSR0_MASK) >> CAN_FDCTRL_MBDSR0_SHIFT;
/* Inactivate Message Buffer. */
mbAddr[offset] = 0U;
/* Clean Message Buffer content. */
mbAddr[offset + 1U] = 0U;
/* Calculate the DWORD number, dataSize 0/1/2/3 corresponds to 8/16/32/64
Bytes payload. */
payload_dword = (2U << dataSize);
for (cnt = 0; cnt < payload_dword; cnt++)
{
mbAddr[offset + 2U + cnt] = 0x0;
}
if (enable)
{
/* Setup Message Buffer ID. */
mbAddr[offset + 1U] = pRxMbConfig->id;
/* Setup Message Buffer format. */
if (kFLEXCAN_FrameFormatExtend == pRxMbConfig->format)
{
cs_temp |= CAN_CS_IDE_MASK;
}
/* Setup Message Buffer type. */
if (kFLEXCAN_FrameTypeRemote == pRxMbConfig->type)
{
cs_temp |= CAN_CS_RTR_MASK;
}
/* Activate Rx Message Buffer. */
cs_temp |= CAN_CS_CODE(kFLEXCAN_RxMbEmpty);
mbAddr[offset] = cs_temp;
}
}
#endif
/*!
* brief Configures the FlexCAN Rx FIFO.
*
* This function configures the Rx FIFO with given Rx FIFO configuration.
*
* param base FlexCAN peripheral base address.
* param pRxFifoConfig Pointer to the FlexCAN Rx FIFO configuration structure.
* param enable Enable/disable Rx FIFO.
* - true: Enable Rx FIFO.
* - false: Disable Rx FIFO.
*/
void FLEXCAN_SetRxFifoConfig(CAN_Type *base, const flexcan_rx_fifo_config_t *pRxFifoConfig, bool enable)
{
/* Assertion. */
assert((NULL != pRxFifoConfig) || (false == enable));
volatile uint32_t *mbAddr;
uint8_t i, j, k, rffn = 0, numMbOccupy;
uint32_t setup_mb = 0;
/* Enter Freeze Mode. */
FLEXCAN_EnterFreezeMode(base);
if (enable)
{
assert(pRxFifoConfig->idFilterNum <= 128U);
/* Get the setup_mb value. */
setup_mb = (uint8_t)((base->MCR & CAN_MCR_MAXMB_MASK) >> CAN_MCR_MAXMB_SHIFT);
setup_mb = (setup_mb < (uint32_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base)) ?
setup_mb :
(uint32_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base);
/* Determine RFFN value. */
for (i = 0; i <= 0xFU; i++)
{
if ((8U * (i + 1U)) >= pRxFifoConfig->idFilterNum)
{
rffn = i;
assert(((setup_mb - 8U) - (2U * rffn)) > 0U);
base->CTRL2 = (base->CTRL2 & ~CAN_CTRL2_RFFN_MASK) | CAN_CTRL2_RFFN(rffn);
break;
}
}
/* caculate the Number of Mailboxes occupied by RX Legacy FIFO and the filter. */
numMbOccupy = 6U + (rffn + 1U) * 2U;
/* Copy ID filter table to Message Buffer Region (Fix MISRA_C-2012 Rule 18.1). */
j = 0U;
for (i = 6U; i < numMbOccupy; i++)
{
/* Get address for current mail box. */
mbAddr = &(base->MB[i].CS);
/* One Mail box contain 4U DWORD registers. */
for (k = 0; k < 4U; k++)
{
/* Fill all valid filter in the mail box occupied by filter.
* Disable unused Rx FIFO Filter, the other rest of register in the last Mail box occupied by fiter set
* as 0xffffffff.
*/
mbAddr[k] = (j < pRxFifoConfig->idFilterNum) ? (pRxFifoConfig->idFilterTable[j]) : 0xFFFFFFFFU;
/* Try to fill next filter in current Mail Box. */
j++;
}
}
/* Setup ID Fitlter Type. */
switch (pRxFifoConfig->idFilterType)
{
case kFLEXCAN_RxFifoFilterTypeA:
base->MCR = (base->MCR & ~CAN_MCR_IDAM_MASK) | CAN_MCR_IDAM(0x0);
break;
case kFLEXCAN_RxFifoFilterTypeB:
base->MCR = (base->MCR & ~CAN_MCR_IDAM_MASK) | CAN_MCR_IDAM(0x1);
break;
case kFLEXCAN_RxFifoFilterTypeC:
base->MCR = (base->MCR & ~CAN_MCR_IDAM_MASK) | CAN_MCR_IDAM(0x2);
break;
case kFLEXCAN_RxFifoFilterTypeD:
/* All frames rejected. */
base->MCR = (base->MCR & ~CAN_MCR_IDAM_MASK) | CAN_MCR_IDAM(0x3);
break;
default:
/* All the cases have been listed above, the default clause should not be reached. */
assert(false);
break;
}
/* Setting Message Reception Priority. */
base->CTRL2 = (pRxFifoConfig->priority == kFLEXCAN_RxFifoPrioHigh) ? (base->CTRL2 & ~CAN_CTRL2_MRP_MASK) :
(base->CTRL2 | CAN_CTRL2_MRP_MASK);
/* Enable Rx Message FIFO. */
base->MCR |= CAN_MCR_RFEN_MASK;
}
else
{
rffn = (uint8_t)((base->CTRL2 & CAN_CTRL2_RFFN_MASK) >> CAN_CTRL2_RFFN_SHIFT);
/* caculate the Number of Mailboxes occupied by RX Legacy FIFO and the filter. */
numMbOccupy = 6U + (rffn + 1U) * 2U;
/* Disable Rx Message FIFO. */
base->MCR &= ~CAN_MCR_RFEN_MASK;
/* Clean MB0 ~ MB5 and all MB occupied by ID filters (Fix MISRA_C-2012 Rule 18.1). */
for (i = 0; i < numMbOccupy; i++)
{
FLEXCAN_SetRxMbConfig(base, i, NULL, false);
}
}
/* Exit Freeze Mode. */
FLEXCAN_ExitFreezeMode(base);
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_RX_FIFO_DMA) && FSL_FEATURE_FLEXCAN_HAS_RX_FIFO_DMA)
/*!
* brief Enables or disables the FlexCAN Rx FIFO DMA request.
*
* This function enables or disables the DMA feature of FlexCAN build-in Rx FIFO.
*
* param base FlexCAN peripheral base address.
* param enable true to enable, false to disable.
*/
void FLEXCAN_EnableRxFifoDMA(CAN_Type *base, bool enable)
{
if (enable)
{
/* Enter Freeze Mode. */
FLEXCAN_EnterFreezeMode(base);
/* Enable FlexCAN DMA. */
base->MCR |= CAN_MCR_DMA_MASK;
/* Exit Freeze Mode. */
FLEXCAN_ExitFreezeMode(base);
}
else
{
/* Enter Freeze Mode. */
FLEXCAN_EnterFreezeMode(base);
/* Disable FlexCAN DMA. */
base->MCR &= ~CAN_MCR_DMA_MASK;
/* Exit Freeze Mode. */
FLEXCAN_ExitFreezeMode(base);
}
}
#endif /* FSL_FEATURE_FLEXCAN_HAS_RX_FIFO_DMA */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_6032) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_6032)
/*!
* FlexCAN: A frame with wrong ID or payload is transmitted into
* the CAN bus when the Message Buffer under transmission is
* either aborted or deactivated while the CAN bus is in the Bus Idle state
*
* This function to do workaround for ERR006032
*
* param base FlexCAN peripheral base address.
* param mbIdx The FlexCAN Message Buffer index.
