circuitpython/atmel-samd/common-hal/audiobusio/PDMIn.c

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/*
* This file is part of the Micro Python project, http://micropython.org/
*
* The MIT License (MIT)
*
* Copyright (c) 2017 Scott Shawcroft for Adafruit Industries
*
* 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.
*/
#include <stdint.h>
#include <string.h>
#include "py/gc.h"
#include "py/mperrno.h"
#include "py/runtime.h"
#include "common-hal/analogio/AnalogOut.h"
#include "common-hal/audiobusio/PDMIn.h"
#include "shared-bindings/analogio/AnalogOut.h"
#include "shared-bindings/audiobusio/PDMIn.h"
#include "shared-bindings/microcontroller/Pin.h"
#include "asf/sam0/drivers/port/port.h"
#include "samd21_pins.h"
#include "shared_dma.h"
#include "tick.h"
void pdmin_reset(void) {
while (I2S->SYNCBUSY.reg & I2S_SYNCBUSY_ENABLE) {}
I2S->INTENCLR.reg = I2S_INTENCLR_MASK;
I2S->INTFLAG.reg = I2S_INTFLAG_MASK;
I2S->CTRLA.reg &= ~I2S_SYNCBUSY_ENABLE;
while (I2S->SYNCBUSY.reg & I2S_SYNCBUSY_ENABLE) {}
I2S->CTRLA.reg = I2S_CTRLA_SWRST;
}
void common_hal_audiobusio_pdmin_construct(audiobusio_pdmin_obj_t* self,
const mcu_pin_obj_t* clock_pin,
const mcu_pin_obj_t* data_pin,
uint32_t frequency,
uint8_t bit_depth,
bool mono,
uint8_t oversample) {
self->clock_pin = clock_pin; // PA10, PA20 -> SCK0, PB11 -> SCK1
if (clock_pin == &pin_PA10
#ifdef PIN_PA20
|| clock_pin == &pin_PA20
#endif
) {
self->clock_unit = 0;
#ifdef PIN_PB11
} else if (clock_pin == &pin_PB11) {
self->clock_unit = 1;
#endif
} else {
mp_raise_ValueError("Invalid clock pin");
}
self->data_pin = data_pin; // PA07, PA19 -> SD0, PA08, PB16 -> SD1
if (data_pin == &pin_PA07 || data_pin == &pin_PA19) {
self->serializer = 0;
} else if (data_pin == &pin_PA08
#ifdef PB16
|| data_pin == &pin_PB16) {
#else
) {
#endif
self->serializer = 1;
} else {
mp_raise_ValueError("Invalid data pin");
}
claim_pin(clock_pin);
claim_pin(data_pin);
if (MP_STATE_VM(audiodma_block_counter) == NULL &&
!allocate_block_counter()) {
mp_raise_RuntimeError("Unable to allocate audio DMA block counter.");
}
if (bit_depth != 16 || !mono || oversample != 64) {
mp_raise_NotImplementedError("");
}
// TODO(tannewt): Use the DPLL to get a more precise sampling rate.
// DFLL -> GCLK (/600 for 8khz, /300 for 16khz and /150 for 32khz) -> DPLL (*(63 + 1)) -> GCLK ( / 10) -> 512khz
i2s_init(&self->i2s_instance, I2S);
struct i2s_clock_unit_config config_clock_unit;
i2s_clock_unit_get_config_defaults(&config_clock_unit);
config_clock_unit.clock.gclk_src = GCLK_GENERATOR_3;
config_clock_unit.clock.mck_src = I2S_MASTER_CLOCK_SOURCE_GCLK;
config_clock_unit.clock.mck_out_enable = false;
config_clock_unit.clock.sck_src = I2S_SERIAL_CLOCK_SOURCE_MCKDIV;
config_clock_unit.clock.sck_div = 8000000 / frequency / oversample;
self->frequency = 8000000 / config_clock_unit.clock.sck_div / oversample;
config_clock_unit.frame.number_slots = 2;
config_clock_unit.frame.slot_size = I2S_SLOT_SIZE_16_BIT;
config_clock_unit.frame.data_delay = I2S_DATA_DELAY_1;
config_clock_unit.frame.frame_sync.width = I2S_FRAME_SYNC_WIDTH_SLOT;
config_clock_unit.mck_pin.enable = false;
config_clock_unit.sck_pin.enable = true;
config_clock_unit.sck_pin.gpio = self->clock_pin->pin;
// Mux is always the same.
