/* * Copyright (c) 2015, Freescale Semiconductor, Inc. * Copyright 2016-2019 NXP * All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include "fsl_lpspi.h" /******************************************************************************* * Definitions ******************************************************************************/ /* Component ID definition, used by tools. */ #ifndef FSL_COMPONENT_ID #define FSL_COMPONENT_ID "platform.drivers.lpspi" #endif /*! * @brief Default watermark values. * * The default watermarks are set to zero. */ enum _lpspi_default_watermarks { kLpspiDefaultTxWatermark = 0, kLpspiDefaultRxWatermark = 0, }; /*! @brief Typedef for master interrupt handler. */ typedef void (*lpspi_master_isr_t)(LPSPI_Type *base, lpspi_master_handle_t *handle); /*! @brief Typedef for slave interrupt handler. */ typedef void (*lpspi_slave_isr_t)(LPSPI_Type *base, lpspi_slave_handle_t *handle); /******************************************************************************* * Prototypes ******************************************************************************/ /*! * @brief Configures the LPSPI peripheral chip select polarity. * * This function takes in the desired peripheral chip select (Pcs) and it's corresponding desired polarity and * configures the Pcs signal to operate with the desired characteristic. * * @param base LPSPI peripheral address. * @param pcs The particular peripheral chip select (parameter value is of type lpspi_which_pcs_t) for which we wish to * apply the active high or active low characteristic. * @param activeLowOrHigh The setting for either "active high, inactive low (0)" or "active low, inactive high(1)" of * type lpspi_pcs_polarity_config_t. */ static void LPSPI_SetOnePcsPolarity(LPSPI_Type *base, lpspi_which_pcs_t pcs, lpspi_pcs_polarity_config_t activeLowOrHigh); /*! * @brief Combine the write data for 1 byte to 4 bytes. * This is not a public API. */ static uint32_t LPSPI_CombineWriteData(uint8_t *txData, uint8_t bytesEachWrite, bool isByteSwap); /*! * @brief Separate the read data for 1 byte to 4 bytes. * This is not a public API. */ static void LPSPI_SeparateReadData(uint8_t *rxData, uint32_t readData, uint8_t bytesEachRead, bool isByteSwap); /*! * @brief Master fill up the TX FIFO with data. * This is not a public API. */ static void LPSPI_MasterTransferFillUpTxFifo(LPSPI_Type *base, lpspi_master_handle_t *handle); /*! * @brief Master finish up a transfer. * It would call back if there is callback function and set the state to idle. * This is not a public API. */ static void LPSPI_MasterTransferComplete(LPSPI_Type *base, lpspi_master_handle_t *handle); /*! * @brief Slave fill up the TX FIFO with data. * This is not a public API. */ static void LPSPI_SlaveTransferFillUpTxFifo(LPSPI_Type *base, lpspi_slave_handle_t *handle); /*! * @brief Slave finish up a transfer. * It would call back if there is callback function and set the state to idle. * This is not a public API. */ static void LPSPI_SlaveTransferComplete(LPSPI_Type *base, lpspi_slave_handle_t *handle); /*! * @brief LPSPI common interrupt handler. * * @param handle pointer to s_lpspiHandle which stores the transfer state. */ static void LPSPI_CommonIRQHandler(LPSPI_Type *base, void *param); /******************************************************************************* * Variables ******************************************************************************/ /* Defines constant value arrays for the baud rate pre-scalar and scalar divider values.*/ static const uint8_t s_baudratePrescaler[] = {1, 2, 4, 8, 16, 32, 64, 128}; /*! @brief Pointers to lpspi bases for each instance. */ static LPSPI_Type *const s_lpspiBases[] = LPSPI_BASE_PTRS; /*! @brief Pointers to lpspi IRQ number for each instance. */ static const IRQn_Type s_lpspiIRQ[] = LPSPI_IRQS; #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) /*! @brief Pointers to lpspi clocks for each instance. */ static const clock_ip_name_t s_lpspiClocks[] = LPSPI_CLOCKS; #if defined(LPSPI_PERIPH_CLOCKS) static const clock_ip_name_t s_LpspiPeriphClocks[] = LPSPI_PERIPH_CLOCKS; #endif #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */ /*! @brief Pointers to lpspi handles for each instance. */ static void *s_lpspiHandle[ARRAY_SIZE(s_lpspiBases)]; /*! @brief Pointer to master IRQ handler for each instance. */ static lpspi_master_isr_t s_lpspiMasterIsr; /*! @brief Pointer to slave IRQ handler for each instance. */ static lpspi_slave_isr_t s_lpspiSlaveIsr; /* @brief Dummy data for each instance. This data is used when user's tx buffer is NULL*/ volatile uint8_t g_lpspiDummyData[ARRAY_SIZE(s_lpspiBases)] = {0}; /********************************************************************************************************************** * Code *********************************************************************************************************************/ /*! * brief Get the LPSPI instance from peripheral base address. * * param base LPSPI peripheral base address. * return LPSPI instance. */ uint32_t LPSPI_GetInstance(LPSPI_Type *base) { uint8_t instance = 0; /* Find the instance index from base address mappings. */ for (instance = 0; instance < ARRAY_SIZE(s_lpspiBases); instance++) { if (s_lpspiBases[instance] == base) { break; } } assert(instance < ARRAY_SIZE(s_lpspiBases)); return instance; } /*! * brief Set up the dummy data. * * param base LPSPI peripheral address. * param dummyData Data to be transferred when tx buffer is NULL. * Note: * This API has no effect when LPSPI in slave interrupt mode, because driver * will set the TXMSK bit to 1 if txData is NULL, no data is loaded from transmit * FIFO and output pin is tristated. */ void LPSPI_SetDummyData(LPSPI_Type *base, uint8_t dummyData) { uint32_t instance = LPSPI_GetInstance(base); g_lpspiDummyData[instance] = dummyData; } /*! * brief Initializes the LPSPI master. * * param base LPSPI peripheral address. * param masterConfig Pointer to structure lpspi_master_config_t. * param srcClock_Hz Module source input clock in Hertz */ void LPSPI_MasterInit(LPSPI_Type *base, const lpspi_master_config_t *masterConfig, uint32_t srcClock_Hz) { assert(masterConfig); uint32_t tcrPrescaleValue = 0; #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) uint32_t instance = LPSPI_GetInstance(base); /* Enable LPSPI clock */ (void)CLOCK_EnableClock(s_lpspiClocks[instance]); #if defined(LPSPI_PERIPH_CLOCKS) (void)CLOCK_EnableClock(s_LpspiPeriphClocks[instance]); #endif #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */ /* Set LPSPI to master */ LPSPI_SetMasterSlaveMode(base, kLPSPI_Master); /* Set specific PCS to active high or low */ LPSPI_SetOnePcsPolarity(base, masterConfig->whichPcs, masterConfig->pcsActiveHighOrLow); /* Set Configuration Register 1 related setting.