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coral / mcuxpresso_sdk / 20602c8dd7e6c22a33e76e7325f487e6858506c3 / . / devices / MIMX8MQ6 / drivers / fsl_ecspi.h
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/*
* Copyright (c) 2016, Freescale Semiconductor, Inc.
* Copyright 2016-2020 NXP
* All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#ifndef _FSL_ECSPI_H_
#define _FSL_ECSPI_H_
#include "fsl_common.h"
/*!
* @addtogroup ecspi_driver
* @{
*/
/*******************************************************************************
* Definitions
******************************************************************************/
/*! @name Driver version */
/*@{*/
/*! @brief ECSPI driver version 2.1.0. */
#define FSL_ECSPI_DRIVER_VERSION (MAKE_VERSION(2, 1, 0))
/*@}*/
#ifndef ECSPI_DUMMYDATA
/*! @brief ECSPI dummy transfer data, the data is sent while txBuff is NULL. */
#define ECSPI_DUMMYDATA (0xFFFFFFFFU)
#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 Return status for the ECSPI driver. */
enum
{
kStatus_ECSPI_Busy = MAKE_STATUS(kStatusGroup_ECSPI, 0), /*!< ECSPI bus is busy */
kStatus_ECSPI_Idle = MAKE_STATUS(kStatusGroup_ECSPI, 1), /*!< ECSPI is idle */
kStatus_ECSPI_Error = MAKE_STATUS(kStatusGroup_ECSPI, 2), /*!< ECSPI error */
kStatus_ECSPI_HardwareOverFlow = MAKE_STATUS(kStatusGroup_ECSPI, 3), /*!< ECSPI hardware overflow */
kStatus_ECSPI_Timeout = MAKE_STATUS(kStatusGroup_ECSPI, 4), /*!< ECSPI timeout polling status flags. */
};
/*! @brief ECSPI clock polarity configuration. */
typedef enum _ecspi_clock_polarity
{
kECSPI_PolarityActiveHigh = 0x0U, /*!< Active-high ECSPI polarity high (idles low). */
kECSPI_PolarityActiveLow, /*!< Active-low ECSPI polarity low (idles high). */
} ecspi_clock_polarity_t;
/*! @brief ECSPI clock phase configuration. */
typedef enum _ecspi_clock_phase
{
kECSPI_ClockPhaseFirstEdge =
0x0U, /*!< First edge on SPSCK occurs at the middle of the first cycle of a data transfer. */
kECSPI_ClockPhaseSecondEdge, /*!< First edge on SPSCK occurs at the start of the first cycle of a data transfer. */
} ecspi_clock_phase_t;
/*! @brief ECSPI interrupt sources. */
enum
{
kECSPI_TxfifoEmptyInterruptEnable = ECSPI_INTREG_TEEN_MASK, /*!< Transmit FIFO buffer empty interrupt */
kECSPI_TxFifoDataRequstInterruptEnable = ECSPI_INTREG_TDREN_MASK, /*!< Transmit FIFO data requst interrupt */
kECSPI_TxFifoFullInterruptEnable = ECSPI_INTREG_TFEN_MASK, /*!< Transmit FIFO full interrupt */
kECSPI_RxFifoReadyInterruptEnable = ECSPI_INTREG_RREN_MASK, /*!< Receiver FIFO ready interrupt */
kECSPI_RxFifoDataRequstInterruptEnable = ECSPI_INTREG_RDREN_MASK, /*!< Receiver FIFO data requst interrupt */
kECSPI_RxFifoFullInterruptEnable = ECSPI_INTREG_RFEN_MASK, /*!< Receiver FIFO full interrupt */
kECSPI_RxFifoOverFlowInterruptEnable = ECSPI_INTREG_ROEN_MASK, /*!< Receiver FIFO buffer overflow interrupt */
kECSPI_TransferCompleteInterruptEnable = ECSPI_INTREG_TCEN_MASK, /*!< Transfer complete interrupt */
kECSPI_AllInterruptEnable = (ECSPI_INTREG_TEEN_MASK | ECSPI_INTREG_TDREN_MASK | ECSPI_INTREG_TFEN_MASK |
ECSPI_INTREG_RREN_MASK | ECSPI_INTREG_RDREN_MASK | ECSPI_INTREG_RFEN_MASK |
ECSPI_INTREG_ROEN_MASK | ECSPI_INTREG_TCEN_MASK), /*!< All interrupt */
};
/*! @brief ECSPI status flags. */
enum
{
