/* * Copyright (c) 2013 - 2014, Freescale Semiconductor, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * * o Redistributions of source code must retain the above copyright notice, this list * of conditions and the following disclaimer. * * o Redistributions in binary form must reproduce the above copyright notice, this * list of conditions and the following disclaimer in the documentation and/or * other materials provided with the distribution. * * o Neither the name of Freescale Semiconductor, Inc. nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #ifndef __FSL_SAI_HAL_H__ #define __FSL_SAI_HAL_H__ #include #include #include #include "fsl_device_registers.h" #include "fsl_sai_features.h" /*! * @addtogroup sai_hal * @{ */ /*! @file */ /******************************************************************************* * Definitions ******************************************************************************/ /* Define the bit limits of in a word*/ #define SAI_BIT_MIN 8 #define SAI_BIT_MAX 32 /* Define the max div and fract value for master clock divider. */ #define SAI_FRACT_MAX 256 #define SAI_DIV_MAX 4096 /*! @brief Define the bus type of sai */ typedef enum _sai_protocol { kSaiBusI2SLeft = 0x0, kSaiBusI2SRight = 0x1, kSaiBusI2SType = 0x2, kSaiBusPCMA = 0x3, kSaiBusPCMB = 0x4, kSaiBusAC97 = 0x5 } sai_protocol_t; /*! @brief Master or slave mode */ typedef enum _sai_master_slave { kSaiMaster = 0x0,/*!< Master mode */ kSaiSlave = 0x1/*!< Slave mode */ } sai_master_slave_t; /*! @brief Polarity of SAI clock. */ typedef enum _sai_clk_polarity { kSaiClkPolarityHigh = 0x0, /*!< Clock active high */ kSaiClkPolarityLow = 0x1 /*!< Clock active low */ } sai_clk_polarity_t; /*! @brief Clock generate direction. */ typedef enum _sai_clk_direction { kSaiClkInternal = 0x0, /*!< Clock generated internal. */ kSaiClkExternal = 0x1 /*!< Clock generated external. */ } sai_clk_direction_t; /*! @brief Data transfer polarity, means MSB first of LSB first.*/ typedef enum _sai_data_order { kSaiLSBFirst = 0x0, /*!< Least significant bit transferred first. */ kSaiMSBFirst = 0x1 /*!< Most significant bit transferred first. */ } sai_data_order_t; /*! @brief Synchronous or asynchronous mode */ typedef enum _sai_sync_mode { kSaiModeAsync = 0x0,/*!< Asynchronous mode */ kSaiModeSync = 0x1,/*!< Synchronous mode (with receiver or transmit) */ kSaiModeSyncWithOtherTx = 0x2,/*!< Synchronous with another SAI transmit */ kSaiModeSyncWithOtherRx = 0x3/*!< Synchronous with another SAI receiver */ } sai_sync_mode_t; /*! @brief Mater clock source */ typedef enum _sai_mclk_source { kSaiMclkSourceSysclk = 0x0,/*!< Master clock from the system clock */ kSaiMclkSourceSelect1 = 0x1,/*!< Master clock from source 1 */ kSaiMclkSourceSelect2 = 0x2,/*!< Master clock from source 2 */ kSaiMclkSourceSelect3 = 0x3/*!< Master clock from source 3 */ } sai_mclk_source_t; /*! @brief Bit clock source */ typedef enum _sai_bclk_source { kSaiBclkSourceBusclk = 0x0,/*!< Bit clock using bus clock */ kSaiBclkSourceMclkDiv = 0x1,/*!< Bit clock using master clock divider */ kSaiBclkSourceOtherSai0 = 0x2,/*!< Bit clock from other SAI device */ kSaiBclkSourceOtherSai1 = 0x3/*!< Bit clock from other SAI device */ } sai_bclk_source_t; /*! @brief The SAI state flag. */ typedef enum _sai_interrupt_request { kSaiIntrequestWordStart = 0x0,/*!< Word start flag, means the first word in a frame detected */ kSaiIntrequestSyncError = 0x1,/*!< Sync error flag, means the sync error is detected */ kSaiIntrequestFIFOWarning = 0x2,/*!< FIFO warning flag, means the FIFO is empty */ kSaiIntrequestFIFOError = 0x3,/*!< FIFO error flag */ kSaiIntrequestFIFORequest = 0x4/*!< FIFO request, means reached watermark */ } sai_interrupt_request_t; /*! @brief The DMA request sources */ typedef enum _sai_dma_request { kSaiDmaReqFIFOWarning = 0x0,/*!< FIFO warning caused by the DMA request */ kSaiDmaReqFIFORequest = 0x1/*!< FIFO request caused by the DMA request */ } sai_dma_request_t; /*! @brief The SAI state flag */ typedef enum _sai_state_flag { kSaiStateFlagWordStart = 0x0,/*!< Word start flag, means the first word in a frame detected. */ kSaiStateFlagSyncError = 0x1,/*!< Sync error flag, means the sync error is detected */ kSaiStateFlagFIFOError = 0x2,/*!< FIFO error flag */ kSaiStateFlagFIFORequest = 0x3, kSaiStateFlagFIFOWarning = 0x4, kSaiStateFlagSoftReset = 0x5 /*!< Software reset flag */ } sai_state_flag_t; /*! @brief The reset type */ typedef enum _sai_reset_type { kSaiResetTypeSoftware = 0x0,/*!< Software reset, reset the logic state */ kSaiResetTypeFIFO = 0x1/*!< FIFO reset, reset the FIFO read and write pointer */ } sai_reset_type_t; /* * @brief The SAI running mode * The mode includes normal mode, debug mode, and stop mode. */ typedef enum _sai_running_mode { kSaiRunModeDebug = 0x0,/*!< In debug mode */ kSaiRunModeStop = 0x1/*!< In stop mode */ } sai_run_mode_t; #if FSL_FEATURE_SAI_HAS_FIFO_PACKING /* * @brief The SAI packing mode * The mode includes 8 bit and 16 bit packing. */ typedef enum _sai_fifo_packing { kSaiFifoPackingDisabled = 0x0, /*!< Packing disabled. */ kSaiFifoPacking8bit = 0x2,/*!< 8 bit packing enabled. */ kSaiFifoPacking16bit = 0x3 /*!