*/ base->CFGR1 = (base->CFGR1 & ~(LPSPI_CFGR1_OUTCFG_MASK | LPSPI_CFGR1_PINCFG_MASK | LPSPI_CFGR1_NOSTALL_MASK)) | LPSPI_CFGR1_OUTCFG(masterConfig->dataOutConfig) | LPSPI_CFGR1_PINCFG(masterConfig->pinCfg) | LPSPI_CFGR1_NOSTALL(0); /* Set baudrate and delay times*/ (void)LPSPI_MasterSetBaudRate(base, masterConfig->baudRate, srcClock_Hz, &tcrPrescaleValue); /* Set default watermarks */ LPSPI_SetFifoWatermarks(base, (uint32_t)kLpspiDefaultTxWatermark, (uint32_t)kLpspiDefaultRxWatermark); /* Set Transmit Command Register*/ base->TCR = LPSPI_TCR_CPOL(masterConfig->cpol) | LPSPI_TCR_CPHA(masterConfig->cpha) | LPSPI_TCR_LSBF(masterConfig->direction) | LPSPI_TCR_FRAMESZ(masterConfig->bitsPerFrame - 1U) | LPSPI_TCR_PRESCALE(tcrPrescaleValue) | LPSPI_TCR_PCS(masterConfig->whichPcs); LPSPI_Enable(base, true); (void)LPSPI_MasterSetDelayTimes(base, masterConfig->pcsToSckDelayInNanoSec, kLPSPI_PcsToSck, srcClock_Hz); (void)LPSPI_MasterSetDelayTimes(base, masterConfig->lastSckToPcsDelayInNanoSec, kLPSPI_LastSckToPcs, srcClock_Hz); (void)LPSPI_MasterSetDelayTimes(base, masterConfig->betweenTransferDelayInNanoSec, kLPSPI_BetweenTransfer, srcClock_Hz); LPSPI_SetDummyData(base, LPSPI_DUMMY_DATA); } /*! * brief Sets the lpspi_master_config_t structure to default values. * * This API initializes the configuration structure for LPSPI_MasterInit(). * The initialized structure can remain unchanged in LPSPI_MasterInit(), or can be modified * before calling the LPSPI_MasterInit(). * Example: * code * lpspi_master_config_t masterConfig; * LPSPI_MasterGetDefaultConfig(&masterConfig); * endcode * param masterConfig pointer to lpspi_master_config_t structure */ void LPSPI_MasterGetDefaultConfig(lpspi_master_config_t *masterConfig) { assert(masterConfig); /* Initializes the configure structure to zero. */ (void)memset(masterConfig, 0, sizeof(*masterConfig)); masterConfig->baudRate = 500000; masterConfig->bitsPerFrame = 8; masterConfig->cpol = kLPSPI_ClockPolarityActiveHigh; masterConfig->cpha = kLPSPI_ClockPhaseFirstEdge; masterConfig->direction = kLPSPI_MsbFirst; masterConfig->pcsToSckDelayInNanoSec = 1000000000U / masterConfig->baudRate * 2U; masterConfig->lastSckToPcsDelayInNanoSec = 1000000000U / masterConfig->baudRate * 2U; masterConfig->betweenTransferDelayInNanoSec = 1000000000U / masterConfig->baudRate * 2U; masterConfig->whichPcs = kLPSPI_Pcs0; masterConfig->pcsActiveHighOrLow = kLPSPI_PcsActiveLow; masterConfig->pinCfg = kLPSPI_SdiInSdoOut; masterConfig->dataOutConfig = kLpspiDataOutRetained; } /*! * brief LPSPI slave configuration. * * param base LPSPI peripheral address. * param slaveConfig Pointer to a structure lpspi_slave_config_t. */ void LPSPI_SlaveInit(LPSPI_Type *base, const lpspi_slave_config_t *slaveConfig) { assert(slaveConfig); #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) uint32_t instance = LPSPI_GetInstance(base); /* Enable LPSPI clock */ (void)CLOCK_EnableClock(s_lpspiClocks[instance]); #if defined(LPSPI_PERIPH_CLOCKS) (void)CLOCK_EnableClock(s_LpspiPeriphClocks[instance]); #endif #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */ LPSPI_SetMasterSlaveMode(base, kLPSPI_Slave); LPSPI_SetOnePcsPolarity(base, slaveConfig->whichPcs, slaveConfig->pcsActiveHighOrLow); base->CFGR1 = (base->CFGR1 & ~(LPSPI_CFGR1_OUTCFG_MASK | LPSPI_CFGR1_PINCFG_MASK)) | LPSPI_CFGR1_OUTCFG(slaveConfig->dataOutConfig) | LPSPI_CFGR1_PINCFG(slaveConfig->pinCfg); LPSPI_SetFifoWatermarks(base, (uint32_t)kLpspiDefaultTxWatermark, (uint32_t)kLpspiDefaultRxWatermark); base->TCR = LPSPI_TCR_CPOL(slaveConfig->cpol) | LPSPI_TCR_CPHA(slaveConfig->cpha) | LPSPI_TCR_LSBF(slaveConfig->direction) | LPSPI_TCR_FRAMESZ(slaveConfig->bitsPerFrame - 1U); /* This operation will set the dummy data for edma transfer, no effect in interrupt way. */ LPSPI_SetDummyData(base, LPSPI_DUMMY_DATA); LPSPI_Enable(base, true); } /*! * brief Sets the lpspi_slave_config_t structure to default values. * * This API initializes the configuration structure for LPSPI_SlaveInit(). * The initialized structure can remain unchanged in LPSPI_SlaveInit() or can be modified * before calling the LPSPI_SlaveInit(). * Example: * code * lpspi_slave_config_t slaveConfig; * LPSPI_SlaveGetDefaultConfig(&slaveConfig); * endcode * param slaveConfig pointer to lpspi_slave_config_t structure. */ void LPSPI_SlaveGetDefaultConfig(lpspi_slave_config_t *slaveConfig) { assert(slaveConfig); /* Initializes the configure structure to zero. */ (void)memset(slaveConfig, 0, sizeof(*slaveConfig)); slaveConfig->bitsPerFrame = 8; /*!< Bits per frame, minimum 8, maximum 4096.*/ slaveConfig->cpol = kLPSPI_ClockPolarityActiveHigh; /*!< Clock polarity. */ slaveConfig->cpha = kLPSPI_ClockPhaseFirstEdge; /*!< Clock phase. */ slaveConfig->direction = kLPSPI_MsbFirst; /*!< MSB or LSB data shift direction. */ slaveConfig->whichPcs = kLPSPI_Pcs0; /*!< Desired Peripheral Chip Select (pcs) */ slaveConfig->pcsActiveHighOrLow = kLPSPI_PcsActiveLow; /*!< Desired PCS active high or low */ slaveConfig->pinCfg = kLPSPI_SdiInSdoOut; slaveConfig->dataOutConfig = kLpspiDataOutRetained; } /*! * brief Restores the LPSPI peripheral to reset state. Note that this function * sets all registers to reset state. As a result, the LPSPI module can't work after calling * this API. * param base LPSPI peripheral address. */ void LPSPI_Reset(LPSPI_Type *base) { /* Reset all internal logic and registers, except the Control Register. Remains set until cleared by software.*/ base->CR |= LPSPI_CR_RST_MASK; /* Software reset doesn't reset the CR, so manual reset the FIFOs */ base->CR |= LPSPI_CR_RRF_MASK | LPSPI_CR_RTF_MASK; /* Master logic is not reset and module is disabled.*/ base->CR = 0x00U; } /*! * brief De-initializes the LPSPI peripheral. Call this API to disable the LPSPI clock. * param base LPSPI peripheral address. */ void LPSPI_Deinit(LPSPI_Type *base) { /* Reset to default value */ LPSPI_Reset(base); #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) uint32_t instance = LPSPI_GetInstance(base); /* Enable LPSPI clock */ (void)CLOCK_DisableClock(s_lpspiClocks[instance]); #if defined(LPSPI_PERIPH_CLOCKS) (void)CLOCK_DisableClock(s_LpspiPeriphClocks[instance]); #endif #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */ } static void LPSPI_SetOnePcsPolarity(LPSPI_Type *base, lpspi_which_pcs_t pcs, lpspi_pcs_polarity_config_t activeLowOrHigh) { uint32_t cfgr1Value = 0; /* Clear the PCS polarity bit */ cfgr1Value = base->CFGR1 & ~(1UL << (LPSPI_CFGR1_PCSPOL_SHIFT + (uint32_t)pcs)); /* Configure the PCS polarity bit according to the activeLowOrHigh setting */ base->CFGR1 = cfgr1Value | ((uint32_t)activeLowOrHigh << (LPSPI_CFGR1_PCSPOL_SHIFT + (uint32_t)pcs)); } /*! * brief Sets the LPSPI baud rate in bits per second. * * This function takes in the desired bitsPerSec (baud rate) and calculates the nearest * possible baud rate without exceeding the desired baud rate and returns the * calculated baud rate in bits-per-second. It requires the caller to provide * the frequency of the module source clock (in Hertz). Note that the baud rate * does not go into effect until the Transmit Control Register (TCR) is programmed * with the prescale value. Hence, this function returns the prescale tcrPrescaleValue * parameter for later programming in the TCR. The higher level * peripheral driver should alert the user of an out of range baud rate input. * * Note that the LPSPI module must first be disabled before configuring this. * Note that the LPSPI module must be configured for master mode before configuring this. * * param base LPSPI peripheral address. * param baudRate_Bps The desired baud rate in bits per second. * param srcClock_Hz Module source input clock in Hertz. * param tcrPrescaleValue The TCR prescale value needed to program the TCR. * return The actual calculated baud rate. This function may also return a "0" if the * LPSPI is not configured for master mode or if the LPSPI module is not disabled. */ uint32_t LPSPI_MasterSetBaudRate(LPSPI_Type *base, uint32_t baudRate_Bps, uint32_t srcClock_Hz, uint32_t *tcrPrescaleValue) { assert(tcrPrescaleValue); /* For master mode configuration only, if slave mode detected, return 0. * Also, the LPSPI module needs to be disabled first, if enabled, return 0 */ if ((!LPSPI_IsMaster(base)) || ((base->CR & LPSPI_CR_MEN_MASK) != 0U)) { return 0U; } uint32_t prescaler, bestPrescaler; uint32_t scaler, bestScaler; uint32_t realBaudrate, bestBaudrate; uint32_t diff, min_diff; uint32_t desiredBaudrate = baudRate_Bps; /* find combination of prescaler and scaler resulting in baudrate closest to the * requested value */ min_diff = 0xFFFFFFFFU; /* Set to maximum divisor value bit settings so that if baud rate passed in is less * than the minimum possible baud rate, then the SPI will be configured to the lowest * possible baud rate */ bestPrescaler = 7; bestScaler = 255; bestBaudrate = 0; /* required to avoid compilation warning */ /* In all for loops, if min_diff = 0, the exit for loop*/ for (prescaler = 0U; prescaler < 8U; prescaler++) { if (min_diff == 0U) { break; } for (scaler = 0U; scaler < 256U; scaler++) { if (min_diff == 0U) { break; } realBaudrate = (srcClock_Hz / (s_baudratePrescaler[prescaler] * (scaler + 2U))); /* calculate the baud rate difference based on the conditional statement * that states that the calculated baud rate must not exceed the desired baud rate */ if (desiredBaudrate >= realBaudrate) { diff = desiredBaudrate - realBaudrate; if (min_diff > diff) { /* a better match found */ min_diff = diff; bestPrescaler = prescaler; bestScaler = scaler; bestBaudrate = realBaudrate; } } } } /* Write the best baud rate scalar to the CCR. * Note, no need to check for error since we've already checked to make sure the module is * disabled and in master mode. Also, there is a limit on the maximum divider so we will not * exceed this. */ base->CCR = (base->CCR & ~LPSPI_CCR_SCKDIV_MASK) | LPSPI_CCR_SCKDIV(bestScaler); /* return the best prescaler value for user to use later */ *tcrPrescaleValue = bestPrescaler; /* return the actual calculated baud rate */ return bestBaudrate; } /*! * brief Manually configures a specific LPSPI delay parameter (module must be disabled to * change the delay values). * * This function configures the following: * SCK to PCS delay, or * PCS to SCK delay, or * The configurations must occur between the transfer delay. * * The delay names are available in type lpspi_delay_type_t. * * The user passes the desired delay along with the delay value. * This allows the user to directly set the delay values if they have * pre-calculated them or if they simply wish to manually increment the value. * * Note that the LPSPI module must first be disabled before configuring this. * Note that the LPSPI module must be configured for master mode before configuring this. * * param base LPSPI peripheral address. * param scaler The 8-bit delay value 0x00 to 0xFF (255). * param whichDelay The desired delay to configure, must be of type lpspi_delay_type_t. */ void LPSPI_MasterSetDelayScaler(LPSPI_Type *base, uint32_t scaler, lpspi_delay_type_t whichDelay) { /*These settings are only relevant in master mode */ switch (whichDelay) { case kLPSPI_PcsToSck: base->CCR = (base->CCR & (~LPSPI_CCR_PCSSCK_MASK)) | LPSPI_CCR_PCSSCK(scaler); break; case kLPSPI_LastSckToPcs: base->CCR = (base->CCR & (~LPSPI_CCR_SCKPCS_MASK)) | LPSPI_CCR_SCKPCS(scaler); break; case kLPSPI_BetweenTransfer: base->CCR = (base->CCR & (~LPSPI_CCR_DBT_MASK)) | LPSPI_CCR_DBT(scaler); break; default: assert(false); break; } } /*! * brief Calculates the delay based on the desired delay input in nanoseconds (module must be * disabled to change the delay values). * * This function calculates the values for the following: * SCK to PCS delay, or * PCS to SCK delay, or * The configurations must occur between the transfer delay. * * The delay names are available in type lpspi_delay_type_t. * * The user passes the desired delay and the desired delay value in * nano-seconds. The function calculates the value needed for the desired delay parameter * and returns the actual calculated delay because an exact delay match may not be possible. In this * case, the closest match is calculated without going below the desired delay value input. * It is possible to input a very large delay value that exceeds the capability of the part, in * which case the maximum supported delay is returned. It is up to the higher level * peripheral driver to alert the user of an out of range delay input. * * Note that the LPSPI module must be configured for master mode before configuring this. And note that * the delayTime = LPSPI_clockSource / (PRESCALE * Delay_scaler). * * param base LPSPI peripheral address. * param delayTimeInNanoSec The desired delay value in nano-seconds. * param whichDelay The desired delay to configuration, which must be of type lpspi_delay_type_t. * param srcClock_Hz Module source input clock in Hertz. * return actual Calculated delay value in nano-seconds. */ uint32_t LPSPI_MasterSetDelayTimes(LPSPI_Type *base, uint32_t delayTimeInNanoSec, lpspi_delay_type_t whichDelay, uint32_t srcClock_Hz) { uint64_t realDelay, bestDelay; uint32_t scaler, bestScaler; uint32_t diff, min_diff; uint64_t initialDelayNanoSec; uint32_t clockDividedPrescaler; /* For delay between transfer, an additional scaler value is needed */ uint32_t additionalScaler = 0; /*As the RM note, the LPSPI baud rate clock is itself divided by the PRESCALE setting, which can vary between * transfers.*/ clockDividedPrescaler = srcClock_Hz / s_baudratePrescaler[(base->TCR & LPSPI_TCR_PRESCALE_MASK) >> LPSPI_TCR_PRESCALE_SHIFT]; /* Find combination of prescaler and scaler resulting in the delay closest to the requested value.*/ min_diff = 0xFFFFFFFFU; /* Initialize scaler to max value to generate the max delay */ bestScaler = 0xFFU; /* Calculate the initial (min) delay and maximum possible delay based on the specific delay as * the delay divisors are slightly different based on which delay we are configuring. */ if (whichDelay == kLPSPI_BetweenTransfer) { /* First calculate the initial, default delay, note min delay is 2 clock cycles. Due to large size of calculated values (uint64_t), we need to break up the calculation into several steps to ensure accurate calculated results */ initialDelayNanoSec = 1000000000U; initialDelayNanoSec *= 2U; initialDelayNanoSec /= clockDividedPrescaler; /* Calculate the maximum delay */ bestDelay = 1000000000U; bestDelay *= 257U; /* based on DBT+2, or 255 + 2 */ bestDelay /= clockDividedPrescaler; additionalScaler = 1U; } else { /* First calculate the initial, default delay, min delay is 1 clock cycle. Due to large size of calculated values (uint64_t), we need to break up the calculation into several steps to ensure accurate calculated results. */ initialDelayNanoSec = 1000000000U; initialDelayNanoSec /= clockDividedPrescaler; /* Calculate the maximum delay */ bestDelay = 1000000000U; bestDelay *= 256U; /* based on SCKPCS+1 or PCSSCK+1, or 255 + 1 */ bestDelay /= clockDividedPrescaler; additionalScaler = 0U; } /* If the initial, default delay is already greater than the desired delay, then * set the delay to their initial value (0) and return the delay. In other words, * there is no way to decrease the delay value further. */ if (initialDelayNanoSec >= delayTimeInNanoSec) { LPSPI_MasterSetDelayScaler(base, 0, whichDelay); return (uint32_t)initialDelayNanoSec; } /* If min_diff = 0, the exit for loop */ for (scaler = 0U; scaler < 256U; scaler++) { if (min_diff == 0U) { break; } /* Calculate the real delay value as we cycle through the scaler values. Due to large size of calculated values (uint64_t), we need to break up the calculation into several steps to ensure accurate calculated results */ realDelay = 1000000000U; realDelay *= ((uint64_t)scaler + 1UL + (uint64_t)additionalScaler); realDelay /= clockDividedPrescaler; /* calculate the delay difference based on the conditional statement * that states that the calculated delay must not be less then the desired delay */ if (realDelay >= delayTimeInNanoSec) { diff = (uint32_t)(realDelay - (uint64_t)delayTimeInNanoSec); if (min_diff > diff) { /* a better match found */ min_diff = diff; bestScaler = scaler; bestDelay = realDelay; } } } /* write the best scaler value for the delay */ LPSPI_MasterSetDelayScaler(base, bestScaler, whichDelay); /* return the actual calculated delay value (in ns) */ return (uint32_t)bestDelay; } /*Transactional APIs -- Master*/ /*! * brief Initializes the LPSPI master handle. * * This function initializes the LPSPI handle, which can be used for other LPSPI transactional APIs. Usually, for a * specified LPSPI instance, call this API once to get the initialized handle. * param base LPSPI peripheral address. * param handle LPSPI handle pointer to lpspi_master_handle_t. * param callback DSPI callback. * param userData callback function parameter. */ void LPSPI_MasterTransferCreateHandle(LPSPI_Type *base, lpspi_master_handle_t *handle, lpspi_master_transfer_callback_t callback, void *userData) { assert(handle); /* Zero the handle. */ (void)memset(handle, 0, sizeof(*handle)); s_lpspiHandle[LPSPI_GetInstance(base)] = handle; /* Set irq handler. */ s_lpspiMasterIsr = LPSPI_MasterTransferHandleIRQ; handle->callback = callback; handle->userData = userData; } /*! * brief Check the argument for transfer . * * param transfer the transfer struct to be used. * param bitPerFrame The bit size of one frame. * param bytePerFrame The byte size of one frame. * return Return true for right and false for wrong. */ bool LPSPI_CheckTransferArgument(lpspi_transfer_t *transfer, uint32_t bitsPerFrame, uint32_t bytesPerFrame) { assert(transfer); /* If the transfer count is zero, then return immediately.