/* * Copyright (c) 2006-2018, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2018-4-30 misonyo the first version. */ #include #include #include #ifdef BSP_USING_AUDIO #define LOG_TAG "drv.sai" #include #include #include "drivers/audio.h" #include "bsp_wm8960.h" #include "drv_i2c.h" #include "drv_sai.h" #define RX_DMA_FIFO_SIZE (2048) volatile rt_uint16_t rx_busy = 0; volatile rt_uint16_t tx_busy = 0; struct drv_sai sai_tx = {0}; struct drv_sai sai_rx = {0}; wm8960_config_t wm8960Config = { .route = kWM8960_RoutePlaybackandRecord, .rightInputSource = kWM8960_InputDifferentialMicInput2, .playSource = kWM8960_PlaySourceDAC, .slaveAddress = WM8960_I2C_ADDR, .bus = kWM8960_BusI2S, .format = {.mclk_HZ = 6144000U, .sampleRate = kWM8960_AudioSampleRate16KHz, .bitWidth = kWM8960_AudioBitWidth16bit}, .master_slave = false, }; const clock_audio_pll_config_t audioPllConfig = { .loopDivider = 32, /* PLL loop divider. Valid range for DIV_SELECT divider value: 27~54. */ .postDivider = 1, /* Divider after the PLL, should only be 1, 2, 4, 8, 16. */ .numerator = 77, /* 30 bit numerator of fractional loop divider. */ .denominator = 100, /* 30 bit denominator of fractional loop divider */ }; sai_transfer_format_t format; sai_config_t config; sai_transfer_t xfer; struct imxrt_sai { struct rt_audio_device audio; struct rt_audio_configure play_config; rt_uint16_t volume; rt_uint8_t* tx_fifo; struct rt_i2c_bus_device* i2c_bus; rt_uint8_t* rx_fifo; }; struct imxrt_sai imxrt_payer_dev = { 0 }; static void sai_config(void) { #ifdef BSP_AUDIO_USING_DMA static struct saidma_tx_config sai_txdma = { .channel = 0U, .request = kDmaRequestMuxSai1Tx }; sai_tx.dma_tx = &sai_txdma; sai_tx.dma_flag |= RT_DEVICE_FLAG_DMA_TX; #if defined (BSP_USING_AUDIO_RECORD) static struct saidma_rx_config sai_rxdma = { .channel = 1U, .request = kDmaRequestMuxSai1Rx }; sai_rx.dma_rx = &sai_rxdma; #endif #endif } static void sai_TxDmaCallback(I2S_Type* base, sai_edma_handle_t* handle, rt_int32_t status, void* userData) { tx_busy = 1; rt_audio_tx_complete(&imxrt_payer_dev.audio); } #if defined (BSP_USING_AUDIO_RECORD) static void sai_RxDmaCallback(I2S_Type* base, sai_edma_handle_t* handle, rt_int32_t status, void* userData) { rx_busy = 1; rt_audio_rx_done(&imxrt_payer_dev.audio, &imxrt_payer_dev.rx_fifo[0], RX_DMA_FIFO_SIZE / 2); } #endif void BOARD_EnableSaiMclkOutput(rt_bool_t enable) { if(enable) { IOMUXC_GPR->GPR1 |= IOMUXC_GPR_GPR1_SAI1_MCLK_DIR_MASK; } else { IOMUXC_GPR->GPR1 &= (~IOMUXC_GPR_GPR1_SAI1_MCLK_DIR_MASK); } } void sai_format(void) { SAI_TransferTxCreateHandleEDMA(sai_tx.base, &sai_tx.dma_tx->txHandle, sai_TxDmaCallback, NULL, &sai_tx.dma_tx->edma); SAI_TransferTxSetFormatEDMA(sai_tx.base, &sai_tx.dma_tx->txHandle, &format, DEMO_SAI_CLK_FREQ, DEMO_SAI_CLK_FREQ); #if defined (BSP_USING_AUDIO_RECORD) SAI_TransferRxCreateHandleEDMA(sai_rx.base, &sai_rx.dma_rx->rxHandle, sai_RxDmaCallback, NULL, &sai_rx.dma_rx->edma); SAI_TransferRxSetFormatEDMA(sai_rx.base, &sai_rx.dma_rx->rxHandle, &format, DEMO_SAI_CLK_FREQ, DEMO_SAI_CLK_FREQ); #endif } void sai_init(void) { CLOCK_InitAudioPll(&audioPllConfig); CLOCK_SetMux(kCLOCK_Sai1Mux, DEMO_SAI1_CLOCK_SOURCE_SELECT); CLOCK_SetDiv(kCLOCK_Sai1PreDiv, DEMO_SAI1_CLOCK_SOURCE_PRE_DIVIDER); CLOCK_SetDiv(kCLOCK_Sai1Div, DEMO_SAI1_CLOCK_SOURCE_DIVIDER); BOARD_EnableSaiMclkOutput(RT_TRUE); EDMA_CreateHandle(&sai_tx.dma_tx->edma, DMA0, sai_tx.dma_tx->channel); DMAMUX_SetSource(DMAMUX, sai_tx.dma_tx->channel, (rt_uint8_t)sai_tx.dma_tx->request); DMAMUX_EnableChannel(DMAMUX, sai_tx.dma_tx->channel); SAI_TxGetDefaultConfig(&config); SAI_TxInit(sai_tx.base, &config); #if defined (BSP_USING_AUDIO_RECORD) EDMA_CreateHandle(&sai_rx.dma_rx->edma, DMA0, sai_rx.dma_rx->channel); DMAMUX_SetSource(DMAMUX, sai_rx.dma_rx->channel, (rt_uint8_t)sai_rx.dma_rx->request); DMAMUX_EnableChannel(DMAMUX, sai_rx.dma_rx->channel); SAI_RxGetDefaultConfig(&config); SAI_RxInit(sai_rx.base, &config); #endif format.bitWidth = kSAI_WordWidth16bits; format.channel = 0U; format.sampleRate_Hz = kSAI_SampleRate16KHz; format.masterClockHz = DEMO_SAI_CLK_FREQ; format.protocol = config.protocol; format.stereo = kSAI_Stereo; format.isFrameSyncCompact = true; format.watermark = FSL_FEATURE_SAI_FIFO_COUNT / 2U; SAI_TransferTxCreateHandleEDMA(sai_tx.base, &sai_tx.dma_tx->txHandle, sai_TxDmaCallback, NULL, &sai_tx.dma_tx->edma); SAI_TransferTxSetFormatEDMA(sai_tx.base, &sai_tx.dma_tx->txHandle, &format, DEMO_SAI_CLK_FREQ, DEMO_SAI_CLK_FREQ); #if defined (BSP_USING_AUDIO_RECORD) SAI_TransferRxCreateHandleEDMA(sai_rx.base, &sai_rx.dma_rx->rxHandle, sai_RxDmaCallback, NULL, &sai_rx.dma_rx->edma); SAI_TransferRxSetFormatEDMA(sai_rx.base, &sai_rx.dma_rx->rxHandle, &format, DEMO_SAI_CLK_FREQ, DEMO_SAI_CLK_FREQ); #endif } void SAI_samplerate_set(rt_uint32_t freq) { switch(freq) { case 48000: format.sampleRate_Hz = kSAI_SampleRate48KHz; break; case 44100: format.sampleRate_Hz = kSAI_SampleRate44100Hz; break; case 32000: format.sampleRate_Hz = kSAI_SampleRate32KHz; break; case 24000: format.sampleRate_Hz = kSAI_SampleRate24KHz; break; case 22050: format.sampleRate_Hz = kSAI_SampleRate22050Hz; break; case 16000: format.sampleRate_Hz = kSAI_SampleRate16KHz; break; case 12000: format.sampleRate_Hz = kSAI_SampleRate12KHz; break; case 11025: format.sampleRate_Hz = kSAI_SampleRate11025Hz; break; case 8000: format.sampleRate_Hz = kSAI_SampleRate8KHz; break; default: format.sampleRate_Hz = kSAI_SampleRate16KHz; break; } } void SAI_channels_set(rt_uint16_t channels) { switch(channels) { case 2: format.stereo = kSAI_Stereo; break; case 1: format.stereo = kSAI_MonoRight; break; case 0: format.stereo = kSAI_MonoLeft; break; default: format.stereo = kSAI_Stereo; break; } } void SAI_samplebits_set(rt_uint16_t samplebits) { switch(samplebits) { case 16: format.bitWidth = kSAI_WordWidth16bits; break; case 24: format.bitWidth = kSAI_WordWidth24bits; break; case 32: format.bitWidth = kSAI_WordWidth32bits; break; default: format.bitWidth = kSAI_WordWidth16bits; break; } } static rt_err_t imxrt_payer_getcaps(struct rt_audio_device* audio, struct rt_audio_caps* caps) { rt_err_t result = RT_EOK; RT_ASSERT(audio != RT_NULL); struct imxrt_sai* imxrt_audio = (struct imxrt_sai*)audio->parent.user_data; switch(caps->main_type) { case AUDIO_TYPE_QUERY: /* qurey the types of hw_codec device */ { switch(caps->sub_type) { case AUDIO_TYPE_QUERY: caps->udata.mask = AUDIO_TYPE_OUTPUT | AUDIO_TYPE_MIXER; break; default: result = -RT_ERROR; break; } break; } case AUDIO_TYPE_INPUT: { switch(caps->sub_type) { case AUDIO_DSP_PARAM: caps->udata.config.channels = imxrt_audio->play_config.channels; caps->udata.config.samplebits = imxrt_audio->play_config.samplebits; caps->udata.config.samplerate = imxrt_audio->play_config.samplerate; break; case AUDIO_DSP_SAMPLERATE: caps->udata.config.samplerate = imxrt_audio->play_config.samplerate; break; case AUDIO_DSP_CHANNELS: caps->udata.config.channels = imxrt_audio->play_config.channels; break; case AUDIO_DSP_SAMPLEBITS: caps->udata.config.samplebits = imxrt_audio->play_config.samplebits; break; default: result = -RT_ERROR; break; } break; } case AUDIO_TYPE_OUTPUT: /* Provide capabilities of OUTPUT unit */ { switch(caps->sub_type) { case AUDIO_DSP_PARAM: caps->udata.config.samplerate = imxrt_audio->play_config.samplerate; caps->udata.config.channels = imxrt_audio->play_config.channels; caps->udata.config.samplebits = imxrt_audio->play_config.samplebits; break; case AUDIO_DSP_SAMPLERATE: caps->udata.config.samplerate = imxrt_audio->play_config.samplerate; break; case AUDIO_DSP_CHANNELS: caps->udata.config.channels = imxrt_audio->play_config.channels; break; case AUDIO_DSP_SAMPLEBITS: caps->udata.config.samplebits = imxrt_audio->play_config.samplebits; break; default: result = -RT_ERROR; break; } break; } case AUDIO_TYPE_MIXER: /* report the Mixer Units */ { switch(caps->sub_type) { case AUDIO_MIXER_QUERY: caps->udata.mask = AUDIO_MIXER_VOLUME; break; case AUDIO_MIXER_VOLUME: caps->udata.value = WM8960_GetVolume(imxrt_payer_dev.i2c_bus,kWM8960_ModuleDAC); break; default: result = -RT_ERROR; break; } break; } default: result = -RT_ERROR; break; } return result; } static rt_err_t imxrt_payer_configure(struct rt_audio_device* audio, struct rt_audio_caps* caps) { rt_err_t result = RT_EOK; RT_ASSERT(audio != RT_NULL); struct imxrt_sai* imxrt_audio = (struct imxrt_sai*)audio->parent.user_data; switch(caps->main_type) { case AUDIO_TYPE_MIXER: { switch(caps->sub_type) { case AUDIO_MIXER_MUTE: { /* set mute mode */ WM8960_SetMute(imxrt_payer_dev.i2c_bus, kWM8960_ModuleDAC, RT_FALSE); break; } case AUDIO_MIXER_VOLUME: { int volume = caps->udata.value; imxrt_audio->volume = volume; /* set mixer volume */ WM8960_SetVolume(imxrt_payer_dev.i2c_bus, kWM8960_ModuleDAC, volume); break; } default: result = -RT_ERROR; break; } break; } case AUDIO_TYPE_OUTPUT: { switch(caps->sub_type) { case AUDIO_DSP_PARAM: { struct rt_audio_configure config = caps->udata.config; imxrt_audio->play_config.samplerate = config.samplerate; imxrt_audio->play_config.samplebits = config.samplebits; imxrt_audio->play_config.channels = config.channels; SAI_channels_set(config.channels); SAI_samplerate_set(config.samplerate); SAI_samplebits_set(config.samplebits); break; } case AUDIO_DSP_SAMPLERATE: { imxrt_audio->play_config.samplerate = caps->udata.config.samplerate; SAI_samplerate_set(caps->udata.config.samplerate); break; } case AUDIO_DSP_CHANNELS: { imxrt_audio->play_config.channels = caps->udata.config.channels; SAI_channels_set(caps->udata.config.channels); break; } case AUDIO_DSP_SAMPLEBITS: { imxrt_audio->play_config.samplebits = caps->udata.config.samplebits; SAI_samplebits_set(caps->udata.config.samplebits); break; } default: result = -RT_ERROR; break; } break; } case AUDIO_TYPE_INPUT: { switch(caps->sub_type) { case AUDIO_DSP_PARAM: { imxrt_audio->play_config.samplerate = caps->udata.config.samplerate; imxrt_audio->play_config.channels = caps->udata.config.channels; imxrt_audio->play_config.samplebits = caps->udata.config.samplebits; SAI_TransferTerminateReceiveEDMA(sai_rx.base, &sai_rx.dma_rx->rxHandle); SAI_samplerate_set(caps->udata.config.samplerate); SAI_channels_set(caps->udata.config.channels); SAI_samplebits_set(caps->udata.config.samplebits); break; } case AUDIO_DSP_SAMPLERATE: { imxrt_audio->play_config.samplerate = caps->udata.config.samplerate; SAI_samplerate_set(caps->udata.config.samplerate); break; } case AUDIO_DSP_CHANNELS: { imxrt_audio->play_config.channels = caps->udata.config.channels; SAI_channels_set(caps->udata.config.channels); break; } case AUDIO_DSP_SAMPLEBITS: { imxrt_audio->play_config.samplebits = caps->udata.config.samplebits; SAI_samplebits_set(caps->udata.config.samplebits); break; } default: result = -RT_ERROR; break; } /* After set config, MCLK will stop */ SAI_TxSoftwareReset(sai_tx.base, kSAI_ResetTypeSoftware); SAI_RxSoftwareReset(sai_rx.base, kSAI_ResetTypeSoftware); xfer.data = imxrt_payer_dev.tx_fifo; // +i * (AUD_FIFO_SIZE / 4); xfer.dataSize = AUD_BLOCK_SIZE; SAI_TransferSendEDMA(sai_tx.base, &sai_tx.dma_tx->txHandle, &xfer); SAI_TransferReceiveEDMA(sai_rx.base, &sai_rx.dma_rx->rxHandle, &xfer); break; } default: break; } return result; } static rt_err_t imxrt_payer_init(struct