/* * Copyright (c) 2016, Freescale Semiconductor, Inc. * Copyright 2016-2020,2022 NXP * All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #ifndef FSL_SPI_H_ #define FSL_SPI_H_ #include "fsl_common.h" #include "fsl_flexcomm.h" /*! * @addtogroup spi_driver * @{ */ /*! @file */ /******************************************************************************* * Definitions ******************************************************************************/ /*! @name Driver version */ /*! @{ */ /*! @brief SPI driver version. */ #define FSL_SPI_DRIVER_VERSION (MAKE_VERSION(2, 3, 1)) /*! @} */ /*! @brief SPI default SSEL COUNT*/ #if !(defined(FSL_FEATURE_SPI_SSEL_COUNT) || defined(FSL_FEATURE_SPI_IS_SSEL_PIN_COUNT_EQUAL_TO_THREE)) #define FSL_FEATURE_SPI_SSEL_COUNT (4U) #endif /*! @brief Global variable for dummy data value setting. */ extern volatile uint8_t s_dummyData[]; #ifndef SPI_DUMMYDATA /*! @brief SPI dummy transfer data, the data is sent while txBuff is NULL. */ #define SPI_DUMMYDATA (0x00U) #endif /*! @brief Retry times for waiting flag. */ #ifndef SPI_RETRY_TIMES #define SPI_RETRY_TIMES 0U /* Define to zero means keep waiting until the flag is assert/deassert. */ #endif #define SPI_DATA(n) (((uint32_t)(n)) & 0xFFFFUL) #define SPI_CTRLMASK (0xFFFF0000U) #define SPI_ASSERTNUM_SSEL(n) ((~(1UL << ((n) + 16UL))) & 0xF0000UL) #define SPI_DEASSERTNUM_SSEL(n) (1UL << ((n) + 16UL)) #define SPI_DEASSERT_ALL (0xF0000UL) #define SPI_FIFOWR_FLAGS_MASK (~(SPI_DEASSERT_ALL | SPI_FIFOWR_TXDATA_MASK | SPI_FIFOWR_LEN_MASK)) #define SPI_FIFOTRIG_TXLVL_GET(base) (((base)->FIFOTRIG & SPI_FIFOTRIG_TXLVL_MASK) >> SPI_FIFOTRIG_TXLVL_SHIFT) #define SPI_FIFOTRIG_RXLVL_GET(base) (((base)->FIFOTRIG & SPI_FIFOTRIG_RXLVL_MASK) >> SPI_FIFOTRIG_RXLVL_SHIFT) /*! @brief SPI transfer option.*/ typedef enum _spi_xfer_option { kSPI_FrameDelay = (SPI_FIFOWR_EOF_MASK), /*!< A delay may be inserted, defined in the DLY register.*/ kSPI_FrameAssert = (SPI_FIFOWR_EOT_MASK), /*!< SSEL will be deasserted at the end of a transfer */ } spi_xfer_option_t; /*! @brief SPI data shifter direction options.*/ typedef enum _spi_shift_direction { kSPI_MsbFirst = 0U, /*!< Data transfers start with most significant bit. */ kSPI_LsbFirst = 1U /*!< Data transfers start with least significant bit. */ } spi_shift_direction_t; /*! @brief SPI clock polarity configuration.*/ typedef enum _spi_clock_polarity { kSPI_ClockPolarityActiveHigh = 0x0U, /*!< Active-high SPI clock (idles low). */ kSPI_ClockPolarityActiveLow /*!< Active-low SPI clock (idles high). */ } spi_clock_polarity_t; /*! @brief SPI clock phase configuration.*/ typedef enum _spi_clock_phase { kSPI_ClockPhaseFirstEdge = 0x0U, /*!< First edge on SCK occurs at the middle of the first * cycle of a data transfer. */ kSPI_ClockPhaseSecondEdge /*!< First edge on SCK occurs at the start of the * first cycle of a data transfer. */ } spi_clock_phase_t; /*! @brief txFIFO watermark values */ typedef enum _spi_txfifo_watermark { kSPI_TxFifo0 = 0, /*!< SPI tx watermark is empty */ kSPI_TxFifo1 = 1, /*!< SPI tx watermark at 1 item */ kSPI_TxFifo2 = 2, /*!< SPI tx watermark at 2 items */ kSPI_TxFifo3 = 3, /*!< SPI tx watermark at 3 items */ kSPI_TxFifo4 = 4, /*!< SPI tx watermark at 4 items */ kSPI_TxFifo5 = 5, /*!< SPI tx watermark at 5 items */ kSPI_TxFifo6 = 6, /*!< SPI tx watermark at 6 items */ kSPI_TxFifo7 = 7, /*!< SPI tx watermark at 7 items */ } spi_txfifo_watermark_t; /*! @brief rxFIFO watermark values */ typedef enum _spi_rxfifo_watermark { kSPI_RxFifo1 = 0, /*!< SPI rx watermark at 1 item */ kSPI_RxFifo2 = 1, /*!