rt-thread/bsp/imxrt/libraries/MIMXRT1170/MIMXRT1176/drivers/fsl_sai.c

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/*
* Copyright (c) 2016, Freescale Semiconductor, Inc.
* Copyright 2016-2021 NXP
* All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include "fsl_sai.h"
/* Component ID definition, used by tools. */
#ifndef FSL_COMPONENT_ID
#define FSL_COMPONENT_ID "platform.drivers.sai"
#endif
/*******************************************************************************
* Definitations
******************************************************************************/
/*! @brief _sai_transfer_state sai transfer state.*/
enum
{
kSAI_Busy = 0x0U, /*!< SAI is busy */
kSAI_Idle, /*!< Transfer is done. */
kSAI_Error /*!< Transfer error occurred. */
};
/*! @brief Typedef for sai tx interrupt handler. */
typedef void (*sai_tx_isr_t)(I2S_Type *base, sai_handle_t *saiHandle);
/*! @brief Typedef for sai rx interrupt handler. */
typedef void (*sai_rx_isr_t)(I2S_Type *base, sai_handle_t *saiHandle);
/*! @brief check flag avalibility */
#define IS_SAI_FLAG_SET(reg, flag) (((reg) & ((uint32_t)flag)) != 0UL)
/*******************************************************************************
* Prototypes
******************************************************************************/
/*!
* @brief sai get rx enabled interrupt status.
*
*
* @param base SAI base pointer.
* @param enableFlag enable flag to check.
* @param statusFlag status flag to check.
*/
static bool SAI_RxGetEnabledInterruptStatus(I2S_Type *base, uint32_t enableFlag, uint32_t statusFlag);
/*!
* @brief sai get tx enabled interrupt status.
*
*
* @param base SAI base pointer.
* @param enableFlag enable flag to check.
* @param statusFlag status flag to check.
*/
static bool SAI_TxGetEnabledInterruptStatus(I2S_Type *base, uint32_t enableFlag, uint32_t statusFlag);
/*!
* @brief Set the master clock divider.
*
* This API will compute the master clock divider according to master clock frequency and master
* clock source clock source frequency.
*
* @param base SAI base pointer.
* @param mclk_Hz Mater clock frequency in Hz.
* @param mclkSrcClock_Hz Master clock source frequency in Hz.
*/
static bool SAI_TxGetEnabledInterruptStatus(I2S_Type *base, uint32_t enableFlag, uint32_t statusFlag);
#if ((defined(FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER) && (FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER)) || \
(defined(FSL_FEATURE_SAI_HAS_MCR_MCLK_POST_DIV) && (FSL_FEATURE_SAI_HAS_MCR_MCLK_POST_DIV)))
/*!
* @brief Set the master clock divider.
*
* This API will compute the master clock divider according to master clock frequency and master
* clock source clock source frequency.
*
* @param base SAI base pointer.
* @param mclk_Hz Mater clock frequency in Hz.
* @param mclkSrcClock_Hz Master clock source frequency in Hz.
*/
static void SAI_SetMasterClockDivider(I2S_Type *base, uint32_t mclk_Hz, uint32_t mclkSrcClock_Hz);
#endif /* FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER */
/*!
* @brief Get the instance number for SAI.
*
* @param base SAI base pointer.
*/
static uint32_t SAI_GetInstance(I2S_Type *base);
/*!
* @brief sends a piece of data in non-blocking way.
*
* @param base SAI base pointer
* @param channel start channel number.
* @param channelMask enabled channels mask.
* @param endChannel end channel numbers.
* @param bitWidth How many bits in a audio word, usually 8/16/24/32 bits.
* @param buffer Pointer to the data to be written.
* @param size Bytes to be written.
*/
static void SAI_WriteNonBlocking(I2S_Type *base,
uint32_t channel,
uint32_t channelMask,
uint32_t endChannel,
uint8_t bitWidth,
uint8_t *buffer,
uint32_t size);
/*!
* @brief Receive a piece of data in non-blocking way.
*
* @param base SAI base pointer
* @param channel start channel number.
* @param channelMask enabled channels mask.
* @param endChannel end channel numbers.
* @param bitWidth How many bits in a audio word, usually 8/16/24/32 bits.
* @param buffer Pointer to the data to be read.
* @param size Bytes to be read.
*/
static void SAI_ReadNonBlocking(I2S_Type *base,
uint32_t channel,
uint32_t channelMask,
uint32_t endChannel,
uint8_t bitWidth,
uint8_t *buffer,
uint32_t size);
/*!
* @brief Get classic I2S mode configurations.
*
* @param config transceiver configurations
* @param bitWidth audio data bitWidth.
* @param mode audio data channel
* @param saiChannelMask channel mask value to enable
*/
static void SAI_GetCommonConfig(sai_transceiver_t *config,
sai_word_width_t bitWidth,
sai_mono_stereo_t mode,
uint32_t saiChannelMask);
/*******************************************************************************
* Variables
******************************************************************************/
/* Base pointer array */
static I2S_Type *const s_saiBases[] = I2S_BASE_PTRS;
/*!@brief SAI handle pointer */
static sai_handle_t *s_saiHandle[ARRAY_SIZE(s_saiBases)][2];
/* IRQ number array */
static const IRQn_Type s_saiTxIRQ[] = I2S_TX_IRQS;
static const IRQn_Type s_saiRxIRQ[] = I2S_RX_IRQS;
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/* Clock name array */
static const clock_ip_name_t s_saiClock[] = SAI_CLOCKS;
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
/*! @brief Pointer to tx IRQ handler for each instance. */
static sai_tx_isr_t s_saiTxIsr;
/*! @brief Pointer to tx IRQ handler for each instance. */
static sai_rx_isr_t s_saiRxIsr;
/*******************************************************************************
* Code
******************************************************************************/
static bool SAI_RxGetEnabledInterruptStatus(I2S_Type *base, uint32_t enableFlag, uint32_t statusFlag)
{
uint32_t rcsr = base->RCSR;
return IS_SAI_FLAG_SET(rcsr, enableFlag) && IS_SAI_FLAG_SET(rcsr, statusFlag);
}
static bool SAI_TxGetEnabledInterruptStatus(I2S_Type *base, uint32_t enableFlag, uint32_t statusFlag)
{
uint32_t tcsr = base->TCSR;
return IS_SAI_FLAG_SET(tcsr, enableFlag) && IS_SAI_FLAG_SET(tcsr, statusFlag);
}
#if ((defined(FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER) && (FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER)) || \
(defined(FSL_FEATURE_SAI_HAS_MCR_MCLK_POST_DIV) && (FSL_FEATURE_SAI_HAS_MCR_MCLK_POST_DIV)))
static void SAI_SetMasterClockDivider(I2S_Type *base, uint32_t mclk_Hz, uint32_t mclkSrcClock_Hz)
{
assert(mclk_Hz <= mclkSrcClock_Hz);
uint32_t sourceFreq = mclkSrcClock_Hz / 100U; /*In order to prevent overflow */
uint32_t targetFreq = mclk_Hz / 100U; /*In order to prevent overflow */
#if FSL_FEATURE_SAI_HAS_MCR_MCLK_POST_DIV
uint32_t postDivider = sourceFreq / targetFreq;
/* if source equal to target, then disable divider */
if (postDivider == 1U)
{
base->MCR &= ~I2S_MCR_DIVEN_MASK;
}
else
{
base->MCR = (base->MCR & (~I2S_MCR_DIV_MASK)) | I2S_MCR_DIV(postDivider / 2U - 1U) | I2S_MCR_DIVEN_MASK;
}
#endif
#if FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER
uint16_t fract, divide;
uint32_t remaind = 0;
uint32_t current_remainder = 0xFFFFFFFFU;
uint16_t current_fract = 0;
uint16_t current_divide = 0;
uint32_t mul_freq = 0;
uint32_t max_fract = 256;
/* Compute the max fract number */
max_fract = targetFreq * 4096U / sourceFreq + 1U;
if (max_fract > 256U)
{
max_fract = 256U;
}
/* Looking for the closet frequency */
for (fract = 1; fract < max_fract; fract++)
{
mul_freq = sourceFreq * fract;
remaind = mul_freq % targetFreq;
divide = (uint16_t)(mul_freq / targetFreq);
/* Find the exactly frequency */
if (remaind == 0U)
{
current_fract = fract;
current_divide = (uint16_t)(mul_freq / targetFreq);
break;
}
/* Closer to next one, set the closest to next data */
if (remaind > mclk_Hz / 2U)
{
remaind = targetFreq - remaind;
divide += 1U;
}
/* Update the closest div and fract */
if (remaind < current_remainder)
{
current_fract = fract;
current_divide = divide;
current_remainder = remaind;
}
}
/* Fill the computed fract and divider to registers */
base->MDR = I2S_MDR_DIVIDE(current_divide - 1UL) | I2S_MDR_FRACT(current_fract - 1UL);
/* Waiting for the divider updated */
while ((base->MCR & I2S_MCR_DUF_MASK) != 0UL)
{
}
#endif
}
#endif /* FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER */
static uint32_t SAI_GetInstance(I2S_Type *base)
{
uint32_t instance;
/* Find the instance index from base address mappings. */
for (instance = 0; instance < ARRAY_SIZE(s_saiBases); instance++)
{
if (s_saiBases[instance] == base)
{
break;
}
}
assert(instance < ARRAY_SIZE(s_saiBases));
return instance;
}
static void SAI_WriteNonBlocking(I2S_Type *base,
uint32_t channel,
uint32_t channelMask,
uint32_t endChannel,
uint8_t bitWidth,
uint8_t *buffer,
uint32_t size)
{
uint32_t i = 0, j = 0U;
uint8_t m = 0;
uint8_t bytesPerWord = bitWidth / 8U;
uint32_t data = 0;
uint32_t temp = 0;
for (i = 0; i < size / bytesPerWord; i++)
{
for (j = channel; j <= endChannel; j++)
{
if (IS_SAI_FLAG_SET((1UL << j), channelMask))
{
for (m = 0; m < bytesPerWord; m++)
{
temp = (uint32_t)(*buffer);
data |= (temp << (8U * m));
buffer++;
}
base->TDR[j] = data;
data = 0;
}
}
}
}
static void SAI_ReadNonBlocking(I2S_Type *base,
uint32_t channel,
uint32_t channelMask,
uint32_t endChannel,
uint8_t bitWidth,
uint8_t *buffer,
uint32_t size)
{
uint32_t i = 0, j = 0;
uint8_t m = 0;
uint8_t bytesPerWord = bitWidth / 8U;
uint32_t data = 0;
for (i = 0; i < size / bytesPerWord; i++)
{
for (j = channel; j <= endChannel; j++)
{
if (IS_SAI_FLAG_SET((1UL << j), channelMask))
{
data = base->RDR[j];
for (m = 0; m < bytesPerWord; m++)
{
*buffer = (uint8_t)(data >> (8U * m)) & 0xFFU;
buffer++;
}
}
}
}
}
static void SAI_GetCommonConfig(sai_transceiver_t *config,
sai_word_width_t bitWidth,
sai_mono_stereo_t mode,
uint32_t saiChannelMask)
{
assert(NULL != config);
assert(saiChannelMask != 0U);
(void)memset(config, 0, sizeof(sai_transceiver_t));
config->channelMask = (uint8_t)saiChannelMask;
/* sync mode default configurations */
config->syncMode = kSAI_ModeAsync;
/* master mode default */
config->masterSlave = kSAI_Master;
/* bit default configurations */
config->bitClock.bclkSrcSwap = false;
config->bitClock.bclkInputDelay = false;
config->bitClock.bclkPolarity = kSAI_SampleOnRisingEdge;
config->bitClock.bclkSource = kSAI_BclkSourceMclkDiv;
/* frame sync default configurations */
config->frameSync.frameSyncWidth = (uint8_t)bitWidth;
config->frameSync.frameSyncEarly = true;
#if defined(FSL_FEATURE_SAI_HAS_FRAME_SYNC_ON_DEMAND) && FSL_FEATURE_SAI_HAS_FRAME_SYNC_ON_DEMAND
config->frameSync.frameSyncGenerateOnDemand = false;
#endif
config->frameSync.frameSyncPolarity = kSAI_PolarityActiveLow;
/* serial data default configurations */
#if defined(FSL_FEATURE_SAI_HAS_CHANNEL_MODE) && FSL_FEATURE_SAI_HAS_CHANNEL_MODE
config->serialData.dataMode = kSAI_DataPinStateOutputZero;
#endif
config->serialData.dataOrder = kSAI_DataMSB;
config->serialData.dataWord0Length = (uint8_t)bitWidth;
config->serialData.dataWordLength = (uint8_t)bitWidth;
config->serialData.dataWordNLength = (uint8_t)bitWidth;
config->serialData.dataFirstBitShifted = (uint8_t)bitWidth;
config->serialData.dataWordNum = 2U;
config->serialData.dataMaskedWord = (uint32_t)mode;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
/* fifo configurations */
config->fifo.fifoWatermark = (uint8_t)((uint32_t)FSL_FEATURE_SAI_FIFO_COUNT / 2U);
#endif
#if defined(FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR) && FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR
config->fifo.fifoContinueOneError = true;
#endif
}
/*!
* brief Initializes the SAI Tx peripheral.
*
* deprecated Do not use this function. It has been superceded by @ref SAI_Init
*
* Ungates the SAI clock, resets the module, and configures SAI Tx with a configuration structure.
* The configuration structure can be custom filled or set with default values by
* SAI_TxGetDefaultConfig().
*
* note This API should be called at the beginning of the application to use
* the SAI driver. Otherwise, accessing the SAIM module can cause a hard fault
* because the clock is not enabled.
*
* param base SAI base pointer
* param config SAI configuration structure.