*/ if (transfer->dataSize == 0U) { return false; } /* If both send buffer and receive buffer is null */ if ((NULL == (transfer->txData)) && (NULL == (transfer->rxData))) { return false; } /*The transfer data size should be integer multiples of bytesPerFrame if bytesPerFrame is less than or equal to 4 . *For bytesPerFrame greater than 4 situation: *the transfer data size should be equal to bytesPerFrame if the bytesPerFrame is not integer multiples of 4 , *otherwise , the transfer data size can be integer multiples of bytesPerFrame. */ if (bytesPerFrame <= 4U) { if ((transfer->dataSize % bytesPerFrame) != 0U) { return false; } } else { if ((bytesPerFrame % 4U) != 0U) { if (transfer->dataSize != bytesPerFrame) { return false; } } else { if ((transfer->dataSize % bytesPerFrame) != 0U) { return false; } } } return true; } /*! * brief LPSPI master transfer data using a polling method. * * This function transfers data using a polling method. This is a blocking function, which does not return until all * transfers have been * completed. * * Note: * The transfer data size should be integer multiples of bytesPerFrame if bytesPerFrame is less than or equal to 4. * For bytesPerFrame greater than 4: * The transfer data size should be equal to bytesPerFrame if the bytesPerFrame is not integer multiples of 4. * Otherwise, the transfer data size can be an integer multiple of bytesPerFrame. * * param base LPSPI peripheral address. * param transfer pointer to lpspi_transfer_t structure. * return status of status_t. */ status_t LPSPI_MasterTransferBlocking(LPSPI_Type *base, lpspi_transfer_t *transfer) { assert(transfer); uint32_t bitsPerFrame = ((base->TCR & LPSPI_TCR_FRAMESZ_MASK) >> LPSPI_TCR_FRAMESZ_SHIFT) + 1U; uint32_t bytesPerFrame = (bitsPerFrame + 7U) / 8U; uint32_t temp = 0U; uint8_t dummyData = g_lpspiDummyData[LPSPI_GetInstance(base)]; if (!LPSPI_CheckTransferArgument(transfer, bitsPerFrame, bytesPerFrame)) { return kStatus_InvalidArgument; } /* Check that LPSPI is not busy.*/ if ((LPSPI_GetStatusFlags(base) & (uint32_t)kLPSPI_ModuleBusyFlag) != 0U) { return kStatus_LPSPI_Busy; } uint8_t *txData = transfer->txData; uint8_t *rxData = transfer->rxData; uint32_t txRemainingByteCount = transfer->dataSize; uint32_t rxRemainingByteCount = transfer->dataSize; uint8_t bytesEachWrite; uint8_t bytesEachRead; uint32_t readData = 0U; uint32_t wordToSend = ((uint32_t)dummyData) | ((uint32_t)dummyData << 8) | ((uint32_t)dummyData << 16) | ((uint32_t)dummyData << 24); /*The TX and RX FIFO sizes are always the same*/ uint32_t fifoSize = LPSPI_GetRxFifoSize(base); uint32_t rxFifoMaxBytes = MIN(bytesPerFrame, 4U) * fifoSize; uint32_t whichPcs = (transfer->configFlags & LPSPI_MASTER_PCS_MASK) >> LPSPI_MASTER_PCS_SHIFT; bool isPcsContinuous = ((transfer->configFlags & (uint32_t)kLPSPI_MasterPcsContinuous) != 0U); bool isRxMask = false; bool isByteSwap = ((transfer->configFlags & (uint32_t)kLPSPI_MasterByteSwap) != 0U); #if SPI_RETRY_TIMES uint32_t waitTimes; #endif LPSPI_FlushFifo(base, true, true); LPSPI_ClearStatusFlags(base, (uint32_t)kLPSPI_AllStatusFlag); if (NULL == rxData) { isRxMask = true; } LPSPI_Enable(base, false); base->CFGR1 &= (~LPSPI_CFGR1_NOSTALL_MASK); /* Check if using 3-wire mode and the txData is NULL, set the output pin to tristated. */ temp = base->CFGR1; temp &= LPSPI_CFGR1_PINCFG_MASK; if ((temp == LPSPI_CFGR1_PINCFG(kLPSPI_SdiInSdiOut)) || (temp == LPSPI_CFGR1_PINCFG(kLPSPI_SdoInSdoOut))) { if (NULL == txData) { base->CFGR1 |= LPSPI_CFGR1_OUTCFG_MASK; } /* The 3-wire mode can't send and receive data at the same time. */ if ((txData != NULL) && (rxData != NULL)) { return kStatus_InvalidArgument; } } LPSPI_Enable(base, true); base->TCR = (base->TCR & ~(LPSPI_TCR_CONT_MASK | LPSPI_TCR_CONTC_MASK | LPSPI_TCR_RXMSK_MASK | LPSPI_TCR_PCS_MASK)) | LPSPI_TCR_CONT(isPcsContinuous) | LPSPI_TCR_CONTC(0) | LPSPI_TCR_RXMSK(isRxMask) | LPSPI_TCR_PCS(whichPcs); if (bytesPerFrame <= 4U) { bytesEachWrite = (uint8_t)bytesPerFrame; bytesEachRead = (uint8_t)bytesPerFrame; } else { bytesEachWrite = 4U; bytesEachRead = 4U; } /*Write the TX data until txRemainingByteCount is equal to 0 */ while (txRemainingByteCount > 0U) { if (txRemainingByteCount < bytesEachWrite) { bytesEachWrite = (uint8_t)txRemainingByteCount; } /*Wait until TX FIFO is not full*/ #if SPI_RETRY_TIMES waitTimes = SPI_RETRY_TIMES; while ((LPSPI_GetTxFifoCount(base) == fifoSize) && (--waitTimes != 0U)) #else while (LPSPI_GetTxFifoCount(base) == fifoSize) #endif { } #if SPI_RETRY_TIMES if (waitTimes == 0U) { return kStatus_SPI_Timeout; } #endif /* To prevent rxfifo overflow, ensure transmitting and receiving are executed in parallel */ if (((NULL == rxData) || (rxRemainingByteCount - txRemainingByteCount) < rxFifoMaxBytes)) { if (txData != NULL) { wordToSend = LPSPI_CombineWriteData(txData, bytesEachWrite, isByteSwap); txData += bytesEachWrite; } LPSPI_WriteData(base, wordToSend); txRemainingByteCount -= bytesEachWrite; } /*Check whether there is RX data in RX FIFO . Read out the RX data so that the RX FIFO would not overrun.*/ if (rxData != NULL) { #if SPI_RETRY_TIMES waitTimes = SPI_RETRY_TIMES; while ((LPSPI_GetRxFifoCount(base) != 0U) && (--waitTimes != 0U)) #else while (LPSPI_GetRxFifoCount(base) != 0U) #endif { readData = LPSPI_ReadData(base); if (rxRemainingByteCount < bytesEachRead) { bytesEachRead = (uint8_t)rxRemainingByteCount; } LPSPI_SeparateReadData(rxData, readData, bytesEachRead, isByteSwap); rxData += bytesEachRead; rxRemainingByteCount -= bytesEachRead; } #if SPI_RETRY_TIMES if (waitTimes == 0U) { return kStatus_SPI_Timeout; } #endif } } /* After write all the data in TX FIFO , should write the TCR_CONTC to 0 to de-assert the PCS. Note that TCR * register also use the TX FIFO. */ #if SPI_RETRY_TIMES waitTimes = SPI_RETRY_TIMES; while ((LPSPI_GetTxFifoCount(base) == fifoSize) && (--waitTimes != 0U)) #else while (LPSPI_GetTxFifoCount(base) == fifoSize) #endif { } #if SPI_RETRY_TIMES if (waitTimes == 0U) { return kStatus_SPI_Timeout; } #endif base->TCR = (base->TCR & ~(LPSPI_TCR_CONTC_MASK)); /*Read out the RX data in FIFO*/ if (rxData != NULL) { while (rxRemainingByteCount > 0U) { #if SPI_RETRY_TIMES waitTimes = SPI_RETRY_TIMES; while ((LPSPI_GetRxFifoCount(base) != 0U) && (--waitTimes != 0U)) #else while (LPSPI_GetRxFifoCount(base) != 0U) #endif { readData = LPSPI_ReadData(base); if (rxRemainingByteCount < bytesEachRead) { bytesEachRead = (uint8_t)rxRemainingByteCount; } LPSPI_SeparateReadData(rxData, readData, bytesEachRead, isByteSwap); rxData += bytesEachRead; rxRemainingByteCount -= bytesEachRead; } #if SPI_RETRY_TIMES if (waitTimes == 0U) { return kStatus_SPI_Timeout; } #endif } } else { /* If no RX buffer, then transfer is not complete until transfer complete flag sets */ #if SPI_RETRY_TIMES waitTimes = SPI_RETRY_TIMES; while (((LPSPI_GetStatusFlags(base) & (uint32_t)kLPSPI_TransferCompleteFlag) == 0U) && (--waitTimes != 0U)) #else while ((LPSPI_GetStatusFlags(base) & (uint32_t)kLPSPI_TransferCompleteFlag) == 0U) #endif { } #if SPI_RETRY_TIMES if (waitTimes == 0U) { return kStatus_SPI_Timeout; } #endif } return kStatus_Success; } /*! * brief LPSPI master transfer data using an interrupt method. * * This function transfers data using an interrupt method. This is a non-blocking function, which returns right