kECSPI_TxfifoEmptyFlag = ECSPI_STATREG_TE_MASK, /*!< Transmit FIFO buffer empty flag */
kECSPI_TxFifoDataRequstFlag = ECSPI_STATREG_TDR_MASK, /*!< Transmit FIFO data requst flag */
kECSPI_TxFifoFullFlag = ECSPI_STATREG_TF_MASK, /*!< Transmit FIFO full flag */
kECSPI_RxFifoReadyFlag = ECSPI_STATREG_RR_MASK, /*!< Receiver FIFO ready flag */
kECSPI_RxFifoDataRequstFlag = ECSPI_STATREG_RDR_MASK, /*!< Receiver FIFO data requst flag */
kECSPI_RxFifoFullFlag = ECSPI_STATREG_RF_MASK, /*!< Receiver FIFO full flag */
kECSPI_RxFifoOverFlowFlag = ECSPI_STATREG_RO_MASK, /*!< Receiver FIFO buffer overflow flag */
kECSPI_TransferCompleteFlag = ECSPI_STATREG_TC_MASK, /*!< Transfer complete flag */
};
/*! @brief ECSPI DMA enable.*/
enum
{
kECSPI_TxDmaEnable = ECSPI_DMAREG_TEDEN_MASK, /*!< Tx DMA request source */
kECSPI_RxDmaEnable = ECSPI_DMAREG_RXDEN_MASK, /*!< Rx DMA request source */
kECSPI_DmaAllEnable = (ECSPI_DMAREG_TEDEN_MASK | ECSPI_DMAREG_RXDEN_MASK) /*!< All DMA request source*/
};
/*! @brief ECSPI SPI_RDY signal configuration. */
typedef enum _ecspi_data_ready
{
kECSPI_DataReadyIgnore = 0x0U, /*!< SPI_RDY signal is ignored */
kECSPI_DataReadyFallingEdge, /*!< SPI_RDY signal will be triggerd by the falling edge */
kECSPI_DataReadyLowLevel, /*!< SPI_RDY signal will be triggerd by a low level */
} ecspi_Data_ready_t;
/*! @brief ECSPI channel select source. */
typedef enum _ecspi_channel_source
{
kECSPI_Channel0 = 0x0U, /*!< Channel 0 is selectd */
kECSPI_Channel1, /*!< Channel 1 is selectd */
kECSPI_Channel2, /*!< Channel 2 is selectd */
kECSPI_Channel3, /*!< Channel 3 is selectd */
} ecspi_channel_source_t;
/*! @brief ECSPI master or slave mode configuration. */
typedef enum _ecspi_master_slave_mode
{
kECSPI_Slave = 0U, /*!< ECSPI peripheral operates in slave mode.*/
kECSPI_Master, /*!< ECSPI peripheral operates in master mode.*/
} ecspi_master_slave_mode_t;
/*! @brief ECSPI data line inactive state configuration. */
typedef enum _ecspi_data_line_inactive_state_t
{
kECSPI_DataLineInactiveStateHigh = 0x0U, /*!< The data line inactive state stays high. */
kECSPI_DataLineInactiveStateLow, /*!< The data line inactive state stays low. */
} ecspi_data_line_inactive_state_t;
/*! @brief ECSPI clock inactive state configuration. */
typedef enum _ecspi_clock_inactive_state_t
{
kECSPI_ClockInactiveStateLow = 0x0U, /*!< The SCLK inactive state stays low. */
kECSPI_ClockInactiveStateHigh, /*!< The SCLK inactive state stays high. */
} ecspi_clock_inactive_state_t;
/*! @brief ECSPI active state configuration.*/
typedef enum _ecspi_chip_select_active_state_t
{
kECSPI_ChipSelectActiveStateLow = 0x0U, /*!< The SS signal line active stays low. */
kECSPI_ChipSelectActiveStateHigh, /*!< The SS signal line active stays high. */
} ecspi_chip_select_active_state_t;
/*! @brief ECSPI wave form configuration.*/
typedef enum _ecspi_wave_form_t
{
kECSPI_WaveFormSingle = 0x0U, /*!< The wave form for signal burst */
kECSPI_WaveFormMultiple, /*!< The wave form for multiple burst */
} ecspi_wave_form_t;
/*! @brief ECSPI sample period clock configuration.*/
typedef enum _ecspi_sample_period_clock_source
{
kECSPI_spiClock = 0x0U, /*!< The sample period clock source is SCLK. */
kECSPI_lowFreqClock, /*!< The sample seriod clock source is low_frequency reference clock(32.768 kHz). */