*/
static void FLEXCAN_ERRATA_6032(CAN_Type *base, volatile uint32_t *mbCSAddr)
{
uint32_t dbg_temp = 0U;
uint32_t u32TempCS = 0U;
uint32_t u32Timeout = DELAY_BUSIDLE;
uint32_t u32TempIMASK1 = base->IMASK1;
/*after backup all interruption, disable ALL interruption*/
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint32_t u32TempIMASK2 = base->IMASK2;
base->IMASK2 = 0;
#endif
base->IMASK1 = 0;
dbg_temp = (uint32_t)(base->DBG1);
switch (dbg_temp & CAN_DBG1_CFSM_MASK)
{
case RXINTERMISSION:
if (CBN_VALUE3 == (dbg_temp & CAN_DBG1_CBN_MASK))
{
/*wait until CFSM is different from RXINTERMISSION */
while (RXINTERMISSION == (base->DBG1 & CAN_DBG1_CFSM_MASK))
{
__NOP();
}
}
break;
case TXINTERMISSION:
if (CBN_VALUE3 == (dbg_temp & CAN_DBG1_CBN_MASK))
{
/*wait until CFSM is different from TXINTERMISSION*/
while (TXINTERMISSION == (base->DBG1 & CAN_DBG1_CFSM_MASK))
{
__NOP();
}
}
break;
default:
/* To avoid MISRA-C 2012 rule 16.4 issue. */
break;
}
/*Anyway, BUSIDLE need to delay*/
if (BUSIDLE == (base->DBG1 & CAN_DBG1_CFSM_MASK))
{
while (u32Timeout-- > 0U)
{
__NOP();
}
/*Write 0x0 into Code field of CS word.*/
u32TempCS = (uint32_t)(*mbCSAddr);
u32TempCS &= ~CAN_CS_CODE_MASK;
*mbCSAddr = u32TempCS;
}
/*restore interruption*/
base->IMASK1 = u32TempIMASK1;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
base->IMASK2 = u32TempIMASK2;
#endif
}
#endif
/*!
* brief Writes a FlexCAN Message to the Transmit Message Buffer.
*
* This function writes a CAN Message to the specified Transmit Message Buffer
* and changes the Message Buffer state to start CAN Message transmit. After
* that the function returns immediately.
*
* param base FlexCAN peripheral base address.
* param mbIdx The FlexCAN Message Buffer index.
* param pTxFrame Pointer to CAN message frame to be sent.
* retval kStatus_Success - Write Tx Message Buffer Successfully.
* retval kStatus_Fail - Tx Message Buffer is currently in use.
*/
status_t FLEXCAN_WriteTxMb(CAN_Type *base, uint8_t mbIdx, const flexcan_frame_t *pTxFrame)
{
/* Assertion. */
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
assert(NULL != pTxFrame);
assert(pTxFrame->length <= 8U);
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
uint32_t cs_temp = 0;
status_t status;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_6032) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_6032)
FLEXCAN_ERRATA_6032(base, &(base->MB[mbIdx].CS));
#endif
/* Check if Message Buffer is available. */
if (CAN_CS_CODE(kFLEXCAN_TxMbDataOrRemote) != (base->MB[mbIdx].CS & CAN_CS_CODE_MASK))
{
/* Inactive Tx Message Buffer. */
base->MB[mbIdx].CS = (base->MB[mbIdx].CS & ~CAN_CS_CODE_MASK) | CAN_CS_CODE(kFLEXCAN_TxMbInactive);
/* Fill Message ID field. */
base->MB[mbIdx].ID = pTxFrame->id;
/* Fill Message Format field. */
if ((uint32_t)kFLEXCAN_FrameFormatExtend == pTxFrame->format)
{
cs_temp |= CAN_CS_SRR_MASK | CAN_CS_IDE_MASK;
}
/* Fill Message Type field. */
if ((uint32_t)kFLEXCAN_FrameTypeRemote == pTxFrame->type)
{
cs_temp |= CAN_CS_RTR_MASK;
}
cs_temp |= CAN_CS_CODE(kFLEXCAN_TxMbDataOrRemote) | CAN_CS_DLC(pTxFrame->length);
/* Load Message Payload. */
base->MB[mbIdx].WORD0 = pTxFrame->dataWord0;
base->MB[mbIdx].WORD1 = pTxFrame->dataWord1;
/* Activate Tx Message Buffer. */
base->MB[mbIdx].CS = cs_temp;
#if ((defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) || \
(defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829))
base->MB[FLEXCAN_GetFirstValidMb(base)].CS = CAN_CS_CODE(kFLEXCAN_TxMbInactive);
base->MB[FLEXCAN_GetFirstValidMb(base)].CS = CAN_CS_CODE(kFLEXCAN_TxMbInactive);
#endif
status = kStatus_Success;
}
else
{
/* Tx Message Buffer is activated, return immediately. */
status = kStatus_Fail;
}
return status;
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/*!
* brief Writes a FlexCAN FD Message to the Transmit Message Buffer.
*
* This function writes a CAN FD Message to the specified Transmit Message Buffer
* and changes the Message Buffer state to start CAN FD Message transmit. After
* that the function returns immediately.
*
* param base FlexCAN peripheral base address.
* param mbIdx The FlexCAN FD Message Buffer index.
* param pTxFrame Pointer to CAN FD message frame to be sent.
* retval kStatus_Success - Write Tx Message Buffer Successfully.
* retval kStatus_Fail - Tx Message Buffer is currently in use.
*/
status_t FLEXCAN_WriteFDTxMb(CAN_Type *base, uint8_t mbIdx, const flexcan_fd_frame_t *pTxFrame)
{
/* Assertion. */
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
assert(NULL != pTxFrame);
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
status_t status;
uint32_t cs_temp = 0;
uint8_t cnt = 0;
uint32_t can_cs = 0;
uint8_t payload_dword = 1;
uint32_t dataSize = (base->FDCTRL & CAN_FDCTRL_MBDSR0_MASK) >> CAN_FDCTRL_MBDSR0_SHIFT;
#if ((defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) || \
(defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829))
uint32_t availoffset = FLEXCAN_GetFDMailboxOffset(base, FLEXCAN_GetFirstValidMb(base));
#endif
volatile uint32_t *mbAddr = &(base->MB[0].CS);
uint32_t offset = FLEXCAN_GetFDMailboxOffset(base, mbIdx);
#if (defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_6032) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_6032)
FLEXCAN_ERRATA_6032(base, &(mbAddr[offset]));
#endif
can_cs = mbAddr[offset];
/* Check if Message Buffer is available. */
if (CAN_CS_CODE(kFLEXCAN_TxMbDataOrRemote) != (can_cs & CAN_CS_CODE_MASK))
{
/* Inactive Tx Message Buffer and Fill Message ID field. */
mbAddr[offset] = (can_cs & ~CAN_CS_CODE_MASK) | CAN_CS_CODE(kFLEXCAN_TxMbInactive);
mbAddr[offset + 1U] = pTxFrame->id;
/* Fill Message Format field. */
if ((uint32_t)kFLEXCAN_FrameFormatExtend == pTxFrame->format)
{
cs_temp |= CAN_CS_SRR_MASK | CAN_CS_IDE_MASK;
}
/* Fill Message Type field. */
if ((uint32_t)kFLEXCAN_FrameTypeRemote == pTxFrame->type)
{
cs_temp |= CAN_CS_RTR_MASK;
}
cs_temp |= CAN_CS_CODE(kFLEXCAN_TxMbDataOrRemote) | CAN_CS_DLC(pTxFrame->length) | CAN_CS_EDL(1) |
CAN_CS_BRS(pTxFrame->brs);
/* Calculate the DWORD number, dataSize 0/1/2/3 corresponds to 8/16/32/64
Bytes payload. */
for (cnt = 0; cnt < (dataSize + 1U); cnt++)
{
payload_dword *= 2U;
}
/* Load Message Payload and Activate Tx Message Buffer. */
for (cnt = 0; cnt < payload_dword; cnt++)
{
mbAddr[offset + 2U + cnt] = pTxFrame->dataWord[cnt];
}
mbAddr[offset] = cs_temp;
#if ((defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5641) || \
(defined(FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829) && FSL_FEATURE_FLEXCAN_HAS_ERRATA_5829))
mbAddr[availoffset] = CAN_CS_CODE(kFLEXCAN_TxMbInactive);
mbAddr[availoffset] = CAN_CS_CODE(kFLEXCAN_TxMbInactive);
#endif
status = kStatus_Success;
}
else
{
/* Tx Message Buffer is activated, return immediately. */
status = kStatus_Fail;
}
return status;
}
#endif
/*!