< SPI rx watermark at 2 items */ kSPI_RxFifo3 = 2, /*!< SPI rx watermark at 3 items */ kSPI_RxFifo4 = 3, /*!< SPI rx watermark at 4 items */ kSPI_RxFifo5 = 4, /*!< SPI rx watermark at 5 items */ kSPI_RxFifo6 = 5, /*!< SPI rx watermark at 6 items */ kSPI_RxFifo7 = 6, /*!< SPI rx watermark at 7 items */ kSPI_RxFifo8 = 7, /*!< SPI rx watermark at 8 items */ } spi_rxfifo_watermark_t; /*! @brief Transfer data width */ typedef enum _spi_data_width { kSPI_Data4Bits = 3, /*!< 4 bits data width */ kSPI_Data5Bits = 4, /*!< 5 bits data width */ kSPI_Data6Bits = 5, /*!< 6 bits data width */ kSPI_Data7Bits = 6, /*!< 7 bits data width */ kSPI_Data8Bits = 7, /*!< 8 bits data width */ kSPI_Data9Bits = 8, /*!< 9 bits data width */ kSPI_Data10Bits = 9, /*!< 10 bits data width */ kSPI_Data11Bits = 10, /*!< 11 bits data width */ kSPI_Data12Bits = 11, /*!< 12 bits data width */ kSPI_Data13Bits = 12, /*!< 13 bits data width */ kSPI_Data14Bits = 13, /*!< 14 bits data width */ kSPI_Data15Bits = 14, /*!< 15 bits data width */ kSPI_Data16Bits = 15, /*!< 16 bits data width */ } spi_data_width_t; /*! @brief Slave select */ typedef enum _spi_ssel { kSPI_Ssel0 = 0, /*!< Slave select 0 */ kSPI_Ssel1 = 1, /*!< Slave select 1 */ kSPI_Ssel2 = 2, /*!< Slave select 2 */ kSPI_Ssel3 = 3, /*!< Slave select 3 */ } spi_ssel_t; /*! @brief ssel polarity */ typedef enum _spi_spol { kSPI_Spol0ActiveHigh = SPI_CFG_SPOL0(1), kSPI_Spol1ActiveHigh = SPI_CFG_SPOL1(1), #if ((defined(FSL_FEATURE_SPI_SSEL_COUNT) && (FSL_FEATURE_SPI_SSEL_COUNT > 2)) || \ (defined(FSL_FEATURE_SPI_IS_SSEL_PIN_COUNT_EQUAL_TO_THREE) && \ (FSL_FEATURE_SPI_IS_SSEL_PIN_COUNT_EQUAL_TO_THREE))) kSPI_Spol2ActiveHigh = SPI_CFG_SPOL2(1), #endif #if defined(FSL_FEATURE_SPI_IS_SSEL_PIN_COUNT_EQUAL_TO_THREE) && (FSL_FEATURE_SPI_IS_SSEL_PIN_COUNT_EQUAL_TO_THREE) kSPI_SpolActiveAllHigh = (kSPI_Spol0ActiveHigh | kSPI_Spol1ActiveHigh | kSPI_Spol2ActiveHigh), #else #if (defined(FSL_FEATURE_SPI_SSEL_COUNT) && (FSL_FEATURE_SPI_SSEL_COUNT == 2)) kSPI_SpolActiveAllHigh = (kSPI_Spol0ActiveHigh | kSPI_Spol1ActiveHigh), #else kSPI_Spol3ActiveHigh = SPI_CFG_SPOL3(1), kSPI_SpolActiveAllHigh = (kSPI_Spol0ActiveHigh | kSPI_Spol1ActiveHigh | kSPI_Spol2ActiveHigh | kSPI_Spol3ActiveHigh), #endif /* FSL_FEATURE_SPI_SSEL_COUNT == 2 */ #endif /* FSL_FEATURE_SPI_IS_SSEL_PIN_COUNT_EQUAL_TO_THREE */ kSPI_SpolActiveAllLow = 0, } spi_spol_t; /*! * @brief SPI delay time configure structure. * Note: * The DLY register controls several programmable delays related to SPI signalling, * it stands for how many SPI clock time will be inserted. * The maxinun value of these delay time is 15. */ typedef struct _spi_delay_config { uint8_t preDelay; /*!< Delay between SSEL assertion and the beginning of transfer. */ uint8_t postDelay; /*!< Delay between the end of transfer and SSEL deassertion. */ uint8_t frameDelay; /*!< Delay between frame to frame. */ uint8_t transferDelay; /*!< Delay between transfer to transfer. */ } spi_delay_config_t; /*! @brief SPI master user configure structure.*/ typedef struct _spi_master_config { bool enableLoopback; /*!< Enable loopback for test purpose */ bool enableMaster; /*!< Enable SPI at initialization time */ spi_clock_polarity_t polarity; /*!< Clock polarity */ spi_clock_phase_t phase; /*!< Clock phase */ spi_shift_direction_t direction; /*!< MSB or LSB */ uint32_t baudRate_Bps; /*!< Baud Rate for SPI in Hz */ spi_data_width_t dataWidth; /*!< Width of the data */ spi_ssel_t sselNum; /*!< Slave select number */ spi_spol_t sselPol; /*!< Configure active CS polarity */ uint8_t txWatermark; /*!