} ecspi_sample_period_clock_source_t;
/*! @brief ECSPI user channel configure structure.*/
typedef struct _ecspi_channel_config
{
ecspi_master_slave_mode_t channelMode; /*!< Channel mode */
ecspi_clock_inactive_state_t clockInactiveState; /*!< Clock line (SCLK) inactive state */
ecspi_data_line_inactive_state_t dataLineInactiveState; /*!< Data line (MOSI&MISO) inactive state */
ecspi_chip_select_active_state_t chipSlectActiveState; /*!< Chip select(SS) line active state */
ecspi_wave_form_t waveForm; /*!< Wave form */
ecspi_clock_polarity_t polarity; /*!< Clock polarity */
ecspi_clock_phase_t phase; /*!< Clock phase */
} ecspi_channel_config_t;
/*! @brief ECSPI master configure structure.*/
typedef struct _ecspi_master_config
{
ecspi_channel_source_t channel; /*!< Channel number */
ecspi_channel_config_t channelConfig; /*!< Channel configuration */
ecspi_sample_period_clock_source_t samplePeriodClock; /*!< Sample period clock source */
uint8_t burstLength; /*!< Burst length */
uint8_t chipSelectDelay; /*!< SS delay time */
uint16_t samplePeriod; /*!< Sample period */
uint8_t txFifoThreshold; /*!< TX Threshold */
uint8_t rxFifoThreshold; /*!< RX Threshold */
uint32_t baudRate_Bps; /*!< ECSPI baud rate for master mode */
bool enableLoopback; /*!< Enable the ECSPI loopback test. */
} ecspi_master_config_t;
/*! @brief ECSPI slave configure structure.*/
typedef struct _ecspi_slave_config
{
ecspi_channel_source_t channel; /*Channel number */
uint8_t burstLength; /*!< Burst length */
uint8_t txFifoThreshold; /*!< TX Threshold */
uint8_t rxFifoThreshold; /*!< RX Threshold */
ecspi_channel_config_t channelConfig; /*!< Channel configuration */
} ecspi_slave_config_t;
/*! @brief ECSPI transfer structure */
typedef struct _ecspi_transfer
{
uint32_t *txData; /*!< Send buffer */
uint32_t *rxData; /*!< Receive buffer */
size_t dataSize; /*!< Transfer bytes */
ecspi_channel_source_t channel; /*!< ECSPI channel select */
} ecspi_transfer_t;
typedef struct _ecspi_master_handle ecspi_master_handle_t;
/*! @brief Slave handle is the same with master handle */
typedef ecspi_master_handle_t ecspi_slave_handle_t;
/*! @brief ECSPI master callback for finished transmit */
typedef void (*ecspi_master_callback_t)(ECSPI_Type *base,
ecspi_master_handle_t *handle,
status_t status,
void *userData);
/*! @brief ECSPI slave callback for finished transmit */
typedef void (*ecspi_slave_callback_t)(ECSPI_Type *base, ecspi_slave_handle_t *handle, status_t status, void *userData);
/*! @brief ECSPI master handle structure */
struct _ecspi_master_handle
{
ecspi_channel_source_t channel; /*!< Channel number */
uint32_t *volatile txData; /*!< Transfer buffer */
uint32_t *volatile rxData; /*!< Receive buffer */
volatile size_t txRemainingBytes; /*!< Send data remaining in bytes */
volatile size_t rxRemainingBytes; /*!< Receive data remaining in bytes */
volatile uint32_t state; /*!< ECSPI internal state */
size_t transferSize; /*!< Bytes to be transferred */
ecspi_master_callback_t callback; /*!< ECSPI callback */
void *userData; /*!< Callback parameter */
};
#if defined(__cplusplus)
extern "C" {
#endif
/*******************************************************************************
* APIs
******************************************************************************/
/*!