< 16bit packing enabled. */ } sai_fifo_packing_t; #endif /******************************************************************************* * API ******************************************************************************/ #if defined(__cplusplus) extern "C" { #endif /*! * @name Module control * @{ */ /*! * @brief Initializes the SAI Tx. * * The initialization resets the SAI module by setting the SR bit of TCSR register. * Note that the function writes 0 to every control registers. * @param saiBaseAddr Register base address of SAI module. */ void SAI_HAL_TxInit(uint32_t saiBaseAddr); /*! * @brief Initializes the SAI Rx. * * The initialization resets the SAI module by setting the SR bit of RCSR register. * Note that the function writes 0 to every control registers. * @param saiBaseAddr Register base address of SAI module. */ void SAI_HAL_RxInit(uint32_t saiBaseAddr); /*! * @brief Sets Tx protocol relevant settings. * * The bus mode means which protocol SAI uses. It can be I2S left, right and so on. Each protocol * has a different configuration on bit clock and frame sync. * @param saiBaseAddr Register base address of SAI module. * @param protocol The protocol selection. It can be I2S left aligned, I2S right aligned, etc. */ void SAI_HAL_TxSetProtocol(uint32_t saiBaseAddr, sai_protocol_t protocol); /*! * @brief Sets Rx protocol relevant settings. * * The bus mode means which protocol SAI uses. It can be I2S left, right and so on. Each protocol * has a different configuration on bit clock and frame sync. * @param saiBaseAddr Register base address of SAI module. * @param protocol The protocol selection. It can be I2S left aligned, I2S right aligned, etc. */ void SAI_HAL_RxSetProtocol(uint32_t saiBaseAddr, sai_protocol_t protocol); /*! * @brief Sets master or slave mode. * * The function determines master or slave mode. Master mode provides its * own clock and slave mode uses an external clock. * @param saiBaseAddr Register base address of SAI module. * @param master_slave_mode Mater or slave mode. */ void SAI_HAL_TxSetMasterSlave(uint32_t saiBaseAddr, sai_master_slave_t master_slave_mode); /*! * @brief Sets master or slave mode. * * The function determines master or slave mode. Master mode provides its * own clock and slave mode uses external clock. * @param saiBaseAddr Register base address of SAI module. * @param master_slave_mode Mater or slave mode. */ void SAI_HAL_RxSetMasterSlave(uint32_t saiBaseAddr, sai_master_slave_t master_slave_mode); /*! @}*/ /*! * @name Master clock configuration * @{ */ /*! * @brief Sets the master clock source. * * The source of the clock is different from socs. * This function sets the clock source for SAI master clock source. * Master clock is used to produce the bit clock for the data transfer. * @param saiBaseAddr Register base address of SAI module. * @param source Mater clock source */ static inline void SAI_HAL_SetMclkSrc(uint32_t saiBaseAddr, sai_mclk_source_t source) { BW_I2S_MCR_MICS(saiBaseAddr,source); } /*! * @brief Gets the master clock source. * * The source of the clock is different from socs. * This function gets the clock source for SAI master clock source. * Master clock is used to produce the bit clock for the data transfer. * @param saiBaseAddr Register base address of SAI module. * @return Mater clock source */ static inline uint32_t SAI_HAL_GetMclkSrc(uint32_t saiBaseAddr) { return BR_I2S_MCR_MICS(saiBaseAddr); } /*! * @brief Sets the direction of the SAI master clock. * * This function would decides the direction of bit clock generated. * @param saiBaseAddr Register base address of SAI module. * @param enable True means enable, false means disable. */ static inline void SAI_HAL_SetMclkDividerCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_MCR_MOE(saiBaseAddr,enable); } /*! * @brief Sets the divider of the master clock. * * Using the divider to get the master clock frequency wanted from the source. * mclk = clk_source * fract/divide. The input is the master clock frequency needed and the source clock frequency. * The master clock is decided by the sample rate and the multi-clock number. * Notice that mclk should less than src_clk, or it would do hang as the HW refuses to write in this situation. * @param saiBaseAddr Register base address of SAI module. * @param mclk Master clock frequency needed. * @param src_clk The source clock frequency. */ void SAI_HAL_SetMclkDiv(uint32_t saiBaseAddr, uint32_t mclk, uint32_t src_clk); /*! * @brief Flag to see if the master clock divider is re-divided. * @param saiBaseAddr Register base address of SAI module. * @return True if the divider updated otherwise false. */ static inline bool SAI_HAL_GetMclkDivUpdatingCmd(uint32_t saiBaseAddr) { return BR_I2S_MCR_DUF(saiBaseAddr); } /*! @}*/ /*! * @name Bit clock configuration * @{ */ /*! * @brief Sets the bit clock source of Tx. It is generated by the master clock, bus clock and other devices. * * The function sets the source of the bit clock. The bit clock can be produced by the master * clock and from the bus clock or other SAI Tx/Rx. Tx and Rx in the SAI module use the same bit * clock either from Tx or Rx. * @param saiBaseAddr Register base address of SAI module. * @param source Bit clock source. */ static inline void SAI_HAL_TxSetBclkSrc(uint32_t saiBaseAddr, sai_bclk_source_t source) { BW_I2S_TCR2_MSEL(saiBaseAddr,source); } /*! * @brief Sets bit clock source of the Rx. It is generated by the master clock, bus clock and other devices. * * The function sets the source of the bit clock. The bit clock can be produced by the master * clock, and from the bus clock or other SAI Tx/Rx. Tx and Rx in the SAI module use the same bit * clock either from Tx or Rx. * @param saiBaseAddr Register base address of SAI module. * @param source Bit clock source. */ static inline void SAI_HAL_RxSetBclkSrc(uint32_t saiBaseAddr, sai_bclk_source_t source) { BW_I2S_RCR2_MSEL(saiBaseAddr,source); } /*! * @brief Gets the bit clock source of Tx. It is generated by the master clock, bus clock and other devices. * * The function gets the source of the bit clock. The bit clock can be produced by the master * clock and from the bus clock or other SAI Tx/Rx. Tx and Rx in the SAI module use the same bit * clock either from Tx or Rx. * @param saiBaseAddr Register base address of SAI module. * @return Bit clock source. */ static inline uint32_t SAI_HAL_TxGetBclkSrc(uint32_t saiBaseAddr) { return BR_I2S_TCR2_MSEL(saiBaseAddr); } /*! * @brief Gets bit clock source of the Rx. It is generated by the master clock, bus clock and other devices. * * The function gets the source of the bit clock. The bit clock can be produced by the master * clock, and from the bus clock or other SAI Tx/Rx. Tx and Rx in the SAI module