away. * When all data * is transferred, the callback function is called. * * Note: * The transfer data size should be integer multiples of bytesPerFrame if bytesPerFrame is less than or equal to 4. * For bytesPerFrame greater than 4: * The transfer data size should be equal to bytesPerFrame if the bytesPerFrame is not integer multiples of 4. * Otherwise, the transfer data size can be an integer multiple of bytesPerFrame. * * param base LPSPI peripheral address. * param handle pointer to lpspi_master_handle_t structure which stores the transfer state. * param transfer pointer to lpspi_transfer_t structure. * return status of status_t. */ status_t LPSPI_MasterTransferNonBlocking(LPSPI_Type *base, lpspi_master_handle_t *handle, lpspi_transfer_t *transfer) { assert(handle); assert(transfer); uint32_t bitsPerFrame = ((base->TCR & LPSPI_TCR_FRAMESZ_MASK) >> LPSPI_TCR_FRAMESZ_SHIFT) + 1U; uint32_t bytesPerFrame = (bitsPerFrame + 7U) / 8U; uint32_t temp = 0U; uint8_t dummyData = g_lpspiDummyData[LPSPI_GetInstance(base)]; bool isPcsContinuous; uint32_t tmpTimes; if (!LPSPI_CheckTransferArgument(transfer, bitsPerFrame, bytesPerFrame)) { return kStatus_InvalidArgument; } /* Check that we're not busy.*/ if (handle->state == (uint8_t)kLPSPI_Busy) { return kStatus_LPSPI_Busy; } handle->state = (uint8_t)kLPSPI_Busy; bool isRxMask = false; uint8_t txWatermark; uint32_t whichPcs = (transfer->configFlags & LPSPI_MASTER_PCS_MASK) >> LPSPI_MASTER_PCS_SHIFT; handle->txData = transfer->txData; handle->rxData = transfer->rxData; handle->txRemainingByteCount = transfer->dataSize; handle->rxRemainingByteCount = transfer->dataSize; handle->totalByteCount = transfer->dataSize; handle->writeTcrInIsr = false; handle->writeRegRemainingTimes = (transfer->dataSize / bytesPerFrame) * ((bytesPerFrame + 3U) / 4U); handle->readRegRemainingTimes = handle->writeRegRemainingTimes; handle->txBuffIfNull = ((uint32_t)dummyData) | ((uint32_t)dummyData << 8) | ((uint32_t)dummyData << 16) | ((uint32_t)dummyData << 24); /*The TX and RX FIFO sizes are always the same*/ handle->fifoSize = LPSPI_GetRxFifoSize(base); handle->isPcsContinuous = ((transfer->configFlags & (uint32_t)kLPSPI_MasterPcsContinuous) != 0U); isPcsContinuous = handle->isPcsContinuous; handle->isByteSwap = ((transfer->configFlags & (uint32_t)kLPSPI_MasterByteSwap) != 0U); /*Set the RX and TX watermarks to reduce the ISR times.*/ if (handle->fifoSize > 1U) { txWatermark = 1U; handle->rxWatermark = handle->fifoSize - 2U; } else { txWatermark = 0U; handle->rxWatermark = 0U; } LPSPI_SetFifoWatermarks(base, txWatermark, handle->rxWatermark); LPSPI_Enable(base, false); /*Transfers will stall when transmit FIFO is empty or receive FIFO is full. */ base->CFGR1 &= (~LPSPI_CFGR1_NOSTALL_MASK); /* Check if using 3-wire mode and the txData is NULL, set the output pin to tristated. */ temp = base->CFGR1; temp &= LPSPI_CFGR1_PINCFG_MASK; if ((temp == LPSPI_CFGR1_PINCFG(kLPSPI_SdiInSdiOut)) || (temp == LPSPI_CFGR1_PINCFG(kLPSPI_SdoInSdoOut))) { if (NULL == handle->txData) { base->CFGR1 |= LPSPI_CFGR1_OUTCFG_MASK; } /* The 3-wire mode can't send and receive data at the same time. */ if ((NULL != handle->txData) && (NULL != handle->rxData)) { return kStatus_InvalidArgument; } } LPSPI_Enable(base, true); /*Flush FIFO , clear status , disable all the inerrupts.*/ LPSPI_FlushFifo(base, true, true); LPSPI_ClearStatusFlags(base, (uint32_t)kLPSPI_AllStatusFlag); LPSPI_DisableInterrupts(base, (uint32_t)kLPSPI_AllInterruptEnable); /* If there is not rxData , can mask the receive data (receive data is not stored in receive FIFO). * For master transfer , we'd better not masked the transmit data in TCR since the transfer flow is hard to * controlled by software.*/ if (handle->rxData == NULL) { isRxMask = true; handle->rxRemainingByteCount = 0; } base->TCR = (base->TCR & ~(LPSPI_TCR_CONT_MASK | LPSPI_TCR_CONTC_MASK | LPSPI_TCR_RXMSK_MASK | LPSPI_TCR_PCS_MASK)) | LPSPI_TCR_CONT(isPcsContinuous) | LPSPI_TCR_CONTC(0) | LPSPI_TCR_RXMSK(isRxMask) | LPSPI_TCR_PCS(whichPcs); /*Calculate the bytes for write/read the TX/RX register each time*/ if (bytesPerFrame <= 4U) { handle->bytesEachWrite = (uint8_t)bytesPerFrame; handle->bytesEachRead = (uint8_t)bytesPerFrame; } else { handle->bytesEachWrite = 4U; handle->bytesEachRead = 4U; } /* Enable the NVIC for LPSPI peripheral. Note that below code is useless if the LPSPI interrupt is in INTMUX , * and you should also enable the INTMUX interupt in your application. */ (void)EnableIRQ(s_lpspiIRQ[LPSPI_GetInstance(base)]); /*TCR is also shared the FIFO , so wait for TCR written.*/ #if SPI_RETRY_TIMES uint32_t waitTimes = SPI_RETRY_TIMES; while ((LPSPI_GetTxFifoCount(base) != 0U) && (--waitTimes != 0U)) #else while (LPSPI_GetTxFifoCount(base) != 0U) #endif { } #if SPI_RETRY_TIMES if (waitTimes == 0U) { return kStatus_SPI_Timeout; } #endif /*Fill up the TX data in FIFO */ LPSPI_MasterTransferFillUpTxFifo(base, handle); /* Since SPI is a synchronous interface, we only need to enable the RX interrupt if there is RX data. * The IRQ handler will get the status of RX and TX interrupt flags. */ if (handle->rxData != NULL) { /*Set rxWatermark to (readRegRemainingTimes-1) if readRegRemainingTimes less than rxWatermark. Otherwise there *is not RX interrupt for the last datas because the RX count is not greater than rxWatermark. */ tmpTimes = handle->readRegRemainingTimes; if (tmpTimes <= handle->rxWatermark) { base->FCR = (base->FCR & (~LPSPI_FCR_RXWATER_MASK)) | LPSPI_FCR_RXWATER(tmpTimes - 1U); } LPSPI_EnableInterrupts(base, (uint32_t)kLPSPI_RxInterruptEnable); } else { LPSPI_EnableInterrupts(base, (uint32_t)kLPSPI_TxInterruptEnable); } return kStatus_Success; } static void LPSPI_MasterTransferFillUpTxFifo(LPSPI_Type *base, lpspi_master_handle_t *handle) { assert(handle); uint32_t wordToSend = 0; uint8_t fifoSize = handle->fifoSize; uint32_t writeRegRemainingTimes = handle->writeRegRemainingTimes; uint32_t readRegRemainingTimes = handle->readRegRemainingTimes; size_t txRemainingByteCount = handle->txRemainingByteCount; uint8_t bytesEachWrite = handle->bytesEachWrite; bool isByteSwap = handle->isByteSwap; /* Make sure the difference in remaining TX and RX byte counts does not exceed FIFO depth * and that the number of TX FIFO entries does not exceed the FIFO depth. * But no need to make the protection if there is no rxData. */ while ((LPSPI_GetTxFifoCount(base) < fifoSize) && (((readRegRemainingTimes - writeRegRemainingTimes) < (uint32_t)fifoSize) || (handle->rxData == NULL))) { if (txRemainingByteCount < (size_t)bytesEachWrite) { handle->bytesEachWrite = (uint8_t)txRemainingByteCount; bytesEachWrite = handle->bytesEachWrite; } if (handle->txData != NULL) { wordToSend = LPSPI_CombineWriteData(handle->txData, bytesEachWrite, isByteSwap); handle->txData += bytesEachWrite; } else { wordToSend = handle->txBuffIfNull; } /*Write the word to TX register*/ LPSPI_WriteData(base, wordToSend); /*Decrease the write TX register times.*/ --handle->writeRegRemainingTimes; writeRegRemainingTimes = handle->writeRegRemainingTimes; /*Decrease the remaining TX byte count.