* @brief Get the instance for ECSPI module.
*
* @param base ECSPI base address
*/
uint32_t ECSPI_GetInstance(ECSPI_Type *base);
/*!
* @name Initialization and deinitialization
* @{
*/
/*!
* @brief Sets the ECSPI configuration structure to default values.
*
* The purpose of this API is to get the configuration structure initialized for use in ECSPI_MasterInit().
* User may use the initialized structure unchanged in ECSPI_MasterInit, or modify
* some fields of the structure before calling ECSPI_MasterInit. After calling this API,
* the master is ready to transfer.
* Example:
@code
ecspi_master_config_t config;
ECSPI_MasterGetDefaultConfig(&config);
@endcode
*
* @param config pointer to config structure
*/
void ECSPI_MasterGetDefaultConfig(ecspi_master_config_t *config);
/*!
* @brief Initializes the ECSPI with configuration.
*
* The configuration structure can be filled by user from scratch, or be set with default
* values by ECSPI_MasterGetDefaultConfig(). After calling this API, the slave is ready to transfer.
* Example
@code
ecspi_master_config_t config = {
.baudRate_Bps = 400000,
...
};
ECSPI_MasterInit(ECSPI0, &config);
@endcode
*
* @param base ECSPI base pointer
* @param config pointer to master configuration structure
* @param srcClock_Hz Source clock frequency.
*/
void ECSPI_MasterInit(ECSPI_Type *base, const ecspi_master_config_t *config, uint32_t srcClock_Hz);
/*!
* @brief Sets the ECSPI configuration structure to default values.
*
* The purpose of this API is to get the configuration structure initialized for use in ECSPI_SlaveInit().
* User may use the initialized structure unchanged in ECSPI_SlaveInit(), or modify
* some fields of the structure before calling ECSPI_SlaveInit(). After calling this API,
* the master is ready to transfer.
* Example:
@code
ecspi_Slaveconfig_t config;
ECSPI_SlaveGetDefaultConfig(&config);
@endcode
*
* @param config pointer to config structure
*/
void ECSPI_SlaveGetDefaultConfig(ecspi_slave_config_t *config);
/*!
* @brief Initializes the ECSPI with configuration.
*
* The configuration structure can be filled by user from scratch, or be set with default
* values by ECSPI_SlaveGetDefaultConfig(). After calling this API, the slave is ready to transfer.
* Example
@code
ecspi_Salveconfig_t config = {
.baudRate_Bps = 400000,
...
};
ECSPI_SlaveInit(ECSPI1, &config);
@endcode
*
* @param base ECSPI base pointer
* @param config pointer to master configuration structure
*/
void ECSPI_SlaveInit(ECSPI_Type *base, const ecspi_slave_config_t *config);
/*!
* @brief De-initializes the ECSPI.
*
* Calling this API resets the ECSPI module, gates the ECSPI clock.
* The ECSPI module can't work unless calling the ECSPI_MasterInit/ECSPI_SlaveInit to initialize module.
*
* @param base ECSPI base pointer
*/
void ECSPI_Deinit(ECSPI_Type *base);
/*!
* @brief Enables or disables the ECSPI.
*
* @param base ECSPI base pointer
* @param enable pass true to enable module, false to disable module
*/
static inline void ECSPI_Enable(ECSPI_Type *base, bool enable)
{
if (enable)
{
base->CONREG |= ECSPI_CONREG_EN_MASK;
}
else
{
base->CONREG &= ~ECSPI_CONREG_EN_MASK;
}
}
/*! @} */
/*!
* @name Status
* @{
*/
/*!
* @brief Gets the status flag.
*
* @param base ECSPI base pointer
* @return ECSPI Status, use status flag to AND _ecspi_flags could get the related status.
*/
static inline uint32_t ECSPI_GetStatusFlags(ECSPI_Type *base)
{
return (base->STATREG);
}
/*!
* @brief Clear the status flag.
*
* @param base ECSPI base pointer
* @param mask ECSPI Status, use status flag to AND _ecspi_flags could get the related status.
*/
static inline void ECSPI_ClearStatusFlags(ECSPI_Type *base, uint32_t mask)
{
base->STATREG |= mask;
}
/*! @} */
/*!