rt_audio_device* audio) { RT_ASSERT(audio != RT_NULL); imxrt_payer_dev.i2c_bus = (struct rt_i2c_bus_device*)rt_device_find(CODEC_I2C_NAME); sai_init(); return RT_EOK; } static rt_err_t imxrt_payer_start(struct rt_audio_device* audio, int stream) { RT_ASSERT(audio != RT_NULL); sai_format(); WM8960_init(imxrt_payer_dev.i2c_bus, &wm8960Config); xfer.data = imxrt_payer_dev.rx_fifo; xfer.dataSize = AUD_BLOCK_SIZE; #if defined (BSP_USING_AUDIO_RECORD) SAI_TransferReceiveEDMA(sai_rx.base, &sai_rx.dma_rx->rxHandle, &xfer); #endif SAI_TransferSendEDMA(sai_tx.base, &sai_tx.dma_tx->txHandle, &xfer); return RT_EOK; } static rt_err_t imxrt_payer_stop(struct rt_audio_device* audio, int stream) { RT_ASSERT(audio != RT_NULL); SAI_TransferTerminateSendEDMA(sai_tx.base, &sai_tx.dma_tx->txHandle); SAI_TransferTerminateReceiveEDMA(sai_rx.base, &sai_rx.dma_rx->rxHandle); WM8960_Deinit(imxrt_payer_dev.i2c_bus); return RT_EOK; } static rt_size_t imxrt_payer_transmit(struct rt_audio_device* audio, const void* writeBuf, void* readBuf, rt_size_t size) { RT_ASSERT(audio != RT_NULL); #if defined (BSP_USING_AUDIO_RECORD) xfer.data = imxrt_payer_dev.rx_fifo; xfer.dataSize = RX_DMA_FIFO_SIZE; SAI_TransferReceiveEDMA(sai_rx.base, &sai_rx.dma_rx->rxHandle, &xfer); SAI_TransferSendEDMA(sai_tx.base, &sai_tx.dma_tx->txHandle, &xfer); #else xfer.data = (rt_uint8_t*)writeBuf; xfer.dataSize = size; SAI_TransferSendEDMA(sai_tx.base, &sai_tx.dma_tx->txHandle, &xfer); #endif return size; } static void imxrt_payer_buffer_info(struct rt_audio_device* audio, struct rt_audio_buf_info* info) { RT_ASSERT(audio != RT_NULL); /** * AUD_FIFO * +----------------+----------------+ * | block1 | block2 | * +----------------+----------------+ * \ block_size / */ info->buffer = imxrt_payer_dev.tx_fifo; info->total_size = AUD_DMA_FIFO_SIZE; info->block_size = AUD_DMA_FIFO_SIZE / 2; info->block_count = 2; } static struct rt_audio_ops imxrt_payer_ops = { .getcaps = imxrt_payer_getcaps, .configure = imxrt_payer_configure, .init = imxrt_payer_init, .start = imxrt_payer_start, .stop = imxrt_payer_stop, .transmit = imxrt_payer_transmit, .buffer_info = imxrt_payer_buffer_info, }; int rt_hw_sound_init(void) { rt_uint8_t* tx_fifo = RT_NULL; rt_uint8_t* rx_fifo = RT_NULL; sai_tx.base = SAI1; sai_rx.base = SAI1; sai_tx.irqn = SAI1_IRQn; sai_config(); tx_fifo = rt_calloc(1, AUD_DMA_FIFO_SIZE); rx_fifo = rt_calloc(1, AUD_DMA_FIFO_SIZE); if(tx_fifo == RT_NULL) { return -RT_ENOMEM; } rt_memset(tx_fifo, 0, AUD_DMA_FIFO_SIZE); imxrt_payer_dev.tx_fifo = tx_fifo; rt_memset(rx_fifo, 0, AUD_DMA_FIFO_SIZE); imxrt_payer_dev.rx_fifo = rx_fifo; imxrt_payer_dev.audio.ops = &imxrt_payer_ops; rt_audio_register(&imxrt_payer_dev.audio, "mic", RT_DEVICE_FLAG_RDWR, &imxrt_payer_dev); return RT_EOK; } INIT_DEVICE_EXPORT(rt_hw_sound_init); #endif /* BSP_USING_AUDIO*/