* brief Reads a FlexCAN Message from Receive Message Buffer.
*
* This function reads a CAN message from a specified Receive Message Buffer.
* The function fills a receive CAN message frame structure with
* just received data and activates the Message Buffer again.
* The function returns immediately.
*
* param base FlexCAN peripheral base address.
* param mbIdx The FlexCAN Message Buffer index.
* param pRxFrame Pointer to CAN message frame structure for reception.
* retval kStatus_Success - Rx Message Buffer is full and has been read successfully.
* retval kStatus_FLEXCAN_RxOverflow - Rx Message Buffer is already overflowed and has been read successfully.
* retval kStatus_Fail - Rx Message Buffer is empty.
*/
status_t FLEXCAN_ReadRxMb(CAN_Type *base, uint8_t mbIdx, flexcan_frame_t *pRxFrame)
{
/* Assertion. */
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
assert(NULL != pRxFrame);
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
uint32_t cs_temp;
uint32_t rx_code;
status_t status;
/* Read CS field of Rx Message Buffer to lock Message Buffer. */
cs_temp = base->MB[mbIdx].CS;
/* Get Rx Message Buffer Code field. */
rx_code = (cs_temp & CAN_CS_CODE_MASK) >> CAN_CS_CODE_SHIFT;
/* Check to see if Rx Message Buffer is full. */
if (((uint32_t)kFLEXCAN_RxMbFull == rx_code) || ((uint32_t)kFLEXCAN_RxMbOverrun == rx_code))
{
/* Store Message ID. */
pRxFrame->id = base->MB[mbIdx].ID & (CAN_ID_EXT_MASK | CAN_ID_STD_MASK);
/* Get the message ID and format. */
pRxFrame->format = (cs_temp & CAN_CS_IDE_MASK) != 0U ? (uint8_t)kFLEXCAN_FrameFormatExtend :
(uint8_t)kFLEXCAN_FrameFormatStandard;
/* Get the message type. */
pRxFrame->type =
(cs_temp & CAN_CS_RTR_MASK) != 0U ? (uint8_t)kFLEXCAN_FrameTypeRemote : (uint8_t)kFLEXCAN_FrameTypeData;
/* Get the message length. */
pRxFrame->length = (uint8_t)((cs_temp & CAN_CS_DLC_MASK) >> CAN_CS_DLC_SHIFT);
/* Get the time stamp. */
pRxFrame->timestamp = (uint16_t)((cs_temp & CAN_CS_TIME_STAMP_MASK) >> CAN_CS_TIME_STAMP_SHIFT);
/* Store Message Payload. */
pRxFrame->dataWord0 = base->MB[mbIdx].WORD0;
pRxFrame->dataWord1 = base->MB[mbIdx].WORD1;
/* Read free-running timer to unlock Rx Message Buffer. */
(void)base->TIMER;
if ((uint32_t)kFLEXCAN_RxMbFull == rx_code)
{
status = kStatus_Success;
}
else
{
status = kStatus_FLEXCAN_RxOverflow;
}
}
else
{
/* Read free-running timer to unlock Rx Message Buffer. */
(void)base->TIMER;
status = kStatus_Fail;
}
return status;
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/*!
* brief Reads a FlexCAN FD Message from Receive Message Buffer.
*
* This function reads a CAN FD message from a specified Receive Message Buffer.
* The function fills a receive CAN FD message frame structure with
* just received data and activates the Message Buffer again.
* The function returns immediately.
*
* param base FlexCAN peripheral base address.
* param mbIdx The FlexCAN FD Message Buffer index.
* param pRxFrame Pointer to CAN FD message frame structure for reception.
* retval kStatus_Success - Rx Message Buffer is full and has been read successfully.
* retval kStatus_FLEXCAN_RxOverflow - Rx Message Buffer is already overflowed and has been read successfully.
* retval kStatus_Fail - Rx Message Buffer is empty.
*/
status_t FLEXCAN_ReadFDRxMb(CAN_Type *base, uint8_t mbIdx, flexcan_fd_frame_t *pRxFrame)
{
/* Assertion. */
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
assert(NULL != pRxFrame);
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
status_t status;
uint32_t cs_temp;
uint8_t rx_code;
uint8_t cnt = 0;
uint32_t can_id = 0;
uint32_t dataSize;
dataSize = (base->FDCTRL & CAN_FDCTRL_MBDSR0_MASK) >> CAN_FDCTRL_MBDSR0_SHIFT;
uint8_t payload_dword = 1;
volatile uint32_t *mbAddr = &(base->MB[0].CS);
uint32_t offset = FLEXCAN_GetFDMailboxOffset(base, mbIdx);
/* Read CS field of Rx Message Buffer to lock Message Buffer. */
cs_temp = mbAddr[offset];
can_id = mbAddr[offset + 1U];
/* Get Rx Message Buffer Code field. */
rx_code = (uint8_t)((cs_temp & CAN_CS_CODE_MASK) >> CAN_CS_CODE_SHIFT);
/* Check to see if Rx Message Buffer is full. */
if (((uint8_t)kFLEXCAN_RxMbFull == rx_code) || ((uint8_t)kFLEXCAN_RxMbOverrun == rx_code))
{
/* Store Message ID. */
pRxFrame->id = can_id & (CAN_ID_EXT_MASK | CAN_ID_STD_MASK);
/* Get the message ID and format. */
pRxFrame->format = (cs_temp & CAN_CS_IDE_MASK) != 0U ? (uint8_t)kFLEXCAN_FrameFormatExtend :
(uint8_t)kFLEXCAN_FrameFormatStandard;
/* Get the message type. */
pRxFrame->type =
(cs_temp & CAN_CS_RTR_MASK) != 0U ? (uint8_t)kFLEXCAN_FrameTypeRemote : (uint8_t)kFLEXCAN_FrameTypeData;
/* Get the message length. */
pRxFrame->length = (uint8_t)((cs_temp & CAN_CS_DLC_MASK) >> CAN_CS_DLC_SHIFT);
/* Get the time stamp. */
pRxFrame->timestamp = (uint16_t)((cs_temp & CAN_CS_TIME_STAMP_MASK) >> CAN_CS_TIME_STAMP_SHIFT);
/* Calculate the DWORD number, dataSize 0/1/2/3 corresponds to 8/16/32/64
Bytes payload. */
for (cnt = 0; cnt < (dataSize + 1U); cnt++)
{
payload_dword *= 2U;
}
/* Store Message Payload. */
for (cnt = 0; cnt < payload_dword; cnt++)
{
pRxFrame->dataWord[cnt] = mbAddr[offset + 2U + cnt];
}
/* Read free-running timer to unlock Rx Message Buffer. */
(void)base->TIMER;
if ((uint32_t)kFLEXCAN_RxMbFull == rx_code)
{
status = kStatus_Success;
}
else
{
status = kStatus_FLEXCAN_RxOverflow;
}
}
else
{
/* Read free-running timer to unlock Rx Message Buffer. */
(void)base->TIMER;
status = kStatus_Fail;
}
return status;
}
#endif
/*!
* brief Reads a FlexCAN Message from Rx FIFO.
*
* This function reads a CAN message from the FlexCAN build-in Rx FIFO.
*
* param base FlexCAN peripheral base address.