*/
void SAI_TxInit(I2S_Type *base, const sai_config_t *config)
{
uint32_t val = 0;
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/* Enable the SAI clock */
(void)CLOCK_EnableClock(s_saiClock[SAI_GetInstance(base)]);
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
#if defined(FSL_FEATURE_SAI_HAS_MCR) && (FSL_FEATURE_SAI_HAS_MCR)
#if !(defined(FSL_FEATURE_SAI_HAS_NO_MCR_MICS) && (FSL_FEATURE_SAI_HAS_NO_MCR_MICS))
/* Master clock source setting */
val = (base->MCR & ~I2S_MCR_MICS_MASK);
base->MCR = (val | I2S_MCR_MICS(config->mclkSource));
#endif
/* Configure Master clock output enable */
val = (base->MCR & ~I2S_MCR_MOE_MASK);
base->MCR = (val | I2S_MCR_MOE(config->mclkOutputEnable));
#endif /* FSL_FEATURE_SAI_HAS_MCR */
SAI_TxReset(base);
/* Configure audio protocol */
if (config->protocol == kSAI_BusLeftJustified)
{
base->TCR2 |= I2S_TCR2_BCP_MASK;
base->TCR3 &= ~I2S_TCR3_WDFL_MASK;
base->TCR4 = I2S_TCR4_MF(1U) | I2S_TCR4_SYWD(31U) | I2S_TCR4_FSE(0U) | I2S_TCR4_FSP(0U) | I2S_TCR4_FRSZ(1U);
}
else if (config->protocol == kSAI_BusRightJustified)
{
base->TCR2 |= I2S_TCR2_BCP_MASK;
base->TCR3 &= ~I2S_TCR3_WDFL_MASK;
base->TCR4 = I2S_TCR4_MF(1U) | I2S_TCR4_SYWD(31U) | I2S_TCR4_FSE(0U) | I2S_TCR4_FSP(0U) | I2S_TCR4_FRSZ(1U);
}
else if (config->protocol == kSAI_BusI2S)
{
base->TCR2 |= I2S_TCR2_BCP_MASK;
base->TCR3 &= ~I2S_TCR3_WDFL_MASK;
base->TCR4 = I2S_TCR4_MF(1U) | I2S_TCR4_SYWD(31U) | I2S_TCR4_FSE(1U) | I2S_TCR4_FSP(1U) | I2S_TCR4_FRSZ(1U);
}
else if (config->protocol == kSAI_BusPCMA)
{
base->TCR2 &= ~I2S_TCR2_BCP_MASK;
base->TCR3 &= ~I2S_TCR3_WDFL_MASK;
base->TCR4 = I2S_TCR4_MF(1U) | I2S_TCR4_SYWD(0U) | I2S_TCR4_FSE(1U) | I2S_TCR4_FSP(0U) | I2S_TCR4_FRSZ(1U);
}
else
{
base->TCR2 &= ~I2S_TCR2_BCP_MASK;
base->TCR3 &= ~I2S_TCR3_WDFL_MASK;
base->TCR4 = I2S_TCR4_MF(1U) | I2S_TCR4_SYWD(0U) | I2S_TCR4_FSE(0U) | I2S_TCR4_FSP(0U) | I2S_TCR4_FRSZ(1U);
}
/* Set master or slave */
if (config->masterSlave == kSAI_Master)
{
base->TCR2 |= I2S_TCR2_BCD_MASK;
base->TCR4 |= I2S_TCR4_FSD_MASK;
/* Bit clock source setting */
val = base->TCR2 & (~I2S_TCR2_MSEL_MASK);
base->TCR2 = (val | I2S_TCR2_MSEL(config->bclkSource));
}
else
{
base->TCR2 &= ~I2S_TCR2_BCD_MASK;
base->TCR4 &= ~I2S_TCR4_FSD_MASK;
}
/* Set Sync mode */
if (config->syncMode == kSAI_ModeAsync)
{
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(0U));
}
if (config->syncMode == kSAI_ModeSync)
{
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(1U));
/* If sync with Rx, should set Rx to async mode */
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(0U));
}
#if defined(FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI) && (FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI)
if (config->syncMode == kSAI_ModeSyncWithOtherTx)
{
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(2U));
}
if (config->syncMode == kSAI_ModeSyncWithOtherRx)
{
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(3U));
}
#endif /* FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI */
#if defined(FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR) && FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR
SAI_TxSetFIFOErrorContinue(base, true);
#endif /* FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR */
}
/*!
* brief Initializes the SAI Rx peripheral.
*
* deprecated Do not use this function. It has been superceded by @ref SAI_Init
*
* Ungates the SAI clock, resets the module, and configures the SAI Rx with a configuration structure.
* The configuration structure can be custom filled or set with default values by
* SAI_RxGetDefaultConfig().
*
* note This API should be called at the beginning of the application to use
* the SAI driver. Otherwise, accessing the SAI module can cause a hard fault
* because the clock is not enabled.
*
* param base SAI base pointer
* param config SAI configuration structure.
*/
void SAI_RxInit(I2S_Type *base, const sai_config_t *config)
{
uint32_t val = 0;
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/* Enable SAI clock first. */
(void)CLOCK_EnableClock(s_saiClock[SAI_GetInstance(base)]);
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
#if defined(FSL_FEATURE_SAI_HAS_MCR) && (FSL_FEATURE_SAI_HAS_MCR)
#if !(defined(FSL_FEATURE_SAI_HAS_NO_MCR_MICS) && (FSL_FEATURE_SAI_HAS_NO_MCR_MICS))
/* Master clock source setting */
val = (base->MCR & ~I2S_MCR_MICS_MASK);
base->MCR = (val | I2S_MCR_MICS(config->mclkSource));
#endif
/* Configure Master clock output enable */
val = (base->MCR & ~I2S_MCR_MOE_MASK);
base->MCR = (val | I2S_MCR_MOE(config->mclkOutputEnable));
#endif /* FSL_FEATURE_SAI_HAS_MCR */
SAI_RxReset(base);
/* Configure audio protocol */
if (config->protocol == kSAI_BusLeftJustified)
{
base->RCR2 |= I2S_RCR2_BCP_MASK;
base->RCR3 &= ~I2S_RCR3_WDFL_MASK;
base->RCR4 = I2S_RCR4_MF(1U) | I2S_RCR4_SYWD(31U) | I2S_RCR4_FSE(0U) | I2S_RCR4_FSP(0U) | I2S_RCR4_FRSZ(1U);
}
else if (config->protocol == kSAI_BusRightJustified)
{
base->RCR2 |= I2S_RCR2_BCP_MASK;
base->RCR3 &= ~I2S_RCR3_WDFL_MASK;
base->RCR4 = I2S_RCR4_MF(1U) | I2S_RCR4_SYWD(31U) | I2S_RCR4_FSE(0U) | I2S_RCR4_FSP(0U) | I2S_RCR4_FRSZ(1U);
}
else if (config->protocol == kSAI_BusI2S)
{
base->RCR2 |= I2S_RCR2_BCP_MASK;
base->RCR3 &= ~I2S_RCR3_WDFL_MASK;
base->RCR4 = I2S_RCR4_MF(1U) | I2S_RCR4_SYWD(31U) | I2S_RCR4_FSE(1U) | I2S_RCR4_FSP(1U) | I2S_RCR4_FRSZ(1U);
}
else if (config->protocol == kSAI_BusPCMA)
{
base->RCR2 &= ~I2S_RCR2_BCP_MASK;
base->RCR3 &= ~I2S_RCR3_WDFL_MASK;
base->RCR4 = I2S_RCR4_MF(1U) | I2S_RCR4_SYWD(0U) | I2S_RCR4_FSE(1U) | I2S_RCR4_FSP(0U) | I2S_RCR4_FRSZ(1U);
}
else
{
base->RCR2 &= ~I2S_RCR2_BCP_MASK;
base->RCR3 &= ~I2S_RCR3_WDFL_MASK;
base->RCR4 = I2S_RCR4_MF(1U) | I2S_RCR4_SYWD(0U) | I2S_RCR4_FSE(0U) | I2S_RCR4_FSP(0U) | I2S_RCR4_FRSZ(1U);
}
/* Set master or slave */
if (config->masterSlave == kSAI_Master)
{
base->RCR2 |= I2S_RCR2_BCD_MASK;
base->RCR4 |= I2S_RCR4_FSD_MASK;
/* Bit clock source setting */
val = base->RCR2 & (~I2S_RCR2_MSEL_MASK);
base->RCR2 = (val | I2S_RCR2_MSEL(config->bclkSource));
}
else
{
base->RCR2 &= ~I2S_RCR2_BCD_MASK;
base->RCR4 &= ~I2S_RCR4_FSD_MASK;
}
/* Set Sync mode */
if (config->syncMode == kSAI_ModeAsync)
{
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(0U));
}
if (config->syncMode == kSAI_ModeSync)
{
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(1U));
/* If sync with Tx, should set Tx to async mode */
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(0U));
}
#if defined(FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI) && (FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI)
if (config->syncMode == kSAI_ModeSyncWithOtherTx)
{
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(2U));
}
if (config->syncMode == kSAI_ModeSyncWithOtherRx)
{
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(3U));
}
#endif /* FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI */
#if defined(FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR) && FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR
SAI_RxSetFIFOErrorContinue(base, true);
#endif /* FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR */
}
/*!
* brief Initializes the SAI peripheral.
*
* This API gates the SAI clock. The SAI module can't operate unless SAI_Init is called to enable the clock.
*
* param base SAI base pointer
*/
void SAI_Init(I2S_Type *base)
{
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/* Enable the SAI clock */
(void)CLOCK_EnableClock(s_saiClock[SAI_GetInstance(base)]);
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
/* disable interrupt and DMA request*/
base->TCSR &=
~(I2S_TCSR_FRIE_MASK | I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK | I2S_TCSR_FRDE_MASK | I2S_TCSR_FWDE_MASK);
base->RCSR &=
~(I2S_RCSR_FRIE_MASK | I2S_RCSR_FWIE_MASK | I2S_RCSR_FEIE_MASK | I2S_RCSR_FRDE_MASK | I2S_RCSR_FWDE_MASK);
#else
/* disable interrupt and DMA request*/
base->TCSR &= ~(I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK | I2S_TCSR_FWDE_MASK);
base->RCSR &= ~(I2S_RCSR_FWIE_MASK | I2S_RCSR_FEIE_MASK | I2S_RCSR_FWDE_MASK);
#endif
}
/*!
* brief De-initializes the SAI peripheral.
*
* This API gates the SAI clock. The SAI module can't operate unless SAI_TxInit
* or SAI_RxInit is called to enable the clock.
*
* param base SAI base pointer
*/
void SAI_Deinit(I2S_Type *base)
{
SAI_TxEnable(base, false);
SAI_RxEnable(base, false);
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
(void)CLOCK_DisableClock(s_saiClock[SAI_GetInstance(base)]);
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
}
/*!
* brief Sets the SAI Tx configuration structure to default values.
*
* deprecated Do not use this function. It has been superceded by @ref
* SAI_GetClassicI2SConfig, SAI_GetLeftJustifiedConfig,SAI_GetRightJustifiedConfig, SAI_GetDSPConfig,SAI_GetTDMConfig
*
* This API initializes the configuration structure for use in SAI_TxConfig().
* The initialized structure can remain unchanged in SAI_TxConfig(), or it can be modified
* before calling SAI_TxConfig().
* This is an example.
code
sai_config_t config;
SAI_TxGetDefaultConfig(&config);
endcode
*
* param config pointer to master configuration structure
*/
void SAI_TxGetDefaultConfig(sai_config_t *config)
{
/* Initializes the configure structure to zero. */
(void)memset(config, 0, sizeof(*config));
config->bclkSource = kSAI_BclkSourceMclkDiv;
config->masterSlave = kSAI_Master;
#if defined(FSL_FEATURE_SAI_HAS_MCR) && (FSL_FEATURE_SAI_HAS_MCR)
config->mclkOutputEnable = true;
#if !(defined(FSL_FEATURE_SAI_HAS_NO_MCR_MICS) && (FSL_FEATURE_SAI_HAS_NO_MCR_MICS))
config->mclkSource = kSAI_MclkSourceSysclk;
#endif
#endif /* FSL_FEATURE_SAI_HAS_MCR */
config->protocol = kSAI_BusI2S;
config->syncMode = kSAI_ModeAsync;
}
/*!
* brief Sets the SAI Rx configuration structure to default values.
*
* deprecated Do not use this function. It has been superceded by @ref
* SAI_GetClassicI2SConfig,SAI_GetLeftJustifiedConfig,SAI_GetRightJustifiedConfig,SAI_GetDSPConfig,SAI_GetTDMConfig
*
* This API initializes the configuration structure for use in SAI_RxConfig().
* The initialized structure can remain unchanged in SAI_RxConfig() or it can be modified
* before calling SAI_RxConfig().
* This is an example.
code
sai_config_t config;
SAI_RxGetDefaultConfig(&config);
endcode
*
* param config pointer to master configuration structure
*/
void SAI_RxGetDefaultConfig(sai_config_t *config)
{
/* Initializes the configure structure to zero. */
(void)memset(config, 0, sizeof(*config));
config->bclkSource = kSAI_BclkSourceMclkDiv;
config->masterSlave = kSAI_Master;
#if defined(FSL_FEATURE_SAI_HAS_MCR) && (FSL_FEATURE_SAI_HAS_MCR)
config->mclkOutputEnable = true;
#if !(defined(FSL_FEATURE_SAI_HAS_NO_MCR_MICS) && (FSL_FEATURE_SAI_HAS_NO_MCR_MICS))
config->mclkSource = kSAI_MclkSourceSysclk;
#endif
#endif /* FSL_FEATURE_SAI_HAS_MCR */
config->protocol = kSAI_BusI2S;
config->syncMode = kSAI_ModeSync;
}
/*!
* brief Resets the SAI Tx.
*
* This function enables the software reset and FIFO reset of SAI Tx. After reset, clear the reset bit.
*
* param base SAI base pointer
*/
void SAI_TxReset(I2S_Type *base)
{
/* Set the software reset and FIFO reset to clear internal state */
base->TCSR = I2S_TCSR_SR_MASK | I2S_TCSR_FR_MASK;
/* Clear software reset bit, this should be done by software */
base->TCSR &= ~I2S_TCSR_SR_MASK;
/* Reset all Tx register values */
base->TCR2 = 0;
base->TCR3 = 0;
base->TCR4 = 0;
base->TCR5 = 0;
base->TMR = 0;
}
/*!
* brief Resets the SAI Rx.
*
* This function enables the software reset and FIFO reset of SAI Rx. After reset, clear the reset bit.
*
* param base SAI base pointer
*/
void SAI_RxReset(I2S_Type *base)
{
/* Set the software reset and FIFO reset to clear internal state */
base->RCSR = I2S_RCSR_SR_MASK | I2S_RCSR_FR_MASK;
/* Clear software reset bit, this should be done by software */
base->RCSR &= ~I2S_RCSR_SR_MASK;
/* Reset all Rx register values */
base->RCR2 = 0;
base->RCR3 = 0;
base->RCR4 = 0;
base->RCR5 = 0;
base->RMR = 0;
}
/*!
