rt-thread-official/bsp/imxrt/libraries/MIMXRT1020/MIMXRT1021/drivers/fsl_spdif.h

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/*
* Copyright (c) 2016, Freescale Semiconductor, Inc.
* Copyright 2017-2020 NXP
* All rights reserved.
*
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#ifndef _FSL_SPDIF_H_
#define _FSL_SPDIF_H_
#include "fsl_common.h"
/*!
* @addtogroup spdif
* @{
*/
/*******************************************************************************
* Definitions
******************************************************************************/
/*! @name Driver version */
/*@{*/
#define FSL_SPDIF_DRIVER_VERSION (MAKE_VERSION(2, 0, 6)) /*!< Version 2.0.6 */
/*@}*/
/*! @brief SPDIF return status*/
enum
{
kStatus_SPDIF_RxDPLLLocked = MAKE_STATUS(kStatusGroup_SPDIF, 0), /*!< SPDIF Rx PLL locked. */
kStatus_SPDIF_TxFIFOError = MAKE_STATUS(kStatusGroup_SPDIF, 1), /*!< SPDIF Tx FIFO error. */
kStatus_SPDIF_TxFIFOResync = MAKE_STATUS(kStatusGroup_SPDIF, 2), /*!< SPDIF Tx left and right FIFO resync. */
kStatus_SPDIF_RxCnew = MAKE_STATUS(kStatusGroup_SPDIF, 3), /*!< SPDIF Rx status channel value updated. */
kStatus_SPDIF_ValidatyNoGood = MAKE_STATUS(kStatusGroup_SPDIF, 4), /*!< SPDIF validaty flag not good. */
kStatus_SPDIF_RxIllegalSymbol = MAKE_STATUS(kStatusGroup_SPDIF, 5), /*!< SPDIF Rx receive illegal symbol. */
kStatus_SPDIF_RxParityBitError = MAKE_STATUS(kStatusGroup_SPDIF, 6), /*!< SPDIF Rx parity bit error. */
kStatus_SPDIF_UChannelOverrun = MAKE_STATUS(kStatusGroup_SPDIF, 7), /*!< SPDIF receive U channel overrun. */
kStatus_SPDIF_QChannelOverrun = MAKE_STATUS(kStatusGroup_SPDIF, 8), /*!< SPDIF receive Q channel overrun. */
kStatus_SPDIF_UQChannelSync = MAKE_STATUS(kStatusGroup_SPDIF, 9), /*!< SPDIF U/Q channel sync found. */
kStatus_SPDIF_UQChannelFrameError = MAKE_STATUS(kStatusGroup_SPDIF, 10), /*!< SPDIF U/Q channel frame error. */
kStatus_SPDIF_RxFIFOError = MAKE_STATUS(kStatusGroup_SPDIF, 11), /*!< SPDIF Rx FIFO error. */
kStatus_SPDIF_RxFIFOResync = MAKE_STATUS(kStatusGroup_SPDIF, 12), /*!< SPDIF Rx left and right FIFO resync. */
kStatus_SPDIF_LockLoss = MAKE_STATUS(kStatusGroup_SPDIF, 13), /*!< SPDIF Rx PLL clock lock loss. */
kStatus_SPDIF_TxIdle = MAKE_STATUS(kStatusGroup_SPDIF, 14), /*!< SPDIF Tx is idle */
kStatus_SPDIF_RxIdle = MAKE_STATUS(kStatusGroup_SPDIF, 15), /*!< SPDIF Rx is idle */
kStatus_SPDIF_QueueFull = MAKE_STATUS(kStatusGroup_SPDIF, 16) /*!< SPDIF queue full */
};
/*! @brief SPDIF Rx FIFO full falg select, it decides when assert the rx full flag */
typedef enum _spdif_rxfull_select
{
kSPDIF_RxFull1Sample = 0x0u, /*!< Rx full at least 1 sample in left and right FIFO */
kSPDIF_RxFull4Samples, /*!< Rx full at least 4 sample in left and right FIFO*/
kSPDIF_RxFull8Samples, /*!< Rx full at least 8 sample in left and right FIFO*/
kSPDIF_RxFull16Samples, /*!< Rx full at least 16 sample in left and right FIFO*/
} spdif_rxfull_select_t;
/*! @brief SPDIF tx FIFO EMPTY falg select, it decides when assert the tx empty flag */
typedef enum _spdif_txempty_select
{
