Skip to content
Permalink
bcafcf8fc3
Switch branches/tags

Name already in use

A tag already exists with the provided branch name. Many Git commands accept both tag and branch names, so creating this branch may cause unexpected behavior. Are you sure you want to create this branch?

micropython/ports/mimxrt/machine_i2s.c

Go to file
 
 
Cannot retrieve contributors at this time
725 lines (629 sloc) 27 KB
Raw Blame
/*
* This file is part of the MicroPython project, http://micropython.org/
*
* The MIT License (MIT)
*
* Copyright (c) 2022 Mike Teachman
* Copyright (c) 2022 Robert Hammelrath
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
// This file is never compiled standalone, it's included directly from
// extmod/machine_i2s.c via MICROPY_PY_MACHINE_I2S_INCLUDEFILE.
#include "py/mphal.h"
#include "dma_manager.h"
#include CLOCK_CONFIG_H
#include "fsl_iomuxc.h"
#include "fsl_dmamux.h"
#include "fsl_edma.h"
#include "fsl_sai.h"
// Notes on this port's specific implementation of I2S:
// - the DMA callback is used to implement the asynchronous background operations, for non-blocking mode
// - all 3 Modes of operation are implemented using the peripheral drivers in the NXP MCUXpresso SDK
// - all sample data transfers use DMA
// - the DMA ping-pong buffer needs to be aligned to a cache line size of 32 bytes. 32 byte
// alignment is needed to use the routines that clean and invalidate D-Cache which work on a
// 32 byte address boundary.
// - master clock frequency is sampling frequency * 256
// DMA ping-pong buffer size was empirically determined. It is a tradeoff between:
// 1. memory use (smaller buffer size desirable to reduce memory footprint)
// 2. interrupt frequency (larger buffer size desirable to reduce interrupt frequency)
// The sizeof 1/2 of the DMA buffer must be evenly divisible by the cache line size of 32 bytes.
#define SIZEOF_DMA_BUFFER_IN_BYTES (256)
#define SIZEOF_HALF_DMA_BUFFER_IN_BYTES (SIZEOF_DMA_BUFFER_IN_BYTES / 2)
// For non-blocking mode, to avoid underflow/overflow, sample data is written/read to/from the ring buffer at a rate faster
// than the DMA transfer rate
#define NON_BLOCKING_RATE_MULTIPLIER (4)
#define SIZEOF_NON_BLOCKING_COPY_IN_BYTES (SIZEOF_HALF_DMA_BUFFER_IN_BYTES * NON_BLOCKING_RATE_MULTIPLIER)
#define SAI_CHANNEL_0 (0)
#define SAI_NUM_AUDIO_CHANNELS (2U)
typedef enum {
SCK,
WS,
SD,
MCK
} i2s_pin_function_t;
typedef enum {
RX,
TX,
} i2s_mode_t;
typedef enum {
TOP_HALF,
BOTTOM_HALF
} ping_pong_t;
typedef struct _machine_i2s_obj_t {
mp_obj_base_t base;
uint8_t i2s_id;
mp_hal_pin_obj_t sck;
mp_hal_pin_obj_t ws;
mp_hal_pin_obj_t sd;
mp_hal_pin_obj_t mck;
i2s_mode_t mode;
int8_t bits;
format_t format;
int32_t rate;
int32_t ibuf;
mp_obj_t callback_for_non_blocking;
uint8_t dma_buffer[SIZEOF_DMA_BUFFER_IN_BYTES + 0x1f]; // 0x1f related to D-Cache alignment
uint8_t *dma_buffer_dcache_aligned;