* brief Enables/disables the SAI Tx.
*
* param base SAI base pointer
* param enable True means enable SAI Tx, false means disable.
*/
void SAI_TxEnable(I2S_Type *base, bool enable)
{
if (enable)
{
/* If clock is sync with Rx, should enable RE bit. */
if (((base->TCR2 & I2S_TCR2_SYNC_MASK) >> I2S_TCR2_SYNC_SHIFT) == 0x1U)
{
base->RCSR = ((base->RCSR & 0xFFE3FFFFU) | I2S_RCSR_RE_MASK);
}
base->TCSR = ((base->TCSR & 0xFFE3FFFFU) | I2S_TCSR_TE_MASK);
/* Also need to clear the FIFO error flag before start */
SAI_TxClearStatusFlags(base, kSAI_FIFOErrorFlag);
}
else
{
/* If Rx not in sync with Tx, then disable Tx, otherwise, shall not disable Tx */
if (((base->RCR2 & I2S_RCR2_SYNC_MASK) >> I2S_RCR2_SYNC_SHIFT) != 0x1U)
{
/* Disable TE bit */
base->TCSR = ((base->TCSR & 0xFFE3FFFFU) & (~I2S_TCSR_TE_MASK));
}
}
}
/*!
* brief Enables/disables the SAI Rx.
*
* param base SAI base pointer
* param enable True means enable SAI Rx, false means disable.
*/
void SAI_RxEnable(I2S_Type *base, bool enable)
{
if (enable)
{
/* If clock is sync with Tx, should enable TE bit. */
if (((base->RCR2 & I2S_RCR2_SYNC_MASK) >> I2S_RCR2_SYNC_SHIFT) == 0x1U)
{
base->TCSR = ((base->TCSR & 0xFFE3FFFFU) | I2S_TCSR_TE_MASK);
}
base->RCSR = ((base->RCSR & 0xFFE3FFFFU) | I2S_RCSR_RE_MASK);
/* Also need to clear the FIFO error flag before start */
SAI_RxClearStatusFlags(base, kSAI_FIFOErrorFlag);
}
else
{
/* If Tx not in sync with Rx, then disable Rx, otherwise, shall not disable Rx */
if (((base->TCR2 & I2S_TCR2_SYNC_MASK) >> I2S_TCR2_SYNC_SHIFT) != 0x1U)
{
/* Disable RE bit */
base->RCSR = ((base->RCSR & 0xFFE3FFFFU) & (~I2S_RCSR_RE_MASK));
}
}
}
/*!
* brief Do software reset or FIFO reset .
*
* FIFO reset means clear all the data in the FIFO, and make the FIFO pointer both to 0.
* Software reset means clear the Tx internal logic, including the bit clock, frame count etc. But software
* reset will not clear any configuration registers like TCR1~TCR5.
* This function will also clear all the error flags such as FIFO error, sync error etc.
*
* param base SAI base pointer
* param type Reset type, FIFO reset or software reset
*/
void SAI_TxSoftwareReset(I2S_Type *base, sai_reset_type_t type)
{
base->TCSR |= (uint32_t)type;
/* Clear the software reset */
base->TCSR &= ~I2S_TCSR_SR_MASK;
}
/*!
* brief Do software reset or FIFO reset .
*
* FIFO reset means clear all the data in the FIFO, and make the FIFO pointer both to 0.
* Software reset means clear the Rx internal logic, including the bit clock, frame count etc. But software
* reset will not clear any configuration registers like RCR1~RCR5.
* This function will also clear all the error flags such as FIFO error, sync error etc.
*
* param base SAI base pointer
* param type Reset type, FIFO reset or software reset
*/
void SAI_RxSoftwareReset(I2S_Type *base, sai_reset_type_t type)
{
base->RCSR |= (uint32_t)type;
/* Clear the software reset */
base->RCSR &= ~I2S_RCSR_SR_MASK;
}
/*!
* brief Set the Tx channel FIFO enable mask.
*
* param base SAI base pointer
* param mask Channel enable mask, 0 means all channel FIFO disabled, 1 means channel 0 enabled,
* 3 means both channel 0 and channel 1 enabled.
*/
void SAI_TxSetChannelFIFOMask(I2S_Type *base, uint8_t mask)
{
base->TCR3 &= ~I2S_TCR3_TCE_MASK;
base->TCR3 |= I2S_TCR3_TCE(mask);
}
/*!
* brief Set the Rx channel FIFO enable mask.
*
* param base SAI base pointer
* param mask Channel enable mask, 0 means all channel FIFO disabled, 1 means channel 0 enabled,
* 3 means both channel 0 and channel 1 enabled.
*/
void SAI_RxSetChannelFIFOMask(I2S_Type *base, uint8_t mask)
{
base->RCR3 &= ~I2S_RCR3_RCE_MASK;
base->RCR3 |= I2S_RCR3_RCE(mask);
}
/*!
* brief Set the Tx data order.
*
* param base SAI base pointer
* param order Data order MSB or LSB
*/
void SAI_TxSetDataOrder(I2S_Type *base, sai_data_order_t order)
{
uint32_t val = (base->TCR4) & (~I2S_TCR4_MF_MASK);
val |= I2S_TCR4_MF(order);
base->TCR4 = val;
}
/*!
* brief Set the Rx data order.
*
* param base SAI base pointer
* param order Data order MSB or LSB
*/
void SAI_RxSetDataOrder(I2S_Type *base, sai_data_order_t order)
{
uint32_t val = (base->RCR4) & (~I2S_RCR4_MF_MASK);
val |= I2S_RCR4_MF(order);
base->RCR4 = val;
}
/*!
* brief Set the Tx data order.
*
* param base SAI base pointer
* param order Data order MSB or LSB
*/
void SAI_TxSetBitClockPolarity(I2S_Type *base, sai_clock_polarity_t polarity)
{
uint32_t val = (base->TCR2) & (~I2S_TCR2_BCP_MASK);
val |= I2S_TCR2_BCP(polarity);
base->TCR2 = val;
}
/*!
* brief Set the Rx data order.
*
* param base SAI base pointer
* param order Data order MSB or LSB
*/
void SAI_RxSetBitClockPolarity(I2S_Type *base, sai_clock_polarity_t polarity)
{
uint32_t val = (base->RCR2) & (~I2S_RCR2_BCP_MASK);
val |= I2S_RCR2_BCP(polarity);
base->RCR2 = val;
}
/*!
* brief Set the Tx data order.
*
* param base SAI base pointer
* param order Data order MSB or LSB
*/
void SAI_TxSetFrameSyncPolarity(I2S_Type *base, sai_clock_polarity_t polarity)
{
uint32_t val = (base->TCR4) & (~I2S_TCR4_FSP_MASK);
val |= I2S_TCR4_FSP(polarity);
base->TCR4 = val;
}
/*!
* brief Set the Rx data order.
*
* param base SAI base pointer
* param order Data order MSB or LSB
*/
void SAI_RxSetFrameSyncPolarity(I2S_Type *base, sai_clock_polarity_t polarity)
{
uint32_t val = (base->RCR4) & (~I2S_RCR4_FSP_MASK);
val |= I2S_RCR4_FSP(polarity);
base->RCR4 = val;
}
#if defined(FSL_FEATURE_SAI_HAS_FIFO_PACKING) && FSL_FEATURE_SAI_HAS_FIFO_PACKING
/*!
* brief Set Tx FIFO packing feature.
*
* param base SAI base pointer.
* param pack FIFO pack type. It is element of sai_fifo_packing_t.
*/
void SAI_TxSetFIFOPacking(I2S_Type *base, sai_fifo_packing_t pack)
{
uint32_t val = base->TCR4;
val &= ~I2S_TCR4_FPACK_MASK;
val |= I2S_TCR4_FPACK(pack);
base->TCR4 = val;
}
/*!
* brief Set Rx FIFO packing feature.
*
* param base SAI base pointer.
* param pack FIFO pack type. It is element of sai_fifo_packing_t.
*/
void SAI_RxSetFIFOPacking(I2S_Type *base, sai_fifo_packing_t pack)
{
uint32_t val = base->RCR4;
val &= ~I2S_RCR4_FPACK_MASK;
val |= I2S_RCR4_FPACK(pack);
base->RCR4 = val;
}
#endif /* FSL_FEATURE_SAI_HAS_FIFO_PACKING */
/*!
* brief Transmitter bit clock rate configurations.
*
* param base SAI base pointer.
* param sourceClockHz, bit clock source frequency.
* param sampleRate audio data sample rate.
* param bitWidth, audio data bitWidth.
* param channelNumbers, audio channel numbers.
*/
void SAI_TxSetBitClockRate(
I2S_Type *base, uint32_t sourceClockHz, uint32_t sampleRate, uint32_t bitWidth, uint32_t channelNumbers)
{
uint32_t tcr2 = base->TCR2;
uint32_t bitClockDiv = 0;
uint32_t bitClockFreq = sampleRate * bitWidth * channelNumbers;
assert(sourceClockHz >= bitClockFreq);
tcr2 &= ~I2S_TCR2_DIV_MASK;
/* need to check the divided bclk, if bigger than target, then divider need to re-calculate. */
bitClockDiv = sourceClockHz / bitClockFreq;
/* for the condition where the source clock is smaller than target bclk */
if (bitClockDiv == 0U)
{
bitClockDiv++;
}
/* recheck the divider if properly or not, to make sure output blck not bigger than target*/
if ((sourceClockHz / bitClockDiv) > bitClockFreq)
{
bitClockDiv++;
}
#if defined(FSL_FEATURE_SAI_HAS_BCLK_BYPASS) && (FSL_FEATURE_SAI_HAS_BCLK_BYPASS)
/* if bclk same with MCLK, bypass the divider */
if (bitClockDiv == 1U)
{
tcr2 |= I2S_TCR2_BYP_MASK;
}
else
#endif
{
tcr2 |= I2S_TCR2_DIV(bitClockDiv / 2U - 1UL);
}
base->TCR2 = tcr2;
}
/*!
* brief Receiver bit clock rate configurations.
*
* param base SAI base pointer.
* param sourceClockHz, bit clock source frequency.
* param sampleRate audio data sample rate.
* param bitWidth, audio data bitWidth.
* param channelNumbers, audio channel numbers.
*/
void SAI_RxSetBitClockRate(
I2S_Type *base, uint32_t sourceClockHz, uint32_t sampleRate, uint32_t bitWidth, uint32_t channelNumbers)
{
uint32_t rcr2 = base->RCR2;
uint32_t bitClockDiv = 0;
uint32_t bitClockFreq = sampleRate * bitWidth * channelNumbers;
assert(sourceClockHz >= bitClockFreq);
rcr2 &= ~I2S_RCR2_DIV_MASK;
/* need to check the divided bclk, if bigger than target, then divider need to re-calculate. */
bitClockDiv = sourceClockHz / bitClockFreq;
/* for the condition where the source clock is smaller than target bclk */
if (bitClockDiv == 0U)
{
bitClockDiv++;
}
/* recheck the divider if properly or not, to make sure output blck not bigger than target*/
if ((sourceClockHz / bitClockDiv) > bitClockFreq)
{
bitClockDiv++;
}
#if defined(FSL_FEATURE_SAI_HAS_BCLK_BYPASS) && (FSL_FEATURE_SAI_HAS_BCLK_BYPASS)
/* if bclk same with MCLK, bypass the divider */
if (bitClockDiv == 1U)
{
rcr2 |= I2S_RCR2_BYP_MASK;
}
else
#endif
{
rcr2 |= I2S_RCR2_DIV(bitClockDiv / 2U - 1UL);
}
base->RCR2 = rcr2;
}
/*!
* brief Transmitter Bit clock configurations.
*
* param base SAI base pointer.
* param masterSlave master or slave.
* param config bit clock other configurations, can be NULL in slave mode.
*/
void SAI_TxSetBitclockConfig(I2S_Type *base, sai_master_slave_t masterSlave, sai_bit_clock_t *config)
{
uint32_t tcr2 = base->TCR2;
if ((masterSlave == kSAI_Master) || (masterSlave == kSAI_Bclk_Master_FrameSync_Slave))
{
assert(config != NULL);
tcr2 &= ~(I2S_TCR2_BCD_MASK | I2S_TCR2_BCP_MASK | I2S_TCR2_BCI_MASK | I2S_TCR2_BCS_MASK | I2S_TCR2_MSEL_MASK);
tcr2 |= I2S_TCR2_BCD(1U) | I2S_TCR2_BCP(config->bclkPolarity) | I2S_TCR2_BCI(config->bclkInputDelay) |
I2S_TCR2_BCS(config->bclkSrcSwap) | I2S_TCR2_MSEL(config->bclkSource);
}
else
{
tcr2 &= ~(I2S_TCR2_BCD_MASK);
tcr2 |= I2S_TCR2_BCP(config->bclkPolarity);
}
base->TCR2 = tcr2;
}
/*!
* brief Receiver Bit clock configurations.
*
* param base SAI base pointer.
* param masterSlave master or slave.
* param config bit clock other configurations, can be NULL in slave mode.
*/
void SAI_RxSetBitclockConfig(I2S_Type *base, sai_master_slave_t masterSlave, sai_bit_clock_t *config)
{
uint32_t rcr2 = base->RCR2;
if ((masterSlave == kSAI_Master) || (masterSlave == kSAI_Bclk_Master_FrameSync_Slave))
{
assert(config != NULL);
rcr2 &= ~(I2S_RCR2_BCD_MASK | I2S_RCR2_BCP_MASK | I2S_RCR2_BCI_MASK | I2S_RCR2_BCS_MASK | I2S_RCR2_MSEL_MASK);
rcr2 |= I2S_RCR2_BCD(1U) | I2S_RCR2_BCP(config->bclkPolarity) | I2S_RCR2_BCI(config->bclkInputDelay) |
I2S_RCR2_BCS(config->bclkSrcSwap) | I2S_RCR2_MSEL(config->bclkSource);
}
else
{
rcr2 &= ~(I2S_RCR2_BCD_MASK);
rcr2 |= I2S_RCR2_BCP(config->bclkPolarity);
}
base->RCR2 = rcr2;
}
#if (defined(FSL_FEATURE_SAI_HAS_MCR) && (FSL_FEATURE_SAI_HAS_MCR)) || \
(defined(FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER) && (FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER))
/*!
* brief Master clock configurations.