* param pRxFrame Pointer to CAN message frame structure for reception.
* retval kStatus_Success - Read Message from Rx FIFO successfully.
* retval kStatus_Fail - Rx FIFO is not enabled.
*/
status_t FLEXCAN_ReadRxFifo(CAN_Type *base, flexcan_frame_t *pRxFrame)
{
/* Assertion. */
assert(NULL != pRxFrame);
uint32_t cs_temp;
status_t status;
/* Check if Rx FIFO is Enabled. */
if (0U != (base->MCR & CAN_MCR_RFEN_MASK))
{
/* Read CS field of Rx Message Buffer to lock Message Buffer. */
cs_temp = base->MB[0].CS;
/* Read data from Rx FIFO output port. */
/* Store Message ID. */
pRxFrame->id = base->MB[0].ID & (CAN_ID_EXT_MASK | CAN_ID_STD_MASK);
/* Get the message ID and format. */
pRxFrame->format = (cs_temp & CAN_CS_IDE_MASK) != 0U ? (uint8_t)kFLEXCAN_FrameFormatExtend :
(uint8_t)kFLEXCAN_FrameFormatStandard;
/* Get the message type. */
pRxFrame->type =
(cs_temp & CAN_CS_RTR_MASK) != 0U ? (uint8_t)kFLEXCAN_FrameTypeRemote : (uint8_t)kFLEXCAN_FrameTypeData;
/* Get the message length. */
pRxFrame->length = (uint8_t)((cs_temp & CAN_CS_DLC_MASK) >> CAN_CS_DLC_SHIFT);
/* Get the time stamp. */
pRxFrame->timestamp = (uint16_t)((cs_temp & CAN_CS_TIME_STAMP_MASK) >> CAN_CS_TIME_STAMP_SHIFT);
/* Store Message Payload. */
pRxFrame->dataWord0 = base->MB[0].WORD0;
pRxFrame->dataWord1 = base->MB[0].WORD1;
/* Store ID Filter Hit Index. */
pRxFrame->idhit = (uint16_t)(base->RXFIR & CAN_RXFIR_IDHIT_MASK);
/* Read free-running timer to unlock Rx Message Buffer. */
(void)base->TIMER;
status = kStatus_Success;
}
else
{
status = kStatus_Fail;
}
return status;
}
/*!
* brief Performs a polling send transaction on the CAN bus.
*
* Note that a transfer handle does not need to be created before calling this API.
*
* param base FlexCAN peripheral base pointer.
* param mbIdx The FlexCAN Message Buffer index.
* param pTxFrame Pointer to CAN message frame to be sent.
* retval kStatus_Success - Write Tx Message Buffer Successfully.
* retval kStatus_Fail - Tx Message Buffer is currently in use.
*/
status_t FLEXCAN_TransferSendBlocking(CAN_Type *base, uint8_t mbIdx, flexcan_frame_t *pTxFrame)
{
status_t status;
/* Write Tx Message Buffer to initiate a data sending. */
if (kStatus_Success == FLEXCAN_WriteTxMb(base, mbIdx, (const flexcan_frame_t *)(uint32_t)pTxFrame))
{
/* Wait until CAN Message send out. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64flag = 1;
while (0U == FLEXCAN_GetMbStatusFlags(base, u64flag << mbIdx))
#else
uint32_t u32flag = 1;
while (0U == FLEXCAN_GetMbStatusFlags(base, u32flag << mbIdx))
#endif
{
}
/* Clean Tx Message Buffer Flag. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
FLEXCAN_ClearMbStatusFlags(base, u64flag << mbIdx);
#else
FLEXCAN_ClearMbStatusFlags(base, u32flag << mbIdx);
#endif
/*After TX MB tranfered success, update the Timestamp from MB[mbIdx].CS register*/
pTxFrame->timestamp = (uint16_t)((base->MB[mbIdx].CS & CAN_CS_TIME_STAMP_MASK) >> CAN_CS_TIME_STAMP_SHIFT);
status = kStatus_Success;
}
else
{
status = kStatus_Fail;
}
return status;
}
/*!
* brief Performs a polling receive transaction on the CAN bus.
*
* Note that a transfer handle does not need to be created before calling this API.
*
* param base FlexCAN peripheral base pointer.
* param mbIdx The FlexCAN Message Buffer index.
* param pRxFrame Pointer to CAN message frame structure for reception.
* retval kStatus_Success - Rx Message Buffer is full and has been read successfully.
* retval kStatus_FLEXCAN_RxOverflow - Rx Message Buffer is already overflowed and has been read successfully.
* retval kStatus_Fail - Rx Message Buffer is empty.
*/
status_t FLEXCAN_TransferReceiveBlocking(CAN_Type *base, uint8_t mbIdx, flexcan_frame_t *pRxFrame)
{
/* Wait until Rx Message Buffer non-empty. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64flag = 1;
while (0U == FLEXCAN_GetMbStatusFlags(base, u64flag << mbIdx))
#else
uint32_t u32flag = 1;
while (0U == FLEXCAN_GetMbStatusFlags(base, u32flag << mbIdx))
#endif
{
}
/* Clean Rx Message Buffer Flag. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
FLEXCAN_ClearMbStatusFlags(base, u64flag << mbIdx);
#else
FLEXCAN_ClearMbStatusFlags(base, u32flag << mbIdx);
#endif
/* Read Received CAN Message. */
return FLEXCAN_ReadRxMb(base, mbIdx, pRxFrame);
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/*!
* brief Performs a polling send transaction on the CAN bus.
*
* Note that a transfer handle does not need to be created before calling this API.
*
* param base FlexCAN peripheral base pointer.
* param mbIdx The FlexCAN FD Message Buffer index.
* param pTxFrame Pointer to CAN FD message frame to be sent.
* retval kStatus_Success - Write Tx Message Buffer Successfully.
* retval kStatus_Fail - Tx Message Buffer is currently in use.
*/
status_t FLEXCAN_TransferFDSendBlocking(CAN_Type *base, uint8_t mbIdx, flexcan_fd_frame_t *pTxFrame)
{
status_t status;
/* Write Tx Message Buffer to initiate a data sending. */
if (kStatus_Success == FLEXCAN_WriteFDTxMb(base, mbIdx, (const flexcan_fd_frame_t *)(uint32_t)pTxFrame))
{
/* Wait until CAN Message send out. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64flag = 1;
while (0U == FLEXCAN_GetMbStatusFlags(base, u64flag << mbIdx))
#else
uint32_t u32flag = 1;
while (0U == FLEXCAN_GetMbStatusFlags(base, u32flag << mbIdx))
#endif
{
}
/* Clean Tx Message Buffer Flag. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
FLEXCAN_ClearMbStatusFlags(base, u64flag << mbIdx);
#else
FLEXCAN_ClearMbStatusFlags(base, u32flag << mbIdx);
#endif
/*After TX MB tranfered success, update the Timestamp from base->MB[offset for CANFD].CS register*/
volatile uint32_t *mbAddr = &(base->MB[0].CS);
uint32_t offset = FLEXCAN_GetFDMailboxOffset(base, mbIdx);
pTxFrame->timestamp = (uint16_t)((mbAddr[offset] & CAN_CS_TIME_STAMP_MASK) >> CAN_CS_TIME_STAMP_SHIFT);
status = kStatus_Success;
}
else
{
status = kStatus_Fail;
}
return status;
}
/*!
* brief Performs a polling receive transaction on the CAN bus.
*
* Note that a transfer handle does not need to be created before calling this API.
*
* param base FlexCAN peripheral base pointer.
* param mbIdx The FlexCAN FD Message Buffer index.
* param pRxFrame Pointer to CAN FD message frame structure for reception.
* retval kStatus_Success - Rx Message Buffer is full and has been read successfully.
* retval kStatus_FLEXCAN_RxOverflow - Rx Message Buffer is already overflowed and has been read successfully.