use the same bit * clock either from Tx or Rx. * @param saiBaseAddr Register base address of SAI module. * @return Bit clock source. */ static inline uint32_t SAI_HAL_RxGetBclkSrc(uint32_t saiBaseAddr) { return BR_I2S_RCR2_MSEL(saiBaseAddr); } /*! * @brief Sets the Tx bit clock divider value. * * bclk = mclk / divider. At the same time, bclk = sample_rate * channel * bits. This means * how much time is needed to transfer one bit. * Notice: The function is called while the bit clock source is the master clock. * @param saiBaseAddr Register base address of SAI module. * @param divider The divide number of bit clock. */ static inline void SAI_HAL_TxSetBclkDiv(uint32_t saiBaseAddr, uint32_t divider) { BW_I2S_TCR2_DIV(saiBaseAddr,divider/2 -1); } /*! * @brief Sets the Rx bit clock divider value. * * bclk = mclk / divider. At the same time, bclk = sample_rate * channel * bits. This means * how much time is needed to transfer one bit. * Notice: The function is called while the bit clock source is the master clock. * @param saiBaseAddr Register base address of SAI module. * @param divider The divide number of bit clock. */ static inline void SAI_HAL_RxSetBclkDiv(uint32_t saiBaseAddr, uint32_t divider) { BW_I2S_RCR2_DIV(saiBaseAddr,divider/2 -1); } /*! * @brief Enables or disables the Tx bit clock. * * @param saiBaseAddr Register base address of SAI module. * @param enable True means enable, false means disable. */ static inline void SAI_HAL_TxSetBclkCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_TCSR_BCE(saiBaseAddr,enable); } /*! * @brief Enables or disables the Rx bit clock. * * @param saiBaseAddr Register base address of SAI module. * @param enable True means enable, false means disable. */ static inline void SAI_HAL_RxSetBclkCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_RCSR_BCE(saiBaseAddr, enable); } /*! * @brief Enables or disables the Tx bit clock input bit. * * @param saiBaseAddr Register base address of SAI module. * @param enable True means enable, false means disable. */ static inline void SAI_HAL_TxSetBclkInputCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_TCR2_BCI(saiBaseAddr,enable); } /*! * @brief Enables or disables the Rx bit clock input bit. * * @param saiBaseAddr Register base address of SAI module. * @param enable True means enable, false means disable. */ static inline void SAI_HAL_RxSetBclkInputCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_RCR2_BCI(saiBaseAddr,enable); } /*! * @brief Sets the Tx bit clock swap. * * This field swaps the bit clock used by the transmitter. When the transmitter is configured in * asynchronous mode and this bit is set, the transmitter is clocked by the receiver bit clock. * This allows the transmitter and receiver to share the same bit clock, but the transmitter * continues to use the transmit frame sync (SAI_TX_SYNC). * When the transmitter is configured in synchronous mode, the transmitter BCS field and receiver * BCS field must be set to the same value. When both are set, the transmitter and receiver are both * clocked by the transmitter bit clock (SAI_TX_BCLK) but use the receiver frame sync (SAI_RX_SYNC). * @param saiBaseAddr Register base address of SAI module. * @param enable True means swap bit closk, false means no swap. */ static inline void SAI_HAL_TxSetSwapBclkCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_TCR2_BCS(saiBaseAddr,enable); } /*! * @brief Sets the Rx bit clock swap. * * This field swaps the bit clock used by the receiver. When the receiver is configured in * asynchronous mode and this bit is set, the receiver is clocked by the transmitter bit clock * (SAI_TX_BCLK). This allows the transmitter and receiver to share the same bit clock, but the * receiver continues to use the receiver frame sync (SAI_RX_SYNC). * When the receiver is configured in synchronous mode, the transmitter BCS field and receiver BCS * field must be set to the same value. When both are set, the transmitter and receiver are both * clocked by the receiver bit clock (SAI_RX_BCLK) but use the transmitter frame sync (SAI_TX_SYNC). * @param saiBaseAddr Register base address of SAI module. * @param enable True means swap bit closk, false means no swap. */ static inline void SAI_HAL_RxSetSwapBclkCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_RCR2_BCS(saiBaseAddr, enable); } /*! * @brief Sets the direction of the Tx SAI bit clock. * * This function sets the direction of the bit clock generated. * @param saiBaseAddr Register base address of SAI module. * @param direction Bit clock generated internal or external. */ static inline void SAI_HAL_TxSetBclkDir(uint32_t saiBaseAddr, sai_clk_direction_t direction) { BW_I2S_TCR2_BCD(saiBaseAddr,direction); } /*! * @brief Sets the direction of the Rx SAI bit clock. * * This function sets the direction of the bit clock generated. * @param saiBaseAddr Register base address of SAI module. * @param direction Bit clock generated internal or external. */ static inline void SAI_HAL_RxSetBclkDir(uint32_t saiBaseAddr, sai_clk_direction_t direction) { BW_I2S_RCR2_BCD(saiBaseAddr,direction); } /*! * @brief Sets the polarity of the Tx SAI bit clock. * * @param saiBaseAddr Register base address of SAI module. * @param pol Polarity of the SAI bit clock, which can be configured to active high or low. */ static inline void SAI_HAL_TxSetBclkPolarity(uint32_t saiBaseAddr, sai_clk_polarity_t pol) { BW_I2S_TCR2_BCP(saiBaseAddr, pol); } /*! * @brief Sets the polarity of the Rx SAI bit clock. * * @param saiBaseAddr Register base address of SAI module. * @param pol Polarity of SAI bit clock, which can be configured to active high or low. */ static inline void SAI_HAL_RxSetBclkPolarity(uint32_t saiBaseAddr, sai_clk_polarity_t pol) { BW_I2S_RCR2_BCP(saiBaseAddr, pol); } /*! @} */ /*! * @name Frame sync configuration * @{ */ /*! * @brief Sets the Tx frame size. * * The frame size means how many words are in a frame. For example 2-channel * audio data, the