kSPDIF_TxEmpty0Sample = 0x0u, /*!< Tx empty at most 0 sample in left and right FIFO */
kSPDIF_TxEmpty4Samples, /*!< Tx empty at most 4 sample in left and right FIFO*/
kSPDIF_TxEmpty8Samples, /*!< Tx empty at most 8 sample in left and right FIFO*/
kSPDIF_TxEmpty12Samples, /*!< Tx empty at most 12 sample in left and right FIFO*/
} spdif_txempty_select_t;
/*! @brief SPDIF U channel source */
typedef enum _spdif_uchannel_source
{
kSPDIF_NoUChannel = 0x0U, /*!< No embedded U channel */
kSPDIF_UChannelFromRx = 0x1U, /*!< U channel from receiver, it is CD mode */
kSPDIF_UChannelFromTx = 0x3U, /*!< U channel from on chip tx */
} spdif_uchannel_source_t;
/*! @brief SPDIF clock gain*/
typedef enum _spdif_gain_select
{
kSPDIF_GAIN_24 = 0x0U, /*!< Gain select is 24 */
kSPDIF_GAIN_16, /*!< Gain select is 16 */
kSPDIF_GAIN_12, /*!< Gain select is 12 */
kSPDIF_GAIN_8, /*!< Gain select is 8 */
kSPDIF_GAIN_6, /*!< Gain select is 6 */
kSPDIF_GAIN_4, /*!< Gain select is 4 */
kSPDIF_GAIN_3, /*!< Gain select is 3 */
} spdif_gain_select_t;
/*! @brief SPDIF tx data source */
typedef enum _spdif_tx_source
{
kSPDIF_txFromReceiver = 0x1U, /*!< Tx data directly through SPDIF receiver */
kSPDIF_txNormal = 0x5U, /*!< Normal operation, data from processor */
} spdif_tx_source_t;
/*! @brief SPDIF tx data source */
typedef enum _spdif_validity_config
{
kSPDIF_validityFlagAlwaysSet = 0x0U, /*!< Outgoing validity flags always set */
kSPDIF_validityFlagAlwaysClear, /*!< Outgoing validity flags always clear */
} spdif_validity_config_t;
/*! @brief The SPDIF interrupt enable flag */
enum
{
kSPDIF_RxDPLLLocked = SPDIF_SIE_LOCK_MASK, /*!< SPDIF DPLL locked */
kSPDIF_TxFIFOError = SPDIF_SIE_TXUNOV_MASK, /*!< Tx FIFO underrun or overrun */
kSPDIF_TxFIFOResync = SPDIF_SIE_TXRESYN_MASK, /*!< Tx FIFO left and right channel resync */
kSPDIF_RxControlChannelChange = SPDIF_SIE_CNEW_MASK, /*!< SPDIF Rx control channel value changed */
kSPDIF_ValidityFlagNoGood = SPDIF_SIE_VALNOGOOD_MASK, /*!< SPDIF validity flag no good */
kSPDIF_RxIllegalSymbol = SPDIF_SIE_SYMERR_MASK, /*!< SPDIF receiver found illegal symbol */
kSPDIF_RxParityBitError = SPDIF_SIE_BITERR_MASK, /*!< SPDIF receiver found parity bit error */
kSPDIF_UChannelReceiveRegisterFull = SPDIF_SIE_URXFUL_MASK, /*!< SPDIF U channel revceive register full */
kSPDIF_UChannelReceiveRegisterOverrun = SPDIF_SIE_URXOV_MASK, /*!< SPDIF U channel receive register overrun */
kSPDIF_QChannelReceiveRegisterFull = SPDIF_SIE_QRXFUL_MASK, /*!< SPDIF Q channel receive reigster full */
kSPDIF_QChannelReceiveRegisterOverrun = SPDIF_SIE_QRXOV_MASK, /*!< SPDIF Q channel receive register overrun */
kSPDIF_UQChannelSync = SPDIF_SIE_UQSYNC_MASK, /*!< SPDIF U/Q channel sync found */
kSPDIF_UQChannelFrameError = SPDIF_SIE_UQERR_MASK, /*!< SPDIF U/Q channel frame error */
kSPDIF_RxFIFOError = SPDIF_SIE_RXFIFOUNOV_MASK, /*!< SPDIF Rx FIFO underrun/overrun */
kSPDIF_RxFIFOResync = SPDIF_SIE_RXFIFORESYN_MASK, /*!< SPDIF Rx left and right FIFO resync */
kSPDIF_LockLoss = SPDIF_SIE_LOCKLOSS_MASK, /*!< SPDIF receiver loss of lock */
kSPDIF_TxFIFOEmpty = SPDIF_SIE_TXEM_MASK, /*!< SPDIF Tx FIFO empty */