* @name Interrupts
* @{
*/
/*!
* @brief Enables the interrupt for the ECSPI.
*
* @param base ECSPI base pointer
* @param mask ECSPI interrupt source. The parameter can be any combination of the following values:
* @arg kECSPI_TxfifoEmptyInterruptEnable
* @arg kECSPI_TxFifoDataRequstInterruptEnable
* @arg kECSPI_TxFifoFullInterruptEnable
* @arg kECSPI_RxFifoReadyInterruptEnable
* @arg kECSPI_RxFifoDataRequstInterruptEnable
* @arg kECSPI_RxFifoFullInterruptEnable
* @arg kECSPI_RxFifoOverFlowInterruptEnable
* @arg kECSPI_TransferCompleteInterruptEnable
* @arg kECSPI_AllInterruptEnable
*/
static inline void ECSPI_EnableInterrupts(ECSPI_Type *base, uint32_t mask)
{
base->INTREG |= mask;
}
/*!
* @brief Disables the interrupt for the ECSPI.
*
* @param base ECSPI base pointer
* @param mask ECSPI interrupt source. The parameter can be any combination of the following values:
* @arg kECSPI_TxfifoEmptyInterruptEnable
* @arg kECSPI_TxFifoDataRequstInterruptEnable
* @arg kECSPI_TxFifoFullInterruptEnable
* @arg kECSPI_RxFifoReadyInterruptEnable
* @arg kECSPI_RxFifoDataRequstInterruptEnable
* @arg kECSPI_RxFifoFullInterruptEnable
* @arg kECSPI_RxFifoOverFlowInterruptEnable
* @arg kECSPI_TransferCompleteInterruptEnable
* @arg kECSPI_AllInterruptEnable
*/
static inline void ECSPI_DisableInterrupts(ECSPI_Type *base, uint32_t mask)
{
base->INTREG &= ~(mask);
}
/*! @} */
/*!
* @name Software Reset
* @{
*/
/*!
* @brief Software reset.
*
* @param base ECSPI base pointer
*/
static inline void ECSPI_SoftwareReset(ECSPI_Type *base)
{
/* Disables the block and resets the internal logic with the exception of the ECSPI control register */
base->CONREG &= ~ECSPI_CONREG_EN_MASK;
/* Software reset can not reset the control register, so clear the control register manually */
base->CONREG = 0x0U;
}
/*! @} */
/*!
* @name Channel mode check
* @{
*/
/*!
* @brief Mode check
*
* @param base ECSPI base pointer
* @param channel ECSPI channel source
* @return mode of channel
*/
static inline bool ECSPI_IsMaster(ECSPI_Type *base, ecspi_channel_source_t channel)
{
return (bool)(((base->CONREG & ECSPI_CONREG_CHANNEL_MODE_MASK) >>
(ECSPI_CONREG_CHANNEL_MODE_SHIFT + (uint32_t)channel)) &
0x1U);
}
/*! @} */
/*!
* @name DMA Control
* @{
*/
/*!
* @brief Enables the DMA source for ECSPI.
*
* @param base ECSPI base pointer
* @param mask ECSPI DMA source. The parameter can be any of the following values:
* @arg kECSPI_TxDmaEnable
* @arg kECSPI_RxDmaEnable
* @arg kECSPI_DmaAllEnable
* @param enable True means enable DMA, false means disable DMA
*/
static inline void ECSPI_EnableDMA(ECSPI_Type *base, uint32_t mask, bool enable)
{
if (enable)
{
base->DMAREG |= mask;
}
else
{
base->DMAREG &= ~mask;
}
}
/*! @} */
/*!
* @name FIFO Operation
* @{
*/
/*!
* @brief Get the Tx FIFO data count.
*
* @param base ECSPI base pointer.
* @return the number of words in Tx FIFO buffer.
*/
static inline uint8_t ECSPI_GetTxFifoCount(ECSPI_Type *base)
{
return (uint8_t)((base->TESTREG & ECSPI_TESTREG_TXCNT_MASK) >> ECSPI_TESTREG_TXCNT_SHIFT);
}
/*!
* @brief Get the Rx FIFO data count.
*
* @param base ECSPI base pointer.
* @return the number of words in Rx FIFO buffer.