* retval kStatus_Fail - Rx Message Buffer is empty.
*/
status_t FLEXCAN_TransferFDReceiveBlocking(CAN_Type *base, uint8_t mbIdx, flexcan_fd_frame_t *pRxFrame)
{
/* Wait until Rx Message Buffer non-empty. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64flag = 1;
while (0U == FLEXCAN_GetMbStatusFlags(base, u64flag << mbIdx))
#else
uint32_t u32flag = 1;
while (0U == FLEXCAN_GetMbStatusFlags(base, u32flag << mbIdx))
#endif
{
}
/* Clean Rx Message Buffer Flag. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
FLEXCAN_ClearMbStatusFlags(base, u64flag << mbIdx);
#else
FLEXCAN_ClearMbStatusFlags(base, u32flag << mbIdx);
#endif
/* Read Received CAN Message. */
return FLEXCAN_ReadFDRxMb(base, mbIdx, pRxFrame);
}
#endif
/*!
* brief Performs a polling receive transaction from Rx FIFO on the CAN bus.
*
* Note that a transfer handle does not need to be created before calling this API.
*
* param base FlexCAN peripheral base pointer.
* param pRxFrame Pointer to CAN message frame structure for reception.
* retval kStatus_Success - Read Message from Rx FIFO successfully.
* retval kStatus_Fail - Rx FIFO is not enabled.
*/
status_t FLEXCAN_TransferReceiveFifoBlocking(CAN_Type *base, flexcan_frame_t *pRxFrame)
{
status_t rxFifoStatus;
/* Wait until Rx FIFO non-empty. */
while (0U == FLEXCAN_GetMbStatusFlags(base, (uint32_t)kFLEXCAN_RxFifoFrameAvlFlag))
{
}
/* */
rxFifoStatus = FLEXCAN_ReadRxFifo(base, pRxFrame);
/* Clean Rx Fifo available flag. */
FLEXCAN_ClearMbStatusFlags(base, (uint32_t)kFLEXCAN_RxFifoFrameAvlFlag);
return rxFifoStatus;
}
/*!
* brief Initializes the FlexCAN handle.
*
* This function initializes the FlexCAN handle, which can be used for other FlexCAN
* transactional APIs. Usually, for a specified FlexCAN instance,
* call this API once to get the initialized handle.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param callback The callback function.
* param userData The parameter of the callback function.
*/
void FLEXCAN_TransferCreateHandle(CAN_Type *base,
flexcan_handle_t *handle,
flexcan_transfer_callback_t callback,
void *userData)
{
assert(NULL != handle);
uint8_t instance;
/* Clean FlexCAN transfer handle. */
(void)memset(handle, 0, sizeof(*handle));
/* Get instance from peripheral base address. */
instance = (uint8_t)FLEXCAN_GetInstance(base);
/* Save the context in global variables to support the double weak mechanism. */
s_flexcanHandle[instance] = handle;
/* Register Callback function. */
handle->callback = callback;
handle->userData = userData;
s_flexcanIsr = FLEXCAN_TransferHandleIRQ;
/* We Enable Error & Status interrupt here, because this interrupt just
* report current status of FlexCAN module through Callback function.
* It is insignificance without a available callback function.
*/
if (handle->callback != NULL)
{
FLEXCAN_EnableInterrupts(
base, (uint32_t)kFLEXCAN_BusOffInterruptEnable | (uint32_t)kFLEXCAN_ErrorInterruptEnable |
(uint32_t)kFLEXCAN_RxWarningInterruptEnable | (uint32_t)kFLEXCAN_TxWarningInterruptEnable |
(uint32_t)kFLEXCAN_WakeUpInterruptEnable);
}
else
{
FLEXCAN_DisableInterrupts(
base, (uint32_t)kFLEXCAN_BusOffInterruptEnable | (uint32_t)kFLEXCAN_ErrorInterruptEnable |
(uint32_t)kFLEXCAN_RxWarningInterruptEnable | (uint32_t)kFLEXCAN_TxWarningInterruptEnable |
(uint32_t)kFLEXCAN_WakeUpInterruptEnable);
}
/* Enable interrupts in NVIC. */
(void)EnableIRQ((IRQn_Type)(s_flexcanRxWarningIRQ[instance]));
(void)EnableIRQ((IRQn_Type)(s_flexcanTxWarningIRQ[instance]));
(void)EnableIRQ((IRQn_Type)(s_flexcanWakeUpIRQ[instance]));
(void)EnableIRQ((IRQn_Type)(s_flexcanErrorIRQ[instance]));
(void)EnableIRQ((IRQn_Type)(s_flexcanBusOffIRQ[instance]));
(void)EnableIRQ((IRQn_Type)(s_flexcanMbIRQ[instance]));
}
/*!
* brief Sends a message using IRQ.
*
* This function sends a message using IRQ. This is a non-blocking function, which returns
* right away. When messages have been sent out, the send callback function is called.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param pMbXfer FlexCAN Message Buffer transfer structure. See the #flexcan_mb_transfer_t.
* retval kStatus_Success Start Tx Message Buffer sending process successfully.
* retval kStatus_Fail Write Tx Message Buffer failed.
* retval kStatus_FLEXCAN_TxBusy Tx Message Buffer is in use.
*/
status_t FLEXCAN_TransferSendNonBlocking(CAN_Type *base, flexcan_handle_t *handle, flexcan_mb_transfer_t *pMbXfer)
{
/* Assertion. */
assert(NULL != handle);
assert(NULL != pMbXfer);
assert(pMbXfer->mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, pMbXfer->mbIdx));
#endif
status_t status;
/* Check if Message Buffer is idle. */
if ((uint8_t)kFLEXCAN_StateIdle == handle->mbState[pMbXfer->mbIdx])
{
/* Distinguish transmit type. */
if ((uint32_t)kFLEXCAN_FrameTypeRemote == pMbXfer->frame->type)
{
handle->mbState[pMbXfer->mbIdx] = (uint8_t)kFLEXCAN_StateTxRemote;
}
else
{
handle->mbState[pMbXfer->mbIdx] = (uint8_t)kFLEXCAN_StateTxData;
}
if (kStatus_Success ==
FLEXCAN_WriteTxMb(base, pMbXfer->mbIdx, (const flexcan_frame_t *)(uint32_t)pMbXfer->frame))
{
/* Enable Message Buffer Interrupt. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64mask = 1;
FLEXCAN_EnableMbInterrupts(base, u64mask << pMbXfer->mbIdx);
#else
uint32_t u32mask = 1;
FLEXCAN_EnableMbInterrupts(base, u32mask << pMbXfer->mbIdx);
#endif
status = kStatus_Success;
}
else
{
handle->mbState[pMbXfer->mbIdx] = (uint8_t)kFLEXCAN_StateIdle;
status = kStatus_Fail;
}
}
else
{
status = kStatus_FLEXCAN_TxBusy;
}
return status;
}
/*!
* brief Receives a message using IRQ.
*
* This function receives a message using IRQ. This is non-blocking function, which returns
* right away. When the message has been received, the receive callback function is called.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param pMbXfer FlexCAN Message Buffer transfer structure. See the #flexcan_mb_transfer_t.
* retval kStatus_Success - Start Rx Message Buffer receiving process successfully.
* retval kStatus_FLEXCAN_RxBusy - Rx Message Buffer is in use.