< txFIFO watermark */ uint8_t rxWatermark; /*!< rxFIFO watermark */ spi_delay_config_t delayConfig; /*!< Delay configuration. */ } spi_master_config_t; /*! @brief SPI slave user configure structure.*/ typedef struct _spi_slave_config { bool enableSlave; /*!< Enable SPI at initialization time */ spi_clock_polarity_t polarity; /*!< Clock polarity */ spi_clock_phase_t phase; /*!< Clock phase */ spi_shift_direction_t direction; /*!< MSB or LSB */ spi_data_width_t dataWidth; /*!< Width of the data */ spi_spol_t sselPol; /*!< Configure active CS polarity */ uint8_t txWatermark; /*!< txFIFO watermark */ uint8_t rxWatermark; /*!< rxFIFO watermark */ } spi_slave_config_t; /*! @brief SPI transfer status.*/ enum { kStatus_SPI_Busy = MAKE_STATUS(kStatusGroup_LPC_SPI, 0), /*!< SPI bus is busy */ kStatus_SPI_Idle = MAKE_STATUS(kStatusGroup_LPC_SPI, 1), /*!< SPI is idle */ kStatus_SPI_Error = MAKE_STATUS(kStatusGroup_LPC_SPI, 2), /*!< SPI error */ kStatus_SPI_BaudrateNotSupport = MAKE_STATUS(kStatusGroup_LPC_SPI, 3), /*!< Baudrate is not support in current clock source */ kStatus_SPI_Timeout = MAKE_STATUS(kStatusGroup_LPC_SPI, 4) /*!< SPI timeout polling status flags. */ }; /*! @brief SPI interrupt sources.*/ enum _spi_interrupt_enable { kSPI_RxLvlIrq = SPI_FIFOINTENSET_RXLVL_MASK, /*!< Rx level interrupt */ kSPI_TxLvlIrq = SPI_FIFOINTENSET_TXLVL_MASK, /*!< Tx level interrupt */ }; /*! @brief SPI status flags.*/ enum _spi_statusflags { kSPI_TxEmptyFlag = SPI_FIFOSTAT_TXEMPTY_MASK, /*!< txFifo is empty */ kSPI_TxNotFullFlag = SPI_FIFOSTAT_TXNOTFULL_MASK, /*!< txFifo is not full */ kSPI_RxNotEmptyFlag = SPI_FIFOSTAT_RXNOTEMPTY_MASK, /*!< rxFIFO is not empty */ kSPI_RxFullFlag = SPI_FIFOSTAT_RXFULL_MASK, /*!< rxFIFO is full */ }; /*! @brief SPI transfer structure */ typedef struct _spi_transfer { uint8_t *txData; /*!< Send buffer */ uint8_t *rxData; /*!< Receive buffer */ uint32_t configFlags; /*!< Additional option to control transfer, @ref spi_xfer_option_t. */ size_t dataSize; /*!< Transfer bytes */ } spi_transfer_t; /*! @brief SPI half-duplex(master only) transfer structure */ typedef struct _spi_half_duplex_transfer { uint8_t *txData; /*!< Send buffer */ uint8_t *rxData; /*!< Receive buffer */ size_t txDataSize; /*!< Transfer bytes for transmit */ size_t rxDataSize; /*!< Transfer bytes */ uint32_t configFlags; /*!< Transfer configuration flags, @ref spi_xfer_option_t. */ bool isPcsAssertInTransfer; /*!< If PCS pin keep assert between transmit and receive. true for assert and false for deassert. */ bool isTransmitFirst; /*!< True for transmit first and false for receive first. */ } spi_half_duplex_transfer_t; /*! @brief Internal configuration structure used in 'spi' and 'spi_dma' driver */ typedef struct _spi_config { spi_data_width_t dataWidth; spi_ssel_t sselNum; } spi_config_t; /*! @brief Master handle type */ typedef struct _spi_master_handle spi_master_handle_t; /*! @brief Slave handle type */ typedef spi_master_handle_t spi_slave_handle_t; /*! @brief SPI master callback for finished transmit */ typedef void (*spi_master_callback_t)(SPI_Type *base, spi_master_handle_t *handle, status_t status, void *userData); /*! @brief SPI slave callback for finished transmit */ typedef void (*spi_slave_callback_t)(SPI_Type *base, spi_slave_handle_t *handle, status_t status, void *userData); /*! @brief SPI transfer handle structure */ struct _spi_master_handle { uint8_t *volatile txData; /*!< Transfer buffer */ uint8_t *volatile rxData; /*!< Receive buffer */ volatile size_t txRemainingBytes; /*!