*/ handle->txRemainingByteCount -= (size_t)bytesEachWrite; txRemainingByteCount = handle->txRemainingByteCount; if (handle->txRemainingByteCount == 0U) { /* If PCS is continuous, update TCR to de-assert PCS */ if (handle->isPcsContinuous) { /* Only write to the TCR if the FIFO has room */ if (LPSPI_GetTxFifoCount(base) < fifoSize) { base->TCR = (base->TCR & ~(LPSPI_TCR_CONTC_MASK)); handle->writeTcrInIsr = false; } /* Else, set a global flag to tell the ISR to do write to the TCR */ else { handle->writeTcrInIsr = true; } } break; } } } static void LPSPI_MasterTransferComplete(LPSPI_Type *base, lpspi_master_handle_t *handle) { assert(handle); /* Disable interrupt requests*/ LPSPI_DisableInterrupts(base, (uint32_t)kLPSPI_AllInterruptEnable); handle->state = (uint8_t)kLPSPI_Idle; if (handle->callback != NULL) { handle->callback(base, handle, kStatus_Success, handle->userData); } } /*! * brief Gets the master transfer remaining bytes. * * This function gets the master transfer remaining bytes. * * param base LPSPI peripheral address. * param handle pointer to lpspi_master_handle_t structure which stores the transfer state. * param count Number of bytes transferred so far by the non-blocking transaction. * return status of status_t. */ status_t LPSPI_MasterTransferGetCount(LPSPI_Type *base, lpspi_master_handle_t *handle, size_t *count) { assert(handle); if (NULL == count) { return kStatus_InvalidArgument; } /* Catch when there is not an active transfer. */ if (handle->state != (uint8_t)kLPSPI_Busy) { *count = 0; return kStatus_NoTransferInProgress; } size_t remainingByte; if (handle->rxData != NULL) { remainingByte = handle->rxRemainingByteCount; } else { remainingByte = handle->txRemainingByteCount; } *count = handle->totalByteCount - remainingByte; return kStatus_Success; } /*! * brief LPSPI master abort transfer which uses an interrupt method. * * This function aborts a transfer which uses an interrupt method. * * param base LPSPI peripheral address. * param handle pointer to lpspi_master_handle_t structure which stores the transfer state. */ void LPSPI_MasterTransferAbort(LPSPI_Type *base, lpspi_master_handle_t *handle) { assert(handle); /* Disable interrupt requests*/ LPSPI_DisableInterrupts(base, (uint32_t)kLPSPI_AllInterruptEnable); LPSPI_Reset(base); handle->state = (uint8_t)kLPSPI_Idle; handle->txRemainingByteCount = 0; handle->rxRemainingByteCount = 0; } /*! * brief LPSPI Master IRQ handler function. * * This function processes the LPSPI transmit and receive IRQ. * * param base LPSPI peripheral address. * param handle pointer to lpspi_master_handle_t structure which stores the transfer state. */ void LPSPI_MasterTransferHandleIRQ(LPSPI_Type *base, lpspi_master_handle_t *handle) { assert(handle); uint32_t readData; uint8_t bytesEachRead = handle->bytesEachRead; bool isByteSwap = handle->isByteSwap; uint32_t readRegRemainingTimes = handle->readRegRemainingTimes; if (handle->rxData != NULL) { if (handle->rxRemainingByteCount != 0U) { /* First, disable the interrupts to avoid potentially triggering another interrupt * while reading out the RX FIFO as more data may be coming into the RX FIFO. We'll * re-enable the interrupts based on the LPSPI state after reading out the FIFO. */ LPSPI_DisableInterrupts(base, (uint32_t)kLPSPI_RxInterruptEnable); while ((LPSPI_GetRxFifoCount(base) != 0U) && (handle->rxRemainingByteCount != 0U)) { /*Read out the data*/ readData = LPSPI_ReadData(base); /*Decrease the read RX register times.*/ --handle->readRegRemainingTimes; readRegRemainingTimes = handle->readRegRemainingTimes; if (handle->rxRemainingByteCount < (size_t)bytesEachRead) { handle->bytesEachRead = (uint8_t)(handle->rxRemainingByteCount); bytesEachRead = handle->bytesEachRead; } LPSPI_SeparateReadData(handle->rxData, readData, bytesEachRead, isByteSwap); handle->rxData += bytesEachRead; /*Decrease the remaining RX byte count.*/ handle->rxRemainingByteCount -= (size_t)bytesEachRead; } /* Re-enable the interrupts only if rxCount indicates there is more data to receive, * else we may get a spurious interrupt. * */ if (handle->rxRemainingByteCount != 0U) { /* Set the TDF and RDF interrupt enables simultaneously to avoid race conditions */ LPSPI_EnableInterrupts(base, (uint32_t)kLPSPI_RxInterruptEnable); } } /*Set rxWatermark to (readRegRemainingTimes-1) if readRegRemainingTimes less than rxWatermark. Otherwise there *is not RX interrupt for the last datas because the RX count is not greater than rxWatermark. */ if (readRegRemainingTimes <= (uint32_t)handle->rxWatermark) { base->FCR = (base->FCR & (~LPSPI_FCR_RXWATER_MASK)) | LPSPI_FCR_RXWATER((readRegRemainingTimes > 1U) ? (readRegRemainingTimes - 1U) : (0U)); } } if (handle->txRemainingByteCount != 0U) { LPSPI_MasterTransferFillUpTxFifo(base, handle); } else { if ((LPSPI_GetTxFifoCount(base) < (handle->fifoSize))) { if ((handle->isPcsContinuous) && (handle->writeTcrInIsr)) { base->TCR = (base->TCR & ~(LPSPI_TCR_CONTC_MASK)); handle->writeTcrInIsr = false; } } } if ((handle->txRemainingByteCount == 0U) && (handle->rxRemainingByteCount == 0U) && (!handle->writeTcrInIsr)) { /* If no RX buffer, then transfer is not complete until transfer complete flag sets */ if (handle->rxData == NULL) { if ((LPSPI_GetStatusFlags(base) & (uint32_t)kLPSPI_TransferCompleteFlag) != 0U) { LPSPI_ClearStatusFlags(base, (uint32_t)kLPSPI_TransferCompleteFlag); /* Complete the transfer and disable the interrupts */ LPSPI_MasterTransferComplete(base, handle); } else { LPSPI_EnableInterrupts(base, (uint32_t)kLPSPI_TransferCompleteInterruptEnable); LPSPI_DisableInterrupts(base, (uint32_t)kLPSPI_TxInterruptEnable | (uint32_t)kLPSPI_RxInterruptEnable); } } else { /* Complete the transfer and disable the interrupts */ LPSPI_MasterTransferComplete(base, handle); } } } /*Transactional APIs -- Slave*/ /*! * brief Initializes the LPSPI slave handle. * * This function initializes the LPSPI handle, which can be used for other LPSPI transactional APIs. Usually, for a * specified LPSPI instance, call this API once to get the initialized handle. * * param base LPSPI peripheral address. * param handle LPSPI handle pointer to lpspi_slave_handle_t. * param callback DSPI callback. * param userData callback function parameter. */ void LPSPI_SlaveTransferCreateHandle(LPSPI_Type *base, lpspi_slave_handle_t *handle, lpspi_slave_transfer_callback_t callback, void *userData) { assert(handle); /* Zero the handle. */ (void)memset(handle, 0, sizeof(*handle)); s_lpspiHandle[LPSPI_GetInstance(base)] = handle; /* Set irq handler. */ s_lpspiSlaveIsr = LPSPI_SlaveTransferHandleIRQ; handle->callback = callback; handle->userData = userData; } /*! * brief LPSPI slave transfer data using an interrupt method. * * This function transfer data using an interrupt method. This is a non-blocking function, which returns right away. * When all data * is transferred, the callback function is called. * * Note: * The transfer data size should be integer multiples of bytesPerFrame if bytesPerFrame is less than or equal to 4. * For bytesPerFrame greater than 4: * The transfer data size should be equal to bytesPerFrame if the bytesPerFrame is not an integer multiple of 4. * Otherwise, the transfer data size can be an integer multiple of bytesPerFrame. * * param base LPSPI peripheral address. * param handle pointer to lpspi_slave_handle_t structure which stores the transfer state. * param transfer pointer to lpspi_transfer_t structure. * return status of status_t. */ status_t LPSPI_SlaveTransferNonBlocking(LPSPI_Type *base, lpspi_slave_handle_t *handle, lpspi_transfer_t *transfer) { assert(handle); assert(transfer); uint32_t bitsPerFrame = ((base->TCR & LPSPI_TCR_FRAMESZ_MASK) >> LPSPI_TCR_FRAMESZ_SHIFT) + 1U; uint32_t bytesPerFrame = (bitsPerFrame + 7U) / 8U; uint32_t temp = 0U; uint32_t readRegRemainingTimes; if (!LPSPI_CheckTransferArgument(transfer, bitsPerFrame, bytesPerFrame)) { return kStatus_InvalidArgument; } /* Check that we're not busy.*/ if (handle->state == (uint8_t)kLPSPI_Busy) { return kStatus_LPSPI_Busy; } handle->state = (uint8_t)kLPSPI_Busy; bool isRxMask = false; bool isTxMask = false; uint32_t whichPcs = (transfer->configFlags & LPSPI_SLAVE_PCS_MASK) >> LPSPI_SLAVE_PCS_SHIFT; handle->txData = transfer->txData; handle->rxData = transfer->rxData; handle->txRemainingByteCount = transfer->dataSize; handle->rxRemainingByteCount = transfer->dataSize; handle->totalByteCount = transfer->dataSize; handle->writeRegRemainingTimes = (transfer->dataSize / bytesPerFrame) * ((bytesPerFrame + 3U) / 4U); handle->readRegRemainingTimes = handle->writeRegRemainingTimes; /*The TX and RX FIFO sizes are always the same*/ handle->fifoSize = LPSPI_GetRxFifoSize(base); handle->isByteSwap = ((transfer->configFlags & (uint32_t)kLPSPI_SlaveByteSwap) != 0U); /*Set the RX and TX watermarks to reduce the ISR times.