*/
status_t FLEXCAN_TransferReceiveNonBlocking(CAN_Type *base, flexcan_handle_t *handle, flexcan_mb_transfer_t *pMbXfer)
{
status_t status;
/* Assertion. */
assert(NULL != handle);
assert(NULL != pMbXfer);
assert(pMbXfer->mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, pMbXfer->mbIdx));
#endif
/* Check if Message Buffer is idle. */
if ((uint8_t)kFLEXCAN_StateIdle == handle->mbState[pMbXfer->mbIdx])
{
handle->mbState[pMbXfer->mbIdx] = (uint8_t)kFLEXCAN_StateRxData;
/* Register Message Buffer. */
handle->mbFrameBuf[pMbXfer->mbIdx] = pMbXfer->frame;
/* Enable Message Buffer Interrupt. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64mask = 1;
FLEXCAN_EnableMbInterrupts(base, u64mask << pMbXfer->mbIdx);
#else
uint32_t u32mask = 1;
FLEXCAN_EnableMbInterrupts(base, u32mask << pMbXfer->mbIdx);
#endif
status = kStatus_Success;
}
else
{
status = kStatus_FLEXCAN_RxBusy;
}
return status;
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/*!
* brief Sends a message using IRQ.
*
* This function sends a message using IRQ. This is a non-blocking function, which returns
* right away. When messages have been sent out, the send callback function is called.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param pMbXfer FlexCAN FD Message Buffer transfer structure. See the #flexcan_mb_transfer_t.
* retval kStatus_Success Start Tx Message Buffer sending process successfully.
* retval kStatus_Fail Write Tx Message Buffer failed.
* retval kStatus_FLEXCAN_TxBusy Tx Message Buffer is in use.
*/
status_t FLEXCAN_TransferFDSendNonBlocking(CAN_Type *base, flexcan_handle_t *handle, flexcan_mb_transfer_t *pMbXfer)
{
/* Assertion. */
assert(NULL != handle);
assert(NULL != pMbXfer);
assert(pMbXfer->mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, pMbXfer->mbIdx));
#endif
status_t status;
/* Check if Message Buffer is idle. */
if ((uint8_t)kFLEXCAN_StateIdle == handle->mbState[pMbXfer->mbIdx])
{
/* Distinguish transmit type. */
if ((uint32_t)kFLEXCAN_FrameTypeRemote == pMbXfer->framefd->type)
{
handle->mbState[pMbXfer->mbIdx] = (uint8_t)kFLEXCAN_StateTxRemote;
}
else
{
handle->mbState[pMbXfer->mbIdx] = (uint8_t)kFLEXCAN_StateTxData;
}
if (kStatus_Success ==
FLEXCAN_WriteFDTxMb(base, pMbXfer->mbIdx, (const flexcan_fd_frame_t *)(uint32_t)pMbXfer->framefd))
{
/* Enable Message Buffer Interrupt. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64mask = 1;
FLEXCAN_EnableMbInterrupts(base, u64mask << pMbXfer->mbIdx);
#else
uint32_t u32mask = 1;
FLEXCAN_EnableMbInterrupts(base, u32mask << pMbXfer->mbIdx);
#endif
status = kStatus_Success;
}
else
{
handle->mbState[pMbXfer->mbIdx] = (uint8_t)kFLEXCAN_StateIdle;
status = kStatus_Fail;
}
}
else
{
status = kStatus_FLEXCAN_TxBusy;
}
return status;
}
/*!
* brief Receives a message using IRQ.
*
* This function receives a message using IRQ. This is non-blocking function, which returns
* right away. When the message has been received, the receive callback function is called.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param pMbXfer FlexCAN FD Message Buffer transfer structure. See the #flexcan_mb_transfer_t.
* retval kStatus_Success - Start Rx Message Buffer receiving process successfully.
* retval kStatus_FLEXCAN_RxBusy - Rx Message Buffer is in use.
*/
status_t FLEXCAN_TransferFDReceiveNonBlocking(CAN_Type *base, flexcan_handle_t *handle, flexcan_mb_transfer_t *pMbXfer)
{
/* Assertion. */
assert(NULL != handle);
assert(NULL != pMbXfer);
assert(pMbXfer->mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, pMbXfer->mbIdx));
#endif
status_t status;
/* Check if Message Buffer is idle. */
if ((uint8_t)kFLEXCAN_StateIdle == handle->mbState[pMbXfer->mbIdx])
{
handle->mbState[pMbXfer->mbIdx] = (uint8_t)kFLEXCAN_StateRxData;
/* Register Message Buffer. */
handle->mbFDFrameBuf[pMbXfer->mbIdx] = pMbXfer->framefd;
/* Enable Message Buffer Interrupt. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64mask = 1;
FLEXCAN_EnableMbInterrupts(base, u64mask << pMbXfer->mbIdx);
#else
uint32_t u32mask = 1;
FLEXCAN_EnableMbInterrupts(base, u32mask << pMbXfer->mbIdx);
#endif
status = kStatus_Success;
}
else
{
status = kStatus_FLEXCAN_RxBusy;
}
return status;
}
#endif
/*!
* brief Receives a message from Rx FIFO using IRQ.
*
* This function receives a message using IRQ. This is a non-blocking function, which returns
* right away. When all messages have been received, the receive callback function is called.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param pFifoXfer FlexCAN Rx FIFO transfer structure. See the ref flexcan_fifo_transfer_t.
* retval kStatus_Success - Start Rx FIFO receiving process successfully.
* retval kStatus_FLEXCAN_RxFifoBusy - Rx FIFO is currently in use.
*/
status_t FLEXCAN_TransferReceiveFifoNonBlocking(CAN_Type *base,
flexcan_handle_t *handle,
flexcan_fifo_transfer_t *pFifoXfer)
{
/* Assertion. */
assert(NULL != handle);
assert(NULL != pFifoXfer);
status_t status;
/* Check if Message Buffer is idle. */
if ((uint8_t)kFLEXCAN_StateIdle == handle->rxFifoState)
{
handle->rxFifoState = (uint8_t)kFLEXCAN_StateRxFifo;
/* Register Message Buffer. */
handle->rxFifoFrameBuf = pFifoXfer->frame;
/* Enable Message Buffer Interrupt. */
FLEXCAN_EnableMbInterrupts(base, (uint32_t)kFLEXCAN_RxFifoOverflowFlag | (uint32_t)kFLEXCAN_RxFifoWarningFlag |
(uint32_t)kFLEXCAN_RxFifoFrameAvlFlag);
status = kStatus_Success;
}
else
{
status = kStatus_FLEXCAN_RxFifoBusy;
}
return status;
}
/*!
* brief Aborts the interrupt driven message send process.
*
* This function aborts the interrupt driven message send process.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param mbIdx The FlexCAN Message Buffer index.
*/
void FLEXCAN_TransferAbortSend(CAN_Type *base, flexcan_handle_t *handle, uint8_t mbIdx)
{
uint16_t timestamp;
/* Assertion. */
assert(NULL != handle);
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
/* Disable Message Buffer Interrupt. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64mask = 1;
FLEXCAN_DisableMbInterrupts(base, u64mask << mbIdx);
#else
uint32_t u32mask = 1;
FLEXCAN_DisableMbInterrupts(base, u32mask << mbIdx);
#endif
/* Update the TX frame 's time stamp by MB[mbIdx].cs. */
timestamp = (uint16_t)((base->MB[mbIdx].CS & CAN_CS_TIME_STAMP_MASK) >> CAN_CS_TIME_STAMP_SHIFT);
handle->timestamp[mbIdx] = timestamp;
/* Clean Message Buffer. */
FLEXCAN_SetTxMbConfig(base, mbIdx, true);
handle->mbState[mbIdx] = (uint8_t)kFLEXCAN_StateIdle;
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
/*!
* brief Aborts the interrupt driven message send process.
*
* This function aborts the interrupt driven message send process.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param mbIdx The FlexCAN FD Message Buffer index.