frame size is 2, which means 2 words in a frame. * @param saiBaseAddr Register base address of SAI module. * @param size Words number in a frame. */ static inline void SAI_HAL_TxSetFrameSize(uint32_t saiBaseAddr, uint32_t size) { BW_I2S_TCR4_FRSZ(saiBaseAddr,size -1); } /*! * @brief Sets the Rx frame size. * * The frame size means how many words are in a frame. For example 2-channel * audio data, the frame size is 2, which means 2 words in a frame. * @param saiBaseAddr Register base address of SAI module. * @param size Words number in a frame. */ static inline void SAI_HAL_RxSetFrameSize(uint32_t saiBaseAddr, uint32_t size) { BW_I2S_RCR4_FRSZ(saiBaseAddr,size - 1); } /*! * @brief Gets the Tx frame size. * * @param saiBaseAddr Register base address of SAI module. */ static inline uint32_t SAI_HAL_TxGetFrameSize(uint32_t saiBaseAddr) { return BR_I2S_TCR4_FRSZ(saiBaseAddr); } /*! * @brief Gets the Tx frame size. * * @param saiBaseAddr Register base address of SAI module. */ static inline uint32_t SAI_HAL_RxGetFrameSize(uint32_t saiBaseAddr) { return BR_I2S_RCR4_FRSZ(saiBaseAddr); } /*! * @brief Sets the Tx sync width. * * A sync is the number of bit clocks of a frame. The sync width cannot be longer than the * length of the first word of the frame. * @param saiBaseAddr Register base address of SAI module. * @param width How many bit clock in a sync. */ static inline void SAI_HAL_TxSetFrameSyncWidth(uint32_t saiBaseAddr, uint32_t width) { BW_I2S_TCR4_SYWD(saiBaseAddr, width -1); } /*! * @brief Sets the Rx sync width. * * A sync is the number of bit clocks of a frame. The sync width cannot be longer than the * length of the first word of the frame. * @param saiBaseAddr Register base address of SAI module. * @param width How many bit clock in a sync. */ static inline void SAI_HAL_RxSetFrameSyncWidth(uint32_t saiBaseAddr, uint32_t width) { BW_I2S_RCR4_SYWD(saiBaseAddr, width -1); } /*! * @brief Sets the polarity of the Tx frame sync. * * @param saiBaseAddr Register base address of SAI module. * @param pol Polarity of sai frame sync, can be configured to active high or low. */ static inline void SAI_HAL_TxSetFrameSyncPolarity(uint32_t saiBaseAddr, sai_clk_polarity_t pol) { BW_I2S_TCR4_FSP(saiBaseAddr,pol); } /*! * @brief Sets the polarity of the Rx frame sync. * * @param saiBaseAddr Register base address of SAI module.. * @param pol Polarity of SAI frame sync, can be configured to active high or low. */ static inline void SAI_HAL_RxSetFrameSyncPolarity(uint32_t saiBaseAddr, sai_clk_polarity_t pol) { BW_I2S_RCR4_FSP(saiBaseAddr,pol); } /*! * @brief Sets the direction of the SAI Tx frame sync. * * This function sets the direction of frame sync. * @param saiBaseAddr Register base address of SAI module. * @param direction Frame sync generated internal or external. */ static inline void SAI_HAL_TxSetFrameSyncDir(uint32_t saiBaseAddr,sai_clk_direction_t direction) { BW_I2S_TCR4_FSD(saiBaseAddr,direction); } /*! * @brief Sets the direction of the SAI Rx frame sync. * * This function sets the direction of frame sync. * @param saiBaseAddr Register base address of SAI module. * @param direction Frame sync generated internal or external. */ static inline void SAI_HAL_RxSetFrameSyncDir(uint32_t saiBaseAddr,sai_clk_direction_t direction) { BW_I2S_RCR4_FSD(saiBaseAddr,direction); } /*! * @brief Sets the Tx data transfer order. * * This function sets the data transfer order. It can be set to MSB first or LSB first. * @param saiBaseAddr Register base address of SAI module. * @param order MSB transmit first or LSB transmit first. */ static inline void SAI_HAL_TxSetBitOrder(uint32_t saiBaseAddr, sai_data_order_t order) { BW_I2S_TCR4_MF(saiBaseAddr,order); } /*! * @brief Sets the Rx data transfer order. * * This function sets the data transfer order. It can be set to MSB first or LSB first. * @param saiBaseAddr Register base address of SAI module. * @param order MSB transmit first or LSB transmit first. */ static inline void SAI_HAL_RxSetBitOrder(uint32_t saiBaseAddr, sai_data_order_t order) { BW_I2S_RCR4_MF(saiBaseAddr,order); } /*! * @brief Tx Frame sync one bit early. * * @param saiBaseAddr Register base address of SAI module. * @param enable True means the frame sync one bit early and false means no early. */ static inline void SAI_HAL_TxSetFrameSyncEarlyCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_TCR4_FSE(saiBaseAddr,enable); } /*! * @brief Rx Frame sync one bit early. * * @param saiBaseAddr Register base address of SAI module. * @param enable True means the frame sync one bit early and false means no early. */ static inline void SAI_HAL_RxSetFrameSyncEarlyCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_RCR4_FSE(saiBaseAddr,enable); } /*! @} */ /*! * @name Word configurations * @{ */ /*! * @brief Sets the word size for Tx. * * The word size means the quantization level of audio file. * SAI supports the 8 bit, 16 bit, 24 bit, and 32 bit formats. * @param saiBaseAddr Register base address of SAI module. * @param bits How many bits in a word. */ static inline void SAI_HAL_TxSetWordSize(uint32_t saiBaseAddr,uint32_t bits) { BW_I2S_TCR5_WNW(saiBaseAddr,bits-1); } /*! * @brief Sets the word size for Rx. * * The word size means the quantization level of audio file. * SAI supports 8 bit, 16 bit, 24 bit, and 32 bit formats. * @param saiBaseAddr Register base address of SAI module. * @param bits How many bits in a word. */ static inline void SAI_HAL_RxSetWordSize(uint32_t saiBaseAddr,uint32_t bits) { BW_I2S_RCR5_WNW(saiBaseAddr,bits-1); } /*! * @brief Gets the Tx word size. * @param saiBaseAddr Register base address of SAI module. */ static inline uint32_t SAI_HAL_TxGetWordSize(uint32_t saiBaseAddr) { return BR_I2S_TCR5_WNW(saiBaseAddr); } /*! * @brief Gets the Rx word size. * @param saiBaseAddr Register base address of SAI module. */ static inline uint32_t SAI_HAL_RxGetWordSize(uint32_t saiBaseAddr) { return BR_I2S_RCR5_WNW(saiBaseAddr); } /*! * @brief Sets