kSPDIF_RxFIFOFull = SPDIF_SIE_RXFIFOFUL_MASK, /*!< SPDIF Rx FIFO full */
kSPDIF_AllInterrupt = kSPDIF_RxDPLLLocked | kSPDIF_TxFIFOError | kSPDIF_TxFIFOResync |
kSPDIF_RxControlChannelChange | kSPDIF_ValidityFlagNoGood | kSPDIF_RxIllegalSymbol |
kSPDIF_RxParityBitError | kSPDIF_UChannelReceiveRegisterFull |
kSPDIF_UChannelReceiveRegisterOverrun | kSPDIF_QChannelReceiveRegisterFull |
kSPDIF_QChannelReceiveRegisterOverrun | kSPDIF_UQChannelSync | kSPDIF_UQChannelFrameError |
kSPDIF_RxFIFOError | kSPDIF_RxFIFOResync | kSPDIF_LockLoss | kSPDIF_TxFIFOEmpty |
kSPDIF_RxFIFOFull, /*!< all interrupt */
};
/*! @brief The DMA request sources */
enum
{
kSPDIF_RxDMAEnable = SPDIF_SCR_DMA_RX_EN_MASK, /*!< Rx FIFO full */
kSPDIF_TxDMAEnable = SPDIF_SCR_DMA_TX_EN_MASK, /*!< Tx FIFO empty */
};
/*! @brief SPDIF user configuration structure */
typedef struct _spdif_config
{
bool isTxAutoSync; /*!< If auto sync mechanism open */
bool isRxAutoSync; /*!< If auto sync mechanism open */
uint8_t DPLLClkSource; /*!< SPDIF DPLL clock source, range from 0~15, meaning is chip-specific */
uint8_t txClkSource; /*!< SPDIF tx clock source, range from 0~7, meaning is chip-specific */
spdif_rxfull_select_t rxFullSelect; /*!< SPDIF rx buffer full select */
spdif_txempty_select_t txFullSelect; /*!< SPDIF tx buffer empty select */
spdif_uchannel_source_t uChannelSrc; /*!< U channel source */
spdif_tx_source_t txSource; /*!< SPDIF tx data source */
spdif_validity_config_t validityConfig; /*!< Validity flag config */
spdif_gain_select_t gain; /*!< Rx receive clock measure gain parameter. */
} spdif_config_t;
/*!@brief SPDIF transfer queue size, user can refine it according to use case. */
#define SPDIF_XFER_QUEUE_SIZE (4U)
/*! @brief SPDIF transfer structure */
typedef struct _spdif_transfer
{
uint8_t *data; /*!< Data start address to transfer. */
uint8_t *qdata; /*!< Data buffer for Q channel */
uint8_t *udata; /*!< Data buffer for C channel */
size_t dataSize; /*!< Transfer size. */
} spdif_transfer_t;
typedef struct _spdif_handle spdif_handle_t;
/*! @brief SPDIF transfer callback prototype */
typedef void (*spdif_transfer_callback_t)(SPDIF_Type *base, spdif_handle_t *handle, status_t status, void *userData);
/*! @brief SPDIF handle structure */
struct _spdif_handle
{
uint32_t state; /*!< Transfer status */
spdif_transfer_callback_t callback; /*!< Callback function called at transfer event*/
void *userData; /*!< Callback parameter passed to callback function*/
spdif_transfer_t spdifQueue[SPDIF_XFER_QUEUE_SIZE]; /*!< Transfer queue storing queued transfer */
size_t transferSize[SPDIF_XFER_QUEUE_SIZE]; /*!< Data bytes need to transfer */
volatile uint8_t queueUser; /*!< Index for user to queue transfer */
volatile uint8_t queueDriver; /*!< Index for driver to get the transfer data and size */
uint8_t watermark; /*!< Watermark value */
};
/*******************************************************************************
* API
******************************************************************************/
#if defined(__cplusplus)
extern "C" {
#endif /*_cplusplus*/
/*!