ring_buf_t ring_buffer;
uint8_t *ring_buffer_storage;
non_blocking_descriptor_t non_blocking_descriptor;
io_mode_t io_mode;
I2S_Type *i2s_inst;
int dma_channel;
edma_handle_t edmaHandle;
edma_tcd_t *edmaTcd;
} machine_i2s_obj_t;
typedef struct _iomux_table_t {
uint32_t muxRegister;
uint32_t muxMode;
uint32_t inputRegister;
uint32_t inputDaisy;
uint32_t configRegister;
} iomux_table_t;
typedef struct _gpio_map_t {
uint8_t hw_id;
i2s_pin_function_t fn;
i2s_mode_t mode;
qstr name;
iomux_table_t iomux;
} gpio_map_t;
typedef struct _i2s_clock_config_t {
sai_sample_rate_t rate;
const clock_audio_pll_config_t *pll_config;
uint32_t clock_pre_divider;
uint32_t clock_divider;
} i2s_clock_config_t;
static mp_obj_t machine_i2s_deinit(mp_obj_t self_in);
// The frame map is used with the readinto() method to transform the audio sample data coming
// from DMA memory (32-bit stereo) to the format specified
// in the I2S constructor. e.g. 16-bit mono
static const int8_t i2s_frame_map[NUM_I2S_USER_FORMATS][I2S_RX_FRAME_SIZE_IN_BYTES] = {
{-1, -1, 0, 1, -1, -1, -1, -1 }, // Mono, 16-bits
{ 0, 1, 2, 3, -1, -1, -1, -1 }, // Mono, 32-bits
{-1, -1, 0, 1, -1, -1, 2, 3 }, // Stereo, 16-bits
{ 0, 1, 2, 3, 4, 5, 6, 7 }, // Stereo, 32-bits
};
// 2 PLL configurations
// PLL output frequency = 24MHz * (.loopDivider + .numerator/.denominator)
// Configuration 1: for sampling frequencies [Hz]: 8000, 12000, 16000, 24000, 32000, 48000
// Clock frequency = 786,432,000 Hz = 48000 * 64 * 256
static const clock_audio_pll_config_t audioPllConfig_8000_48000 = {
.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 = 76800, // 30 bit numerator of fractional loop divider
.denominator = 100000, // 30 bit denominator of fractional loop divider
#if !defined(MIMXRT117x_SERIES)
.src = kCLOCK_PllClkSrc24M // Pll clock source
#endif
};
// Configuration 2: for sampling frequencies [Hz]: 11025, 22050, 44100
// Clock frequency = 722,534,400 = 44100 * 64 * 256
static const clock_audio_pll_config_t audioPllConfig_11025_44100 = {
.loopDivider = 30, // 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 = 10560, // 30 bit numerator of fractional loop divider
.denominator = 100000, // 30 bit denominator of fractional loop divider
#if !defined(MIMXRT117x_SERIES)
.src = kCLOCK_PllClkSrc24M // Pll clock source
#endif
};
#if defined(MIMXRT117x_SERIES)
// for 1176 the pre_div value is used for post_div of the Audio PLL,
// which is 2**n: 0->1, 1->2, 2->4, 3->8, 4->16, 5->32
// The divider is 8 bit and must be given as n (not n-1)
// So the total division factor is given by (2**p) * d
static const i2s_clock_config_t clock_config_map[] = {
{kSAI_SampleRate8KHz, &audioPllConfig_8000_48000, 1, 192}, // 384
{kSAI_SampleRate11025Hz, &audioPllConfig_11025_44100, 1, 128}, // 256
{kSAI_SampleRate12KHz, &audioPllConfig_8000_48000, 1, 128}, // 256
{kSAI_SampleRate16KHz, &audioPllConfig_8000_48000, 0, 192}, // 192
