/* * Copyright (c) 2015, Freescale Semiconductor, Inc. * Copyright 2016-2020,2021 NXP * All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #ifndef _FSL_LPSPI_H_ #define _FSL_LPSPI_H_ #include "fsl_common.h" /*! * @addtogroup lpspi_driver * @{ */ /********************************************************************************************************************** * Definitions *********************************************************************************************************************/ /*! @name Driver version */ /*@{*/ /*! @brief LPSPI driver version. */ #define FSL_LPSPI_DRIVER_VERSION (MAKE_VERSION(2, 2, 1)) /*@}*/ #ifndef LPSPI_DUMMY_DATA /*! @brief LPSPI dummy data if no Tx data.*/ #define LPSPI_DUMMY_DATA (0x00U) /*!< Dummy data used for tx if there is not txData. */ #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 /*! @brief Global variable for dummy data value setting. */ extern volatile uint8_t g_lpspiDummyData[]; /*! @brief Status for the LPSPI driver.*/ enum { kStatus_LPSPI_Busy = MAKE_STATUS(kStatusGroup_LPSPI, 0), /*!< LPSPI transfer is busy.*/ kStatus_LPSPI_Error = MAKE_STATUS(kStatusGroup_LPSPI, 1), /*!< LPSPI driver error. */ kStatus_LPSPI_Idle = MAKE_STATUS(kStatusGroup_LPSPI, 2), /*!< LPSPI is idle.*/ kStatus_LPSPI_OutOfRange = MAKE_STATUS(kStatusGroup_LPSPI, 3), /*!< LPSPI transfer out Of range. */ kStatus_LPSPI_Timeout = MAKE_STATUS(kStatusGroup_LPSPI, 4) /*!< LPSPI timeout polling status flags. */ }; /*! @brief LPSPI status flags in SPIx_SR register.*/ enum _lpspi_flags { kLPSPI_TxDataRequestFlag = LPSPI_SR_TDF_MASK, /*!< Transmit data flag */ kLPSPI_RxDataReadyFlag = LPSPI_SR_RDF_MASK, /*!< Receive data flag */ kLPSPI_WordCompleteFlag = LPSPI_SR_WCF_MASK, /*!< Word Complete flag */ kLPSPI_FrameCompleteFlag = LPSPI_SR_FCF_MASK, /*!< Frame Complete flag */ kLPSPI_TransferCompleteFlag = LPSPI_SR_TCF_MASK, /*!< Transfer Complete flag */ kLPSPI_TransmitErrorFlag = LPSPI_SR_TEF_MASK, /*!< Transmit Error flag (FIFO underrun) */ kLPSPI_ReceiveErrorFlag = LPSPI_SR_REF_MASK, /*!< Receive Error flag (FIFO overrun) */ kLPSPI_DataMatchFlag = LPSPI_SR_DMF_MASK, /*!< Data Match flag */ kLPSPI_ModuleBusyFlag = LPSPI_SR_MBF_MASK, /*!< Module Busy flag */ kLPSPI_AllStatusFlag = (LPSPI_SR_TDF_MASK | LPSPI_SR_RDF_MASK | LPSPI_SR_WCF_MASK | LPSPI_SR_FCF_MASK | LPSPI_SR_TCF_MASK | LPSPI_SR_TEF_MASK | LPSPI_SR_REF_MASK | LPSPI_SR_DMF_MASK | LPSPI_SR_MBF_MASK) /*!< Used for clearing all w1c status flags */ }; /*! @brief LPSPI interrupt source.*/ enum _lpspi_interrupt_enable { kLPSPI_TxInterruptEnable = LPSPI_IER_TDIE_MASK, /*!< Transmit data interrupt enable */ kLPSPI_RxInterruptEnable = LPSPI_IER_RDIE_MASK, /*!< Receive data interrupt enable */ kLPSPI_WordCompleteInterruptEnable = LPSPI_IER_WCIE_MASK, /*!< Word complete interrupt enable */ kLPSPI_FrameCompleteInterruptEnable = LPSPI_IER_FCIE_MASK, /*!< Frame complete interrupt enable */ kLPSPI_TransferCompleteInterruptEnable = LPSPI_IER_TCIE_MASK, /*!< Transfer complete interrupt enable */ kLPSPI_TransmitErrorInterruptEnable = LPSPI_IER_TEIE_MASK, /*!< Transmit error interrupt enable(FIFO underrun)*/ kLPSPI_ReceiveErrorInterruptEnable = LPSPI_IER_REIE_MASK, /*!< Receive Error interrupt enable (FIFO overrun) */ kLPSPI_DataMatchInterruptEnable = LPSPI_IER_DMIE_MASK, /*!< Data Match interrupt enable */ kLPSPI_AllInterruptEnable = (LPSPI_IER_TDIE_MASK | LPSPI_IER_RDIE_MASK | LPSPI_IER_WCIE_MASK | LPSPI_IER_FCIE_MASK | LPSPI_IER_TCIE_MASK | LPSPI_IER_TEIE_MASK | LPSPI_IER_REIE_MASK | LPSPI_IER_DMIE_MASK) /*!< All above interrupts enable.*/ }; /*! @brief LPSPI DMA source.*/ enum _lpspi_dma_enable { kLPSPI_TxDmaEnable = LPSPI_DER_TDDE_MASK, /*!< Transmit data DMA enable */ kLPSPI_RxDmaEnable = LPSPI_DER_RDDE_MASK /*!