the size of the first word of the Tx frame . * * In I2S protocol, the size of the first word is the same as the size of other words. In some protocols, * for example, AC'97, the first word is not the same size as others. This function * sets the length of the first word which is, in most situations, the same as others. * @param saiBaseAddr Register base address of SAI module. * @param size The length of frame head word. */ static inline void SAI_HAL_TxSetFirstWordSize(uint32_t saiBaseAddr, uint8_t size) { BW_I2S_TCR5_W0W(saiBaseAddr, size-1); } /*! * @brief Sets the size of the first word of Rx frame . * * In I2S protocol, the size of the first word is the same as the size of other words. In some protocols, * for example, AC'97, the first word is not the same size as others. This function * sets the length of the first word which is, in most situations, the same as others. * @param saiBaseAddr Register base address of SAI module. * @param size The length of frame head word. */ static inline void SAI_HAL_RxSetFirstWordSize(uint32_t saiBaseAddr, uint8_t size) { BW_I2S_RCR5_W0W(saiBaseAddr, size-1); } /*! * @brief Sets the FIFO index for the first bit data. * * The FIFO is 32-bit in SAI. However, not all audio data is 32-bit, but is mostly 16-bit. * In this situation, the codec needs to know which bit of the FIFO marks the valid audio data. * @param saiBaseAddr Register base address of SAI module. * @param index First bit shifted in FIFO. */ static inline void SAI_HAL_TxSetFirstBitShifted(uint32_t saiBaseAddr, uint32_t index) { BW_I2S_TCR5_FBT(saiBaseAddr, index-1); } /*! * @brief Sets the index in FIFO for the first bit data. * * The FIFO is 32-bit in SAI. However, not all audio data is 32-bit, but is mostly 16-bit. * In this situation, the codec needs to know which bit of the FIFO marks the valid audio data. * @param saiBaseAddr Register base address of SAI module. * @param index First bit shifted in FIFO. */ static inline void SAI_HAL_RxSetFirstBitShifted(uint32_t saiBaseAddr, uint32_t index) { BW_I2S_RCR5_FBT(saiBaseAddr, index-1); } /*!@}*/ /*! * @name watermark settings * @{ */ /*! * @brief Sets the Tx watermark value. * * While the value in the FIFO is less or equal to the watermark , it generates an interrupt * request or a DMA request. The watermark value cannot be greater than the depth of FIFO. * @param saiBaseAddr Register base address of SAI module. * @param watermark Watermark value of a FIFO. */ static inline void SAI_HAL_TxSetWatermark(uint32_t saiBaseAddr, uint32_t watermark) { BW_I2S_TCR1_TFW(saiBaseAddr, watermark); } /*! * @brief Sets the Tx watermark value. * * While the value in the FIFO is more or equal to the watermark , it generates an interrupt * request or a DMA request. The watermark value cannot be greater than the depth of FIFO. * @param saiBaseAddr Register base address of SAI module. * @param watermark Watermark value of a FIFO. */ static inline void SAI_HAL_RxSetWatermark(uint32_t saiBaseAddr, uint32_t watermark) { BW_I2S_RCR1_RFW(saiBaseAddr, watermark); } /*! * @brief Gets the Tx watermark value. * * @param saiBaseAddr Register base address of SAI module. */ static inline uint32_t SAI_HAL_TxGetWatermark(uint32_t saiBaseAddr) { return BR_I2S_TCR1_TFW(saiBaseAddr); } /*! * @brief Gets the Rx watermark value. * * @param saiBaseAddr Register base address of SAI module. */ static inline uint32_t SAI_HAL_RxGetWatermark(uint32_t saiBaseAddr) { return BR_I2S_RCR1_RFW(saiBaseAddr); } /*! @}*/ /*! * @brief SAI Tx sync mode setting. * * The mode can be asynchronous mode, synchronous, or synchronous with another SAI device. * When configured for a synchronous mode of operation, the receiver must be configured for the * asynchronous operation. * @param saiBaseAddr Register base address of SAI module. * @param sync_mode Synchronous mode or Asynchronous mode. */ void SAI_HAL_TxSetSyncMode(uint32_t saiBaseAddr, sai_sync_mode_t sync_mode); /*! * @brief SAI Rx sync mode setting. * * The mode can be asynchronous mode, synchronous, or synchronous with another SAI device. * When configured for a synchronous mode of operation, the receiver must be configured for the * asynchronous operation. * @param saiBaseAddr Register base address of SAI module. * @param sync_mode Synchronous mode or Asynchronous mode. */ void SAI_HAL_RxSetSyncMode(uint32_t saiBaseAddr, sai_sync_mode_t sync_mode); /*! * @brief Gets the Tx FIFO read pointer. * * It is used to determine whether the FIFO is full or empty and know how much space there is for FIFO. * If read_ptr == write_ptr, the FIFO is empty. While the bit of the read_ptr and the write_ptr are * equal except for the MSB, the FIFO is full. * @param saiBaseAddr Register base address of SAI module. * @param fifo_channel FIFO channel selected. * @return FIFO read pointer value. */ static inline uint8_t SAI_HAL_TxGetFifoReadPointer(uint32_t saiBaseAddr, uint32_t fifo_channel) { return BR_I2S_TFRn_RFP(saiBaseAddr,fifo_channel); } /*! * @brief Gets the Rx FIFO read pointer. * * It is used to determine whether the FIFO is full or empty and know how much space there is for FIFO. * If read_ptr == write_ptr, the FIFO is empty. While the bit of the read_ptr and the write_ptr are * equal except for the MSB, the FIFO is full. * @param saiBaseAddr Register base address of SAI module. * @param fifo_channel FIFO channel selected. * @return FIFO read pointer value. */ static inline uint8_t SAI_HAL_RxGetFifoReadPointer(uint32_t saiBaseAddr, uint32_t fifo_channel) { return BR_I2S_RFRn_RFP(saiBaseAddr,fifo_channel); } /*! * @brief Gets the Tx FIFO write pointer. * * It is used to determine whether the FIFO is full or empty and know how much space there is for FIFO. * If read_ptr == write_ptr, the FIFO is empty. While the bit of the read_ptr and write_ptr are * equal except for the MSB, the FIFO is full. * @param saiBaseAddr Register base address of SAI module. * @param fifo_channel FIFO channel selected. * @return FIFO