{kSAI_SampleRate22050Hz, &audioPllConfig_11025_44100, 0, 128}, // 128
{kSAI_SampleRate24KHz, &audioPllConfig_8000_48000, 0, 128}, // 128
{kSAI_SampleRate32KHz, &audioPllConfig_8000_48000, 0, 96}, // 96
{kSAI_SampleRate44100Hz, &audioPllConfig_11025_44100, 0, 64}, // 64
{kSAI_SampleRate48KHz, &audioPllConfig_8000_48000, 0, 64} // 64
};
static const clock_root_t i2s_clock_mux[] = I2S_CLOCK_MUX;
#else
// for 10xx the total division factor is given by (p + 1) * (d + 1)
static const i2s_clock_config_t clock_config_map[] = {
{kSAI_SampleRate8KHz, &audioPllConfig_8000_48000, 5, 63}, // 384
{kSAI_SampleRate11025Hz, &audioPllConfig_11025_44100, 3, 63}, // 256
{kSAI_SampleRate12KHz, &audioPllConfig_8000_48000, 3, 63}, // 256
{kSAI_SampleRate16KHz, &audioPllConfig_8000_48000, 2, 63}, // 192
{kSAI_SampleRate22050Hz, &audioPllConfig_11025_44100, 1, 63}, // 128
{kSAI_SampleRate24KHz, &audioPllConfig_8000_48000, 1, 63}, // 128
{kSAI_SampleRate32KHz, &audioPllConfig_8000_48000, 1, 47}, // 96
{kSAI_SampleRate44100Hz, &audioPllConfig_11025_44100, 0, 63}, // 64
{kSAI_SampleRate48KHz, &audioPllConfig_8000_48000, 0, 63} // 64
};
static const clock_mux_t i2s_clock_mux[] = I2S_CLOCK_MUX;
static const clock_div_t i2s_clock_pre_div[] = I2S_CLOCK_PRE_DIV;
static const clock_div_t i2s_clock_div[] = I2S_CLOCK_DIV;
static const iomuxc_gpr_mode_t i2s_iomuxc_gpr_mode[] = I2S_IOMUXC_GPR_MODE;
#endif
static const I2S_Type *i2s_base_ptr[] = I2S_BASE_PTRS;
static const dma_request_source_t i2s_dma_req_src_tx[] = I2S_DMA_REQ_SRC_TX;
static const dma_request_source_t i2s_dma_req_src_rx[] = I2S_DMA_REQ_SRC_RX;
static const gpio_map_t i2s_gpio_map[] = I2S_GPIO_MAP;
AT_NONCACHEABLE_SECTION_ALIGN(edma_tcd_t edmaTcd[MICROPY_HW_I2S_NUM], 32);
// called on processor reset
void machine_i2s_init0() {
for (uint8_t i = 0; i < MICROPY_HW_I2S_NUM; i++) {
MP_STATE_PORT(machine_i2s_obj)[i] = NULL;
}
}
// called on soft reboot
void machine_i2s_deinit_all(void) {
for (uint8_t i = 0; i < MICROPY_HW_I2S_NUM; i++) {
machine_i2s_obj_t *i2s_obj = MP_STATE_PORT(machine_i2s_obj)[i];
if (i2s_obj != NULL) {
machine_i2s_deinit(i2s_obj);
MP_STATE_PORT(machine_i2s_obj)[i] = NULL;
}
}
}
static int8_t get_frame_mapping_index(int8_t bits, format_t format) {
if (format == MONO) {
if (bits == 16) {
return 0;
} else { // 32 bits
return 1;
}
} else { // STEREO
if (bits == 16) {
return 2;
} else { // 32 bits
return 3;
}
}
}
static int8_t get_dma_bits(uint16_t mode, int8_t bits) {
if (mode == TX) {
if (bits == 16) {
return 16;
} else {
return 32;
}
return bits;
} else { // RX
// always read 32 bit words for I2S e.g. I2S MEMS microphones
return 32;
}
}
static bool lookup_gpio(const machine_pin_obj_t *pin, i2s_pin_function_t fn, uint8_t hw_id, uint16_t *index) {
for (uint16_t i = 0; i < ARRAY_SIZE(i2s_gpio_map); i++) {
if ((pin->name == i2s_gpio_map[i].name) &&
(i2s_gpio_map[i].fn == fn) &&