< Receive data DMA enable */ }; /*! @brief LPSPI master or slave mode configuration.*/ typedef enum _lpspi_master_slave_mode { kLPSPI_Master = 1U, /*!< LPSPI peripheral operates in master mode.*/ kLPSPI_Slave = 0U /*!< LPSPI peripheral operates in slave mode.*/ } lpspi_master_slave_mode_t; /*! @brief LPSPI Peripheral Chip Select (PCS) configuration (which PCS to configure).*/ typedef enum _lpspi_which_pcs_config { kLPSPI_Pcs0 = 0U, /*!< PCS[0] */ kLPSPI_Pcs1 = 1U, /*!< PCS[1] */ kLPSPI_Pcs2 = 2U, /*!< PCS[2] */ kLPSPI_Pcs3 = 3U /*!< PCS[3] */ } lpspi_which_pcs_t; /*! @brief LPSPI Peripheral Chip Select (PCS) Polarity configuration.*/ typedef enum _lpspi_pcs_polarity_config { kLPSPI_PcsActiveHigh = 1U, /*!< PCS Active High (idles low) */ kLPSPI_PcsActiveLow = 0U /*!< PCS Active Low (idles high) */ } lpspi_pcs_polarity_config_t; /*! @brief LPSPI Peripheral Chip Select (PCS) Polarity.*/ enum _lpspi_pcs_polarity { kLPSPI_Pcs0ActiveLow = 1U << 0, /*!< Pcs0 Active Low (idles high). */ kLPSPI_Pcs1ActiveLow = 1U << 1, /*!< Pcs1 Active Low (idles high). */ kLPSPI_Pcs2ActiveLow = 1U << 2, /*!< Pcs2 Active Low (idles high). */ kLPSPI_Pcs3ActiveLow = 1U << 3, /*!< Pcs3 Active Low (idles high). */ kLPSPI_PcsAllActiveLow = 0xFU /*!< Pcs0 to Pcs5 Active Low (idles high). */ }; /*! @brief LPSPI clock polarity configuration.*/ typedef enum _lpspi_clock_polarity { kLPSPI_ClockPolarityActiveHigh = 0U, /*!< CPOL=0. Active-high LPSPI clock (idles low)*/ kLPSPI_ClockPolarityActiveLow = 1U /*!< CPOL=1. Active-low LPSPI clock (idles high)*/ } lpspi_clock_polarity_t; /*! @brief LPSPI clock phase configuration.*/ typedef enum _lpspi_clock_phase { kLPSPI_ClockPhaseFirstEdge = 0U, /*!< CPHA=0. Data is captured on the leading edge of the SCK and changed on the following edge.*/ kLPSPI_ClockPhaseSecondEdge = 1U /*!< CPHA=1. Data is changed on the leading edge of the SCK and captured on the following edge.*/ } lpspi_clock_phase_t; /*! @brief LPSPI data shifter direction options.*/ typedef enum _lpspi_shift_direction { kLPSPI_MsbFirst = 0U, /*!< Data transfers start with most significant bit.*/ kLPSPI_LsbFirst = 1U /*!< Data transfers start with least significant bit.*/ } lpspi_shift_direction_t; /*! @brief LPSPI Host Request select configuration. */ typedef enum _lpspi_host_request_select { kLPSPI_HostReqExtPin = 0U, /*!< Host Request is an ext pin. */ kLPSPI_HostReqInternalTrigger = 1U /*!< Host Request is an internal trigger. */ } lpspi_host_request_select_t; /*! @brief LPSPI Match configuration options. */ typedef enum _lpspi_match_config { kLPSI_MatchDisabled = 0x0U, /*!< LPSPI Match Disabled. */ kLPSI_1stWordEqualsM0orM1 = 0x2U, /*!< LPSPI Match Enabled. */ kLPSI_AnyWordEqualsM0orM1 = 0x3U, /*!< LPSPI Match Enabled. */ kLPSI_1stWordEqualsM0and2ndWordEqualsM1 = 0x4U, /*!< LPSPI Match Enabled. */ kLPSI_AnyWordEqualsM0andNxtWordEqualsM1 = 0x5U, /*!< LPSPI Match Enabled. */ kLPSI_1stWordAndM1EqualsM0andM1 = 0x6U, /*!< LPSPI Match Enabled. */ kLPSI_AnyWordAndM1EqualsM0andM1 = 0x7U, /*!< LPSPI Match Enabled. */ } lpspi_match_config_t; /*! @brief LPSPI pin (SDO and SDI) configuration. */ typedef enum _lpspi_pin_config { kLPSPI_SdiInSdoOut = 0U, /*!< LPSPI SDI input, SDO output. */ kLPSPI_SdiInSdiOut = 1U, /*!< LPSPI SDI input, SDI output. */ kLPSPI_SdoInSdoOut = 2U, /*!< LPSPI SDO input, SDO output. */ kLPSPI_SdoInSdiOut = 3U /*!< LPSPI SDO input, SDI output. */ } lpspi_pin_config_t; /*! @brief LPSPI data output configuration. */ typedef enum _lpspi_data_out_config { kLpspiDataOutRetained = 0U, /*!< Data out retains last value when chip select is de-asserted */ kLpspiDataOutTristate = 1U /*!< Data out is tristated when chip select is de-asserted */ } lpspi_data_out_config_t; /*! @brief LPSPI transfer width configuration. */ typedef enum _lpspi_transfer_width { kLPSPI_SingleBitXfer = 0U, /*!