*
* param base SAI base pointer.
* param config master clock configurations.
*/
void SAI_SetMasterClockConfig(I2S_Type *base, sai_master_clock_t *config)
{
assert(config != NULL);
#if defined(FSL_FEATURE_SAI_HAS_MCR) && (FSL_FEATURE_SAI_HAS_MCR)
uint32_t val = 0;
#if !(defined(FSL_FEATURE_SAI_HAS_NO_MCR_MICS) && (FSL_FEATURE_SAI_HAS_NO_MCR_MICS))
/* Master clock source setting */
val = (base->MCR & ~I2S_MCR_MICS_MASK);
base->MCR = (val | I2S_MCR_MICS(config->mclkSource));
#endif
/* Configure Master clock output enable */
val = (base->MCR & ~I2S_MCR_MOE_MASK);
base->MCR = (val | I2S_MCR_MOE(config->mclkOutputEnable));
#endif /* FSL_FEATURE_SAI_HAS_MCR */
#if ((defined(FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER) && (FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER)) || \
(defined(FSL_FEATURE_SAI_HAS_MCR_MCLK_POST_DIV) && (FSL_FEATURE_SAI_HAS_MCR_MCLK_POST_DIV)))
/* Check if master clock divider enabled, then set master clock divider */
if (config->mclkOutputEnable)
{
SAI_SetMasterClockDivider(base, config->mclkHz, config->mclkSourceClkHz);
}
#endif /* FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER */
}
#endif
#if FSL_SAI_HAS_FIFO_EXTEND_FEATURE
/*!
* brief SAI transmitter fifo configurations.
*
* param base SAI base pointer.
* param config fifo configurations.
*/
void SAI_TxSetFifoConfig(I2S_Type *base, sai_fifo_t *config)
{
assert(config != NULL);
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
assert(config->fifoWatermark <= (I2S_TCR1_TFW_MASK >> I2S_TCR1_TFW_SHIFT));
#endif
uint32_t tcr4 = base->TCR4;
#if defined(FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE) && FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE
tcr4 &= ~I2S_TCR4_FCOMB_MASK;
tcr4 |= I2S_TCR4_FCOMB(config->fifoCombine);
#endif
#if defined(FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR) && FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR
tcr4 &= ~I2S_TCR4_FCONT_MASK;
/* ERR05144: not set FCONT = 1 when TMR > 0, the transmit shift register may not load correctly that will cause TX
* not work */
if (base->TMR == 0U)
{
tcr4 |= I2S_TCR4_FCONT(config->fifoContinueOneError);
}
#endif
#if defined(FSL_FEATURE_SAI_HAS_FIFO_PACKING) && FSL_FEATURE_SAI_HAS_FIFO_PACKING
tcr4 &= ~I2S_TCR4_FPACK_MASK;
tcr4 |= I2S_TCR4_FPACK(config->fifoPacking);
#endif
base->TCR4 = tcr4;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
base->TCR1 = (base->TCR1 & (~I2S_TCR1_TFW_MASK)) | I2S_TCR1_TFW(config->fifoWatermark);
#endif
}
/*!
* brief SAI receiver fifo configurations.
*
* param base SAI base pointer.
* param config fifo configurations.
*/
void SAI_RxSetFifoConfig(I2S_Type *base, sai_fifo_t *config)
{
assert(config != NULL);
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
assert(config->fifoWatermark <= (I2S_TCR1_TFW_MASK >> I2S_TCR1_TFW_SHIFT));
#endif
uint32_t rcr4 = base->RCR4;
#if defined(FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE) && FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE
rcr4 &= ~I2S_RCR4_FCOMB_MASK;
rcr4 |= I2S_RCR4_FCOMB(config->fifoCombine);
#endif
#if defined(FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR) && FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR
rcr4 &= ~I2S_RCR4_FCONT_MASK;
rcr4 |= I2S_RCR4_FCONT(config->fifoContinueOneError);
#endif
#if defined(FSL_FEATURE_SAI_HAS_FIFO_PACKING) && FSL_FEATURE_SAI_HAS_FIFO_PACKING
rcr4 &= ~I2S_RCR4_FPACK_MASK;
rcr4 |= I2S_RCR4_FPACK(config->fifoPacking);
#endif
base->RCR4 = rcr4;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
base->RCR1 = (base->RCR1 & (~I2S_RCR1_RFW_MASK)) | I2S_RCR1_RFW(config->fifoWatermark);
#endif
}
#endif
/*!
* brief SAI transmitter Frame sync configurations.
*
* param base SAI base pointer.
* param masterSlave master or slave.
* param config frame sync configurations, can be NULL in slave mode.
*/
void SAI_TxSetFrameSyncConfig(I2S_Type *base, sai_master_slave_t masterSlave, sai_frame_sync_t *config)
{
assert(config != NULL);
assert((config->frameSyncWidth - 1UL) <= (I2S_TCR4_SYWD_MASK >> I2S_TCR4_SYWD_SHIFT));
uint32_t tcr4 = base->TCR4;
tcr4 &= ~(I2S_TCR4_FSE_MASK | I2S_TCR4_FSP_MASK | I2S_TCR4_FSD_MASK | I2S_TCR4_SYWD_MASK);
#if defined(FSL_FEATURE_SAI_HAS_FRAME_SYNC_ON_DEMAND) && FSL_FEATURE_SAI_HAS_FRAME_SYNC_ON_DEMAND
tcr4 &= ~I2S_TCR4_ONDEM_MASK;
tcr4 |= I2S_TCR4_ONDEM(config->frameSyncGenerateOnDemand);
#endif
tcr4 |=
I2S_TCR4_FSE(config->frameSyncEarly) | I2S_TCR4_FSP(config->frameSyncPolarity) |
I2S_TCR4_FSD(((masterSlave == kSAI_Master) || (masterSlave == kSAI_Bclk_Slave_FrameSync_Master)) ? 1UL : 0U) |
I2S_TCR4_SYWD(config->frameSyncWidth - 1UL);
base->TCR4 = tcr4;
}
/*!
* brief SAI receiver Frame sync configurations.
*
* param base SAI base pointer.
* param masterSlave master or slave.
* param config frame sync configurations, can be NULL in slave mode.
*/
void SAI_RxSetFrameSyncConfig(I2S_Type *base, sai_master_slave_t masterSlave, sai_frame_sync_t *config)
{
assert(config != NULL);
assert((config->frameSyncWidth - 1UL) <= (I2S_RCR4_SYWD_MASK >> I2S_RCR4_SYWD_SHIFT));
uint32_t rcr4 = base->RCR4;
rcr4 &= ~(I2S_RCR4_FSE_MASK | I2S_RCR4_FSP_MASK | I2S_RCR4_FSD_MASK | I2S_RCR4_SYWD_MASK);
#if defined(FSL_FEATURE_SAI_HAS_FRAME_SYNC_ON_DEMAND) && FSL_FEATURE_SAI_HAS_FRAME_SYNC_ON_DEMAND
rcr4 &= ~I2S_RCR4_ONDEM_MASK;
rcr4 |= I2S_RCR4_ONDEM(config->frameSyncGenerateOnDemand);
#endif
rcr4 |=
I2S_RCR4_FSE(config->frameSyncEarly) | I2S_RCR4_FSP(config->frameSyncPolarity) |
I2S_RCR4_FSD(((masterSlave == kSAI_Master) || (masterSlave == kSAI_Bclk_Slave_FrameSync_Master)) ? 1UL : 0U) |
I2S_RCR4_SYWD(config->frameSyncWidth - 1UL);
base->RCR4 = rcr4;
}
/*!
* brief SAI transmitter Serial data configurations.
*
* param base SAI base pointer.
* param config serial data configurations.
*/
void SAI_TxSetSerialDataConfig(I2S_Type *base, sai_serial_data_t *config)
{
assert(config != NULL);
uint32_t tcr4 = base->TCR4;
base->TCR5 = I2S_TCR5_WNW(config->dataWordNLength - 1UL) | I2S_TCR5_W0W(config->dataWord0Length - 1UL) |
I2S_TCR5_FBT(config->dataFirstBitShifted - 1UL);
base->TMR = config->dataMaskedWord;
#if defined(FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR) && FSL_FEATURE_SAI_HAS_FIFO_FUNCTION_AFTER_ERROR
/* ERR05144: not set FCONT = 1 when TMR > 0, the transmit shift register may not load correctly that will cause TX
* not work */
if (config->dataMaskedWord > 0U)
{
tcr4 &= ~I2S_TCR4_FCONT_MASK;
}
#endif
tcr4 &= ~(I2S_TCR4_FRSZ_MASK | I2S_TCR4_MF_MASK);
tcr4 |= I2S_TCR4_FRSZ(config->dataWordNum - 1UL) | I2S_TCR4_MF(config->dataOrder);
#if defined(FSL_FEATURE_SAI_HAS_CHANNEL_MODE) && FSL_FEATURE_SAI_HAS_CHANNEL_MODE
tcr4 &= ~I2S_TCR4_CHMOD_MASK;
tcr4 |= I2S_TCR4_CHMOD(config->dataMode);
#endif
base->TCR4 = tcr4;
}
/*!
* @brief SAI receiver Serial data configurations.
*
* @param base SAI base pointer.
* @param config serial data configurations.
*/
void SAI_RxSetSerialDataConfig(I2S_Type *base, sai_serial_data_t *config)
{
assert(config != NULL);
uint32_t rcr4 = base->RCR4;
base->RCR5 = I2S_RCR5_WNW(config->dataWordNLength - 1UL) | I2S_RCR5_W0W(config->dataWord0Length - 1UL) |
I2S_RCR5_FBT(config->dataFirstBitShifted - 1UL);
base->RMR = config->dataMaskedWord;
rcr4 &= ~(I2S_RCR4_FRSZ_MASK | I2S_RCR4_MF_MASK);
rcr4 |= I2S_RCR4_FRSZ(config->dataWordNum - 1uL) | I2S_RCR4_MF(config->dataOrder);
base->RCR4 = rcr4;
}
/*!
* brief SAI transmitter configurations.
*
* param base SAI base pointer.
* param config transmitter configurations.
*/
void SAI_TxSetConfig(I2S_Type *base, sai_transceiver_t *config)
{
assert(config != NULL);
assert(FSL_FEATURE_SAI_CHANNEL_COUNTn(base) != -1);
uint8_t i = 0U;
uint32_t val = 0U;
uint8_t channelNums = 0U;
/* reset transmitter */
SAI_TxReset(base);
/* if channel mask is not set, then format->channel must be set,
use it to get channel mask value */
if (config->channelMask == 0U)
{
config->channelMask = 1U << config->startChannel;
}
for (i = 0U; i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base); i++)
{
if (IS_SAI_FLAG_SET(1UL << i, config->channelMask))
{
channelNums++;
config->endChannel = i;
}
}
for (i = 0U; i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base); i++)
{
if (IS_SAI_FLAG_SET((1UL << i), config->channelMask))
{
config->startChannel = i;
break;
}
}
config->channelNums = channelNums;
#if defined(FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE) && (FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE)
/* make sure combine mode disabled while multipe channel is used */
if (config->channelNums > 1U)
{
base->TCR4 &= ~I2S_TCR4_FCOMB_MASK;
}
#endif
/* Set data channel */
base->TCR3 &= ~I2S_TCR3_TCE_MASK;
base->TCR3 |= I2S_TCR3_TCE(config->channelMask);
if (config->syncMode == kSAI_ModeAsync)
{
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(0U));
}
if (config->syncMode == kSAI_ModeSync)
{
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(1U));
/* If sync with Rx, should set Rx to async mode */
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(0U));
}
#if defined(FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI) && (FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI)
if (config->syncMode == kSAI_ModeSyncWithOtherTx)
{
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(2U));
}
if (config->syncMode == kSAI_ModeSyncWithOtherRx)
{
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(3U));
}
#endif /* FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI */
/* bit clock configurations */
SAI_TxSetBitclockConfig(base, config->masterSlave, &config->bitClock);
/* serial data configurations */
SAI_TxSetSerialDataConfig(base, &config->serialData);
/* frame sync configurations */
SAI_TxSetFrameSyncConfig(base, config->masterSlave, &config->frameSync);
#if FSL_SAI_HAS_FIFO_EXTEND_FEATURE
/* fifo configurations */
SAI_TxSetFifoConfig(base, &config->fifo);
#endif
}
/*!
* brief SAI transmitter transfer configurations.
*
* This function initializes the TX, include bit clock, frame sync, master clock, serial data and fifo configurations.
*
* param base SAI base pointer.
* param handle SAI handle pointer.
* param config tranmitter configurations.
*/
void SAI_TransferTxSetConfig(I2S_Type *base, sai_handle_t *handle, sai_transceiver_t *config)
{
assert(handle != NULL);
assert(config != NULL);
assert(config->channelNums <= (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base));
handle->bitWidth = config->frameSync.frameSyncWidth;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
handle->watermark = config->fifo.fifoWatermark;
#endif
/* transmitter configurations */
SAI_TxSetConfig(base, config);
handle->channel = config->startChannel;
/* used for multi channel */
handle->channelMask = config->channelMask;
handle->channelNums = config->channelNums;
handle->endChannel = config->endChannel;
}
/*!
* brief SAI receiver configurations.
*
* param base SAI base pointer.
* param config transmitter configurations.