* @name Initialization and deinitialization
* @{
*/
/*!
* @brief Initializes the SPDIF peripheral.
*
* Ungates the SPDIF clock, resets the module, and configures SPDIF with a configuration structure.
* The configuration structure can be custom filled or set with default values by
* SPDIF_GetDefaultConfig().
*
* @note This API should be called at the beginning of the application to use
* the SPDIF driver. Otherwise, accessing the SPDIF module can cause a hard fault
* because the clock is not enabled.
*
* @param base SPDIF base pointer
* @param config SPDIF configuration structure.
*/
void SPDIF_Init(SPDIF_Type *base, const spdif_config_t *config);
/*!
* @brief Sets the SPDIF configuration structure to default values.
*
* This API initializes the configuration structure for use in SPDIF_Init.
* The initialized structure can remain unchanged in SPDIF_Init, or it can be modified
* before calling SPDIF_Init.
* This is an example.
@code
spdif_config_t config;
SPDIF_GetDefaultConfig(&config);
@endcode
*
* @param config pointer to master configuration structure
*/
void SPDIF_GetDefaultConfig(spdif_config_t *config);
/*!
* @brief De-initializes the SPDIF peripheral.
*
* This API gates the SPDIF clock. The SPDIF module can't operate unless SPDIF_Init is called to enable the clock.
*
* @param base SPDIF base pointer
*/
void SPDIF_Deinit(SPDIF_Type *base);
/*!
* @brief Get the instance number for SPDIF.
*
* @param base SPDIF base pointer.
*/
uint32_t SPDIF_GetInstance(SPDIF_Type *base);
/*!
* @brief Resets the SPDIF Tx.
*
* This function makes Tx FIFO in reset mode.
*
* @param base SPDIF base pointer
*/
static inline void SPDIF_TxFIFOReset(SPDIF_Type *base)
{
base->SCR |= SPDIF_SCR_RXFIFO_RST_MASK;
}
/*!
* @brief Resets the SPDIF Rx.
*
* This function enables the software reset and FIFO reset of SPDIF Rx. After reset, clear the reset bit.
*
* @param base SPDIF base pointer
*/
static inline void SPDIF_RxFIFOReset(SPDIF_Type *base)
{
base->SCR |= SPDIF_SCR_RXFIFO_RST_MASK;
}
/*!
* @brief Enables/disables the SPDIF Tx.
*
* @param base SPDIF base pointer
* @param enable True means enable SPDIF Tx, false means disable.
*/
void SPDIF_TxEnable(SPDIF_Type *base, bool enable);
/*!
* @brief Enables/disables the SPDIF Rx.
*
* @param base SPDIF base pointer
* @param enable True means enable SPDIF Rx, false means disable.
*/
static inline void SPDIF_RxEnable(SPDIF_Type *base, bool enable)
{
if (enable)
{
/* Open Rx FIFO */
base->SCR &= ~(SPDIF_SCR_RXFIFO_CTRL_MASK | SPDIF_SCR_RXFIFO_OFF_ON_MASK);
}
else
{
base->SCR |= SPDIF_SCR_RXFIFO_OFF_ON_MASK;
}
}
/*! @} */
/*!
* @name Status
* @{
*/
/*!
* @brief Gets the SPDIF status flag state.
*
* @param base SPDIF base pointer
* @return SPDIF status flag value. Use the _spdif_interrupt_enable_t to get the status value needed.
*/
static inline uint32_t SPDIF_GetStatusFlag(SPDIF_Type *base)
{
return base->SIS;
}
/*!
* @brief Clears the SPDIF status flag state.
*
* @param base SPDIF base pointer
* @param mask State mask. It can be a combination of the _spdif_interrupt_enable_t member. Notice these members
* cannot be included, as these flags cannot be cleared by writing 1 to these bits:
* @arg kSPDIF_UChannelReceiveRegisterFull
* @arg kSPDIF_QChannelReceiveRegisterFull
* @arg kSPDIF_TxFIFOEmpty
* @arg kSPDIF_RxFIFOFull
*/
static inline void SPDIF_ClearStatusFlags(SPDIF_Type *base, uint32_t mask)
{
base->SIC = mask;
}
/*! @} */
/*!