*/ uint8_t txWatermark; if (handle->fifoSize > 1U) { txWatermark = 1U; handle->rxWatermark = handle->fifoSize - 2U; } else { txWatermark = 0U; handle->rxWatermark = 0U; } LPSPI_SetFifoWatermarks(base, txWatermark, handle->rxWatermark); /* Check if using 3-wire mode and the txData is NULL, set the output pin to tristated. */ temp = base->CFGR1; temp &= LPSPI_CFGR1_PINCFG_MASK; if ((temp == LPSPI_CFGR1_PINCFG(kLPSPI_SdiInSdiOut)) || (temp == LPSPI_CFGR1_PINCFG(kLPSPI_SdoInSdoOut))) { if (NULL == handle->txData) { LPSPI_Enable(base, false); base->CFGR1 |= LPSPI_CFGR1_OUTCFG_MASK; LPSPI_Enable(base, true); } /* The 3-wire mode can't send and receive data at the same time. */ if ((handle->txData != NULL) && (handle->rxData != NULL)) { return kStatus_InvalidArgument; } } /*Flush FIFO , clear status , disable all the inerrupts.*/ LPSPI_FlushFifo(base, true, true); LPSPI_ClearStatusFlags(base, (uint32_t)kLPSPI_AllStatusFlag); LPSPI_DisableInterrupts(base, (uint32_t)kLPSPI_AllInterruptEnable); /*If there is not rxData , can mask the receive data (receive data is not stored in receive FIFO).*/ if (handle->rxData == NULL) { isRxMask = true; handle->rxRemainingByteCount = 0U; } /*If there is not txData , can mask the transmit data (no data is loaded from transmit FIFO and output pin * is tristated). */ if (handle->txData == NULL) { isTxMask = true; handle->txRemainingByteCount = 0U; } base->TCR = (base->TCR & ~(LPSPI_TCR_CONT_MASK | LPSPI_TCR_CONTC_MASK | LPSPI_TCR_RXMSK_MASK | LPSPI_TCR_TXMSK_MASK | LPSPI_TCR_PCS_MASK)) | LPSPI_TCR_CONT(0) | LPSPI_TCR_CONTC(0) | LPSPI_TCR_RXMSK(isRxMask) | LPSPI_TCR_TXMSK(isTxMask) | LPSPI_TCR_PCS(whichPcs); /*Calculate the bytes for write/read the TX/RX register each time*/ if (bytesPerFrame <= 4U) { handle->bytesEachWrite = (uint8_t)bytesPerFrame; handle->bytesEachRead = (uint8_t)bytesPerFrame; } else { handle->bytesEachWrite = 4U; handle->bytesEachRead = 4U; } /* Enable the NVIC for LPSPI peripheral. Note that below code is useless if the LPSPI interrupt is in INTMUX , * and you should also enable the INTMUX interupt in your application. */ (void)EnableIRQ(s_lpspiIRQ[LPSPI_GetInstance(base)]); /*TCR is also shared the FIFO , so wait for TCR written.*/ #if SPI_RETRY_TIMES uint32_t waitTimes = SPI_RETRY_TIMES; while ((LPSPI_GetTxFifoCount(base) != 0U) && (--waitTimes != 0U)) #else while (LPSPI_GetTxFifoCount(base) != 0U) #endif { } #if SPI_RETRY_TIMES if (waitTimes == 0U) { return kStatus_SPI_Timeout; } #endif /*Fill up the TX data in FIFO */ if (handle->txData != NULL) { LPSPI_SlaveTransferFillUpTxFifo(base, handle); } /* Since SPI is a synchronous interface, we only need to enable the RX interrupt if there is RX data. * The IRQ handler will get the status of RX and TX interrupt flags. */ if (handle->rxData != NULL) { /*Set rxWatermark to (readRegRemainingTimes-1) if readRegRemainingTimes less than rxWatermark. Otherwise there *is not RX interrupt for the last datas because the RX count is not greater than rxWatermark. */ readRegRemainingTimes = handle->readRegRemainingTimes; if (readRegRemainingTimes <= (uint32_t)handle->rxWatermark) { base->FCR = (base->FCR & (~LPSPI_FCR_RXWATER_MASK)) | LPSPI_FCR_RXWATER(readRegRemainingTimes - 1U); } LPSPI_EnableInterrupts(base, (uint32_t)kLPSPI_RxInterruptEnable); } else { LPSPI_EnableInterrupts(base, (uint32_t)kLPSPI_TxInterruptEnable); } if (handle->rxData != NULL) { /* RX FIFO overflow request enable */ LPSPI_EnableInterrupts(base, (uint32_t)kLPSPI_ReceiveErrorInterruptEnable); } if (handle->txData != NULL) { /* TX FIFO underflow request enable */ LPSPI_EnableInterrupts(base, (uint32_t)kLPSPI_TransmitErrorInterruptEnable); } return kStatus_Success; } static void LPSPI_SlaveTransferFillUpTxFifo(LPSPI_Type *base, lpspi_slave_handle_t *handle) { assert(handle); uint32_t wordToSend = 0U; uint8_t bytesEachWrite = handle->bytesEachWrite; bool isByteSwap = handle->isByteSwap; while (LPSPI_GetTxFifoCount(base) < (handle->fifoSize)) { if (handle->txRemainingByteCount < (size_t)bytesEachWrite) { handle->bytesEachWrite = (uint8_t)handle->txRemainingByteCount; bytesEachWrite = handle->bytesEachWrite; } wordToSend = LPSPI_CombineWriteData(handle->txData, bytesEachWrite, isByteSwap); handle->txData += bytesEachWrite; /*Decrease the remaining TX byte count.*/ handle->txRemainingByteCount -= (size_t)bytesEachWrite; /*Write the word to TX register*/ LPSPI_WriteData(base, wordToSend); if (handle->txRemainingByteCount == 0U) { break; } } } static void LPSPI_SlaveTransferComplete(LPSPI_Type *base, lpspi_slave_handle_t *handle) { assert(handle); status_t status = kStatus_Success; /* Disable interrupt requests*/ LPSPI_DisableInterrupts(base, (uint32_t)kLPSPI_AllInterruptEnable); if (handle->state == (uint8_t)kLPSPI_Error) { status = kStatus_LPSPI_Error; } else { status = kStatus_Success; } handle->state = (uint8_t)kLPSPI_Idle; if (handle->callback != NULL) { handle->callback(base, handle, status, handle->userData); } } /*! * brief Gets the slave transfer remaining bytes. * * This function gets the slave transfer remaining bytes. * * param base LPSPI peripheral address. * param handle pointer to lpspi_slave_handle_t structure which stores the transfer state. * param count Number of bytes transferred so far by the non-blocking transaction. * return status of status_t. */ status_t LPSPI_SlaveTransferGetCount(LPSPI_Type *base, lpspi_slave_handle_t *handle, size_t *count) { assert(handle != NULL); if (NULL == count) { return kStatus_InvalidArgument; } /* Catch when there is not an active transfer. */ if (handle->state != (uint8_t)kLPSPI_Busy) { *count = 0; return kStatus_NoTransferInProgress; } size_t remainingByte; if (handle->rxData != NULL) { remainingByte = handle->rxRemainingByteCount; } else { remainingByte = handle->txRemainingByteCount; } *count = handle->totalByteCount - remainingByte; return kStatus_Success; } /*! * brief LPSPI slave aborts a transfer which uses an interrupt method. * * This function aborts a transfer which uses an interrupt method. * * param base LPSPI peripheral address. * param handle pointer to lpspi_slave_handle_t structure which stores the transfer state. */ void LPSPI_SlaveTransferAbort(LPSPI_Type *base, lpspi_slave_handle_t *handle) { assert(handle); /* Disable interrupt requests*/ LPSPI_DisableInterrupts(base, (uint32_t)kLPSPI_TxInterruptEnable | (uint32_t)kLPSPI_RxInterruptEnable); LPSPI_Reset(base); handle->state = (uint8_t)kLPSPI_Idle; handle->txRemainingByteCount = 0U; handle->rxRemainingByteCount = 0U; } /*! * brief LPSPI Slave IRQ handler function. * * This function processes the LPSPI transmit and receives an IRQ. * * param base LPSPI peripheral address. * param handle pointer to lpspi_slave_handle_t structure which stores the transfer state. */ void LPSPI_SlaveTransferHandleIRQ(LPSPI_Type *base, lpspi_slave_handle_t *handle) { assert(handle); uint32_t readData; /* variable to store word read from RX FIFO */ uint32_t wordToSend; /* variable to store word to write to TX FIFO */ uint8_t bytesEachRead = handle->bytesEachRead; uint8_t bytesEachWrite = handle->bytesEachWrite; bool isByteSwap = handle->isByteSwap; uint32_t readRegRemainingTimes; if (handle->rxData != NULL) { if (handle->rxRemainingByteCount > 0U) { while (LPSPI_GetRxFifoCount(base) != 0U) { /*Read out the data*/ readData = LPSPI_ReadData(base); /*Decrease the read RX register times.*/ --handle->readRegRemainingTimes; if (handle->rxRemainingByteCount < (size_t)bytesEachRead) { handle->bytesEachRead = (uint8_t)handle->rxRemainingByteCount; bytesEachRead = handle->bytesEachRead; } LPSPI_SeparateReadData(handle->rxData, readData, bytesEachRead, isByteSwap); handle->rxData += bytesEachRead; /*Decrease the remaining RX byte count.*/ handle->rxRemainingByteCount -= (size_t)bytesEachRead; if ((handle->txRemainingByteCount > 0U) && (handle->txData != NULL)) { if (handle->txRemainingByteCount < (size_t)bytesEachWrite) { handle->bytesEachWrite = (uint8_t)handle->txRemainingByteCount; bytesEachWrite = handle->bytesEachWrite; } wordToSend = LPSPI_CombineWriteData(handle->txData, bytesEachWrite, isByteSwap); handle->txData += bytesEachWrite; /*Decrease the remaining TX byte count.