(i2s_gpio_map[i].hw_id == hw_id)) {
*index = i;
return true;
}
}
return false;
}
static bool set_iomux(const machine_pin_obj_t *pin, i2s_pin_function_t fn, uint8_t hw_id) {
uint16_t mapping_index;
if (lookup_gpio(pin, fn, hw_id, &mapping_index)) {
iomux_table_t iom = i2s_gpio_map[mapping_index].iomux;
IOMUXC_SetPinMux(iom.muxRegister, iom.muxMode, iom.inputRegister, iom.inputDaisy, iom.configRegister, 1U);
IOMUXC_SetPinConfig(iom.muxRegister, iom.muxMode, iom.inputRegister, iom.inputDaisy, iom.configRegister,
pin_generate_config(PIN_PULL_DISABLED, PIN_MODE_OUT, 2, iom.configRegister));
return true;
} else {
return false;
}
}
static bool is_rate_supported(int32_t rate) {
for (uint16_t i = 0; i < ARRAY_SIZE(clock_config_map); i++) {
if (clock_config_map[i].rate == rate) {
return true;
}
}
return false;
}
static const clock_audio_pll_config_t *get_pll_config(int32_t rate) {
for (uint16_t i = 0; i < ARRAY_SIZE(clock_config_map); i++) {
if (clock_config_map[i].rate == rate) {
return clock_config_map[i].pll_config;
}
}
return 0;
}
static const uint32_t get_clock_pre_divider(int32_t rate) {
for (uint16_t i = 0; i < ARRAY_SIZE(clock_config_map); i++) {
if (clock_config_map[i].rate == rate) {
return clock_config_map[i].clock_pre_divider;
}
}
return 0;
}
static const uint32_t get_clock_divider(int32_t rate) {
for (uint16_t i = 0; i < ARRAY_SIZE(clock_config_map); i++) {
if (clock_config_map[i].rate == rate) {
return clock_config_map[i].clock_divider;
}
}
return 0;
}
// function is used in IRQ context
static void empty_dma(machine_i2s_obj_t *self, ping_pong_t dma_ping_pong) {
uint16_t dma_buffer_offset = 0;
if (dma_ping_pong == TOP_HALF) {
dma_buffer_offset = 0;
} else { // BOTTOM_HALF
dma_buffer_offset = SIZEOF_HALF_DMA_BUFFER_IN_BYTES;
}
uint8_t *dma_buffer_p = &self->dma_buffer_dcache_aligned[dma_buffer_offset];
// flush and invalidate cache so the CPU reads data placed into RAM by DMA
MP_HAL_CLEANINVALIDATE_DCACHE(dma_buffer_p, SIZEOF_HALF_DMA_BUFFER_IN_BYTES);
// when space exists, copy samples into ring buffer
if (ringbuf_available_space(&self->ring_buffer) >= SIZEOF_HALF_DMA_BUFFER_IN_BYTES) {
for (uint32_t i = 0; i < SIZEOF_HALF_DMA_BUFFER_IN_BYTES; i++) {
ringbuf_push(&self->ring_buffer, dma_buffer_p[i]);
}
}
}
// function is used in IRQ context
static void feed_dma(machine_i2s_obj_t *self, ping_pong_t dma_ping_pong) {
uint16_t dma_buffer_offset = 0;
if (dma_ping_pong == TOP_HALF) {
dma_buffer_offset = 0;
} else { // BOTTOM_HALF
dma_buffer_offset = SIZEOF_HALF_DMA_BUFFER_IN_BYTES;
}
uint8_t *dma_buffer_p = &self->dma_buffer_dcache_aligned[dma_buffer_offset];
// when data exists, copy samples from ring buffer
if (ringbuf_available_data(&self->ring_buffer) >= SIZEOF_HALF_DMA_BUFFER_IN_BYTES) {
// copy a block of samples from the ring buffer to the dma buffer.
// mono format is implemented by duplicating each sample into both L and R channels.