*/
static inline uint8_t ECSPI_GetRxFifoCount(ECSPI_Type *base)
{
return (uint8_t)((base->TESTREG & ECSPI_TESTREG_RXCNT_MASK) >> ECSPI_TESTREG_RXCNT_SHIFT);
}
/*! @} */
/*!
* @name Bus Operations
* @{
*/
/*!
* @brief Set channel select for transfer.
*
* @param base ECSPI base pointer
* @param channel Channel source.
*/
static inline void ECSPI_SetChannelSelect(ECSPI_Type *base, ecspi_channel_source_t channel)
{
/* Clear Channel select bits in CONREG register */
uint32_t temp = base->CONREG & (~(ECSPI_CONREG_CHANNEL_SELECT_MASK));
/* Set channel select bits */
base->CONREG = (temp | ECSPI_CONREG_CHANNEL_SELECT(channel));
}
/*!
* @brief Set channel select configuration for transfer.
*
* The purpose of this API is to set the channel will be use to transfer.
* User may use this API after instance has been initialized or before transfer start.
* The configuration structure _ecspi_channel_config_ can be filled by user from scratch.
* After calling this API, user can select this channel as transfer channel.
*
* @param base ECSPI base pointer
* @param channel Channel source.
* @param config Configuration struct of channel
*/
void ECSPI_SetChannelConfig(ECSPI_Type *base, ecspi_channel_source_t channel, const ecspi_channel_config_t *config);
/*!
* @brief Sets the baud rate for ECSPI transfer. This is only used in master.
*
* @param base ECSPI base pointer
* @param baudRate_Bps baud rate needed in Hz.
* @param srcClock_Hz ECSPI source clock frequency in Hz.
*/
void ECSPI_SetBaudRate(ECSPI_Type *base, uint32_t baudRate_Bps, uint32_t srcClock_Hz);
/*!
* @brief Sends a buffer of data bytes using a blocking method.
*
* @note This function blocks via polling until all bytes have been sent.
*
* @param base ECSPI base pointer
* @param buffer The data bytes to send
* @param size The number of data bytes to send
* @retval kStatus_Success Successfully start a transfer.
* @retval kStatus_ECSPI_Timeout The transfer timed out and was aborted.
*/
status_t ECSPI_WriteBlocking(ECSPI_Type *base, uint32_t *buffer, size_t size);
/*!
* @brief Writes a data into the ECSPI data register.
*
* @param base ECSPI base pointer
* @param data Data needs to be write.
*/
static inline void ECSPI_WriteData(ECSPI_Type *base, uint32_t data)
{
base->TXDATA = data;
}
/*!
* @brief Gets a data from the ECSPI data register.
*
* @param base ECSPI base pointer
* @return Data in the register.
*/
static inline uint32_t ECSPI_ReadData(ECSPI_Type *base)
{
return (uint32_t)(base->RXDATA);
}
/*! @} */
/*!
* @name Transactional
* @{
*/
/*!
* @brief Initializes the ECSPI master handle.
*
* This function initializes the ECSPI master handle which can be used for other ECSPI master transactional APIs.
* Usually,
* for a specified ECSPI instance, call this API once to get the initialized handle.
*
* @param base ECSPI peripheral base address.
* @param handle ECSPI handle pointer.
* @param callback Callback function.
* @param userData User data.
*/
void ECSPI_MasterTransferCreateHandle(ECSPI_Type *base,
ecspi_master_handle_t *handle,
ecspi_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_ECSPI_Timeout The transfer timed out and was aborted.
*/
status_t ECSPI_MasterTransferBlocking(ECSPI_Type *base, ecspi_transfer_t *xfer);
/*!
* @brief Performs a non-blocking ECSPI interrupt transfer.
*
* @note The API immediately returns after transfer initialization is finished.
* @note If ECSPI transfer data frame size is 16 bits, the transfer size cannot be an odd number.
*
* @param base ECSPI peripheral base address.
* @param handle pointer to ecspi_master_handle_t structure which stores the transfer state
* @param xfer pointer to ecspi_transfer_t structure
* @retval kStatus_Success Successfully start a transfer.
* @retval kStatus_InvalidArgument Input argument is invalid.
* @retval kStatus_ECSPI_Busy ECSPI is not idle, is running another transfer.