read pointer value. */ static inline uint8_t SAI_HAL_TxGetFifoWritePointer(uint32_t saiBaseAddr,uint32_t fifo_channel) { return BR_I2S_TFRn_WFP(saiBaseAddr,fifo_channel); } /*! * @brief Gets the Rx FIFO write pointer. * * It is used to determine whether the FIFO is full or empty and know how much space there is for FIFO. * If read_ptr == write_ptr, the FIFO is empty. While the bit of the read_ptr and write_ptr are * equal except for the MSB, the FIFO is full. * @param saiBaseAddr Register base address of SAI module. * @param fifo_channel FIFO channel selected. * @return FIFO read pointer value. */ static inline uint8_t SAI_HAL_RxGetFifoWritePointer(uint32_t saiBaseAddr,uint32_t fifo_channel) { return BR_I2S_RFRn_WFP(saiBaseAddr,fifo_channel); } /*! * @brief Gets the TDR register address. * * This function determines the dest/src address of the DMA transfer. * @param saiBaseAddr Register base address of SAI module. * @param fifo_channel FIFO channel selected. * @return TDR register or RDR register address */ static inline uint32_t* SAI_HAL_TxGetFifoAddr(uint32_t saiBaseAddr, uint32_t fifo_channel) { return (uint32_t *)HW_I2S_TDRn_ADDR(saiBaseAddr, fifo_channel); } /*! * @brief Gets the RDR register address. * * This function determines the dest/src address of the DMA transfer. * @param saiBaseAddr Register base address of SAI module. * @param fifo_channel FIFO channel selected. * @return TDR register or RDR register address */ static inline uint32_t* SAI_HAL_RxGetFifoAddr(uint32_t saiBaseAddr, uint32_t fifo_channel) { return (uint32_t *)HW_I2S_RDRn_ADDR(saiBaseAddr, fifo_channel); } /*! * @brief Enables the SAI Tx module. * * Enables the Tx. This function enables both the bit clock and the transfer channel. * @param saiBaseAddr Register base address of SAI module. */ static inline void SAI_HAL_TxEnable(uint32_t saiBaseAddr) { BW_I2S_TCSR_BCE(saiBaseAddr,true); BW_I2S_TCSR_TE(saiBaseAddr,true); } /*! * @brief Enables the SAI Rx module. * * Enables the Rx. This function enables both the bit clock and the receive channel. * @param saiBaseAddr Register base address of SAI module. */ static inline void SAI_HAL_RxEnable(uint32_t saiBaseAddr) { BW_I2S_RCSR_BCE(saiBaseAddr,true); BW_I2S_RCSR_RE(saiBaseAddr,true); } /*! * @brief Disables the Tx module. * * Disables the Tx. This function disables both the bit clock and the transfer channel. * @param saiBaseAddr Register base address of SAI module. */ static inline void SAI_HAL_TxDisable(uint32_t saiBaseAddr) { BW_I2S_TCSR_TE(saiBaseAddr,false); BW_I2S_TCSR_BCE(saiBaseAddr,false); } /*! * @brief Disables the Rx module. * * Disables the Rx. This function disables both the bit clock and the receive channel. * @param saiBaseAddr Register base address of SAI module. */ static inline void SAI_HAL_RxDisable(uint32_t saiBaseAddr) { BW_I2S_RCSR_RE(saiBaseAddr,false); BW_I2S_RCSR_BCE(saiBaseAddr,false); } /*! * @brief Enables the Tx interrupt from different interrupt sources. * * The interrupt source can be : Word start flag, Sync error flag, FIFO error flag, FIFO warning flag, FIFO request flag. * This function sets which flag causes an interrupt request. * @param saiBaseAddr Register base address of SAI module. * @param source SAI interrupt request source. * @param enable Enable or disable. */ void SAI_HAL_TxSetIntCmd(uint32_t saiBaseAddr,sai_interrupt_request_t source, bool enable); /*! * @brief Enables the Rx interrupt from different interrupt sources. * * The interrupt source can be : Word start flag, Sync error flag, FIFO error flag, FIFO warning flag, FIFO request flag. * This function sets which flag causes an interrupt request. * @param saiBaseAddr Register base address of SAI module. * @param source SAI interrupt request source. * @param enable Enable or disable. */ void SAI_HAL_RxSetIntCmd(uint32_t saiBaseAddr,sai_interrupt_request_t source, bool enable); /*! * @brief Gets the status as to whether the Tx interrupt source is enabled. * * The interrupt source can be : Word start flag, Sync error flag, FIFO error flag, FIFO warning flag, FIFO request flag. * This function sets which flag causes an interrupt request. * @param saiBaseAddr Register base address of SAI module. * @param source SAI interrupt request source. * @return Enabled or disabled. */ bool SAI_HAL_TxGetIntCmd(uint32_t saiBaseAddr,sai_interrupt_request_t source); /*! * @brief Gets the status as to whether the Rx interrupt source is enabled. * * The interrupt source can be : Word start flag, Sync error flag, FIFO error flag, FIFO warning flag, FIFO request flag. * This function sets which flag causes an interrupt request. * @param saiBaseAddr Register base address of SAI module. * @param source SAI interrupt request source. * @return Enabled or disabled. */ bool SAI_HAL_RxGetIntCmd(uint32_t saiBaseAddr,sai_interrupt_request_t source); /*! * @brief Enables the Tx DMA request from different sources. * * The DMA sources can be: FIFO warning and FIFO request. * This function enables the DMA request from different DMA request sources. * @param saiBaseAddr Register base address of SAI module. * @param source SAI DMA request source. * @param enable Enable or disable. */ void SAI_HAL_TxSetDmaCmd(uint32_t saiBaseAddr, sai_dma_request_t source, bool enable); /*! * @brief Enables the Rx DMA request from different sources. * * The DMA sources can be: FIFO warning and FIFO request. * This function enables the DMA request from different DMA request sources. * @param saiBaseAddr Register base address of SAI module. * @param source SAI DMA request source. * @param enable Enable or disable. */ void SAI_HAL_RxSetDmaCmd(uint32_t saiBaseAddr, sai_dma_request_t source, bool enable); /*! * @brief Gets the status whether the Tx DMA source is enabled. * * The DMA sources can be: FIFO warning and FIFO request. * This function enables the DMA request from different DMA request sources. * @param saiBaseAddr Register base address of SAI module. * @param source SAI DMA request