if ((self->format == MONO) && (self->bits == 16)) {
for (uint32_t i = 0; i < SIZEOF_HALF_DMA_BUFFER_IN_BYTES / 4; i++) {
for (uint8_t b = 0; b < sizeof(uint16_t); b++) {
ringbuf_pop(&self->ring_buffer, &dma_buffer_p[i * 4 + b]);
dma_buffer_p[i * 4 + b + 2] = dma_buffer_p[i * 4 + b]; // duplicated mono sample
}
}
} else if ((self->format == MONO) && (self->bits == 32)) {
for (uint32_t i = 0; i < SIZEOF_HALF_DMA_BUFFER_IN_BYTES / 8; i++) {
for (uint8_t b = 0; b < sizeof(uint32_t); b++) {
ringbuf_pop(&self->ring_buffer, &dma_buffer_p[i * 8 + b]);
dma_buffer_p[i * 8 + b + 4] = dma_buffer_p[i * 8 + b]; // duplicated mono sample
}
}
} else { // STEREO, both 16-bit and 32-bit
for (uint32_t i = 0; i < SIZEOF_HALF_DMA_BUFFER_IN_BYTES; i++) {
ringbuf_pop(&self->ring_buffer, &dma_buffer_p[i]);
}
}
} else {
// underflow. clear buffer to transmit "silence" on the I2S bus
memset(dma_buffer_p, 0, SIZEOF_HALF_DMA_BUFFER_IN_BYTES);
}
// flush cache to RAM so DMA can read the sample data
MP_HAL_CLEAN_DCACHE(dma_buffer_p, SIZEOF_HALF_DMA_BUFFER_IN_BYTES);
}
static void edma_i2s_callback(edma_handle_t *handle, void *userData, bool transferDone, uint32_t tcds) {
machine_i2s_obj_t *self = userData;
if (self->mode == TX) {
// for non-blocking mode, sample copying (appbuf->ibuf) is initiated in this callback routine
if ((self->io_mode == NON_BLOCKING) && (self->non_blocking_descriptor.copy_in_progress)) {
copy_appbuf_to_ringbuf_non_blocking(self);
}
if (transferDone) {
// bottom half of buffer now emptied,
// safe to fill the bottom half while the top half of buffer is being emptied
feed_dma(self, BOTTOM_HALF);
} else {
// top half of buffer now emptied,
// safe to fill the top half while the bottom half of buffer is being emptied
feed_dma(self, TOP_HALF);
}
} else { // RX
if (transferDone) {
// bottom half of buffer now filled,
// safe to empty the bottom half while the top half of buffer is being filled
empty_dma(self, BOTTOM_HALF);
} else {
// top half of buffer now filled,
// safe to empty the top half while the bottom half of buffer is being filled
empty_dma(self, TOP_HALF);
}
// for non-blocking mode, sample copying (ibuf->appbuf) is initiated in this callback routine
if ((self->io_mode == NON_BLOCKING) && (self->non_blocking_descriptor.copy_in_progress)) {
fill_appbuf_from_ringbuf_non_blocking(self);
}
}
}
static bool i2s_init(machine_i2s_obj_t *self) {
#if defined(MIMXRT117x_SERIES)
clock_audio_pll_config_t pll_config = *get_pll_config(self->rate);
pll_config.postDivider = get_clock_pre_divider(self->rate);
CLOCK_InitAudioPll(&pll_config);
CLOCK_SetRootClockMux(i2s_clock_mux[self->i2s_id], I2S_AUDIO_PLL_CLOCK);
CLOCK_SetRootClockDiv(i2s_clock_mux[self->i2s_id], get_clock_divider(self->rate));
uint32_t clock_freq = CLOCK_GetFreq(kCLOCK_AudioPllOut) / get_clock_divider(self->rate);
#else
CLOCK_InitAudioPll(get_pll_config(self->rate));
CLOCK_SetMux(i2s_clock_mux[self->i2s_id], I2S_AUDIO_PLL_CLOCK);
CLOCK_SetDiv(i2s_clock_pre_div[self->i2s_id], get_clock_pre_divider(self->rate));