< Number of data to be transmitted [in bytes] */ volatile size_t rxRemainingBytes; /*!< Number of data to be received [in bytes] */ volatile int8_t toReceiveCount; /*!< The number of data expected to receive in data width. Since the received count and sent count should be the same to complete the transfer, if the sent count is x and the received count is y, toReceiveCount is x-y. */ size_t totalByteCount; /*!< A number of transfer bytes */ volatile uint32_t state; /*!< SPI internal state */ spi_master_callback_t callback; /*!< SPI callback */ void *userData; /*!< Callback parameter */ uint8_t dataWidth; /*!< Width of the data [Valid values: 1 to 16] */ uint8_t sselNum; /*!< Slave select number to be asserted when transferring data [Valid values: 0 to 3] */ uint32_t configFlags; /*!< Additional option to control transfer */ uint8_t txWatermark; /*!< txFIFO watermark */ uint8_t rxWatermark; /*!< rxFIFO watermark */ }; /*! @brief Typedef for master interrupt handler. */ typedef void (*flexcomm_spi_master_irq_handler_t)(SPI_Type *base, spi_master_handle_t *handle); /*! @brief Typedef for slave interrupt handler. */ typedef void (*flexcomm_spi_slave_irq_handler_t)(SPI_Type *base, spi_slave_handle_t *handle); /*! @} */ /******************************************************************************* * API ******************************************************************************/ #if defined(__cplusplus) extern "C" { #endif /*! @brief Returns instance number for SPI peripheral base address. */ uint32_t SPI_GetInstance(SPI_Type *base); /*! * @name Initialization and deinitialization * @{ */ /*! * @brief Sets the SPI master configuration structure to default values. * * The purpose of this API is to get the configuration structure initialized for use in SPI_MasterInit(). * User may use the initialized structure unchanged in SPI_MasterInit(), or modify * some fields of the structure before calling SPI_MasterInit(). After calling this API, * the master is ready to transfer. * Example: @code spi_master_config_t config; SPI_MasterGetDefaultConfig(&config); @endcode * * @param config pointer to master config structure */ void SPI_MasterGetDefaultConfig(spi_master_config_t *config); /*! * @brief Initializes the SPI with master configuration. * * The configuration structure can be filled by user from scratch, or be set with default * values by SPI_MasterGetDefaultConfig(). After calling this API, the slave is ready to transfer. * Example @code spi_master_config_t config = { .baudRate_Bps = 400000, ... }; SPI_MasterInit(SPI0, &config); @endcode * * @param base SPI base pointer * @param config pointer to master configuration structure * @param srcClock_Hz Source clock frequency. */ status_t SPI_MasterInit(SPI_Type *base, const spi_master_config_t *config, uint32_t srcClock_Hz); /*! * @brief Sets the SPI slave configuration structure to default values. * * The purpose of this API is to get the configuration structure initialized for use in SPI_SlaveInit(). * Modify some fields of the structure before calling SPI_SlaveInit(). * Example: @code spi_slave_config_t config; SPI_SlaveGetDefaultConfig(&config); @endcode * * @param config pointer to slave configuration structure */ void SPI_SlaveGetDefaultConfig(spi_slave_config_t *config); /*! * @brief Initializes the SPI with slave configuration. * * The configuration structure can be filled by user from scratch or be set with * default values by SPI_SlaveGetDefaultConfig(). * After calling this API, the slave is ready to transfer. * Example @code spi_slave_config_t config = { .polarity = flexSPIClockPolarity_ActiveHigh; .phase = flexSPIClockPhase_FirstEdge; .direction = flexSPIMsbFirst; ... }; SPI_SlaveInit(SPI0, &config); @endcode * * @param base SPI base pointer * @param config pointer to slave configuration structure */ status_t SPI_SlaveInit(SPI_Type *base, const spi_slave_config_t *config); /*! * @brief De-initializes the SPI. * * Calling this API resets the SPI module, gates the SPI clock. * The SPI module can't work unless calling the SPI_MasterInit/SPI_SlaveInit to initialize module. * * @param base SPI base pointer */ void SPI_Deinit(SPI_Type *base); /*! * @brief Enable or disable the SPI Master or Slave * @param base SPI base pointer * @param enable or disable ( true = enable, false = disable) */ static inline void SPI_Enable(SPI_Type *base, bool enable) { if (enable) { base->CFG |= SPI_CFG_ENABLE_MASK; } else { base->CFG &= ~SPI_CFG_ENABLE_MASK; } } /*! @} */ /*! * @name Status * @{ */ /*! * @brief Gets the status flag. * * @param base SPI base pointer * @return SPI Status, use status flag to AND @ref _spi_statusflags could get the related status. */ static inline uint32_t SPI_GetStatusFlags(SPI_Type *base) { assert(NULL != base); return base->FIFOSTAT; } /*! @} */ /*! * @name Interrupts * @{ */ /*! * @brief Enables the interrupt for the SPI. * * @param base SPI base pointer * @param irqs SPI interrupt source. The parameter can be any combination of the following values: * @arg kSPI_RxLvlIrq * @arg kSPI_TxLvlIrq */ static inline void SPI_EnableInterrupts(SPI_Type *base, uint32_t irqs) { assert(NULL != base); base->FIFOINTENSET = irqs; } /*! * @brief Disables the interrupt for the SPI. * * @param base SPI base pointer * @param irqs SPI interrupt source. The parameter can be any combination of the following values: * @arg kSPI_RxLvlIrq * @arg kSPI_TxLvlIrq */ static inline void SPI_DisableInterrupts(SPI_Type *base, uint32_t irqs) { assert(NULL != base); base->FIFOINTENCLR = irqs; } /*! @} */ /*! * @name DMA Control * @{ */ /*! * @brief Enables the DMA request from SPI txFIFO. * * @param base SPI base pointer * @param enable True means enable DMA, false means disable DMA */ void SPI_EnableTxDMA(SPI_Type *base, bool enable); /*! * @brief Enables the DMA request from SPI rxFIFO. * * @param base SPI base pointer * @param enable True means enable DMA, false means disable DMA */ void SPI_EnableRxDMA(SPI_Type *base, bool enable); /*! @} */ /*! * @name Bus Operations * @{ */ /*! * @brief Returns the configurations. * * @param base SPI peripheral address. * @return return configurations which contain datawidth and SSEL numbers. * return data type is a pointer of spi_config_t. */ void *SPI_GetConfig(SPI_Type *base); /*! * @brief Sets the baud rate for SPI transfer. This is only used in master. * * @param base SPI base pointer * @param baudrate_Bps baud rate needed in Hz. * @param srcClock_Hz SPI source clock frequency in Hz. */ status_t SPI_MasterSetBaud(SPI_Type *base, uint32_t baudrate_Bps, uint32_t srcClock_Hz); /*! * @brief Writes a data into the SPI data register. * * @param base SPI base pointer * @param data needs to be write. * @param configFlags transfer configuration options @ref spi_xfer_option_t */ void SPI_WriteData(SPI_Type *base, uint16_t data, uint32_t configFlags); /*! * @brief Gets a data from the SPI data register. * * @param base SPI base pointer * @return Data in the register. */ static inline uint32_t SPI_ReadData(SPI_Type *base) { assert(NULL != base); return base->FIFORD; } /*! * @brief Set delay time for transfer. * the delay uint is SPI clock time, maximum value is 0xF. * @param base SPI base