* @name Interrupts
* @{
*/
/*!
* @brief Enables the SPDIF Tx interrupt requests.
*
* @param base SPDIF base pointer
* @param mask interrupt source
* The parameter can be a combination of the following sources if defined.
* @arg kSPDIF_WordStartInterruptEnable
* @arg kSPDIF_SyncErrorInterruptEnable
* @arg kSPDIF_FIFOWarningInterruptEnable
* @arg kSPDIF_FIFORequestInterruptEnable
* @arg kSPDIF_FIFOErrorInterruptEnable
*/
static inline void SPDIF_EnableInterrupts(SPDIF_Type *base, uint32_t mask)
{
base->SIE |= mask;
}
/*!
* @brief Disables the SPDIF Tx interrupt requests.
*
* @param base SPDIF base pointer
* @param mask interrupt source
* The parameter can be a combination of the following sources if defined.
* @arg kSPDIF_WordStartInterruptEnable
* @arg kSPDIF_SyncErrorInterruptEnable
* @arg kSPDIF_FIFOWarningInterruptEnable
* @arg kSPDIF_FIFORequestInterruptEnable
* @arg kSPDIF_FIFOErrorInterruptEnable
*/
static inline void SPDIF_DisableInterrupts(SPDIF_Type *base, uint32_t mask)
{
base->SIE &= ~mask;
}
/*! @} */
/*!
* @name DMA Control
* @{
*/
/*!
* @brief Enables/disables the SPDIF DMA requests.
* @param base SPDIF base pointer
* @param mask SPDIF DMA enable mask, The parameter can be a combination of the following sources if defined
* @arg kSPDIF_RxDMAEnable
* @arg kSPDIF_TxDMAEnable
* @param enable True means enable DMA, false means disable DMA.
*/
static inline void SPDIF_EnableDMA(SPDIF_Type *base, uint32_t mask, bool enable)
{
if (enable)
{
base->SCR |= mask;
}
else
{
base->SCR &= ~mask;
}
}
/*!
* @brief Gets the SPDIF Tx left data register address.
*
* This API is used to provide a transfer address for the SPDIF DMA transfer configuration.
*
* @param base SPDIF base pointer.
* @return data register address.
*/
static inline uint32_t SPDIF_TxGetLeftDataRegisterAddress(SPDIF_Type *base)
{
return (uint32_t)(&(base->STL));
}
/*!
* @brief Gets the SPDIF Tx right data register address.
*
* This API is used to provide a transfer address for the SPDIF DMA transfer configuration.
*
* @param base SPDIF base pointer.
* @return data register address.
*/
static inline uint32_t SPDIF_TxGetRightDataRegisterAddress(SPDIF_Type *base)
{
return (uint32_t)(&(base->STR));
}
/*!
* @brief Gets the SPDIF Rx left data register address.
*
* This API is used to provide a transfer address for the SPDIF DMA transfer configuration.
*
* @param base SPDIF base pointer.
* @return data register address.
*/
static inline uint32_t SPDIF_RxGetLeftDataRegisterAddress(SPDIF_Type *base)
{
return (uint32_t)(&(base->SRL));
}
/*!
* @brief Gets the SPDIF Rx right data register address.
*
* This API is used to provide a transfer address for the SPDIF DMA transfer configuration.
*
* @param base SPDIF base pointer.
* @return data register address.
*/
static inline uint32_t SPDIF_RxGetRightDataRegisterAddress(SPDIF_Type *base)
{
return (uint32_t)(&(base->SRR));
}
/*! @} */
/*!
* @name Bus Operations
* @{
*/
/*!
* @brief Configures the SPDIF Tx sample rate.
*
* The audio format can be changed at run-time. This function configures the sample rate.
*
* @param base SPDIF base pointer.
* @param sampleRate_Hz SPDIF sample rate frequency in Hz.
* @param sourceClockFreq_Hz SPDIF tx clock source frequency in Hz.
*/
void SPDIF_TxSetSampleRate(SPDIF_Type *base, uint32_t sampleRate_Hz, uint32_t sourceClockFreq_Hz);
/*!