CLOCK_SetDiv(i2s_clock_div[self->i2s_id], get_clock_divider(self->rate));
uint32_t clock_freq =
(CLOCK_GetFreq(kCLOCK_AudioPllClk) / (get_clock_divider(self->rate) + 1U) /
(get_clock_pre_divider(self->rate) + 1U));
#endif
if (!set_iomux(self->sck, SCK, self->i2s_id)) {
return false;
}
if (!set_iomux(self->ws, WS, self->i2s_id)) {
return false;
}
if (!set_iomux(self->sd, SD, self->i2s_id)) {
return false;
}
if (self->mck) {
if (!set_iomux(self->mck, MCK, self->i2s_id)) {
return false;
}
#if defined(MIMXRT117x_SERIES)
switch (self->i2s_id) {
case 1:
IOMUXC_GPR->GPR0 |= IOMUXC_GPR_GPR0_SAI1_MCLK_DIR_MASK;
break;
case 2:
IOMUXC_GPR->GPR1 |= IOMUXC_GPR_GPR1_SAI2_MCLK_DIR_MASK;
break;
case 3:
IOMUXC_GPR->GPR2 |= IOMUXC_GPR_GPR2_SAI3_MCLK_DIR_MASK;
break;
case 4:
IOMUXC_GPR->GPR2 |= IOMUXC_GPR_GPR2_SAI4_MCLK_DIR_MASK;
break;
}
#else
IOMUXC_EnableMode(IOMUXC_GPR, i2s_iomuxc_gpr_mode[self->i2s_id], true);
#endif
}
self->dma_channel = allocate_dma_channel();
DMAMUX_Init(DMAMUX);
if (self->mode == TX) {
DMAMUX_SetSource(DMAMUX, self->dma_channel, i2s_dma_req_src_tx[self->i2s_id]);
} else { // RX
DMAMUX_SetSource(DMAMUX, self->dma_channel, i2s_dma_req_src_rx[self->i2s_id]);
}
DMAMUX_EnableChannel(DMAMUX, self->dma_channel);
dma_init();
EDMA_CreateHandle(&self->edmaHandle, DMA0, self->dma_channel);
EDMA_SetCallback(&self->edmaHandle, edma_i2s_callback, self);
EDMA_ResetChannel(DMA0, self->dma_channel);
SAI_Init(self->i2s_inst);
sai_transceiver_t saiConfig;
SAI_GetClassicI2SConfig(&saiConfig, get_dma_bits(self->mode, self->bits), kSAI_Stereo, kSAI_Channel0Mask);
saiConfig.masterSlave = kSAI_Master;
uint16_t sck_index;
lookup_gpio(self->sck, SCK, self->i2s_id, &sck_index);
if ((self->mode == TX) && (i2s_gpio_map[sck_index].mode == TX)) {
saiConfig.syncMode = kSAI_ModeAsync;
SAI_TxSetConfig(self->i2s_inst, &saiConfig);
} else if ((self->mode == RX) && (i2s_gpio_map[sck_index].mode == RX)) {
saiConfig.syncMode = kSAI_ModeAsync;
SAI_RxSetConfig(self->i2s_inst, &saiConfig);
} else if ((self->mode == TX) && (i2s_gpio_map[sck_index].mode == RX)) {
saiConfig.syncMode = kSAI_ModeAsync;
SAI_RxSetConfig(self->i2s_inst, &saiConfig);
saiConfig.bitClock.bclkSrcSwap = true;
saiConfig.syncMode = kSAI_ModeSync;
SAI_TxSetConfig(self->i2s_inst, &saiConfig);
} else if ((self->mode == RX) && (i2s_gpio_map[sck_index].mode == TX)) {
saiConfig.syncMode = kSAI_ModeAsync;
SAI_TxSetConfig(self->i2s_inst, &saiConfig);
saiConfig.syncMode = kSAI_ModeSync;
SAI_RxSetConfig(self->i2s_inst, &saiConfig);
} else {
return false; // should never happen
}
SAI_TxSetBitClockRate(self->i2s_inst, clock_freq, self->rate, get_dma_bits(self->mode, self->bits),
SAI_NUM_AUDIO_CHANNELS);
SAI_RxSetBitClockRate(self->i2s_inst, clock_freq, self->rate, get_dma_bits(self->mode, self->bits),
SAI_NUM_AUDIO_CHANNELS);
edma_transfer_config_t transferConfig;
uint8_t bytes_per_sample = get_dma_bits(self->mode, self->bits) / 8;
if (self->mode == TX) {
uint32_t destAddr = SAI_TxGetDataRegisterAddress(self->i2s_inst, SAI_CHANNEL_0);
EDMA_PrepareTransfer(&transferConfig,