*/
void SAI_RxSetConfig(I2S_Type *base, sai_transceiver_t *config)
{
assert(config != NULL);
assert(FSL_FEATURE_SAI_CHANNEL_COUNTn(base) != -1);
uint8_t i = 0U;
uint32_t val = 0U;
uint8_t channelNums = 0U;
/* reset receiver */
SAI_RxReset(base);
/* if channel mask is not set, then format->channel must be set,
use it to get channel mask value */
if (config->channelMask == 0U)
{
config->channelMask = 1U << config->startChannel;
}
for (i = 0U; i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base); i++)
{
if (IS_SAI_FLAG_SET((1UL << i), config->channelMask))
{
channelNums++;
config->endChannel = i;
}
}
for (i = 0U; i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base); i++)
{
if (IS_SAI_FLAG_SET((1UL << i), config->channelMask))
{
config->startChannel = i;
break;
}
}
config->channelNums = channelNums;
#if defined(FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE) && (FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE)
/* make sure combine mode disabled while multipe channel is used */
if (config->channelNums > 1U)
{
base->RCR4 &= ~I2S_RCR4_FCOMB_MASK;
}
#endif
/* Set data channel */
base->RCR3 &= ~I2S_RCR3_RCE_MASK;
base->RCR3 |= I2S_RCR3_RCE(config->channelMask);
/* Set Sync mode */
if (config->syncMode == kSAI_ModeAsync)
{
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(0U));
}
if (config->syncMode == kSAI_ModeSync)
{
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(1U));
/* If sync with Tx, should set Tx to async mode */
val = base->TCR2;
val &= ~I2S_TCR2_SYNC_MASK;
base->TCR2 = (val | I2S_TCR2_SYNC(0U));
}
#if defined(FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI) && (FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI)
if (config->syncMode == kSAI_ModeSyncWithOtherTx)
{
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(2U));
}
if (config->syncMode == kSAI_ModeSyncWithOtherRx)
{
val = base->RCR2;
val &= ~I2S_RCR2_SYNC_MASK;
base->RCR2 = (val | I2S_RCR2_SYNC(3U));
}
#endif /* FSL_FEATURE_SAI_HAS_SYNC_WITH_ANOTHER_SAI */
/* bit clock configurations */
SAI_RxSetBitclockConfig(base, config->masterSlave, &config->bitClock);
/* serial data configurations */
SAI_RxSetSerialDataConfig(base, &config->serialData);
/* frame sync configurations */
SAI_RxSetFrameSyncConfig(base, config->masterSlave, &config->frameSync);
#if FSL_SAI_HAS_FIFO_EXTEND_FEATURE
/* fifo configurations */
SAI_RxSetFifoConfig(base, &config->fifo);
#endif
}
/*!
* brief SAI receiver transfer configurations.
*
* This function initializes the TX, include bit clock, frame sync, master clock, serial data and fifo configurations.
*
* param base SAI base pointer.
* param handle SAI handle pointer.
* param config tranmitter configurations.
*/
void SAI_TransferRxSetConfig(I2S_Type *base, sai_handle_t *handle, sai_transceiver_t *config)
{
assert(handle != NULL);
assert(config != NULL);
handle->bitWidth = config->frameSync.frameSyncWidth;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
handle->watermark = config->fifo.fifoWatermark;
#endif
/* receiver configurations */
SAI_RxSetConfig(base, config);
handle->channel = config->startChannel;
/* used for multi channel */
handle->channelMask = config->channelMask;
handle->channelNums = config->channelNums;
handle->endChannel = config->endChannel;
}
/*!
* brief Get classic I2S mode configurations.
*
* param config transceiver configurations.
* param bitWidth audio data bitWidth.
* param mode audio data channel.
* param saiChannelMask channel mask value to enable.
*/
void SAI_GetClassicI2SConfig(sai_transceiver_t *config,
sai_word_width_t bitWidth,
sai_mono_stereo_t mode,
uint32_t saiChannelMask)
{
SAI_GetCommonConfig(config, bitWidth, mode, saiChannelMask);
}
/*!
* brief Get left justified mode configurations.
*
* param config transceiver configurations.
* param bitWidth audio data bitWidth.
* param mode audio data channel.
* param saiChannelMask channel mask value to enable.
*/
void SAI_GetLeftJustifiedConfig(sai_transceiver_t *config,
sai_word_width_t bitWidth,
sai_mono_stereo_t mode,
uint32_t saiChannelMask)
{
assert(NULL != config);
assert(saiChannelMask != 0U);
SAI_GetCommonConfig(config, bitWidth, mode, saiChannelMask);
config->frameSync.frameSyncEarly = false;
config->frameSync.frameSyncPolarity = kSAI_PolarityActiveHigh;
}
/*!
* brief Get right justified mode configurations.
*
* param config transceiver configurations.
* param bitWidth audio data bitWidth.
* param mode audio data channel.
* param saiChannelMask channel mask value to enable.
*/
void SAI_GetRightJustifiedConfig(sai_transceiver_t *config,
sai_word_width_t bitWidth,
sai_mono_stereo_t mode,
uint32_t saiChannelMask)
{
assert(NULL != config);
assert(saiChannelMask != 0U);
SAI_GetCommonConfig(config, bitWidth, mode, saiChannelMask);
config->frameSync.frameSyncEarly = false;
config->frameSync.frameSyncPolarity = kSAI_PolarityActiveHigh;
}
/*!
* brief Get DSP mode configurations.
*
* note DSP mode is also called PCM mode which support MODE A and MODE B,
* DSP/PCM MODE A configuration flow. RX is similiar but uses SAI_RxSetConfig instead of SAI_TxSetConfig:
* code
* SAI_GetDSPConfig(config, kSAI_FrameSyncLenOneBitClk, bitWidth, kSAI_Stereo, channelMask)
* config->frameSync.frameSyncEarly = true;
* SAI_TxSetConfig(base, config)
* endcode
*
* DSP/PCM MODE B configuration flow for TX. RX is similiar but uses SAI_RxSetConfig instead of SAI_TxSetConfig:
* code
* SAI_GetDSPConfig(config, kSAI_FrameSyncLenOneBitClk, bitWidth, kSAI_Stereo, channelMask)
* SAI_TxSetConfig(base, config)
* endcode
*
* param config transceiver configurations.
* param frameSyncWidth length of frame sync.
* param bitWidth audio data bitWidth.
* param mode audio data channel.
* param saiChannelMask mask value of the channel to enable.
*/
void SAI_GetDSPConfig(sai_transceiver_t *config,
sai_frame_sync_len_t frameSyncWidth,
sai_word_width_t bitWidth,
sai_mono_stereo_t mode,
uint32_t saiChannelMask)
{
assert(NULL != config);
assert(saiChannelMask != 0U);
SAI_GetCommonConfig(config, bitWidth, mode, saiChannelMask);
/* frame sync default configurations */
switch (frameSyncWidth)
{
case kSAI_FrameSyncLenOneBitClk:
config->frameSync.frameSyncWidth = 1U;
break;
default:
assert(false);
break;
}
config->frameSync.frameSyncEarly = false;
config->frameSync.frameSyncPolarity = kSAI_PolarityActiveHigh;
}
/*!
* brief Get TDM mode configurations.
*
* param config transceiver configurations.
* param bitWidth audio data bitWidth.
* param mode audio data channel.
* param saiChannelMask channel mask value to enable.
*/
void SAI_GetTDMConfig(sai_transceiver_t *config,
sai_frame_sync_len_t frameSyncWidth,
sai_word_width_t bitWidth,
uint32_t dataWordNum,
uint32_t saiChannelMask)
{
assert(NULL != config);
assert(saiChannelMask != 0U);
assert(dataWordNum <= 32U);
SAI_GetCommonConfig(config, bitWidth, kSAI_Stereo, saiChannelMask);
/* frame sync default configurations */
switch (frameSyncWidth)
{
case kSAI_FrameSyncLenOneBitClk:
config->frameSync.frameSyncWidth = 1U;
break;
case kSAI_FrameSyncLenPerWordWidth:
break;
default:
assert(false);
break;
}
config->frameSync.frameSyncEarly = false;
config->frameSync.frameSyncPolarity = kSAI_PolarityActiveHigh;
config->serialData.dataWordNum = (uint8_t)dataWordNum;
}
/*!
* brief Configures the SAI Tx audio format.
*
* deprecated Do not use this function. It has been superceded by @ref SAI_TxSetConfig
*
* The audio format can be changed at run-time. This function configures the sample rate and audio data
* format to be transferred.
*
* param base SAI base pointer.
* param format Pointer to the SAI audio data format structure.
* param mclkSourceClockHz SAI master clock source frequency in Hz.
* param bclkSourceClockHz SAI bit clock source frequency in Hz. If the bit clock source is a master
* clock, this value should equal the masterClockHz.
*/
void SAI_TxSetFormat(I2S_Type *base,
sai_transfer_format_t *format,
uint32_t mclkSourceClockHz,
uint32_t bclkSourceClockHz)
{
assert(FSL_FEATURE_SAI_CHANNEL_COUNTn(base) != -1);
uint32_t bclk = 0;
uint32_t val = 0;
uint8_t i = 0U, channelNums = 0U;
uint32_t divider = 0U;
if (format->isFrameSyncCompact)
{
bclk = format->sampleRate_Hz * format->bitWidth * (format->stereo == kSAI_Stereo ? 2U : 1U);
val = (base->TCR4 & (~I2S_TCR4_SYWD_MASK));
val |= I2S_TCR4_SYWD(format->bitWidth - 1U);
base->TCR4 = val;
}
else
{
bclk = format->sampleRate_Hz * 32U * 2U;
}
/* Compute the mclk */
#if defined(FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER) && (FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER)
/* Check if master clock divider enabled, then set master clock divider */
if (IS_SAI_FLAG_SET(base->MCR, I2S_MCR_MOE_MASK))
{
SAI_SetMasterClockDivider(base, format->masterClockHz, mclkSourceClockHz);
}
#endif /* FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER */
/* Set bclk if needed */
if (IS_SAI_FLAG_SET(base->TCR2, I2S_TCR2_BCD_MASK))
{
base->TCR2 &= ~I2S_TCR2_DIV_MASK;
/* need to check the divided bclk, if bigger than target, then divider need to re-calculate. */
divider = bclkSourceClockHz / bclk;
/* for the condition where the source clock is smaller than target bclk */
if (divider == 0U)
{
divider++;
}
/* recheck the divider if properly or not, to make sure output blck not bigger than target*/
if ((bclkSourceClockHz / divider) > bclk)
{
divider++;
}
#if defined(FSL_FEATURE_SAI_HAS_BCLK_BYPASS) && (FSL_FEATURE_SAI_HAS_BCLK_BYPASS)
/* if bclk same with MCLK, bypass the divider */
if (divider == 1U)
{
base->TCR2 |= I2S_TCR2_BYP_MASK;
}
else
#endif
{
base->TCR2 |= I2S_TCR2_DIV(divider / 2U - 1U);
}
}
/* Set bitWidth */
val = (format->isFrameSyncCompact) ? (format->bitWidth - 1U) : 31U;
if (format->protocol == kSAI_BusRightJustified)
{
base->TCR5 = I2S_TCR5_WNW(val) | I2S_TCR5_W0W(val) | I2S_TCR5_FBT(val);
}
else
{
if (IS_SAI_FLAG_SET(base->TCR4, I2S_TCR4_MF_MASK))
{
base->TCR5 = I2S_TCR5_WNW(val) | I2S_TCR5_W0W(val) | I2S_TCR5_FBT(format->bitWidth - 1UL);
}
else
{
base->TCR5 = I2S_TCR5_WNW(val) | I2S_TCR5_W0W(val) | I2S_TCR5_FBT(0);
}
}
/* Set mono or stereo */
base->TMR = (uint32_t)format->stereo;
/* if channel mask is not set, then format->channel must be set,
use it to get channel mask value */
if (format->channelMask == 0U)
{
format->channelMask = 1U << format->channel;
}
/* if channel nums is not set, calculate it here according to channelMask*/
for (i = 0U; i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base); i++)
{
if (IS_SAI_FLAG_SET((1UL << i), format->channelMask))
{
channelNums++;
format->endChannel = i;
}
}
for (i = 0U; i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base); i++)
{
if (IS_SAI_FLAG_SET((1UL << i), format->channelMask))
{
format->channel = i;
break;
}
}
format->channelNums = channelNums;
#if defined(FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE) && (FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE)
/* make sure combine mode disabled while multipe channel is used */
if (format->channelNums > 1U)
{
base->TCR4 &= ~I2S_TCR4_FCOMB_MASK;
}
#endif
/* Set data channel */
base->TCR3 &= ~I2S_TCR3_TCE_MASK;
base->TCR3 |= I2S_TCR3_TCE(format->channelMask);
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
/* Set watermark */
base->TCR1 = format->watermark;
#endif /* FSL_FEATURE_SAI_FIFO_COUNT */
}
/*!
* brief Configures the SAI Rx audio format.
*
* deprecated Do not use this function. It has been superceded by @ref SAI_RxSetConfig
*
* The audio format can be changed at run-time. This function configures the sample rate and audio data
* format to be transferred.
*
* param base SAI base pointer.
* param format Pointer to the SAI audio data format structure.
* param mclkSourceClockHz SAI master clock source frequency in Hz.
* param bclkSourceClockHz SAI bit clock source frequency in Hz. If the bit clock source is a master
* clock, this value should equal the masterClockHz.
*/
void SAI_RxSetFormat(I2S_Type *base,
sai_transfer_format_t *format,
uint32_t mclkSourceClockHz,
uint32_t bclkSourceClockHz)
{
assert(FSL_FEATURE_SAI_CHANNEL_COUNTn(base) != -1);
uint32_t bclk = 0;
uint32_t val = 0;
uint8_t i = 0U, channelNums = 0U;
uint32_t divider = 0U;
if (format->isFrameSyncCompact)
{
bclk = format->sampleRate_Hz * format->bitWidth * (format->stereo == kSAI_Stereo ? 2U : 1U);
val = (base->RCR4 & (~I2S_RCR4_SYWD_MASK));
val |= I2S_RCR4_SYWD(format->bitWidth - 1U);
base->RCR4 = val;
}
else
{
bclk = format->sampleRate_Hz * 32U * 2U;
}
/* Compute the mclk */
#if defined(FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER) && (FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER)
/* Check if master clock divider enabled */
if (IS_SAI_FLAG_SET(base->MCR, I2S_MCR_MOE_MASK))
{
SAI_SetMasterClockDivider(base, format->masterClockHz, mclkSourceClockHz);
}
#endif /* FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER */
/* Set bclk if needed */
if (IS_SAI_FLAG_SET(base->RCR2, I2S_RCR2_BCD_MASK))
{
base->RCR2 &= ~I2S_RCR2_DIV_MASK;
/* need to check the divided bclk, if bigger than target, then divider need to re-calculate. */
divider = bclkSourceClockHz / bclk;
/* for the condition where the source clock is smaller than target bclk */
if (divider == 0U)
{
divider++;
}
/* recheck the divider if properly or not, to make sure output blck not bigger than target*/
if ((bclkSourceClockHz / divider) > bclk)
{
divider++;
}
#if defined(FSL_FEATURE_SAI_HAS_BCLK_BYPASS) && (FSL_FEATURE_SAI_HAS_BCLK_BYPASS)
/* if bclk same with MCLK, bypass the divider */
if (divider == 1U)
{
base->RCR2 |= I2S_RCR2_BYP_MASK;
}
else
#endif
{
base->RCR2 |= I2S_RCR2_DIV(divider / 2U - 1U);
}
}
/* Set bitWidth */
val = (format->isFrameSyncCompact) ? (format->bitWidth - 1U) : 31U;
if (format->protocol == kSAI_BusRightJustified)
{
base->RCR5 = I2S_RCR5_WNW(val) | I2S_RCR5_W0W(val) | I2S_RCR5_FBT(val);
}
else
{
if (IS_SAI_FLAG_SET(base->RCR4, I2S_RCR4_MF_MASK))
{
base->RCR5 = I2S_RCR5_WNW(val) | I2S_RCR5_W0W(val) | I2S_RCR5_FBT(format->bitWidth - 1UL);
}
else
{
base->RCR5 = I2S_RCR5_WNW(val) | I2S_RCR5_W0W(val) | I2S_RCR5_FBT(0UL);
}
}
/* Set mono or stereo */
base->RMR = (uint32_t)format->stereo;
/* if channel mask is not set, then format->channel must be set,
use it to get channel mask value */
if (format->channelMask == 0U)
{
format->channelMask = 1U << format->channel;
}
/* if channel nums is not set, calculate it here according to channelMask*/
for (i = 0U; i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base); i++)
{
if (IS_SAI_FLAG_SET((1UL << i), format->channelMask))
{
channelNums++;
format->endChannel = i;
}
}
for (i = 0U; i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base); i++)
{
if (IS_SAI_FLAG_SET((1UL << i), format->channelMask))
{
format->channel = i;
break;
}
}
format->channelNums = channelNums;
#if defined(FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE) && (FSL_FEATURE_SAI_HAS_FIFO_COMBINE_MODE)
/* make sure combine mode disabled while multipe channel is used */
if (format->channelNums > 1U)
{
base->RCR4 &= ~I2S_RCR4_FCOMB_MASK;
}
#endif
/* Set data channel */
base->RCR3 &= ~I2S_RCR3_RCE_MASK;
/* enable all the channel */
base->RCR3 |= I2S_RCR3_RCE(format->channelMask);
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
/* Set watermark */
base->RCR1 = format->watermark;
#endif /* FSL_FEATURE_SAI_FIFO_COUNT */
}
/*!