< 1-bit shift at a time, data out on SDO, in on SDI (normal mode) */ kLPSPI_TwoBitXfer = 1U, /*!< 2-bits shift out on SDO/SDI and in on SDO/SDI */ kLPSPI_FourBitXfer = 2U /*!< 4-bits shift out on SDO/SDI/PCS[3:2] and in on SDO/SDI/PCS[3:2] */ } lpspi_transfer_width_t; /*! @brief LPSPI delay type selection.*/ typedef enum _lpspi_delay_type { kLPSPI_PcsToSck = 1U, /*!< PCS-to-SCK delay. */ kLPSPI_LastSckToPcs, /*!< Last SCK edge to PCS delay. */ kLPSPI_BetweenTransfer /*!< Delay between transfers. */ } lpspi_delay_type_t; #define LPSPI_MASTER_PCS_SHIFT (4U) /*!< LPSPI master PCS shift macro , internal used. */ #define LPSPI_MASTER_PCS_MASK (0xF0U) /*!< LPSPI master PCS shift macro , internal used. */ /*! @brief Use this enumeration for LPSPI master transfer configFlags. */ enum _lpspi_transfer_config_flag_for_master { kLPSPI_MasterPcs0 = 0U << LPSPI_MASTER_PCS_SHIFT, /*!< LPSPI master transfer use PCS0 signal */ kLPSPI_MasterPcs1 = 1U << LPSPI_MASTER_PCS_SHIFT, /*!< LPSPI master transfer use PCS1 signal */ kLPSPI_MasterPcs2 = 2U << LPSPI_MASTER_PCS_SHIFT, /*!< LPSPI master transfer use PCS2 signal */ kLPSPI_MasterPcs3 = 3U << LPSPI_MASTER_PCS_SHIFT, /*!< LPSPI master transfer use PCS3 signal */ kLPSPI_MasterPcsContinuous = 1U << 20, /*!< Is PCS signal continuous */ kLPSPI_MasterByteSwap = 1U << 22 /*!< Is master swap the byte. * For example, when want to send data 1 2 3 4 5 6 7 8 (suppose you set * lpspi_shift_direction_t to MSB). * 1. If you set bitPerFrame = 8 , no matter the kLPSPI_MasterByteSwapyou flag is used * or not, the waveform is 1 2 3 4 5 6 7 8. * 2. If you set bitPerFrame = 16 : * (1) the waveform is 2 1 4 3 6 5 8 7 if you do not use the kLPSPI_MasterByteSwap flag. * (2) the waveform is 1 2 3 4 5 6 7 8 if you use the kLPSPI_MasterByteSwap flag. * 3. If you set bitPerFrame = 32 : * (1) the waveform is 4 3 2 1 8 7 6 5 if you do not use the kLPSPI_MasterByteSwap flag. * (2) the waveform is 1 2 3 4 5 6 7 8 if you use the kLPSPI_MasterByteSwap flag. */ }; #define LPSPI_SLAVE_PCS_SHIFT (4U) /*!< LPSPI slave PCS shift macro , internal used. */ #define LPSPI_SLAVE_PCS_MASK (0xF0U) /*!< LPSPI slave PCS shift macro , internal used. */ /*! @brief Use this enumeration for LPSPI slave transfer configFlags. */ enum _lpspi_transfer_config_flag_for_slave { kLPSPI_SlavePcs0 = 0U << LPSPI_SLAVE_PCS_SHIFT, /*!< LPSPI slave transfer use PCS0 signal */ kLPSPI_SlavePcs1 = 1U << LPSPI_SLAVE_PCS_SHIFT, /*!< LPSPI slave transfer use PCS1 signal */ kLPSPI_SlavePcs2 = 2U << LPSPI_SLAVE_PCS_SHIFT, /*!< LPSPI slave transfer use PCS2 signal */ kLPSPI_SlavePcs3 = 3U << LPSPI_SLAVE_PCS_SHIFT, /*!< LPSPI slave transfer use PCS3 signal */ kLPSPI_SlaveByteSwap = 1U << 22 /*!< Is slave swap the byte. * For example, when want to send data 1 2 3 4 5 6 7 8 (suppose you set * lpspi_shift_direction_t to MSB). * 1. If you set bitPerFrame = 8 , no matter the kLPSPI_SlaveByteSwap flag is used * or not, the waveform is 1 2 3 4 5 6 7 8. * 2. If you set bitPerFrame = 16 : * (1) the waveform is 2 1 4 3 6 5 8 7 if you do not use the kLPSPI_SlaveByteSwap flag. * (2) the waveform is 1 2 3 4 5 6 7 8 if you use the kLPSPI_SlaveByteSwap flag. * 3. If you set bitPerFrame = 32 : * (1) the waveform is 4 3 2 1 8 7 6 5 if you do not use the kLPSPI_SlaveByteSwap flag. * (2) the waveform is 1 2 3 4 5 6 7 8 if you use the kLPSPI_SlaveByteSwap flag. */ }; /*! @brief LPSPI transfer state, which is used for LPSPI transactional API state machine. */ enum _lpspi_transfer_state { kLPSPI_Idle = 0x0U, /*!< Nothing in the transmitter/receiver. */ kLPSPI_Busy, /*!< Transfer queue is not finished. */ kLPSPI_Error /*!< Transfer error. */ }; /*! @brief LPSPI master configuration structure.*/ typedef struct _lpspi_master_config { uint32_t baudRate; /*!