*/
status_t ECSPI_MasterTransferNonBlocking(ECSPI_Type *base, ecspi_master_handle_t *handle, ecspi_transfer_t *xfer);
/*!
* @brief Gets the bytes of the ECSPI interrupt transferred.
*
* @param base ECSPI peripheral base address.
* @param handle Pointer to ECSPI transfer handle, this should be a static variable.
* @param count Transferred bytes of ECSPI master.
* @retval kStatus_ECSPI_Success Succeed get the transfer count.
* @retval kStatus_NoTransferInProgress There is not a non-blocking transaction currently in progress.
*/
status_t ECSPI_MasterTransferGetCount(ECSPI_Type *base, ecspi_master_handle_t *handle, size_t *count);
/*!
* @brief Aborts an ECSPI transfer using interrupt.
*
* @param base ECSPI peripheral base address.
* @param handle Pointer to ECSPI transfer handle, this should be a static variable.
*/
void ECSPI_MasterTransferAbort(ECSPI_Type *base, ecspi_master_handle_t *handle);
/*!
* @brief Interrupts the handler for the ECSPI.
*
* @param base ECSPI peripheral base address.
* @param handle pointer to ecspi_master_handle_t structure which stores the transfer state.
*/
void ECSPI_MasterTransferHandleIRQ(ECSPI_Type *base, ecspi_master_handle_t *handle);
/*!
* @brief Initializes the ECSPI slave handle.
*
* This function initializes the ECSPI slave handle which can be used for other ECSPI slave transactional APIs. Usually,
* for a specified ECSPI instance, call this API once to get the initialized handle.
*
* @param base ECSPI peripheral base address.
* @param handle ECSPI handle pointer.
* @param callback Callback function.
* @param userData User data.
*/
void ECSPI_SlaveTransferCreateHandle(ECSPI_Type *base,
ecspi_slave_handle_t *handle,
ecspi_slave_callback_t callback,
void *userData);
/*!
* @brief Performs a non-blocking ECSPI slave interrupt transfer.
*
* @note The API returns immediately after the transfer initialization is finished.
*
* @param base ECSPI peripheral base address.
* @param handle pointer to ecspi_master_handle_t structure which stores the transfer state
* @param xfer pointer to ecspi_transfer_t structure
* @retval kStatus_Success Successfully start a transfer.
* @retval kStatus_InvalidArgument Input argument is invalid.
* @retval kStatus_ECSPI_Busy ECSPI is not idle, is running another transfer.
*/
static inline status_t ECSPI_SlaveTransferNonBlocking(ECSPI_Type *base,
ecspi_slave_handle_t *handle,
ecspi_transfer_t *xfer)
{
return ECSPI_MasterTransferNonBlocking(base, handle, xfer);
}
/*!
* @brief Gets the bytes of the ECSPI interrupt transferred.
*
* @param base ECSPI peripheral base address.
* @param handle Pointer to ECSPI transfer handle, this should be a static variable.
* @param count Transferred bytes of ECSPI slave.
* @retval kStatus_ECSPI_Success Succeed get the transfer count.
* @retval kStatus_NoTransferInProgress There is not a non-blocking transaction currently in progress.
*/
static inline status_t ECSPI_SlaveTransferGetCount(ECSPI_Type *base, ecspi_slave_handle_t *handle, size_t *count)
{
return ECSPI_MasterTransferGetCount(base, handle, count);
}
/*!
* @brief Aborts an ECSPI slave transfer using interrupt.
*
* @param base ECSPI peripheral base address.
* @param handle Pointer to ECSPI transfer handle, this should be a static variable.
*/
static inline void ECSPI_SlaveTransferAbort(ECSPI_Type *base, ecspi_slave_handle_t *handle)
{
ECSPI_MasterTransferAbort(base, handle);
}
/*!
* @brief Interrupts a handler for the ECSPI slave.
*
* @param base ECSPI peripheral base address.
* @param handle pointer to ecspi_slave_handle_t structure which stores the transfer state
*/
void ECSPI_SlaveTransferHandleIRQ(ECSPI_Type *base, ecspi_slave_handle_t *handle);
/*! @} */
#if defined(__cplusplus)
}
#endif
/*! @} */
#endif /* _FSL_ECSPI_H_*/