* brief Sends data using a blocking method.
*
* note This function blocks by polling until data is ready to be sent.
*
* param base SAI base pointer.
* param channel Data channel used.
* param bitWidth How many bits in an audio word; usually 8/16/24/32 bits.
* param buffer Pointer to the data to be written.
* param size Bytes to be written.
*/
void SAI_WriteBlocking(I2S_Type *base, uint32_t channel, uint32_t bitWidth, uint8_t *buffer, uint32_t size)
{
uint32_t i = 0;
uint32_t bytesPerWord = bitWidth / 8U;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
bytesPerWord = (((uint32_t)FSL_FEATURE_SAI_FIFO_COUNT - base->TCR1) * bytesPerWord);
#endif
while (i < size)
{
/* Wait until it can write data */
while (!(IS_SAI_FLAG_SET(base->TCSR, I2S_TCSR_FWF_MASK)))
{
}
SAI_WriteNonBlocking(base, channel, 1UL << channel, channel, (uint8_t)bitWidth, buffer, bytesPerWord);
buffer = (uint8_t *)((uint32_t)buffer + bytesPerWord);
i += bytesPerWord;
}
/* Wait until the last data is sent */
while (!(IS_SAI_FLAG_SET(base->TCSR, I2S_TCSR_FWF_MASK)))
{
}
}
/*!
* brief Sends data to multi channel using a blocking method.
*
* note This function blocks by polling until data is ready to be sent.
*
* param base SAI base pointer.
* param channel Data channel used.
* param channelMask channel mask.
* param bitWidth How many bits in an audio word; usually 8/16/24/32 bits.
* param buffer Pointer to the data to be written.
* param size Bytes to be written.
*/
void SAI_WriteMultiChannelBlocking(
I2S_Type *base, uint32_t channel, uint32_t channelMask, uint32_t bitWidth, uint8_t *buffer, uint32_t size)
{
assert(FSL_FEATURE_SAI_CHANNEL_COUNTn(base) != -1);
uint32_t i = 0, j = 0;
uint32_t bytesPerWord = bitWidth / 8U;
uint32_t channelNums = 0U, endChannel = 0U;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
bytesPerWord = (((uint32_t)FSL_FEATURE_SAI_FIFO_COUNT - base->TCR1) * bytesPerWord);
#endif
for (i = 0U; (i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base)); i++)
{
if (IS_SAI_FLAG_SET((1UL << i), channelMask))
{
channelNums++;
endChannel = i;
}
}
bytesPerWord *= channelNums;
while (j < size)
{
/* Wait until it can write data */
while (!(IS_SAI_FLAG_SET(base->TCSR, I2S_TCSR_FWF_MASK)))
{
}
SAI_WriteNonBlocking(base, channel, channelMask, endChannel, (uint8_t)bitWidth, buffer,
bytesPerWord * channelNums);
buffer = (uint8_t *)((uint32_t)buffer + bytesPerWord * channelNums);
j += bytesPerWord * channelNums;
}
/* Wait until the last data is sent */
while (!(IS_SAI_FLAG_SET(base->TCSR, I2S_TCSR_FWF_MASK)))
{
}
}
/*!
* brief Receives multi channel data using a blocking method.
*
* note This function blocks by polling until data is ready to be sent.
*
* param base SAI base pointer.
* param channel Data channel used.
* param channelMask channel mask.
* param bitWidth How many bits in an audio word; usually 8/16/24/32 bits.
* param buffer Pointer to the data to be read.
* param size Bytes to be read.
*/
void SAI_ReadMultiChannelBlocking(
I2S_Type *base, uint32_t channel, uint32_t channelMask, uint32_t bitWidth, uint8_t *buffer, uint32_t size)
{
assert(FSL_FEATURE_SAI_CHANNEL_COUNTn(base) != -1);
uint32_t i = 0, j = 0;
uint32_t bytesPerWord = bitWidth / 8U;
uint32_t channelNums = 0U, endChannel = 0U;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
bytesPerWord = base->RCR1 * bytesPerWord;
#endif
for (i = 0U; (i < (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base)); i++)
{
if (IS_SAI_FLAG_SET((1UL << i), channelMask))
{
channelNums++;
endChannel = i;
}
}
bytesPerWord *= channelNums;
while (j < size)
{
/* Wait until data is received */
while (!(IS_SAI_FLAG_SET(base->RCSR, I2S_RCSR_FWF_MASK)))
{
}
SAI_ReadNonBlocking(base, channel, channelMask, endChannel, (uint8_t)bitWidth, buffer,
bytesPerWord * channelNums);
buffer = (uint8_t *)((uint32_t)buffer + bytesPerWord * channelNums);
j += bytesPerWord * channelNums;
}
}
/*!
* brief Receives data using a blocking method.
*
* note This function blocks by polling until data is ready to be sent.
*
* param base SAI base pointer.
* param channel Data channel used.
* param bitWidth How many bits in an audio word; usually 8/16/24/32 bits.
* param buffer Pointer to the data to be read.
* param size Bytes to be read.
*/
void SAI_ReadBlocking(I2S_Type *base, uint32_t channel, uint32_t bitWidth, uint8_t *buffer, uint32_t size)
{
uint32_t i = 0;
uint32_t bytesPerWord = bitWidth / 8U;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
bytesPerWord = base->RCR1 * bytesPerWord;
#endif
while (i < size)
{
/* Wait until data is received */
while (!(IS_SAI_FLAG_SET(base->RCSR, I2S_RCSR_FWF_MASK)))
{
}
SAI_ReadNonBlocking(base, channel, 1UL << channel, channel, (uint8_t)bitWidth, buffer, bytesPerWord);
buffer = (uint8_t *)((uint32_t)buffer + bytesPerWord);
i += bytesPerWord;
}
}
/*!
* brief Initializes the SAI Tx handle.
*
* This function initializes the Tx handle for the SAI Tx transactional APIs. Call
* this function once to get the handle initialized.
*
* param base SAI base pointer
* param handle SAI handle pointer.
* param callback Pointer to the user callback function.
* param userData User parameter passed to the callback function
*/
void SAI_TransferTxCreateHandle(I2S_Type *base, sai_handle_t *handle, sai_transfer_callback_t callback, void *userData)
{
assert(handle != NULL);
/* Zero the handle */
(void)memset(handle, 0, sizeof(*handle));
s_saiHandle[SAI_GetInstance(base)][0] = handle;
handle->callback = callback;
handle->userData = userData;
handle->base = base;
/* Set the isr pointer */
s_saiTxIsr = SAI_TransferTxHandleIRQ;
/* Enable Tx irq */
(void)EnableIRQ(s_saiTxIRQ[SAI_GetInstance(base)]);
}
/*!
* brief Initializes the SAI Rx handle.
*
* This function initializes the Rx handle for the SAI Rx transactional APIs. Call
* this function once to get the handle initialized.
*
* param base SAI base pointer.
* param handle SAI handle pointer.
* param callback Pointer to the user callback function.
* param userData User parameter passed to the callback function.
*/
void SAI_TransferRxCreateHandle(I2S_Type *base, sai_handle_t *handle, sai_transfer_callback_t callback, void *userData)
{
assert(handle != NULL);
/* Zero the handle */
(void)memset(handle, 0, sizeof(*handle));
s_saiHandle[SAI_GetInstance(base)][1] = handle;
handle->callback = callback;
handle->userData = userData;
handle->base = base;
/* Set the isr pointer */
s_saiRxIsr = SAI_TransferRxHandleIRQ;
/* Enable Rx irq */
(void)EnableIRQ(s_saiRxIRQ[SAI_GetInstance(base)]);
}
/*!
* brief Configures the SAI Tx audio format.
*
* deprecated Do not use this function. It has been superceded by @ref SAI_TransferTxSetConfig
*
* The audio format can be changed at run-time. This function configures the sample rate and audio data
* format to be transferred.
*
* param base SAI base pointer.
* param handle SAI handle pointer.
* param format Pointer to the SAI audio data format structure.
* param mclkSourceClockHz SAI master clock source frequency in Hz.
* param bclkSourceClockHz SAI bit clock source frequency in Hz. If a bit clock source is a master
* clock, this value should equal the masterClockHz in format.
* return Status of this function. Return value is the status_t.
*/
status_t SAI_TransferTxSetFormat(I2S_Type *base,
sai_handle_t *handle,
sai_transfer_format_t *format,
uint32_t mclkSourceClockHz,
uint32_t bclkSourceClockHz)
{
assert(handle != NULL);
if ((bclkSourceClockHz < format->sampleRate_Hz)
#if defined(FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER) && (FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER)
|| (mclkSourceClockHz < format->sampleRate_Hz)
#endif
)
{
return kStatus_InvalidArgument;
}
/* Copy format to handle */
handle->bitWidth = (uint8_t)format->bitWidth;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
handle->watermark = format->watermark;
#endif
SAI_TxSetFormat(base, format, mclkSourceClockHz, bclkSourceClockHz);
handle->channel = format->channel;
/* used for multi channel */
handle->channelMask = format->channelMask;
handle->channelNums = format->channelNums;
handle->endChannel = format->endChannel;
return kStatus_Success;
}
/*!
* brief Configures the SAI Rx audio format.
*
* deprecated Do not use this function. It has been superceded by @ref SAI_TransferRxSetConfig
*
* The audio format can be changed at run-time. This function configures the sample rate and audio data
* format to be transferred.
*
* param base SAI base pointer.
* param handle SAI handle pointer.
* param format Pointer to the SAI audio data format structure.
* param mclkSourceClockHz SAI master clock source frequency in Hz.
* param bclkSourceClockHz SAI bit clock source frequency in Hz. If a bit clock source is a master
* clock, this value should equal the masterClockHz in format.
* return Status of this function. Return value is one of status_t.
*/
status_t SAI_TransferRxSetFormat(I2S_Type *base,
sai_handle_t *handle,
sai_transfer_format_t *format,
uint32_t mclkSourceClockHz,
uint32_t bclkSourceClockHz)
{
assert(handle != NULL);
if ((bclkSourceClockHz < format->sampleRate_Hz)
#if defined(FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER) && (FSL_FEATURE_SAI_HAS_MCLKDIV_REGISTER)
|| (mclkSourceClockHz < format->sampleRate_Hz)
#endif
)
{
return kStatus_InvalidArgument;
}
/* Copy format to handle */
handle->bitWidth = (uint8_t)format->bitWidth;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
handle->watermark = format->watermark;
#endif
SAI_RxSetFormat(base, format, mclkSourceClockHz, bclkSourceClockHz);
handle->channel = format->channel;
/* used for multi channel */
handle->channelMask = format->channelMask;
handle->channelNums = format->channelNums;
handle->endChannel = format->endChannel;
return kStatus_Success;
}
/*!
* brief Performs an interrupt non-blocking send transfer on SAI.
*
* note This API returns immediately after the transfer initiates.
* Call the SAI_TxGetTransferStatusIRQ to poll the transfer status and check whether
* the transfer is finished. If the return status is not kStatus_SAI_Busy, the transfer
* is finished.
*
* param base SAI base pointer.
* param handle Pointer to the sai_handle_t structure which stores the transfer state.
* param xfer Pointer to the sai_transfer_t structure.
* retval kStatus_Success Successfully started the data receive.
* retval kStatus_SAI_TxBusy Previous receive still not finished.
* retval kStatus_InvalidArgument The input parameter is invalid.
*/
status_t SAI_TransferSendNonBlocking(I2S_Type *base, sai_handle_t *handle, sai_transfer_t *xfer)
{
assert(handle != NULL);
assert(handle->channelNums <= (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base));
/* Check if the queue is full */
if (handle->saiQueue[handle->queueUser].data != NULL)
{
return kStatus_SAI_QueueFull;
}
/* Add into queue */
handle->transferSize[handle->queueUser] = xfer->dataSize;
handle->saiQueue[handle->queueUser].data = xfer->data;
handle->saiQueue[handle->queueUser].dataSize = xfer->dataSize;
handle->queueUser = (handle->queueUser + 1U) % (uint8_t)SAI_XFER_QUEUE_SIZE;
/* Set the state to busy */
handle->state = (uint32_t)kSAI_Busy;
/* Enable interrupt */
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
/* Use FIFO request interrupt and fifo error*/
SAI_TxEnableInterrupts(base, I2S_TCSR_FEIE_MASK | I2S_TCSR_FRIE_MASK);
#else
SAI_TxEnableInterrupts(base, I2S_TCSR_FEIE_MASK | I2S_TCSR_FWIE_MASK);
#endif /* FSL_FEATURE_SAI_FIFO_COUNT */
/* Enable Tx transfer */
SAI_TxEnable(base, true);
return kStatus_Success;
}
/*!