< Baud Rate for LPSPI. */ uint32_t bitsPerFrame; /*!< Bits per frame, minimum 8, maximum 4096.*/ lpspi_clock_polarity_t cpol; /*!< Clock polarity. */ lpspi_clock_phase_t cpha; /*!< Clock phase. */ lpspi_shift_direction_t direction; /*!< MSB or LSB data shift direction. */ uint32_t pcsToSckDelayInNanoSec; /*!< PCS to SCK delay time in nanoseconds, setting to 0 sets the minimum delay. It sets the boundary value if out of range.*/ uint32_t lastSckToPcsDelayInNanoSec; /*!< Last SCK to PCS delay time in nanoseconds, setting to 0 sets the minimum delay. It sets the boundary value if out of range.*/ uint32_t betweenTransferDelayInNanoSec; /*!< After the SCK delay time with nanoseconds, setting to 0 sets the minimum delay. It sets the boundary value if out of range.*/ lpspi_which_pcs_t whichPcs; /*!< Desired Peripheral Chip Select (PCS). */ lpspi_pcs_polarity_config_t pcsActiveHighOrLow; /*!< Desired PCS active high or low */ lpspi_pin_config_t pinCfg; /*!< Configures which pins are used for input and output data *during single bit transfers.*/ lpspi_data_out_config_t dataOutConfig; /*!< Configures if the output data is tristated * between accesses (LPSPI_PCS is negated). */ } lpspi_master_config_t; /*! @brief LPSPI slave configuration structure.*/ typedef struct _lpspi_slave_config { uint32_t bitsPerFrame; /*!< Bits per frame, minimum 8, maximum 4096.*/ lpspi_clock_polarity_t cpol; /*!< Clock polarity. */ lpspi_clock_phase_t cpha; /*!< Clock phase. */ lpspi_shift_direction_t direction; /*!< MSB or LSB data shift direction. */ lpspi_which_pcs_t whichPcs; /*!< Desired Peripheral Chip Select (pcs) */ lpspi_pcs_polarity_config_t pcsActiveHighOrLow; /*!< Desired PCS active high or low */ lpspi_pin_config_t pinCfg; /*!< Configures which pins are used for input and output data *during single bit transfers.*/ lpspi_data_out_config_t dataOutConfig; /*!< Configures if the output data is tristated * between accesses (LPSPI_PCS is negated). */ } lpspi_slave_config_t; /*! * @brief Forward declaration of the _lpspi_master_handle typedefs. */ typedef struct _lpspi_master_handle lpspi_master_handle_t; /*! * @brief Forward declaration of the _lpspi_slave_handle typedefs. */ typedef struct _lpspi_slave_handle lpspi_slave_handle_t; /*! * @brief Master completion callback function pointer type. * * @param base LPSPI peripheral address. * @param handle Pointer to the handle for the LPSPI master. * @param status Success or error code describing whether the transfer is completed. * @param userData Arbitrary pointer-dataSized value passed from the application. */ typedef void (*lpspi_master_transfer_callback_t)(LPSPI_Type *base, lpspi_master_handle_t *handle, status_t status, void *userData); /*! * @brief Slave completion callback function pointer type. * * @param base LPSPI peripheral address. * @param handle Pointer to the handle for the LPSPI slave. * @param status Success or error code describing whether the transfer is completed. * @param userData Arbitrary pointer-dataSized value passed from the application. */ typedef void (*lpspi_slave_transfer_callback_t)(LPSPI_Type *base, lpspi_slave_handle_t *handle, status_t status, void *userData); /*! @brief LPSPI master/slave transfer structure.*/ typedef struct _lpspi_transfer { uint8_t *txData; /*!< Send buffer. */ uint8_t *rxData; /*!< Receive buffer. */ volatile size_t dataSize; /*!< Transfer bytes. */ uint32_t configFlags; /*!< Transfer transfer configuration flags. Set from _lpspi_transfer_config_flag_for_master if the transfer is used for master or _lpspi_transfer_config_flag_for_slave enumeration if the transfer is used for slave.*/ } lpspi_transfer_t; /*! @brief LPSPI master transfer handle structure used for transactional API. */ struct _lpspi_master_handle { volatile bool isPcsContinuous; /*!