*/ handle->txRemainingByteCount -= (size_t)bytesEachWrite; /*Write the word to TX register*/ LPSPI_WriteData(base, wordToSend); } if (handle->rxRemainingByteCount == 0U) { break; } } } /*Set rxWatermark to (readRegRemainingTimes-1) if readRegRemainingTimes less than rxWatermark. Otherwise there *is not RX interrupt for the last datas because the RX count is not greater than rxWatermark. */ readRegRemainingTimes = handle->readRegRemainingTimes; if (readRegRemainingTimes <= (uint32_t)handle->rxWatermark) { base->FCR = (base->FCR & (~LPSPI_FCR_RXWATER_MASK)) | LPSPI_FCR_RXWATER((readRegRemainingTimes > 1U) ? (readRegRemainingTimes - 1U) : (0U)); } } if ((handle->rxData == NULL) && (handle->txRemainingByteCount != 0U) && (handle->txData != NULL)) { LPSPI_SlaveTransferFillUpTxFifo(base, handle); } if ((handle->txRemainingByteCount == 0U) && (handle->rxRemainingByteCount == 0U)) { /* If no RX buffer, then transfer is not complete until transfer complete flag sets and the TX FIFO empty*/ if (handle->rxData == NULL) { if (((LPSPI_GetStatusFlags(base) & (uint32_t)kLPSPI_FrameCompleteFlag) != 0U) && (LPSPI_GetTxFifoCount(base) == 0U)) { LPSPI_ClearStatusFlags(base, (uint32_t)kLPSPI_FrameCompleteFlag); /* Complete the transfer and disable the interrupts */ LPSPI_SlaveTransferComplete(base, handle); } else { LPSPI_ClearStatusFlags(base, (uint32_t)kLPSPI_FrameCompleteFlag); LPSPI_EnableInterrupts(base, (uint32_t)kLPSPI_FrameCompleteInterruptEnable); LPSPI_DisableInterrupts(base, (uint32_t)kLPSPI_TxInterruptEnable | (uint32_t)kLPSPI_RxInterruptEnable); } } else { /* Complete the transfer and disable the interrupts */ LPSPI_SlaveTransferComplete(base, handle); } } /* Catch tx fifo underflow conditions, service only if tx under flow interrupt enabled */ if (((LPSPI_GetStatusFlags(base) & (uint32_t)kLPSPI_TransmitErrorFlag) != 0U) && ((base->IER & LPSPI_IER_TEIE_MASK) != 0U)) { LPSPI_ClearStatusFlags(base, (uint32_t)kLPSPI_TransmitErrorFlag); /* Change state to error and clear flag */ if (handle->txData != NULL) { handle->state = (uint8_t)kLPSPI_Error; } handle->errorCount++; } /* Catch rx fifo overflow conditions, service only if rx over flow interrupt enabled */ if (((LPSPI_GetStatusFlags(base) & (uint32_t)kLPSPI_ReceiveErrorFlag) != 0U) && ((base->IER & LPSPI_IER_REIE_MASK) != 0U)) { LPSPI_ClearStatusFlags(base, (uint32_t)kLPSPI_ReceiveErrorFlag); /* Change state to error and clear flag */ if (handle->txData != NULL) { handle->state = (uint8_t)kLPSPI_Error; } handle->errorCount++; } } static uint32_t LPSPI_CombineWriteData(uint8_t *txData, uint8_t bytesEachWrite, bool isByteSwap) { assert(txData != NULL); uint32_t wordToSend = 0U; switch (bytesEachWrite) { case 1: wordToSend = *txData; ++txData; break; case 2: if (!isByteSwap) { wordToSend = *txData; ++txData; wordToSend |= (unsigned)(*txData) << 8U; ++txData; } else { wordToSend = (unsigned)(*txData) << 8U; ++txData; wordToSend |= *txData; ++txData; } break; case 3: if (!isByteSwap) { wordToSend = *txData; ++txData; wordToSend |= (unsigned)(*txData) << 8U; ++txData; wordToSend |= (unsigned)(*txData) << 16U; ++txData; } else { wordToSend = (unsigned)(*txData) << 16U; ++txData; wordToSend |= (unsigned)(*txData) << 8U; ++txData; wordToSend |= *txData; ++txData; } break; case 4: if (!isByteSwap) { wordToSend = *txData; ++txData; wordToSend |= (unsigned)(*txData) << 8U; ++txData; wordToSend |= (unsigned)(*txData) << 16U; ++txData; wordToSend |= (unsigned)(*txData) << 24U; ++txData; } else { wordToSend = (unsigned)(*txData) << 24U; ++txData; wordToSend |= (unsigned)(*txData) << 16U; ++txData; wordToSend |= (unsigned)(*txData) << 8U; ++txData; wordToSend |= *txData; ++txData; } break; default: assert(false); break; } return wordToSend; } static void LPSPI_SeparateReadData(uint8_t *rxData, uint32_t readData, uint8_t bytesEachRead, bool isByteSwap) { assert(rxData); switch (bytesEachRead) { case 1: *rxData = (uint8_t)readData; ++rxData; break; case 2: if (!isByteSwap) { *rxData = (uint8_t)readData; ++rxData; *rxData = (uint8_t)(readData >> 8); ++rxData; } else { *rxData = (uint8_t)(readData >> 8); ++rxData; *rxData = (uint8_t)readData; ++rxData; } break; case 3: if (!isByteSwap) { *rxData = (uint8_t)readData; ++rxData; *rxData = (uint8_t)(readData >> 8); ++rxData; *rxData = (uint8_t)(readData >> 16); ++rxData; } else { *rxData = (uint8_t)(readData >> 16); ++rxData; *rxData = (uint8_t)(readData >> 8); ++rxData; *rxData = (uint8_t)readData; ++rxData; } break; case 4: if (!isByteSwap) { *rxData = (uint8_t)readData; ++rxData; *rxData = (uint8_t)(readData >> 8); ++rxData; *rxData = (uint8_t)(readData >> 16); ++rxData; *rxData = (uint8_t)(readData >> 24); ++rxData; } else { *rxData = (uint8_t)(readData >> 24); ++rxData; *rxData = (uint8_t)(readData >> 16); ++rxData; *rxData = (uint8_t)(readData >> 8); ++rxData; *rxData = (uint8_t)readData; ++rxData; } break; default: assert(false); break; } } static void LPSPI_CommonIRQHandler(LPSPI_Type *base, void *param) { if (LPSPI_IsMaster(base)) { s_lpspiMasterIsr(base, (lpspi_master_handle_t *)param); } else { s_lpspiSlaveIsr(base, (lpspi_slave_handle_t *)param); } SDK_ISR_EXIT_BARRIER; } #if defined(LPSPI0) void LPSPI0_DriverIRQHandler(void) { assert(s_lpspiHandle[0]); LPSPI_CommonIRQHandler(LPSPI0, s_lpspiHandle[0]); } #endif #if defined(LPSPI1) void LPSPI1_DriverIRQHandler(void) { assert(s_lpspiHandle[1]); LPSPI_CommonIRQHandler(LPSPI1, s_lpspiHandle[1]); } #endif #if defined(LPSPI2) void LPSPI2_DriverIRQHandler(void) { assert(s_lpspiHandle[2]); LPSPI_CommonIRQHandler(LPSPI2, s_lpspiHandle[2]); } #endif #if defined(LPSPI3) void LPSPI3_DriverIRQHandler(void) { assert(s_lpspiHandle[3]); LPSPI_CommonIRQHandler(LPSPI3, s_lpspiHandle[3]); } #endif #if defined(LPSPI4) void LPSPI4_DriverIRQHandler(void) { assert(s_lpspiHandle[4]); LPSPI_CommonIRQHandler(LPSPI4, s_lpspiHandle[4]); } #endif #if defined(LPSPI5) void LPSPI5_DriverIRQHandler(void) { assert(s_lpspiHandle[5]); LPSPI_CommonIRQHandler(LPSPI5, s_lpspiHandle[5]); } #endif #if defined(DMA__LPSPI0) void DMA_SPI0_INT_DriverIRQHandler(void) { assert(s_lpspiHandle[LPSPI_GetInstance(DMA__LPSPI0)]); LPSPI_CommonIRQHandler(DMA__LPSPI0, s_lpspiHandle[LPSPI_GetInstance(DMA__LPSPI0)]); } #endif #if defined(DMA__LPSPI1) void DMA_SPI1_INT_DriverIRQHandler(void) { assert(s_lpspiHandle[LPSPI_GetInstance(DMA__LPSPI1)]); LPSPI_CommonIRQHandler(DMA__LPSPI1, s_lpspiHandle[LPSPI_GetInstance(DMA__LPSPI1)]); } #endif #if defined(DMA__LPSPI2) void DMA_SPI2_INT_DriverIRQHandler(void) { assert(s_lpspiHandle[LPSPI_GetInstance(DMA__LPSPI2)]); LPSPI_CommonIRQHandler(DMA__LPSPI2, s_lpspiHandle[LPSPI_GetInstance(DMA__LPSPI2)]); } #endif #if defined(DMA__LPSPI3) void DMA_SPI3_INT_DriverIRQHandler(void) { assert(s_lpspiHandle[LPSPI_GetInstance(DMA__LPSPI3)]); LPSPI_CommonIRQHandler(DMA__LPSPI3, s_lpspiHandle[LPSPI_GetInstance(DMA__LPSPI3)]); } #endif #if defined(ADMA__LPSPI0) void ADMA_SPI0_INT_DriverIRQHandler(void) { assert(s_lpspiHandle[LPSPI_GetInstance(ADMA__LPSPI0)]); LPSPI_CommonIRQHandler(ADMA__LPSPI0, s_lpspiHandle[LPSPI_GetInstance(ADMA__LPSPI0)]); } #endif #if defined(ADMA__LPSPI1) void ADMA_SPI1_INT_DriverIRQHandler(void) { assert(s_lpspiHandle[LPSPI_GetInstance(ADMA__LPSPI1)]); LPSPI_CommonIRQHandler(ADMA__LPSPI1, s_lpspiHandle[LPSPI_GetInstance(ADMA__LPSPI1)]); } #endif #if defined(ADMA__LPSPI2) void ADMA_SPI2_INT_DriverIRQHandler(void) { assert(s_lpspiHandle[LPSPI_GetInstance(ADMA__LPSPI2)]); LPSPI_CommonIRQHandler(ADMA__LPSPI2, s_lpspiHandle[LPSPI_GetInstance(ADMA__LPSPI2)]); } #endif #if defined(ADMA__LPSPI3) void ADMA_SPI3_INT_DriverIRQHandler(void) { assert(s_lpspiHandle[LPSPI_GetInstance(ADMA__LPSPI3)]); LPSPI_CommonIRQHandler(ADMA__LPSPI3, s_lpspiHandle[LPSPI_GetInstance(ADMA__LPSPI3)]); } #endif