self->dma_buffer_dcache_aligned, bytes_per_sample,
(void *)destAddr, bytes_per_sample,
(FSL_FEATURE_SAI_FIFO_COUNT - saiConfig.fifo.fifoWatermark) * bytes_per_sample,
SIZEOF_DMA_BUFFER_IN_BYTES, kEDMA_MemoryToPeripheral);
} else { // RX
uint32_t srcAddr = SAI_RxGetDataRegisterAddress(self->i2s_inst, SAI_CHANNEL_0);
EDMA_PrepareTransfer(&transferConfig,
(void *)srcAddr, bytes_per_sample,
self->dma_buffer_dcache_aligned, bytes_per_sample,
(FSL_FEATURE_SAI_FIFO_COUNT - saiConfig.fifo.fifoWatermark) * bytes_per_sample,
SIZEOF_DMA_BUFFER_IN_BYTES, kEDMA_PeripheralToMemory);
}
memset(self->edmaTcd, 0, sizeof(edma_tcd_t));
// continuous DMA operation is achieved using the scatter/gather feature, with one TCD linked back to itself
EDMA_TcdSetTransferConfig(self->edmaTcd, &transferConfig, self->edmaTcd);
EDMA_TcdEnableInterrupts(self->edmaTcd, kEDMA_MajorInterruptEnable | kEDMA_HalfInterruptEnable);
EDMA_InstallTCD(DMA0, self->dma_channel, self->edmaTcd);
EDMA_StartTransfer(&self->edmaHandle);
if (self->mode == TX) {
SAI_TxEnableDMA(self->i2s_inst, kSAI_FIFORequestDMAEnable, true);
SAI_TxEnable(self->i2s_inst, true);
SAI_TxSetChannelFIFOMask(self->i2s_inst, kSAI_Channel0Mask);
} else { // RX
SAI_RxEnableDMA(self->i2s_inst, kSAI_FIFORequestDMAEnable, true);
SAI_RxEnable(self->i2s_inst, true);
SAI_RxSetChannelFIFOMask(self->i2s_inst, kSAI_Channel0Mask);
}
return true;
}
static void mp_machine_i2s_init_helper(machine_i2s_obj_t *self, mp_arg_val_t *args) {
// is Mode valid?
uint16_t i2s_mode = args[ARG_mode].u_int;
if ((i2s_mode != (RX)) &&
(i2s_mode != (TX))) {
mp_raise_ValueError(MP_ERROR_TEXT("invalid mode"));
}
// are I2S pin assignments valid?
uint16_t not_used;
// is SCK valid?
const machine_pin_obj_t *pin_sck = pin_find(args[ARG_sck].u_obj);
if (!lookup_gpio(pin_sck, SCK, self->i2s_id, &not_used)) {
mp_raise_ValueError(MP_ERROR_TEXT("invalid SCK pin"));
}
// is WS valid?
const machine_pin_obj_t *pin_ws = pin_find(args[ARG_ws].u_obj);
if (!lookup_gpio(pin_ws, WS, self->i2s_id, &not_used)) {
mp_raise_ValueError(MP_ERROR_TEXT("invalid WS pin"));
}
// is SD valid?
const machine_pin_obj_t *pin_sd = pin_find(args[ARG_sd].u_obj);
uint16_t mapping_index;
bool invalid_sd = true;
if (lookup_gpio(pin_sd, SD, self->i2s_id, &mapping_index)) {
if (i2s_mode == i2s_gpio_map[mapping_index].mode) {
invalid_sd = false;
}
}
if (invalid_sd) {
mp_raise_ValueError(MP_ERROR_TEXT("invalid SD pin"));
}
// is MCK defined and valid?
const machine_pin_obj_t *pin_mck = NULL;
if (args[ARG_mck].u_obj != mp_const_none) {
pin_mck = pin_find(args[ARG_mck].u_obj);
if (!lookup_gpio(pin_mck, MCK, self->i2s_id, &not_used)) {
mp_raise_ValueError(MP_ERROR_TEXT("invalid MCK pin"));
}
}
// is Bits valid?
int8_t i2s_bits = args[ARG_bits].u_int;
if ((i2s_bits != 16) &&
(i2s_bits != 32)) {
mp_raise_ValueError(MP_ERROR_TEXT("invalid bits"));
}
// is Format valid?
format_t i2s_format = args[ARG_format].u_int;
if ((i2s_format != MONO) &&
(i2s_format != STEREO)) {
mp_raise_ValueError(MP_ERROR_TEXT("invalid format"));
}
// is Rate valid?