< Is PCS continuous in transfer. */ volatile bool writeTcrInIsr; /*!< A flag that whether should write TCR in ISR. */ volatile bool isByteSwap; /*!< A flag that whether should byte swap. */ volatile bool isTxMask; /*!< A flag that whether TCR[TXMSK] is set. */ volatile uint16_t bytesPerFrame; /*!< Number of bytes in each frame */ volatile uint8_t fifoSize; /*!< FIFO dataSize. */ volatile uint8_t rxWatermark; /*!< Rx watermark. */ volatile uint8_t bytesEachWrite; /*!< Bytes for each write TDR. */ volatile uint8_t bytesEachRead; /*!< Bytes for each read RDR. */ uint8_t *volatile txData; /*!< Send buffer. */ uint8_t *volatile rxData; /*!< Receive buffer. */ volatile size_t txRemainingByteCount; /*!< Number of bytes remaining to send.*/ volatile size_t rxRemainingByteCount; /*!< Number of bytes remaining to receive.*/ volatile uint32_t writeRegRemainingTimes; /*!< Write TDR register remaining times. */ volatile uint32_t readRegRemainingTimes; /*!< Read RDR register remaining times. */ uint32_t totalByteCount; /*!< Number of transfer bytes*/ uint32_t txBuffIfNull; /*!< Used if the txData is NULL. */ volatile uint8_t state; /*!< LPSPI transfer state , _lpspi_transfer_state.*/ lpspi_master_transfer_callback_t callback; /*!< Completion callback. */ void *userData; /*!< Callback user data. */ }; /*! @brief LPSPI slave transfer handle structure used for transactional API. */ struct _lpspi_slave_handle { volatile bool isByteSwap; /*!< A flag that whether should byte swap. */ volatile uint8_t fifoSize; /*!< FIFO dataSize. */ volatile uint8_t rxWatermark; /*!< Rx watermark. */ volatile uint8_t bytesEachWrite; /*!< Bytes for each write TDR. */ volatile uint8_t bytesEachRead; /*!< Bytes for each read RDR. */ uint8_t *volatile txData; /*!< Send buffer. */ uint8_t *volatile rxData; /*!< Receive buffer. */ volatile size_t txRemainingByteCount; /*!< Number of bytes remaining to send.*/ volatile size_t rxRemainingByteCount; /*!< Number of bytes remaining to receive.*/ volatile uint32_t writeRegRemainingTimes; /*!< Write TDR register remaining times. */ volatile uint32_t readRegRemainingTimes; /*!< Read RDR register remaining times. */ uint32_t totalByteCount; /*!< Number of transfer bytes*/ volatile uint8_t state; /*!< LPSPI transfer state , _lpspi_transfer_state.*/ volatile uint32_t errorCount; /*!< Error count for slave transfer.*/ lpspi_slave_transfer_callback_t callback; /*!< Completion callback. */ void *userData; /*!< Callback user data. */ }; /********************************************************************************************************************** * API *********************************************************************************************************************/ #if defined(__cplusplus) extern "C" { #endif /*_cplusplus*/ /*! * @name Initialization and deinitialization * @{ */ /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @brief Enables the LPSPI peripheral and sets the MCR MDIS to 0. * * @param base LPSPI peripheral address. * @param enable Pass true to enable module, false to disable module. */ static inline void LPSPI_Enable(LPSPI_Type *base, bool enable) { if (enable) { base->CR |= LPSPI_CR_MEN_MASK; } else { base->CR &= ~LPSPI_CR_MEN_MASK; } } /*! *@} */ /*! * @name Status * @{ */ /*! * @brief Gets the LPSPI status flag state. * @param base LPSPI peripheral address. * @return The LPSPI status(in SR register). */ static inline uint32_t LPSPI_GetStatusFlags(LPSPI_Type *base) { return (base->SR); } /*! * @brief Gets the LPSPI Tx FIFO size. * @param base LPSPI peripheral address. * @return The LPSPI Tx FIFO size. */ static inline uint8_t LPSPI_GetTxFifoSize(LPSPI_Type *base) { return (1U << ((base->PARAM & LPSPI_PARAM_TXFIFO_MASK) >> LPSPI_PARAM_TXFIFO_SHIFT)); } /*! * @brief Gets the LPSPI Rx FIFO