* brief Performs an interrupt non-blocking receive transfer on SAI.
*
* note This API returns immediately after the transfer initiates.
* Call the SAI_RxGetTransferStatusIRQ to poll the transfer status and check whether
* the transfer is finished. If the return status is not kStatus_SAI_Busy, the transfer
* is finished.
*
* param base SAI base pointer
* param handle Pointer to the sai_handle_t structure which stores the transfer state.
* param xfer Pointer to the sai_transfer_t structure.
* retval kStatus_Success Successfully started the data receive.
* retval kStatus_SAI_RxBusy Previous receive still not finished.
* retval kStatus_InvalidArgument The input parameter is invalid.
*/
status_t SAI_TransferReceiveNonBlocking(I2S_Type *base, sai_handle_t *handle, sai_transfer_t *xfer)
{
assert(handle != NULL);
assert(handle->channelNums <= (uint32_t)FSL_FEATURE_SAI_CHANNEL_COUNTn(base));
/* Check if the queue is full */
if (handle->saiQueue[handle->queueUser].data != NULL)
{
return kStatus_SAI_QueueFull;
}
/* Add into queue */
handle->transferSize[handle->queueUser] = xfer->dataSize;
handle->saiQueue[handle->queueUser].data = xfer->data;
handle->saiQueue[handle->queueUser].dataSize = xfer->dataSize;
handle->queueUser = (handle->queueUser + 1U) % (uint8_t)SAI_XFER_QUEUE_SIZE;
/* Set state to busy */
handle->state = (uint32_t)kSAI_Busy;
/* Enable interrupt */
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
/* Use FIFO request interrupt and fifo error*/
SAI_RxEnableInterrupts(base, I2S_TCSR_FEIE_MASK | I2S_TCSR_FRIE_MASK);
#else
SAI_RxEnableInterrupts(base, I2S_TCSR_FEIE_MASK | I2S_TCSR_FWIE_MASK);
#endif /* FSL_FEATURE_SAI_FIFO_COUNT */
/* Enable Rx transfer */
SAI_RxEnable(base, true);
return kStatus_Success;
}
/*!
* brief Gets a set byte count.
*
* param base SAI base pointer.
* param handle Pointer to the sai_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 SAI_TransferGetSendCount(I2S_Type *base, sai_handle_t *handle, size_t *count)
{
assert(handle != NULL);
status_t status = kStatus_Success;
uint32_t queueDriverIndex = handle->queueDriver;
if (handle->state != (uint32_t)kSAI_Busy)
{
status = kStatus_NoTransferInProgress;
}
else
{
*count = (handle->transferSize[queueDriverIndex] - handle->saiQueue[queueDriverIndex].dataSize);
}
return status;
}
/*!
* brief Gets a received byte count.
*
* param base SAI base pointer.
* param handle Pointer to the sai_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 SAI_TransferGetReceiveCount(I2S_Type *base, sai_handle_t *handle, size_t *count)
{
assert(handle != NULL);
status_t status = kStatus_Success;
uint32_t queueDriverIndex = handle->queueDriver;
if (handle->state != (uint32_t)kSAI_Busy)
{
status = kStatus_NoTransferInProgress;
}
else
{
*count = (handle->transferSize[queueDriverIndex] - handle->saiQueue[queueDriverIndex].dataSize);
}
return status;
}
/*!
* 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 SAI base pointer.
* param handle Pointer to the sai_handle_t structure which stores the transfer state.
*/
void SAI_TransferAbortSend(I2S_Type *base, sai_handle_t *handle)
{
assert(handle != NULL);
/* Stop Tx transfer and disable interrupt */
SAI_TxEnable(base, false);
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
/* Use FIFO request interrupt and fifo error */
SAI_TxDisableInterrupts(base, I2S_TCSR_FEIE_MASK | I2S_TCSR_FRIE_MASK);
#else
SAI_TxDisableInterrupts(base, I2S_TCSR_FEIE_MASK | I2S_TCSR_FWIE_MASK);
#endif /* FSL_FEATURE_SAI_FIFO_COUNT */
handle->state = (uint32_t)kSAI_Idle;
/* Clear the queue */
(void)memset(handle->saiQueue, 0, sizeof(sai_transfer_t) * (uint8_t)SAI_XFER_QUEUE_SIZE);
handle->queueDriver = 0;
handle->queueUser = 0;
}
/*!
* 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 SAI base pointer
* param handle Pointer to the sai_handle_t structure which stores the transfer state.
*/
void SAI_TransferAbortReceive(I2S_Type *base, sai_handle_t *handle)
{
assert(handle != NULL);
/* Stop Tx transfer and disable interrupt */
SAI_RxEnable(base, false);
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
/* Use FIFO request interrupt and fifo error */
SAI_RxDisableInterrupts(base, I2S_TCSR_FEIE_MASK | I2S_TCSR_FRIE_MASK);
#else
SAI_RxDisableInterrupts(base, I2S_TCSR_FEIE_MASK | I2S_TCSR_FWIE_MASK);
#endif /* FSL_FEATURE_SAI_FIFO_COUNT */
handle->state = (uint32_t)kSAI_Idle;
/* Clear the queue */
(void)memset(handle->saiQueue, 0, sizeof(sai_transfer_t) * (uint8_t)SAI_XFER_QUEUE_SIZE);
handle->queueDriver = 0;
handle->queueUser = 0;
}
/*!
* brief Terminate all SAI send.
*
* This function will clear all transfer slots buffered in the sai queue. If users only want to abort the
* current transfer slot, please call SAI_TransferAbortSend.
*
* param base SAI base pointer.
* param handle SAI eDMA handle pointer.
*/
void SAI_TransferTerminateSend(I2S_Type *base, sai_handle_t *handle)
{
assert(handle != NULL);
/* Abort the current transfer */
SAI_TransferAbortSend(base, handle);
/* Clear all the internal information */
(void)memset(handle->saiQueue, 0, sizeof(handle->saiQueue));
(void)memset(handle->transferSize, 0, sizeof(handle->transferSize));
handle->queueUser = 0U;
handle->queueDriver = 0U;
}
/*!
* brief Terminate all SAI receive.
*
* This function will clear all transfer slots buffered in the sai queue. If users only want to abort the
* current transfer slot, please call SAI_TransferAbortReceive.
*
* param base SAI base pointer.
* param handle SAI eDMA handle pointer.
*/
void SAI_TransferTerminateReceive(I2S_Type *base, sai_handle_t *handle)
{
assert(handle != NULL);
/* Abort the current transfer */
SAI_TransferAbortReceive(base, handle);
/* Clear all the internal information */
(void)memset(handle->saiQueue, 0, sizeof(handle->saiQueue));
(void)memset(handle->transferSize, 0, sizeof(handle->transferSize));
handle->queueUser = 0U;
handle->queueDriver = 0U;
}
/*!
* brief Tx interrupt handler.
*
* param base SAI base pointer.
* param handle Pointer to the sai_handle_t structure.
*/
void SAI_TransferTxHandleIRQ(I2S_Type *base, sai_handle_t *handle)
{
assert(handle != NULL);
uint8_t *buffer = handle->saiQueue[handle->queueDriver].data;
uint32_t dataSize = (handle->bitWidth / 8UL) * handle->channelNums;
/* Handle Error */
if (IS_SAI_FLAG_SET(base->TCSR, I2S_TCSR_FEF_MASK))
{
/* Clear FIFO error flag to continue transfer */
SAI_TxClearStatusFlags(base, I2S_TCSR_FEF_MASK);
/* Reset FIFO for safety */
SAI_TxSoftwareReset(base, kSAI_ResetTypeFIFO);
/* Call the callback */
if (handle->callback != NULL)
{
(handle->callback)(base, handle, kStatus_SAI_TxError, handle->userData);
}
}
/* Handle transfer */
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if (IS_SAI_FLAG_SET(base->TCSR, I2S_TCSR_FRF_MASK))
{
/* Judge if the data need to transmit is less than space */
size_t size = MIN((handle->saiQueue[handle->queueDriver].dataSize),
(size_t)(((uint32_t)FSL_FEATURE_SAI_FIFO_COUNT - handle->watermark) * dataSize));
/* Copy the data from sai buffer to FIFO */
SAI_WriteNonBlocking(base, handle->channel, handle->channelMask, handle->endChannel, handle->bitWidth, buffer,
size);
/* Update the internal counter */
handle->saiQueue[handle->queueDriver].dataSize -= size;
handle->saiQueue[handle->queueDriver].data = (uint8_t *)((uint32_t)buffer + size);
}
#else
if (IS_SAI_FLAG_SET(base->TCSR, I2S_TCSR_FWF_MASK))
{
size_t size = MIN((handle->saiQueue[handle->queueDriver].dataSize), dataSize);
SAI_WriteNonBlocking(base, handle->channel, handle->channelMask, handle->endChannel, handle->bitWidth, buffer,
size);
/* Update internal counter */
handle->saiQueue[handle->queueDriver].dataSize -= size;
handle->saiQueue[handle->queueDriver].data = (uint8_t *)((uint32_t)buffer + size);
}
#endif /* FSL_FEATURE_SAI_FIFO_COUNT */
/* If finished a block, call the callback function */
if (handle->saiQueue[handle->queueDriver].dataSize == 0U)
{
(void)memset(&handle->saiQueue[handle->queueDriver], 0, sizeof(sai_transfer_t));
handle->queueDriver = (handle->queueDriver + 1U) % (uint8_t)SAI_XFER_QUEUE_SIZE;
if (handle->callback != NULL)
{
(handle->callback)(base, handle, kStatus_SAI_TxIdle, handle->userData);
}
}
/* If all data finished, just stop the transfer */
if (handle->saiQueue[handle->queueDriver].data == NULL)
{
SAI_TransferAbortSend(base, handle);
}
}
/*!
* brief Tx interrupt handler.
*
* param base SAI base pointer.
* param handle Pointer to the sai_handle_t structure.