* @brief Configures the SPDIF Rx audio format.
*
* The audio format can be changed at run-time. This function configures the sample rate and audio data
* format to be transferred.
*
* @param base SPDIF base pointer.
* @param clockSourceFreq_Hz SPDIF system clock frequency in hz.
*/
uint32_t SPDIF_GetRxSampleRate(SPDIF_Type *base, uint32_t clockSourceFreq_Hz);
/*!
* @brief Sends data using a blocking method.
*
* @note This function blocks by polling until data is ready to be sent.
*
* @param base SPDIF base pointer.
* @param buffer Pointer to the data to be written.
* @param size Bytes to be written.
*/
void SPDIF_WriteBlocking(SPDIF_Type *base, uint8_t *buffer, uint32_t size);
/*!
* @brief Writes data into SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @param data Data needs to be written.
*/
static inline void SPDIF_WriteLeftData(SPDIF_Type *base, uint32_t data)
{
base->STL = data;
}
/*!
* @brief Writes data into SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @param data Data needs to be written.
*/
static inline void SPDIF_WriteRightData(SPDIF_Type *base, uint32_t data)
{
base->STR = data;
}
/*!
* @brief Writes data into SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @param data Data needs to be written.
*/
static inline void SPDIF_WriteChannelStatusHigh(SPDIF_Type *base, uint32_t data)
{
base->STCSCH = data;
}
/*!
* @brief Writes data into SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @param data Data needs to be written.
*/
static inline void SPDIF_WriteChannelStatusLow(SPDIF_Type *base, uint32_t data)
{
base->STCSCL = data;
}
/*!
* @brief Receives data using a blocking method.
*
* @note This function blocks by polling until data is ready to be sent.
*
* @param base SPDIF base pointer.
* @param buffer Pointer to the data to be read.
* @param size Bytes to be read.
*/
void SPDIF_ReadBlocking(SPDIF_Type *base, uint8_t *buffer, uint32_t size);
/*!
* @brief Reads data from the SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @return Data in SPDIF FIFO.
*/
static inline uint32_t SPDIF_ReadLeftData(SPDIF_Type *base)
{
return base->SRL;
}
/*!
* @brief Reads data from the SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @return Data in SPDIF FIFO.
*/
static inline uint32_t SPDIF_ReadRightData(SPDIF_Type *base)
{
return base->SRR;
}
/*!
* @brief Reads data from the SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @return Data in SPDIF FIFO.
*/
static inline uint32_t SPDIF_ReadChannelStatusHigh(SPDIF_Type *base)
{
return base->SRCSH;
}
/*!
* @brief Reads data from the SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @return Data in SPDIF FIFO.
*/
static inline uint32_t SPDIF_ReadChannelStatusLow(SPDIF_Type *base)
{
return base->SRCSL;
}
/*!
* @brief Reads data from the SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @return Data in SPDIF FIFO.
*/
static inline uint32_t SPDIF_ReadQChannel(SPDIF_Type *base)
{
return base->SRQ;
}
/*!
* @brief Reads data from the SPDIF FIFO.
*
* @param base SPDIF base pointer.
* @return Data in SPDIF FIFO.
*/
static inline uint32_t SPDIF_ReadUChannel(SPDIF_Type *base)
{
return base->SRU;
}
/*! @} */
/*!
* @name Transactional
* @{
*/
/*!
* @brief Initializes the SPDIF Tx handle.
*
* This function initializes the Tx handle for the SPDIF Tx transactional APIs. Call
* this function once to get the handle initialized.
*
* @param base SPDIF base pointer
* @param handle SPDIF handle pointer.
* @param callback Pointer to the user callback function.
* @param userData User parameter passed to the callback function
*/
void SPDIF_TransferTxCreateHandle(SPDIF_Type *base,
spdif_handle_t *handle,
spdif_transfer_callback_t callback,
void *userData);
/*!
* @brief Initializes the SPDIF Rx handle.
*
* This function initializes the Rx handle for the SPDIF Rx transactional APIs. Call
* this function once to get the handle initialized.
*
* @param base SPDIF base pointer.
* @param handle SPDIF handle pointer.
* @param callback Pointer to the user callback function.
* @param userData User parameter passed to the callback function.