size. * @param base LPSPI peripheral address. * @return The LPSPI Rx FIFO size. */ static inline uint8_t LPSPI_GetRxFifoSize(LPSPI_Type *base) { return (1U << ((base->PARAM & LPSPI_PARAM_RXFIFO_MASK) >> LPSPI_PARAM_RXFIFO_SHIFT)); } /*! * @brief Gets the LPSPI Tx FIFO count. * @param base LPSPI peripheral address. * @return The number of words in the transmit FIFO. */ static inline uint32_t LPSPI_GetTxFifoCount(LPSPI_Type *base) { return ((base->FSR & LPSPI_FSR_TXCOUNT_MASK) >> LPSPI_FSR_TXCOUNT_SHIFT); } /*! * @brief Gets the LPSPI Rx FIFO count. * @param base LPSPI peripheral address. * @return The number of words in the receive FIFO. */ static inline uint32_t LPSPI_GetRxFifoCount(LPSPI_Type *base) { return ((base->FSR & LPSPI_FSR_RXCOUNT_MASK) >> LPSPI_FSR_RXCOUNT_SHIFT); } /*! * @brief Clears the LPSPI status flag. * * This function clears the desired status bit by using a write-1-to-clear. The user passes in the base and the * desired status flag bit to clear. The list of status flags is defined in the _lpspi_flags. * Example usage: * @code * LPSPI_ClearStatusFlags(base, kLPSPI_TxDataRequestFlag|kLPSPI_RxDataReadyFlag); * @endcode * * @param base LPSPI peripheral address. * @param statusFlags The status flag used from type _lpspi_flags. */ static inline void LPSPI_ClearStatusFlags(LPSPI_Type *base, uint32_t statusFlags) { base->SR = statusFlags; /*!< The status flags are cleared by writing 1 (w1c).*/ } /*! *@} */ /*! * @name Interrupts * @{ */ /*! * @brief Enables the LPSPI interrupts. * * This function configures the various interrupt masks of the LPSPI. The parameters are base and an interrupt mask. * Note that, for Tx fill and Rx FIFO drain requests, enabling the interrupt request disables the DMA request. * * @code * LPSPI_EnableInterrupts(base, kLPSPI_TxInterruptEnable | kLPSPI_RxInterruptEnable ); * @endcode * * @param base LPSPI peripheral address. * @param mask The interrupt mask; Use the enum _lpspi_interrupt_enable. */ static inline void LPSPI_EnableInterrupts(LPSPI_Type *base, uint32_t mask) { base->IER |= mask; } /*! * @brief Disables the LPSPI interrupts. * * @code * LPSPI_DisableInterrupts(base, kLPSPI_TxInterruptEnable | kLPSPI_RxInterruptEnable ); * @endcode * * @param base LPSPI peripheral address. * @param mask The interrupt mask; Use the enum _lpspi_interrupt_enable. */ static inline void LPSPI_DisableInterrupts(LPSPI_Type *base, uint32_t mask) { base->IER &= ~mask; } /*! *@} */ /*! * @name DMA Control * @{ */ /*! * @brief Enables the LPSPI DMA request. * * This function configures the Rx and Tx DMA mask of the LPSPI. The parameters are base and a DMA mask. * @code * LPSPI_EnableDMA(base, kLPSPI_TxDmaEnable | kLPSPI_RxDmaEnable); * @endcode * * @param base LPSPI peripheral address. * @param mask The interrupt mask; Use the enum _lpspi_dma_enable. */ static inline void LPSPI_EnableDMA(LPSPI_Type *base, uint32_t mask) { base->DER |= mask; } /*! * @brief Disables the LPSPI DMA request. * * This function configures the Rx and Tx DMA mask of the LPSPI. The parameters are base and a DMA mask. * @code * SPI_DisableDMA(base, kLPSPI_TxDmaEnable | kLPSPI_RxDmaEnable); * @endcode * * @param base LPSPI peripheral address. * @param mask The interrupt mask; Use the enum _lpspi_dma_enable. */ static inline void LPSPI_DisableDMA(LPSPI_Type *base, uint32_t mask) { base->DER &= ~mask; } /*! * @brief Gets the LPSPI Transmit Data Register address for a DMA operation. * * This function gets the LPSPI Transmit Data Register address because this value is needed * for the DMA operation. * This function can be used for either master or slave mode. * * @param base LPSPI peripheral address. * @return The LPSPI Transmit Data Register address. */ static inline uint32_t LPSPI_GetTxRegisterAddress(LPSPI_Type *base) { return (uint32_t) & (base->TDR); } /*! * @brief Gets the LPSPI Receive Data Register address for a DMA operation. * * This function gets the LPSPI Receive Data Register address because this value is needed * for the DMA operation. * This function can be used for either master or slave mode. * * @param base LPSPI peripheral address. * @return The LPSPI Receive Data Register address. */ static inline uint32_t LPSPI_GetRxRegisterAddress(LPSPI_Type *base) { return (uint32_t) & (base->RDR); } /*! *@} */ /*! * @name Bus Operations * @{ */ /*! * @brief Check the argument for transfer . * * @param base LPSPI peripheral address. * @param transfer the transfer struct to be used. * @param isEdma True to check for EDMA transfer, false to check interrupt non-blocking transfer * @return Return true for right and false for wrong. */ bool LPSPI_CheckTransferArgument(LPSPI_Type *base, lpspi_transfer_t *transfer, bool isEdma); /*! * @brief Configures the LPSPI for either master or slave. * * Note that the CFGR1 should only be written when the LPSPI is disabled (LPSPIx_CR_MEN = 0). * * @param base LPSPI peripheral address. * @param mode Mode setting (master or slave) of type lpspi_master_slave_mode_t. */ static inline void LPSPI_SetMasterSlaveMode(LPSPI_Type *base, lpspi_master_slave_mode_t mode) { base->CFGR1 = (base->CFGR1 & (~LPSPI_CFGR1_MASTER_MASK)) | LPSPI_CFGR1_MASTER(mode); } /*! * @brief Configures the peripheral chip select used for the transfer. * * @param base LPSPI peripheral address. * @param select LPSPI Peripheral Chip Select (PCS) configuration. */ static inline void LPSPI_SelectTransferPCS(LPSPI_Type *base, lpspi_which_pcs_t select) { base->TCR = (base->TCR & (~LPSPI_TCR_PCS_MASK)) | LPSPI_TCR_PCS((uint8_t)select); } /*! * @brief Set the PCS signal to continuous or uncontinuous mode. * * @note In master mode, continuous transfer will keep the PCS asserted at the end of the frame size, until a command * word is received that starts a new frame. So PCS must be set back to uncontinuous when transfer finishes. * In slave mode, when continuous transfer is enabled, the LPSPI will only transmit the first frame size bits, after * that the LPSPI will transmit received data back (assuming a 32-bit shift register). * * @param base LPSPI peripheral address. * @param IsContinous True to set the transfer PCS to continuous mode, false to set to uncontinuous mode. */ static inline void LPSPI_SetPCSContinous(LPSPI_Type *base, bool IsContinous) { if (IsContinous) { base->TCR |= LPSPI_TCR_CONT_MASK; } else { base->TCR &= ~LPSPI_TCR_CONT_MASK; } } /*! * @brief Returns whether the LPSPI module is in master mode. * * @param base LPSPI peripheral address. * @return Returns true if the module is in master mode or false if the module is in slave mode. */ static inline bool LPSPI_IsMaster(LPSPI_Type *base) { return (bool)((base->CFGR1) & LPSPI_CFGR1_MASTER_MASK); } /*! * @brief Flushes the LPSPI FIFOs. * * @param base LPSPI peripheral address. * @param flushTxFifo Flushes (true) the Tx FIFO, else do not flush (false) the Tx FIFO. * @param flushRxFifo Flushes (true) the Rx FIFO, else do not flush (false) the Rx FIFO. */ static inline void LPSPI_FlushFifo(LPSPI_Type *base, bool flushTxFifo, bool flushRxFifo) { base->CR |= ((uint32_t)flushTxFifo << LPSPI_CR_RTF_SHIFT) | ((uint32_t)flushRxFifo << LPSPI_CR_RRF_SHIFT); } /*! * @brief Sets the transmit and receive FIFO watermark values. * * This function allows the user to set the receive and transmit FIFO watermarks. The function * does not compare the watermark settings to the FIFO size. The FIFO watermark should not be * equal to or greater than the FIFO size. It is up to the higher level driver to make this check. * * @param base LPSPI peripheral address. * @param txWater The TX FIFO watermark