source. * @param Enable or disable. */ bool SAI_HAL_TxGetDmaCmd(uint32_t saiBaseAddr, sai_dma_request_t source); /*! * @brief Gets the status whether the Rx DMA source is enabled. * * The DMA sources can be: FIFO warning and FIFO request. * This function enables the DMA request from different DMA request sources. * @param saiBaseAddr Register base address of SAI module. * @param source SAI DMA request source. * @return Enable or disable. */ bool SAI_HAL_RxGetDmaCmd(uint32_t saiBaseAddr, sai_dma_request_t source); /*! * @brief Clears the Tx state flags. * * The function is used to clear the flags manually. It can clear word start, FIFO warning, FIFO error, * FIFO request flag. * @param saiBaseAddr Register base address of SAI module. * @param flag SAI state flag type. The flag can be word start, sync error, FIFO error/warning. */ void SAI_HAL_TxClearStateFlag(uint32_t saiBaseAddr, sai_state_flag_t flag); /*! * @brief Clears the Rx state flags. * * The function is used to clear the flags manually. It can clear word start, FIFO warning, FIFO error, * FIFO request flag. * @param saiBaseAddr Register base address of SAI module. * @param flag SAI state flag type. The flag can be word start, sync error, FIFO error/warning. */ void SAI_HAL_RxClearStateFlag(uint32_t saiBaseAddr, sai_state_flag_t flag); /*! * @brief Resets the Tx module. * * There are two kinds of resets: Software reset and FIFO reset. * Software reset: resets all transmitter internal logic, including the bit clock generation, * status flags and FIFO pointers. It does not reset the configuration registers. * FIFO reset: synchronizes the FIFO write pointer to the same value as the FIFO read pointer. * This empties the FIFO contents and is to be used after the Transmit FIFO Error Flag is set, * and before the FIFO is re-initialized and the Error Flag is cleared. * @param saiBaseAddr Register base address of SAI module. * @param type SAI reset type. */ void SAI_HAL_TxSetReset(uint32_t saiBaseAddr, sai_reset_type_t type); /*! * @brief Resets the Rx module. * * There are two kinds of resets: Software reset and FIFO reset. * Software reset: resets all transmitter internal logic, including the bit clock generation, * status flags and FIFO pointers. It does not reset the configuration registers. * FIFO reset: synchronizes the FIFO write pointer to the same value as the FIFO read pointer. * This empties the FIFO contents and is to be used after the Transmit FIFO Error Flag is set, * and before the FIFO is re-initialized and the Error Flag is cleared. * @param saiBaseAddr Register base address of SAI module. * @param type SAI reset type. */ void SAI_HAL_RxSetReset(uint32_t saiBaseAddr, sai_reset_type_t type); /*! * @brief Sets the Tx mask word of the frame. * * Each bit number represent the mask word index. For example, 0 represents mask the 0th word, 3 * represents mask 0th and 1st word. The TMR register can be different from frame to frame. If the * user wants a mono audio, set the mask to 0/1. * @param saiBaseAddr Register base address of SAI module. * @param mask Which bits need to be masked in a frame. */ static inline void SAI_HAL_TxSetWordMask(uint32_t saiBaseAddr, uint32_t mask) { BW_I2S_TMR_TWM(saiBaseAddr, mask); } /*! * @brief Sets the Rx mask word of the frame. * * Each bit number represent the mask word index. For example, 0 represents mask the 0th word, 3 * represents mask 0th and 1st word. The TMR register can be different from frame to frame. If the * user wants a mono audio, set the mask to 0/1. * @param saiBaseAddr Register base address of SAI module. * @param mask Which bits need to be masked in a frame. */ static inline void SAI_HAL_RxSetWordMask(uint32_t saiBaseAddr, uint32_t mask) { BW_I2S_RMR_RWM(saiBaseAddr, mask); } /*! * @brief Sets the Tx FIFO channel. * * A SAI saiBaseAddr includes a Tx and an Rx. Each has several channels according to * different platforms. A channel means a path for the audio data input/output. * @param saiBaseAddr Register base address of SAI module. * @param fifo_channel FIFO channel number. */ static inline void SAI_HAL_TxSetDataChn(uint32_t saiBaseAddr, uint8_t fifo_channel) { BW_I2S_TCR3_TCE(saiBaseAddr, 1u << fifo_channel); } /*! * @brief Sets the Rx FIFO channel. * * A SAI saiBaseAddr includes a Tx and a Rx. Each has several channels according to * different platforms. A channel means a path for the audio data input/output. * @param saiBaseAddr Register base address of SAI module. * @param fifo_channel FIFO channel number. */ static inline void SAI_HAL_RxSetDataChn(uint32_t saiBaseAddr, uint8_t fifo_channel) { BW_I2S_RCR3_RCE(saiBaseAddr, 1u << fifo_channel); } /*! * @brief Sets the running mode of the Tx. There is a debug mode, stop mode, and a normal mode. * * This function can set the working mode of the SAI saiBaseAddr. Stop mode is always * used in low power cases, and the debug mode disables the SAI after the current * transmit/receive is completed. * @param saiBaseAddr Register base address of SAI module. * @param run_mode SAI running mode. * @param enable Enable or disable a mode. */ void SAI_HAL_TxSetRunModeCmd(uint32_t saiBaseAddr, sai_run_mode_t run_mode, bool enable); /*! * @brief Sets the running mode of the Rx. There is a debug mode, stop mode, and a normal mode. * * This function can set the working mode of the SAI saiBaseAddr. Stop mode is always * used in low power cases, and the debug mode disables the SAI after the current * transmit/receive is completed. * @param saiBaseAddr Register base address of SAI module. * @param run_mode SAI running mode. * @param enable Enable or disable a mode. */ void SAI_HAL_RxSetRunModeCmd(uint32_t saiBaseAddr, sai_run_mode_t run_mode, bool enable); /*! * @brief Configures at which word the start of word flag is set in the Tx. * * @param saiBaseAddr Register base address of SAI module. * @param index Which word triggers word start flag. */ static inline void SAI_HAL_TxSetWordStartIndex(uint32_t