int32_t i2s_rate = args[ARG_rate].u_int;
if (!is_rate_supported(i2s_rate)) {
mp_raise_ValueError(MP_ERROR_TEXT("invalid rate"));
}
// is Ibuf valid?
int32_t ring_buffer_len = args[ARG_ibuf].u_int;
if (ring_buffer_len > 0) {
uint8_t *buffer = m_new(uint8_t, ring_buffer_len);
self->ring_buffer_storage = buffer;
ringbuf_init(&self->ring_buffer, buffer, ring_buffer_len);
} else {
mp_raise_ValueError(MP_ERROR_TEXT("invalid ibuf"));
}
self->sck = pin_sck;
self->ws = pin_ws;
self->sd = pin_sd;
self->mck = pin_mck;
self->mode = i2s_mode;
self->bits = i2s_bits;
self->format = i2s_format;
self->rate = i2s_rate;
self->ibuf = ring_buffer_len;
self->callback_for_non_blocking = MP_OBJ_NULL;
self->non_blocking_descriptor.copy_in_progress = false;
self->io_mode = BLOCKING;
self->i2s_inst = (I2S_Type *)i2s_base_ptr[self->i2s_id];
// init the I2S bus
if (!i2s_init(self)) {
mp_raise_msg_varg(&mp_type_OSError, MP_ERROR_TEXT("I2S init failed"));
}
}
static machine_i2s_obj_t *mp_machine_i2s_make_new_instance(mp_int_t i2s_id) {
if (i2s_id < 1 || i2s_id > MICROPY_HW_I2S_NUM) {
mp_raise_msg_varg(&mp_type_ValueError, MP_ERROR_TEXT("I2S(%d) does not exist"), i2s_id);
}
uint8_t i2s_id_zero_base = i2s_id - 1;
machine_i2s_obj_t *self;
if (MP_STATE_PORT(machine_i2s_obj)[i2s_id_zero_base] == NULL) {
self = mp_obj_malloc(machine_i2s_obj_t, &machine_i2s_type);
MP_STATE_PORT(machine_i2s_obj)[i2s_id_zero_base] = self;
self->i2s_id = i2s_id;
self->edmaTcd = &edmaTcd[i2s_id_zero_base];
} else {
self = MP_STATE_PORT(machine_i2s_obj)[i2s_id_zero_base];
machine_i2s_deinit(MP_OBJ_FROM_PTR(self));
}
// align DMA buffer to the cache line size (32 bytes)
self->dma_buffer_dcache_aligned = (uint8_t *)((uint32_t)(self->dma_buffer + 0x1f) & ~0x1f);
// fill the DMA buffer with NULLs
memset(self->dma_buffer_dcache_aligned, 0, SIZEOF_DMA_BUFFER_IN_BYTES);
return self;
}
static void mp_machine_i2s_deinit(machine_i2s_obj_t *self) {
// use self->i2s_inst as in indication that I2S object has already been de-initialized
if (self->i2s_inst != NULL) {
EDMA_AbortTransfer(&self->edmaHandle);
if (self->mode == TX) {
SAI_TxSetChannelFIFOMask(self->i2s_inst, 0);
SAI_TxEnableDMA(self->i2s_inst, kSAI_FIFORequestDMAEnable, false);
SAI_TxEnable(self->i2s_inst, false);
SAI_TxReset(self->i2s_inst);
} else { // RX
SAI_RxSetChannelFIFOMask(self->i2s_inst, 0);
SAI_RxEnableDMA(self->i2s_inst, kSAI_FIFORequestDMAEnable, false);
SAI_RxEnable(self->i2s_inst, false);
SAI_RxReset(self->i2s_inst);
}
SAI_Deinit(self->i2s_inst);
free_dma_channel(self->dma_channel);
m_free(self->ring_buffer_storage);
self->i2s_inst = NULL; // flag object as de-initialized
}
}
static void mp_machine_i2s_irq_update(machine_i2s_obj_t *self) {
(void)self;
}
MP_REGISTER_ROOT_POINTER(struct _machine_i2s_obj_t *machine_i2s_obj[MICROPY_HW_I2S_NUM]);