pointer * @param config configuration for delay option @ref spi_delay_config_t. */ static inline void SPI_SetTransferDelay(SPI_Type *base, const spi_delay_config_t *config) { assert(NULL != base); assert(NULL != config); base->DLY = (SPI_DLY_PRE_DELAY(config->preDelay) | SPI_DLY_POST_DELAY(config->postDelay) | SPI_DLY_FRAME_DELAY(config->frameDelay) | SPI_DLY_TRANSFER_DELAY(config->transferDelay)); } /*! * @brief Set up the dummy data. * * @param base SPI peripheral address. * @param dummyData Data to be transferred when tx buffer is NULL. */ void SPI_SetDummyData(SPI_Type *base, uint8_t dummyData); /*! @} */ /*! * @name Transactional * @{ */ /*! * @brief Initializes the SPI master handle. * * This function initializes the SPI master handle which can be used for other SPI master transactional APIs. Usually, * for a specified SPI instance, call this API once to get the initialized handle. * * @param base SPI peripheral base address. * @param handle SPI handle pointer. * @param callback Callback function. * @param userData User data. */ status_t SPI_MasterTransferCreateHandle(SPI_Type *base, spi_master_handle_t *handle, spi_master_callback_t callback, void *userData); /*! * @brief Transfers a block of data using a polling method. * * @param base SPI base pointer * @param xfer pointer to spi_xfer_config_t structure * @retval kStatus_Success Successfully start a transfer. * @retval kStatus_InvalidArgument Input argument is invalid. * @retval kStatus_SPI_Timeout The transfer timed out and was aborted. */ status_t SPI_MasterTransferBlocking(SPI_Type *base, spi_transfer_t *xfer); /*! * @brief Performs a non-blocking SPI interrupt transfer. * * @param base SPI peripheral base address. * @param handle pointer to spi_master_handle_t structure which stores the transfer state * @param xfer pointer to spi_xfer_config_t structure * @retval kStatus_Success Successfully start a transfer. * @retval kStatus_InvalidArgument Input argument is invalid. * @retval kStatus_SPI_Busy SPI is not idle, is running another transfer. */ status_t SPI_MasterTransferNonBlocking(SPI_Type *base, spi_master_handle_t *handle, spi_transfer_t *xfer); /*! * @brief Transfers a block of data using a polling method. * * This function will do a half-duplex transfer for SPI master, This is a blocking function, * which does not retuen until all transfer have been completed. And data transfer mechanism is half-duplex, * users can set transmit first or receive first. * * @param base SPI base pointer * @param xfer pointer to spi_half_duplex_transfer_t structure * @return status of status_t. */ status_t SPI_MasterHalfDuplexTransferBlocking(SPI_Type *base, spi_half_duplex_transfer_t *xfer); /*! * @brief Performs a non-blocking SPI interrupt transfer. * * This function using polling way to do the first half transimission and using interrupts to * do the second half transimission, the transfer mechanism is half-duplex. * When do the second half transimission, code will return right away. When all data is transferred, * the callback function is called. * * @param base SPI peripheral base address. * @param handle pointer to spi_master_handle_t structure which stores the transfer state * @param xfer pointer to spi_half_duplex_transfer_t structure * @return status of status_t. */ status_t SPI_MasterHalfDuplexTransferNonBlocking(SPI_Type *base, spi_master_handle_t *handle, spi_half_duplex_transfer_t *xfer); /*! * @brief Gets the master transfer count. * * This function gets the master transfer count. * * @param base SPI peripheral base address. * @param handle Pointer