*/
void FLEXCAN_TransferFDAbortSend(CAN_Type *base, flexcan_handle_t *handle, uint8_t mbIdx)
{
volatile uint32_t *mbAddr;
uint32_t offset;
uint16_t timestamp;
/* Assertion. */
assert(NULL != handle);
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
/* Disable Message Buffer Interrupt. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64mask = 1;
FLEXCAN_DisableMbInterrupts(base, u64mask << mbIdx);
#else
uint32_t u32mask = 1;
FLEXCAN_DisableMbInterrupts(base, u32mask << mbIdx);
#endif
/* Update the TX frame 's time stamp by base->MB[offset for CANFD].CS. */
mbAddr = &(base->MB[0].CS);
offset = FLEXCAN_GetFDMailboxOffset(base, mbIdx);
timestamp = (uint16_t)((mbAddr[offset] & CAN_CS_TIME_STAMP_MASK) >> CAN_CS_TIME_STAMP_SHIFT);
handle->timestamp[mbIdx] = timestamp;
/* Clean Message Buffer. */
FLEXCAN_SetFDTxMbConfig(base, mbIdx, true);
handle->mbState[mbIdx] = (uint8_t)kFLEXCAN_StateIdle;
}
/*!
* brief Aborts the interrupt driven message receive process.
*
* This function aborts the interrupt driven message receive process.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param mbIdx The FlexCAN FD Message Buffer index.
*/
void FLEXCAN_TransferFDAbortReceive(CAN_Type *base, flexcan_handle_t *handle, uint8_t mbIdx)
{
/* Assertion. */
assert(NULL != handle);
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
/* Disable Message Buffer Interrupt. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64mask = 1;
FLEXCAN_DisableMbInterrupts(base, u64mask << mbIdx);
#else
uint32_t u32mask = 1;
FLEXCAN_DisableMbInterrupts(base, u32mask << mbIdx);
#endif
/* Un-register handle. */
handle->mbFDFrameBuf[mbIdx] = NULL;
handle->mbState[mbIdx] = (uint8_t)kFLEXCAN_StateIdle;
}
#endif
/*!
* brief Aborts the interrupt driven message receive process.
*
* This function aborts the interrupt driven message receive process.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
* param mbIdx The FlexCAN Message Buffer index.
*/
void FLEXCAN_TransferAbortReceive(CAN_Type *base, flexcan_handle_t *handle, uint8_t mbIdx)
{
/* Assertion. */
assert(NULL != handle);
assert(mbIdx <= (base->MCR & CAN_MCR_MAXMB_MASK));
#if !defined(NDEBUG)
assert(!FLEXCAN_IsMbOccupied(base, mbIdx));
#endif
/* Disable Message Buffer Interrupt. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64mask = 1;
FLEXCAN_DisableMbInterrupts(base, (u64mask << mbIdx));
#else
uint32_t u32mask = 1;
FLEXCAN_DisableMbInterrupts(base, (u32mask << mbIdx));
#endif
/* Un-register handle. */
handle->mbFrameBuf[mbIdx] = NULL;
handle->mbState[mbIdx] = (uint8_t)kFLEXCAN_StateIdle;
}
/*!
* brief Aborts the interrupt driven message receive from Rx FIFO process.
*
* This function aborts the interrupt driven message receive from Rx FIFO process.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
*/
void FLEXCAN_TransferAbortReceiveFifo(CAN_Type *base, flexcan_handle_t *handle)
{
/* Assertion. */
assert(NULL != handle);
/* Check if Rx FIFO is enabled. */
if (0U != (base->MCR & CAN_MCR_RFEN_MASK))
{
/* Disable Rx Message FIFO Interrupts. */
FLEXCAN_DisableMbInterrupts(base, (uint32_t)kFLEXCAN_RxFifoOverflowFlag | (uint32_t)kFLEXCAN_RxFifoWarningFlag |
(uint32_t)kFLEXCAN_RxFifoFrameAvlFlag);
/* Un-register handle. */
handle->rxFifoFrameBuf = NULL;
}
handle->rxFifoState = (uint8_t)kFLEXCAN_StateIdle;
}
/*!
* brief Gets the detail index of Mailbox's Timestamp by handle.
*
* Then function can only be used when calling non-blocking Data transfer (TX/RX) API,
* After TX/RX data transfer done (User can get the status by handler's callback function),
* we can get the detail index of Mailbox's timestamp by handle,
* Detail non-blocking data transfer API (TX/RX) contain.
* -FLEXCAN_TransferSendNonBlocking
* -FLEXCAN_TransferFDSendNonBlocking
* -FLEXCAN_TransferReceiveNonBlocking
* -FLEXCAN_TransferFDReceiveNonBlocking
* -FLEXCAN_TransferReceiveFifoNonBlocking
*
* param handle FlexCAN handle pointer.
* param mbIdx The FlexCAN FD Message Buffer index.
* return the index of mailbox 's timestamp stored in the handle.
*
*/
uint32_t FLEXCAN_GetTimeStamp(flexcan_handle_t *handle, uint8_t mbIdx)
{
/* Assertion. */
assert(NULL != handle);
return (uint32_t)(handle->timestamp[mbIdx]);
}
static bool FLEXCAN_CheckUnhandleInterruptEvents(CAN_Type *base)
{
uint64_t tempmask;
uint64_t tempflag;
bool fgRet = false;
/* Checking exist error flag. */
if (0U == (FLEXCAN_GetStatusFlags(base) &
((uint32_t)kFLEXCAN_TxWarningIntFlag | (uint32_t)kFLEXCAN_RxWarningIntFlag |
(uint32_t)kFLEXCAN_BusOffIntFlag | (uint32_t)kFLEXCAN_ErrorIntFlag | (uint32_t)kFLEXCAN_WakeUpIntFlag)))
{
tempmask = (uint64_t)base->IMASK1;
tempflag = (uint64_t)base->IFLAG1;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
/* Checking whether exist MB interrupt status and legacy RX FIFO interrupt status. */
tempmask |= ((uint64_t)base->IMASK2) << 32;
tempflag |= ((uint64_t)base->IFLAG2) << 32;
#endif
fgRet = (0U != (tempmask & tempflag));
}
else
{
fgRet = true;
}
return fgRet;
}
static status_t FLEXCAN_SubHandlerForDataTransfered(CAN_Type *base, flexcan_handle_t *handle, uint32_t *pResult)
{
status_t status = kStatus_FLEXCAN_UnHandled;
uint32_t result = 0xFFU;
/* For this implementation, we solve the Message with lowest MB index first. */
for (result = 0U; result < (uint32_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base); result++)
{
/* Get the lowest unhandled Message Buffer */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64flag = 1;
if (0U != FLEXCAN_GetMbStatusFlags(base, u64flag << result))
#else
uint32_t u32flag = 1;
if (0U != FLEXCAN_GetMbStatusFlags(base, u32flag << result))
#endif
{
if (FLEXCAN_IsMbIntEnabled(base, (uint8_t)result))
{
break;
}
}
}
/* find Message to deal with. */
if (result < (uint32_t)FSL_FEATURE_FLEXCAN_HAS_MESSAGE_BUFFER_MAX_NUMBERn(base))
{
/* Solve Legacy Rx FIFO interrupt. */
if (((uint8_t)kFLEXCAN_StateIdle != handle->rxFifoState) && (result <= (uint32_t)CAN_IFLAG1_BUF7I_SHIFT))
{
uint32_t u32mask = 1;
switch (u32mask << result)
{
case kFLEXCAN_RxFifoOverflowFlag:
status = kStatus_FLEXCAN_RxFifoOverflow;
break;
case kFLEXCAN_RxFifoWarningFlag:
status = kStatus_FLEXCAN_RxFifoWarning;
break;
case kFLEXCAN_RxFifoFrameAvlFlag:
status = FLEXCAN_ReadRxFifo(base, handle->rxFifoFrameBuf);
if (kStatus_Success == status)
{
/* Align the current (index 0) rxfifo timestamp to the timestamp array by handle. */
handle->timestamp[0] = handle->rxFifoFrameBuf->timestamp;
status = kStatus_FLEXCAN_RxFifoIdle;
}