saiBaseAddr,uint32_t index) { assert(index <= FSL_FEATURE_SAI_MAX_WORDS_PER_FRAME); BW_I2S_TCR3_WDFL(saiBaseAddr, index -1); } /*! * @brief Configures at which word the start of word flag is set in the Tx. * * @param saiBaseAddr Register base address of SAI module. * @param index Which word triggers word start flag. */ static inline void SAI_HAL_RxSetWordStartIndex(uint32_t saiBaseAddr,uint32_t index) { assert(index <= FSL_FEATURE_SAI_MAX_WORDS_PER_FRAME); BW_I2S_RCR3_WDFL(saiBaseAddr, index -1); } /*! * @brief Gets the state of the flags in the TCSR. * @param saiBaseAddr Register base address of SAI module. * @param flag State flag type, it can be FIFO error, FIFO warning and so on. * @return True if detect word start otherwise false. */ bool SAI_HAL_TxGetStateFlag(uint32_t saiBaseAddr, sai_state_flag_t flag); /*! * @brief Gets the state of the flags in the RCSR. * @param saiBaseAddr Register base address of SAI module. * @param flag State flag type, it can be FIFO error, FIFO warning and so on. * @return True if detect word start otherwise false. */ bool SAI_HAL_RxGetStateFlag(uint32_t saiBaseAddr, sai_state_flag_t flag); /*! * @brief Receives the data from the FIFO. * @param saiBaseAddr Register base address of SAI module. * @param rx_channel Rx FIFO channel. * @param data Pointer to the address to be written in. */ static inline uint32_t SAI_HAL_ReceiveData(uint32_t saiBaseAddr, uint32_t rx_channel) { assert(rx_channel < FSL_FEATURE_SAI_CHANNEL_COUNT); return HW_I2S_RDRn_RD(saiBaseAddr, rx_channel); } /*! * @brief Transmits data to the FIFO. * @param saiBaseAddr Register base address of SAI module. * @param tx_channel Tx FIFO channel. * @param data Data value which needs to be written into FIFO. */ static inline void SAI_HAL_SendData(uint32_t saiBaseAddr, uint32_t tx_channel, uint32_t data) { assert(tx_channel < FSL_FEATURE_SAI_CHANNEL_COUNT); HW_I2S_TDRn_WR(saiBaseAddr,tx_channel,data); } /*! * @brief Uses blocking to receive data. * @param saiBaseAddr The SAI saiBaseAddr. * @param rx_channel Rx FIFO channel. * @return Received data. */ uint32_t SAI_HAL_ReceiveDataBlocking(uint32_t saiBaseAddr, uint32_t rx_channel); /*! * @brief Uses blocking to send data. * @param saiBaseAddr The SAI saiBaseAddr. * @param tx_channel Tx FIFO channel. * @param data Data value which needs to be written into FIFO. */ void SAI_HAL_SendDataBlocking(uint32_t saiBaseAddr, uint32_t tx_channel, uint32_t data); #if FSL_FEATURE_SAI_HAS_ON_DEMAND_MODE /*! * @brief Tx on-demand mode setting. * * When set, the frame sync is generated internally. A frame sync is only generated when the * FIFO warning flag is clear. * @param saiBaseAddr Register base address of SAI module. * @param enable True means on demand mode enable, false means disable. */ static inline void SAI_HAL_TxSetOndemandCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_TCR4_ONDEM(saiBaseAddr, enable); } /*! * @brief Rx on-demand mode setting. * * When set, the frame sync is generated internally. A frame sync is only generated when the * FIFO warning flag is clear. * @param saiBaseAddr Register base address of SAI module. * @param enable True means on demand mode enable, false means disable. */ static inline void SAI_HAL_RxSetOndemandCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_RCR4_ONDEM(saiBaseAddr, enable); } #endif #if FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR /*! * @brief Tx FIFO continues on error. * * Configures when the SAI continues transmitting after a FIFO error has been detected. * @param saiBaseAddr Register base address of SAI module. * @param enable True means on demand mode enable, false means disable. */ static inline void SAI_HAL_TxSetFIFOErrorContinueCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_TCR4_FCONT(saiBaseAddr, enable); } /*! * @brief Rx FIFO continues on error. * * Configures when the SAI continues transmitting after a FIFO error has been detected. * @param saiBaseAddr Register base address of SAI module. * @param enable True means on demand mode enable, false means disable. */ static inline void SAI_HAL_RxSetFIFOErrorContinueCmd(uint32_t saiBaseAddr, bool enable) { BW_I2S_RCR4_FCONT(saiBaseAddr, enable); } #endif #if FSL_FEATURE_SAI_HAS_FIFO_PACKING /*! * @brief Tx FIFO packing mode setting. * * Enables packing 8-bit data or 16-bit data into each 32-bit FIFO word. If the word size is * greater than 8-bit or 16-bit, only the first 8-bit or 16-bits are loaded from the FIFO. * The first word in each frame always starts with a new 32-bit FIFO word and the first bit shifted * must be configured within the first packed word. When FIFO packing is enabled, the FIFO write * pointer only increments when the full 32-bit FIFO word has been written by software. * @param saiBaseAddr Register base address of SAI module. * @param mode FIFO packing mode. */ static inline void SAI_HAL_TxSetFIFOPackingMode(uint32_t saiBaseAddr, sai_fifo_packing_t mode) { BW_I2S_TCR4_FPACK(saiBaseAddr,mode); } /*! * @brief Rx FIFO packing mode setting. * * Enables packing 8-bit data or 16-bit data into each 32-bit FIFO word. If the word size is * greater than 8-bit or 16-bit, only the first 8-bit or 16-bits are loaded from the FIFO. * The first word in each frame always starts with a new 32-bit FIFO word and the first bit shifted * must be configured within the first packed word. When FIFO packing is enabled, the FIFO write * pointer only increments when the full 32-bit FIFO word has been written by software. * @param saiBaseAddr Register base address of SAI module. * @param mode FIFO packing mode. */ static inline void SAI_HAL_RxSetFIFOPackingMode(uint32_t saiBaseAddr, sai_fifo_packing_t mode) { BW_I2S_RCR4_FPACK(saiBaseAddr,mode); } #endif #if defined(__cplusplus) } #endif /*! @} */ #endif /* __FSL_SAI_HAL_H__ */ /******************************************************************************* * EOF *******************************************************************************/