*/
void SPDIF_TransferRxCreateHandle(SPDIF_Type *base,
spdif_handle_t *handle,
spdif_transfer_callback_t callback,
void *userData);
/*!
* @brief Performs an interrupt non-blocking send transfer on SPDIF.
*
* @note This API returns immediately after the transfer initiates.
* Call the SPDIF_TxGetTransferStatusIRQ to poll the transfer status and check whether
* the transfer is finished. If the return status is not kStatus_SPDIF_Busy, the transfer
* is finished.
*
* @param base SPDIF base pointer.
* @param handle Pointer to the spdif_handle_t structure which stores the transfer state.
* @param xfer Pointer to the spdif_transfer_t structure.
* @retval kStatus_Success Successfully started the data receive.
* @retval kStatus_SPDIF_TxBusy Previous receive still not finished.
* @retval kStatus_InvalidArgument The input parameter is invalid.
*/
status_t SPDIF_TransferSendNonBlocking(SPDIF_Type *base, spdif_handle_t *handle, spdif_transfer_t *xfer);
/*!
* @brief Performs an interrupt non-blocking receive transfer on SPDIF.
*
* @note This API returns immediately after the transfer initiates.
* Call the SPDIF_RxGetTransferStatusIRQ to poll the transfer status and check whether
* the transfer is finished. If the return status is not kStatus_SPDIF_Busy, the transfer
* is finished.
*
* @param base SPDIF base pointer
* @param handle Pointer to the spdif_handle_t structure which stores the transfer state.
* @param xfer Pointer to the spdif_transfer_t structure.
* @retval kStatus_Success Successfully started the data receive.
* @retval kStatus_SPDIF_RxBusy Previous receive still not finished.
* @retval kStatus_InvalidArgument The input parameter is invalid.
*/
status_t SPDIF_TransferReceiveNonBlocking(SPDIF_Type *base, spdif_handle_t *handle, spdif_transfer_t *xfer);
/*!
* @brief Gets a set byte count.
*
* @param base SPDIF base pointer.
* @param handle Pointer to the spdif_handle_t structure which stores the transfer state.
* @param count Bytes count sent.
* @retval kStatus_Success Succeed get the transfer count.
* @retval kStatus_NoTransferInProgress There is not a non-blocking transaction currently in progress.
*/
status_t SPDIF_TransferGetSendCount(SPDIF_Type *base, spdif_handle_t *handle, size_t *count);
/*!
* @brief Gets a received byte count.
*
* @param base SPDIF base pointer.
* @param handle Pointer to the spdif_handle_t structure which stores the transfer state.
* @param count Bytes count received.
* @retval kStatus_Success Succeed get the transfer count.
* @retval kStatus_NoTransferInProgress There is not a non-blocking transaction currently in progress.
*/
status_t SPDIF_TransferGetReceiveCount(SPDIF_Type *base, spdif_handle_t *handle, size_t *count);
/*!
* @brief Aborts the current send.
*
* @note This API can be called any time when an interrupt non-blocking transfer initiates
* to abort the transfer early.
*
* @param base SPDIF base pointer.
* @param handle Pointer to the spdif_handle_t structure which stores the transfer state.
*/
void SPDIF_TransferAbortSend(SPDIF_Type *base, spdif_handle_t *handle);
/*!
* @brief Aborts the current IRQ receive.
*
* @note This API can be called when an interrupt non-blocking transfer initiates
* to abort the transfer early.
*
* @param base SPDIF base pointer
* @param handle Pointer to the spdif_handle_t structure which stores the transfer state.
*/
void SPDIF_TransferAbortReceive(SPDIF_Type *base, spdif_handle_t *handle);
/*!
* @brief Tx interrupt handler.
*
* @param base SPDIF base pointer.
* @param handle Pointer to the spdif_handle_t structure.
*/
void SPDIF_TransferTxHandleIRQ(SPDIF_Type *base, spdif_handle_t *handle);
/*!
* @brief Tx interrupt handler.
*
* @param base SPDIF base pointer.
* @param handle Pointer to the spdif_handle_t structure.
*/
void SPDIF_TransferRxHandleIRQ(SPDIF_Type *base, spdif_handle_t *handle);
/*! @} */
#if defined(__cplusplus)
}
#endif /*_cplusplus*/
/*! @} */
#endif /* _FSL_SPDIF_H_ */