FLEXCAN_TransferAbortReceiveFifo(base, handle);
break;
default:
status = kStatus_FLEXCAN_UnHandled;
break;
}
}
else
{
/* Get current State of Message Buffer. */
switch (handle->mbState[result])
{
/* Solve Rx Data Frame. */
case (uint8_t)kFLEXCAN_StateRxData:
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
if (0U != (base->MCR & CAN_MCR_FDEN_MASK))
{
status = FLEXCAN_ReadFDRxMb(base, (uint8_t)result, handle->mbFDFrameBuf[result]);
if (kStatus_Success == status)
{
/* Align the current index of RX MB timestamp to the timestamp array by handle. */
handle->timestamp[result] = handle->mbFDFrameBuf[result]->timestamp;
status = kStatus_FLEXCAN_RxIdle;
}
}
else
#endif
{
status = FLEXCAN_ReadRxMb(base, (uint8_t)result, handle->mbFrameBuf[result]);
if (kStatus_Success == status)
{
/* Align the current index of RX MB timestamp to the timestamp array by handle. */
handle->timestamp[result] = handle->mbFrameBuf[result]->timestamp;
status = kStatus_FLEXCAN_RxIdle;
}
}
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
if (0U != (base->MCR & CAN_MCR_FDEN_MASK))
{
FLEXCAN_TransferFDAbortReceive(base, handle, (uint8_t)result);
}
else
#endif
{
FLEXCAN_TransferAbortReceive(base, handle, (uint8_t)result);
}
break;
/* Sove Rx Remote Frame. User need to Read the frame in Mail box in time by Read from MB API. */
case (uint8_t)kFLEXCAN_StateRxRemote:
status = kStatus_FLEXCAN_RxRemote;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
if (0U != (base->MCR & CAN_MCR_FDEN_MASK))
{
FLEXCAN_TransferFDAbortReceive(base, handle, (uint8_t)result);
}
else
#endif
{
FLEXCAN_TransferAbortReceive(base, handle, (uint8_t)result);
}
break;
/* Solve Tx Data Frame. */
case (uint8_t)kFLEXCAN_StateTxData:
status = kStatus_FLEXCAN_TxIdle;
#if (defined(FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE) && FSL_FEATURE_FLEXCAN_HAS_FLEXIBLE_DATA_RATE)
if (0U != (base->MCR & CAN_MCR_FDEN_MASK))
{
FLEXCAN_TransferFDAbortSend(base, handle, (uint8_t)result);
}
else
#endif
{
FLEXCAN_TransferAbortSend(base, handle, (uint8_t)result);
}
break;
/* Solve Tx Remote Frame. */
case (uint8_t)kFLEXCAN_StateTxRemote:
handle->mbState[result] = (uint8_t)kFLEXCAN_StateRxRemote;
status = kStatus_FLEXCAN_TxSwitchToRx;
break;
default:
status = kStatus_FLEXCAN_UnHandled;
break;
}
}
/* Clear resolved Message Buffer IRQ. */
#if (defined(FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER)) && (FSL_FEATURE_FLEXCAN_HAS_EXTENDED_FLAG_REGISTER > 0)
uint64_t u64flag = 1;
FLEXCAN_ClearMbStatusFlags(base, u64flag << result);
#else
uint32_t u32flag = 1;
FLEXCAN_ClearMbStatusFlags(base, u32flag << result);
#endif
}
*pResult = result;
return status;
}
/*!
* brief FlexCAN IRQ handle function.
*
* This function handles the FlexCAN Error, the Message Buffer, and the Rx FIFO IRQ request.
*
* param base FlexCAN peripheral base address.
* param handle FlexCAN handle pointer.
*/
void FLEXCAN_TransferHandleIRQ(CAN_Type *base, flexcan_handle_t *handle)
{
/* Assertion. */
assert(NULL != handle);
status_t status;
uint32_t result = 0xFFU;
uint32_t EsrStatus = 0U;
do
{
/* Get Current FlexCAN Module Error and Status. */
EsrStatus = FLEXCAN_GetStatusFlags(base);
/* To handle FlexCAN Error and Status Interrupt first. */
if (0U != (EsrStatus & ((uint32_t)kFLEXCAN_TxWarningIntFlag | (uint32_t)kFLEXCAN_RxWarningIntFlag |
(uint32_t)kFLEXCAN_BusOffIntFlag | (uint32_t)kFLEXCAN_ErrorIntFlag)))
{
status = kStatus_FLEXCAN_ErrorStatus;
/* Clear FlexCAN Error and Status Interrupt. */
FLEXCAN_ClearStatusFlags(base, (uint32_t)kFLEXCAN_TxWarningIntFlag | (uint32_t)kFLEXCAN_RxWarningIntFlag |
(uint32_t)kFLEXCAN_BusOffIntFlag | (uint32_t)kFLEXCAN_ErrorIntFlag);
result = EsrStatus;
}
else if (0U != (EsrStatus & (uint32_t)kFLEXCAN_WakeUpIntFlag))
{
status = kStatus_FLEXCAN_WakeUp;
FLEXCAN_ClearStatusFlags(base, (uint32_t)kFLEXCAN_WakeUpIntFlag);
}
else
{
/* to handle real data transfer. */
status = FLEXCAN_SubHandlerForDataTransfered(base, handle, &result);
}
/* Calling Callback Function if has one. */
if (handle->callback != NULL)
{
handle->callback(base, handle, status, result, handle->userData);
}
} while (FLEXCAN_CheckUnhandleInterruptEvents(base));
}
#if defined(CAN0)
void CAN0_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[0]);
s_flexcanIsr(CAN0, s_flexcanHandle[0]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(CAN1)
void CAN1_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[1]);
s_flexcanIsr(CAN1, s_flexcanHandle[1]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(CAN2)
void CAN2_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[2]);
s_flexcanIsr(CAN2, s_flexcanHandle[2]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(CAN3)
void CAN3_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[3]);
s_flexcanIsr(CAN3, s_flexcanHandle[3]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(CAN4)
void CAN4_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[4]);
s_flexcanIsr(CAN4, s_flexcanHandle[4]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(DMA__CAN0)
void DMA_FLEXCAN0_INT_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[FLEXCAN_GetInstance(DMA__CAN0)]);
s_flexcanIsr(DMA__CAN0, s_flexcanHandle[FLEXCAN_GetInstance(DMA__CAN0)]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(DMA__CAN1)
void DMA_FLEXCAN1_INT_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[FLEXCAN_GetInstance(DMA__CAN1)]);
s_flexcanIsr(DMA__CAN1, s_flexcanHandle[FLEXCAN_GetInstance(DMA__CAN1)]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(DMA__CAN2)
void DMA_FLEXCAN2_INT_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[FLEXCAN_GetInstance(DMA__CAN2)]);
s_flexcanIsr(DMA__CAN2, s_flexcanHandle[FLEXCAN_GetInstance(DMA__CAN2)]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(ADMA__CAN0)
void ADMA_FLEXCAN0_INT_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[FLEXCAN_GetInstance(ADMA__CAN0)]);
s_flexcanIsr(ADMA__CAN0, s_flexcanHandle[FLEXCAN_GetInstance(ADMA__CAN0)]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(ADMA__CAN1)
void ADMA_FLEXCAN1_INT_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[FLEXCAN_GetInstance(ADMA__CAN1)]);
s_flexcanIsr(ADMA__CAN1, s_flexcanHandle[FLEXCAN_GetInstance(ADMA__CAN1)]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(ADMA__CAN2)
void ADMA_FLEXCAN2_INT_DriverIRQHandler(void)
{
assert(NULL != s_flexcanHandle[FLEXCAN_GetInstance(ADMA__CAN2)]);
s_flexcanIsr(ADMA__CAN2, s_flexcanHandle[FLEXCAN_GetInstance(ADMA__CAN2)]);
SDK_ISR_EXIT_BARRIER;
}
#endif