value. Writing a value equal or greater than the FIFO size is truncated. * @param rxWater The RX FIFO watermark value. Writing a value equal or greater than the FIFO size is truncated. */ static inline void LPSPI_SetFifoWatermarks(LPSPI_Type *base, uint32_t txWater, uint32_t rxWater) { base->FCR = LPSPI_FCR_TXWATER(txWater) | LPSPI_FCR_RXWATER(rxWater); } /*! * @brief Configures all LPSPI peripheral chip select polarities simultaneously. * * Note that the CFGR1 should only be written when the LPSPI is disabled (LPSPIx_CR_MEN = 0). * * This is an example: PCS0 and PCS1 set to active low and other PCSs set to active high. Note that the number of * PCS is device-specific. * @code * LPSPI_SetAllPcsPolarity(base, kLPSPI_Pcs0ActiveLow | kLPSPI_Pcs1ActiveLow); * @endcode * * @param base LPSPI peripheral address. * @param mask The PCS polarity mask; Use the enum _lpspi_pcs_polarity. */ static inline void LPSPI_SetAllPcsPolarity(LPSPI_Type *base, uint32_t mask) { base->CFGR1 = (base->CFGR1 & ~LPSPI_CFGR1_PCSPOL_MASK) | LPSPI_CFGR1_PCSPOL(~mask); } /*! * @brief Configures the frame size. * * The minimum frame size is 8-bits and the maximum frame size is 4096-bits. If the frame size is less than or equal * to 32-bits, the word size and frame size are identical. If the frame size is greater than 32-bits, the word * size is 32-bits for each word except the last (the last word contains the remainder bits if the frame size is not * divisible by 32). The minimum word size is 2-bits. A frame size of 33-bits (or similar) is not supported. * * Note 1: The transmit command register should be initialized before enabling the LPSPI in slave mode, although * the command register does not update until after the LPSPI is enabled. After it is enabled, the transmit command * register * should only be changed if the LPSPI is idle. * * Note 2: The transmit and command FIFO is a combined FIFO that includes both transmit data and command words. That * means the TCR register should be written to when the Tx FIFO is not full. * * @param base LPSPI peripheral address. * @param frameSize The frame size in number of bits. */ static inline void LPSPI_SetFrameSize(LPSPI_Type *base, uint32_t frameSize) { base->TCR = (base->TCR & ~LPSPI_TCR_FRAMESZ_MASK) | LPSPI_TCR_FRAMESZ(frameSize - 1U); } /*! * @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); /*! * @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); /*! * @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); /*! * @brief Writes data into the transmit data buffer. * * This function writes data passed in by the user to the Transmit Data Register (TDR). * The user can pass up to 32-bits of data to load into the TDR. If the frame size exceeds 32-bits, * the user has to manage sending the data one 32-bit word at a time. * Any writes to the TDR result in an immediate push to the transmit FIFO. * This function can be used for either master or slave modes. * * @param base LPSPI peripheral address. * @param data The data word to be sent. */ static inline void LPSPI_WriteData(LPSPI_Type *base, uint32_t data) { base->TDR = data; } /*! * @brief Reads data from the data buffer. * * This function reads the data from the Receive Data Register (RDR). * This function can be used for either master or slave mode. * * @param base LPSPI peripheral address. * @return The data read from the data buffer. */ static inline uint32_t LPSPI_ReadData(LPSPI_Type *base) { return (base->RDR); } /*! * @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); /*! *@} */ /*! * @name Transactional * @{ */ /*Transactional APIs*/ /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! * @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); /*! *@} */ #if defined(__cplusplus) } #endif /*! @}*/ #endif /*_FSL_LPSPI_H_*/