to the spi_master_handle_t structure which stores the transfer state. * @param count The number of bytes transferred by using the non-blocking transaction. * @return status of status_t. */ status_t SPI_MasterTransferGetCount(SPI_Type *base, spi_master_handle_t *handle, size_t *count); /*! * @brief SPI master aborts a transfer using an interrupt. * * This function aborts a transfer using an interrupt. * * @param base SPI peripheral base address. * @param handle Pointer to the spi_master_handle_t structure which stores the transfer state. */ void SPI_MasterTransferAbort(SPI_Type *base, spi_master_handle_t *handle); /*! * @brief Interrupts the handler for the SPI. * * @param base SPI peripheral base address. * @param handle pointer to spi_master_handle_t structure which stores the transfer state. */ void SPI_MasterTransferHandleIRQ(SPI_Type *base, spi_master_handle_t *handle); /*! * @brief Initializes the SPI slave handle. * * This function initializes the SPI slave handle which can be used for other SPI slave transactional APIs. Usually, * for a specified SPI instance, call this API once to get the initialized handle. * * @param base SPI peripheral base address. * @param handle SPI handle pointer. * @param callback Callback function. * @param userData User data. */ static inline status_t SPI_SlaveTransferCreateHandle(SPI_Type *base, spi_slave_handle_t *handle, spi_slave_callback_t callback, void *userData) { return SPI_MasterTransferCreateHandle(base, handle, callback, userData); } /*! * @brief Performs a non-blocking SPI slave interrupt transfer. * * @note The API returns immediately after the transfer initialization is finished. * * @param base SPI peripheral base address. * @param handle pointer to spi_master_handle_t structure which stores the transfer state * @param xfer pointer to spi_xfer_config_t structure * @retval kStatus_Success Successfully start a transfer. * @retval kStatus_InvalidArgument Input argument is invalid. * @retval kStatus_SPI_Busy SPI is not idle, is running another transfer. */ static inline status_t SPI_SlaveTransferNonBlocking(SPI_Type *base, spi_slave_handle_t *handle, spi_transfer_t *xfer) { return SPI_MasterTransferNonBlocking(base, handle, xfer); } /*! * @brief Gets the slave transfer count. * * This function gets the slave transfer count. * * @param base SPI peripheral base address. * @param handle Pointer to the spi_master_handle_t structure which stores the transfer state. * @param count The number of bytes transferred by using the non-blocking transaction. * @return status of status_t. */ static inline status_t SPI_SlaveTransferGetCount(SPI_Type *base, spi_slave_handle_t *handle, size_t *count) { return SPI_MasterTransferGetCount(base, (spi_master_handle_t *)handle, count); } /*! * @brief SPI slave aborts a transfer using an interrupt. * * This function aborts a transfer using an interrupt. * * @param base SPI peripheral base address. * @param handle Pointer to the spi_slave_handle_t structure which stores the transfer state. */ static inline void SPI_SlaveTransferAbort(SPI_Type *base, spi_slave_handle_t *handle) { SPI_MasterTransferAbort(base, (spi_master_handle_t *)handle); } /*! * @brief Interrupts a handler for the SPI slave. * * @param base SPI peripheral base address. * @param handle pointer to spi_slave_handle_t structure which stores the transfer state */ static inline void SPI_SlaveTransferHandleIRQ(SPI_Type *base, spi_slave_handle_t *handle) { SPI_MasterTransferHandleIRQ(base, handle); } /*! @} */ #if defined(__cplusplus) } #endif /*! @} */ #endif /* FSL_SPI_H_*/