*/
void SAI_TransferRxHandleIRQ(I2S_Type *base, sai_handle_t *handle)
{
assert(handle != NULL);
uint8_t *buffer = handle->saiQueue[handle->queueDriver].data;
uint32_t dataSize = (handle->bitWidth / 8UL) * handle->channelNums;
/* Handle Error */
if (IS_SAI_FLAG_SET(base->RCSR, I2S_RCSR_FEF_MASK))
{
/* Clear FIFO error flag to continue transfer */
SAI_RxClearStatusFlags(base, I2S_TCSR_FEF_MASK);
/* Reset FIFO for safety */
SAI_RxSoftwareReset(base, kSAI_ResetTypeFIFO);
/* Call the callback */
if (handle->callback != NULL)
{
(handle->callback)(base, handle, kStatus_SAI_RxError, handle->userData);
}
}
/* Handle transfer */
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if (IS_SAI_FLAG_SET(base->RCSR, I2S_RCSR_FRF_MASK))
{
/* Judge if the data need to transmit is less than space */
size_t size = MIN((handle->saiQueue[handle->queueDriver].dataSize), handle->watermark * dataSize);
/* Copy the data from sai buffer to FIFO */
SAI_ReadNonBlocking(base, handle->channel, handle->channelMask, handle->endChannel, handle->bitWidth, buffer,
size);
/* Update the internal counter */
handle->saiQueue[handle->queueDriver].dataSize -= size;
handle->saiQueue[handle->queueDriver].data = (uint8_t *)((uint32_t)buffer + size);
}
#else
if (IS_SAI_FLAG_SET(base->RCSR, I2S_RCSR_FWF_MASK))
{
size_t size = MIN((handle->saiQueue[handle->queueDriver].dataSize), dataSize);
SAI_ReadNonBlocking(base, handle->channel, handle->channelMask, handle->endChannel, handle->bitWidth, buffer,
size);
/* Update internal state */
handle->saiQueue[handle->queueDriver].dataSize -= size;
handle->saiQueue[handle->queueDriver].data = (uint8_t *)((uint32_t)buffer + size);
}
#endif /* FSL_FEATURE_SAI_FIFO_COUNT */
/* If finished a block, call the callback function */
if (handle->saiQueue[handle->queueDriver].dataSize == 0U)
{
(void)memset(&handle->saiQueue[handle->queueDriver], 0, sizeof(sai_transfer_t));
handle->queueDriver = (handle->queueDriver + 1U) % (uint8_t)SAI_XFER_QUEUE_SIZE;
if (handle->callback != NULL)
{
(handle->callback)(base, handle, kStatus_SAI_RxIdle, handle->userData);
}
}
/* If all data finished, just stop the transfer */
if (handle->saiQueue[handle->queueDriver].data == NULL)
{
SAI_TransferAbortReceive(base, handle);
}
}
#if defined(I2S0)
void I2S0_DriverIRQHandler(void);
void I2S0_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[0][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S0, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[0][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S0, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(I2S0, s_saiHandle[0][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[0][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S0, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[0][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S0, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(I2S0, s_saiHandle[0][0]);
}
SDK_ISR_EXIT_BARRIER;
}
void I2S0_Tx_DriverIRQHandler(void);
void I2S0_Tx_DriverIRQHandler(void)
{
assert(s_saiHandle[0][0] != NULL);
s_saiTxIsr(I2S0, s_saiHandle[0][0]);
SDK_ISR_EXIT_BARRIER;
}
void I2S0_Rx_DriverIRQHandler(void);
void I2S0_Rx_DriverIRQHandler(void)
{
assert(s_saiHandle[0][1] != NULL);
s_saiRxIsr(I2S0, s_saiHandle[0][1]);
SDK_ISR_EXIT_BARRIER;
}
#endif /* I2S0*/
#if defined(I2S1)
void I2S1_DriverIRQHandler(void);
void I2S1_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S1, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S1, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(I2S1, s_saiHandle[1][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S1, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S1, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(I2S1, s_saiHandle[1][0]);
}
SDK_ISR_EXIT_BARRIER;
}
void I2S1_Tx_DriverIRQHandler(void);
void I2S1_Tx_DriverIRQHandler(void)
{
assert(s_saiHandle[1][0] != NULL);
s_saiTxIsr(I2S1, s_saiHandle[1][0]);
SDK_ISR_EXIT_BARRIER;
}
void I2S1_Rx_DriverIRQHandler(void);
void I2S1_Rx_DriverIRQHandler(void)
{
assert(s_saiHandle[1][1] != NULL);
s_saiRxIsr(I2S1, s_saiHandle[1][1]);
SDK_ISR_EXIT_BARRIER;
}
#endif /* I2S1*/
#if defined(I2S2)
void I2S2_DriverIRQHandler(void);
void I2S2_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[2][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S2, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[2][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S2, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(I2S2, s_saiHandle[2][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[2][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S2, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[2][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S2, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(I2S2, s_saiHandle[2][0]);
}
SDK_ISR_EXIT_BARRIER;
}
void I2S2_Tx_DriverIRQHandler(void);
void I2S2_Tx_DriverIRQHandler(void)
{
assert(s_saiHandle[2][0] != NULL);
s_saiTxIsr(I2S2, s_saiHandle[2][0]);
SDK_ISR_EXIT_BARRIER;
}
void I2S2_Rx_DriverIRQHandler(void);
void I2S2_Rx_DriverIRQHandler(void)
{
assert(s_saiHandle[2][1] != NULL);
s_saiRxIsr(I2S2, s_saiHandle[2][1]);
SDK_ISR_EXIT_BARRIER;
}
#endif /* I2S2*/
#if defined(I2S3)
void I2S3_DriverIRQHandler(void);
void I2S3_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[3][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S3, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[3][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S3, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(I2S3, s_saiHandle[3][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[3][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S3, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[3][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S3, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(I2S3, s_saiHandle[3][0]);
}
SDK_ISR_EXIT_BARRIER;
}
void I2S3_Tx_DriverIRQHandler(void);
void I2S3_Tx_DriverIRQHandler(void)
{
assert(s_saiHandle[3][0] != NULL);
s_saiTxIsr(I2S3, s_saiHandle[3][0]);
SDK_ISR_EXIT_BARRIER;
}
void I2S3_Rx_DriverIRQHandler(void);
void I2S3_Rx_DriverIRQHandler(void)
{
assert(s_saiHandle[3][1] != NULL);
s_saiRxIsr(I2S3, s_saiHandle[3][1]);
SDK_ISR_EXIT_BARRIER;
}
#endif /* I2S3*/
#if defined(I2S4)
void I2S4_DriverIRQHandler(void);
void I2S4_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[4][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S4, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[4][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S4, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(I2S4, s_saiHandle[4][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[4][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S4, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[4][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S4, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(I2S4, s_saiHandle[4][0]);
}
SDK_ISR_EXIT_BARRIER;
}
void I2S4_Tx_DriverIRQHandler(void);
void I2S4_Tx_DriverIRQHandler(void)
{
assert(s_saiHandle[4][0] != NULL);
s_saiTxIsr(I2S4, s_saiHandle[4][0]);
SDK_ISR_EXIT_BARRIER;
}
void I2S4_Rx_DriverIRQHandler(void);
void I2S4_Rx_DriverIRQHandler(void)
{
assert(s_saiHandle[4][1] != NULL);
s_saiRxIsr(I2S4, s_saiHandle[4][1]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(FSL_FEATURE_SAI_SAI5_SAI6_SHARE_IRQ) && (FSL_FEATURE_SAI_SAI5_SAI6_SHARE_IRQ) && defined(I2S5) && \
defined(I2S6)
void I2S56_DriverIRQHandler(void);
void I2S56_DriverIRQHandler(void)
{
/* use index 5 to get handle when I2S5 & I2S6 share IRQ NUMBER */
I2S_Type *base = s_saiHandle[5][1]->base;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[5][1] != NULL) && SAI_RxGetEnabledInterruptStatus(base, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[5][1] != NULL) && SAI_RxGetEnabledInterruptStatus(base, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(base, s_saiHandle[5][1]);
}
base = s_saiHandle[5][0]->base;
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[5][0] != NULL) && SAI_TxGetEnabledInterruptStatus(base, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[5][0] != NULL) && SAI_TxGetEnabledInterruptStatus(base, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(base, s_saiHandle[5][0]);
}
SDK_ISR_EXIT_BARRIER;
}
void I2S56_Tx_DriverIRQHandler(void);
void I2S56_Tx_DriverIRQHandler(void)
{
/* use index 5 to get handle when I2S5 & I2S6 share IRQ NUMBER */
assert(s_saiHandle[5][0] != NULL);
s_saiTxIsr(s_saiHandle[5][0]->base, s_saiHandle[5][0]);
SDK_ISR_EXIT_BARRIER;
}
void I2S56_Rx_DriverIRQHandler(void);
void I2S56_Rx_DriverIRQHandler(void)
{
/* use index 5 to get handle when I2S5 & I2S6 share IRQ NUMBER */
assert(s_saiHandle[5][1] != NULL);
s_saiRxIsr(s_saiHandle[5][1]->base, s_saiHandle[5][1]);
SDK_ISR_EXIT_BARRIER;
}
#else
#if defined(I2S5)
void I2S5_DriverIRQHandler(void);
void I2S5_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[5][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S5, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[5][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S5, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(I2S5, s_saiHandle[5][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[5][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S5, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[5][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S5, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(I2S5, s_saiHandle[5][0]);
}
SDK_ISR_EXIT_BARRIER;
}
void I2S5_Tx_DriverIRQHandler(void);
void I2S5_Tx_DriverIRQHandler(void)
{
assert(s_saiHandle[5][0] != NULL);
s_saiTxIsr(I2S5, s_saiHandle[5][0]);
SDK_ISR_EXIT_BARRIER;
}
void I2S5_Rx_DriverIRQHandler(void);
void I2S5_Rx_DriverIRQHandler(void)
{
assert(s_saiHandle[5][1] != NULL);
s_saiRxIsr(I2S5, s_saiHandle[5][1]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(I2S6)
void I2S6_DriverIRQHandler(void);
void I2S6_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[6][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S6, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[6][1] != NULL) && SAI_RxGetEnabledInterruptStatus(I2S6, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(I2S6, s_saiHandle[6][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[6][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S6, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[6][0] != NULL) && SAI_TxGetEnabledInterruptStatus(I2S6, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(I2S6, s_saiHandle[6][0]);
}
SDK_ISR_EXIT_BARRIER;
}
void I2S6_Tx_DriverIRQHandler(void);
void I2S6_Tx_DriverIRQHandler(void)
{
assert(s_saiHandle[6][0] != NULL);
s_saiTxIsr(I2S6, s_saiHandle[6][0]);
SDK_ISR_EXIT_BARRIER;
}
void I2S6_Rx_DriverIRQHandler(void);
void I2S6_Rx_DriverIRQHandler(void)
{
assert(s_saiHandle[6][1] != NULL);
s_saiRxIsr(I2S6, s_saiHandle[6][1]);
SDK_ISR_EXIT_BARRIER;
}
#endif
#endif
#if defined(AUDIO__SAI0)
void AUDIO_SAI0_INT_DriverIRQHandler(void);
void AUDIO_SAI0_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[0][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI0, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[0][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI0, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(AUDIO__SAI0, s_saiHandle[0][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[0][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI0, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[0][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI0, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(AUDIO__SAI0, s_saiHandle[0][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* AUDIO__SAI0 */
#if defined(AUDIO__SAI1)
void AUDIO_SAI1_INT_DriverIRQHandler(void);
void AUDIO_SAI1_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI1, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI1, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(AUDIO__SAI1, s_saiHandle[1][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI1, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI1, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(AUDIO__SAI1, s_saiHandle[1][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* AUDIO__SAI1 */
#if defined(AUDIO__SAI2)
void AUDIO_SAI2_INT_DriverIRQHandler(void);
void AUDIO_SAI2_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[2][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI2, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[2][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI2, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(AUDIO__SAI2, s_saiHandle[2][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[2][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI2, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[2][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI2, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(AUDIO__SAI2, s_saiHandle[2][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* AUDIO__SAI2 */
#if defined(AUDIO__SAI3)
void AUDIO_SAI3_INT_DriverIRQHandler(void);
void AUDIO_SAI3_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[3][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI3, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[3][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI3, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(AUDIO__SAI3, s_saiHandle[3][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[3][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI3, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[3][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI3, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(AUDIO__SAI3, s_saiHandle[3][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif
#if defined(AUDIO__SAI6)
void AUDIO_SAI6_INT_DriverIRQHandler(void);
void AUDIO_SAI6_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[6][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI6, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[6][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI6, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(AUDIO__SAI6, s_saiHandle[6][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[6][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI6, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[6][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI6, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(AUDIO__SAI6, s_saiHandle[6][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* AUDIO__SAI6 */
#if defined(AUDIO__SAI7)
void AUDIO_SAI7_INT_DriverIRQHandler(void);
void AUDIO_SAI7_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[7][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI7, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[7][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(AUDIO__SAI7, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(AUDIO__SAI7, s_saiHandle[7][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[7][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI7, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[7][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(AUDIO__SAI7, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(AUDIO__SAI7, s_saiHandle[7][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* AUDIO__SAI7 */
#if defined(ADMA__SAI0)
void ADMA_SAI0_INT_DriverIRQHandler(void);
void ADMA_SAI0_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI0, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI0, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(ADMA__SAI0, s_saiHandle[1][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI0, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI0, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(ADMA__SAI0, s_saiHandle[1][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* ADMA__SAI0 */
#if defined(ADMA__SAI1)
void ADMA_SAI1_INT_DriverIRQHandler(void);
void ADMA_SAI1_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI1, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI1, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(ADMA__SAI1, s_saiHandle[1][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI1, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI1, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(ADMA__SAI1, s_saiHandle[1][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* ADMA__SAI1 */
#if defined(ADMA__SAI2)
void ADMA_SAI2_INT_DriverIRQHandler(void);
void ADMA_SAI2_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI2, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI2, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(ADMA__SAI2, s_saiHandle[1][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI2, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI2, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(ADMA__SAI2, s_saiHandle[1][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* ADMA__SAI2 */
#if defined(ADMA__SAI3)
void ADMA_SAI3_INT_DriverIRQHandler(void);
void ADMA_SAI3_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI3, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI3, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(ADMA__SAI3, s_saiHandle[1][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI3, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI3, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(ADMA__SAI3, s_saiHandle[1][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* ADMA__SAI3 */
#if defined(ADMA__SAI4)
void ADMA_SAI4_INT_DriverIRQHandler(void);
void ADMA_SAI4_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI4, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI4, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(ADMA__SAI4, s_saiHandle[1][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI4, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI4, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(ADMA__SAI4, s_saiHandle[1][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* ADMA__SAI4 */
#if defined(ADMA__SAI5)
void ADMA_SAI5_INT_DriverIRQHandler(void);
void ADMA_SAI5_INT_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI5, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][1] != NULL) &&
SAI_RxGetEnabledInterruptStatus(ADMA__SAI5, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(ADMA__SAI5, s_saiHandle[1][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI5, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][0] != NULL) &&
SAI_TxGetEnabledInterruptStatus(ADMA__SAI5, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(ADMA__SAI5, s_saiHandle[1][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* ADMA__SAI5 */
#if defined(SAI0)
void SAI0_DriverIRQHandler(void);
void SAI0_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[0][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI0, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[0][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI0, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(SAI0, s_saiHandle[0][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[0][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI0, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[0][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI0, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(SAI0, s_saiHandle[0][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* SAI0 */
#if defined(SAI1)
void SAI1_DriverIRQHandler(void);
void SAI1_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI1, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI1, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(SAI1, s_saiHandle[1][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[1][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI1, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[1][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI1, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(SAI1, s_saiHandle[1][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* SAI1 */
#if defined(SAI2)
void SAI2_DriverIRQHandler(void);
void SAI2_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[2][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI2, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[2][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI2, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(SAI2, s_saiHandle[2][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[2][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI2, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[2][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI2, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(SAI2, s_saiHandle[2][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* SAI2 */
#if defined(SAI3)
void SAI3_DriverIRQHandler(void);
void SAI3_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[3][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI3, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[3][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI3, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(SAI3, s_saiHandle[3][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[3][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI3, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[3][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI3, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(SAI3, s_saiHandle[3][0]);
}
SDK_ISR_EXIT_BARRIER;
}
void SAI3_TX_DriverIRQHandler(void);
void SAI3_TX_DriverIRQHandler(void)
{
assert(s_saiHandle[3][0] != NULL);
s_saiTxIsr(SAI3, s_saiHandle[3][0]);
SDK_ISR_EXIT_BARRIER;
}
void SAI3_RX_DriverIRQHandler(void);
void SAI3_RX_DriverIRQHandler(void)
{
assert(s_saiHandle[3][1] != NULL);
s_saiRxIsr(SAI3, s_saiHandle[3][1]);
SDK_ISR_EXIT_BARRIER;
}
#endif /* SAI3 */
#if defined(SAI4)
void SAI4_DriverIRQHandler(void);
void SAI4_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[4][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI4, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[4][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI4, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(SAI4, s_saiHandle[4][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[4][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI4, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[4][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI4, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(SAI4, s_saiHandle[4][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* SAI4 */
#if defined(SAI5)
void SAI5_DriverIRQHandler(void);
void SAI5_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[5][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI5, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[5][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI5, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(SAI5, s_saiHandle[5][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[5][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI5, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[5][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI5, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(SAI5, s_saiHandle[5][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* SAI5 */
#if defined(SAI6)
void SAI6_DriverIRQHandler(void);
void SAI6_DriverIRQHandler(void)
{
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[6][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI6, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[6][1] != NULL) && SAI_RxGetEnabledInterruptStatus(SAI6, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiRxIsr(SAI6, s_saiHandle[6][1]);
}
#if defined(FSL_FEATURE_SAI_FIFO_COUNT) && (FSL_FEATURE_SAI_FIFO_COUNT > 1)
if ((s_saiHandle[6][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI6, (I2S_TCSR_FRIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FRF_MASK | I2S_TCSR_FEF_MASK)))
#else
if ((s_saiHandle[6][0] != NULL) && SAI_TxGetEnabledInterruptStatus(SAI6, (I2S_TCSR_FWIE_MASK | I2S_TCSR_FEIE_MASK),
(I2S_TCSR_FWF_MASK | I2S_TCSR_FEF_MASK)))
#endif
{
s_saiTxIsr(SAI6, s_saiHandle[6][0]);
}
SDK_ISR_EXIT_BARRIER;
}
#endif /* SAI6 */