config_clock_unit.sck_pin.mux = 6L;
config_clock_unit.fs_pin.enable = false;
i2s_clock_unit_set_config(&self->i2s_instance, self->clock_unit, &config_clock_unit);
struct i2s_serializer_config config_serializer;
i2s_serializer_get_config_defaults(&config_serializer);
config_serializer.clock_unit = self->clock_unit;
config_serializer.mode = I2S_SERIALIZER_PDM2;
config_serializer.data_size = I2S_DATA_SIZE_32BIT;
config_serializer.data_pin.gpio = self->data_pin->pin;
// Mux is always the same.
config_serializer.data_pin.mux = 6L;
config_serializer.data_pin.enable = true;
i2s_serializer_set_config(&self->i2s_instance, self->serializer, &config_serializer);
i2s_enable(&self->i2s_instance);
self->bytes_per_sample = oversample >> 3;
self->bit_depth = bit_depth;
}
void common_hal_audiobusio_pdmin_deinit(audiobusio_pdmin_obj_t* self) {
i2s_disable(&self->i2s_instance);
i2s_reset(&self->i2s_instance);
}
uint8_t common_hal_audiobusio_pdmin_get_bit_depth(audiobusio_pdmin_obj_t* self) {
return self->bit_depth;
}
uint32_t common_hal_audiobusio_pdmin_get_frequency(audiobusio_pdmin_obj_t* self) {
return self->frequency;
}
static void setup_dma(audiobusio_pdmin_obj_t* self, uint32_t length,
DmacDescriptor* second_descriptor,
uint8_t words_per_buffer, uint8_t words_per_sample,
uint32_t* first_buffer, uint32_t* second_buffer) {
// Set up the DMA
struct dma_descriptor_config descriptor_config;
dma_descriptor_get_config_defaults(&descriptor_config);
descriptor_config.beat_size = DMA_BEAT_SIZE_WORD;
descriptor_config.step_selection = DMA_STEPSEL_SRC;
descriptor_config.source_address = (uint32_t)&I2S->DATA[self->serializer];
descriptor_config.src_increment_enable = false;
// Block transfer count is the number of beats per block (aka descriptor).
// In this case there are two bytes per beat so divide the length by two.
uint16_t block_transfer_count = words_per_buffer;
if (length * words_per_sample < words_per_buffer) {
block_transfer_count = length * words_per_sample;
}
descriptor_config.block_transfer_count = block_transfer_count;
descriptor_config.destination_address = ((uint32_t) first_buffer + sizeof(uint32_t) * block_transfer_count);
descriptor_config.event_output_selection = DMA_EVENT_OUTPUT_BLOCK;
descriptor_config.next_descriptor_address = 0;
if (length * words_per_sample > words_per_buffer) {
descriptor_config.next_descriptor_address = ((uint32_t)second_descriptor);
}
dma_descriptor_create(audio_dma.descriptor, &descriptor_config);
if (length * words_per_sample > words_per_buffer) {
block_transfer_count = words_per_buffer;
descriptor_config.next_descriptor_address = ((uint32_t)audio_dma.descriptor);
if (length * words_per_sample < 2 * words_per_buffer) {
block_transfer_count = 2 * words_per_buffer - length * words_per_sample;
descriptor_config.next_descriptor_address = 0;
}
descriptor_config.block_transfer_count = block_transfer_count;
descriptor_config.destination_address = ((uint32_t) second_buffer + sizeof(uint32_t) * block_transfer_count);
dma_descriptor_create(second_descriptor, &descriptor_config);
}
switch_audiodma_trigger(I2S_DMAC_ID_RX_0 + self->serializer);
}
void start_dma(audiobusio_pdmin_obj_t* self) {
dma_start_transfer_job(&audio_dma);
tc_start_counter(MP_STATE_VM(audiodma_block_counter));
i2s_clock_unit_enable(&self->i2s_instance, self->clock_unit);
i2s_serializer_enable(&self->i2s_instance, self->serializer);
I2S->DATA[1].reg = I2S->DATA[1].reg;
}
void stop_dma(audiobusio_pdmin_obj_t* self) {
// Turn off the I2S clock and serializer. Peripheral is still enabled.
i2s_serializer_disable(&self->i2s_instance, self->serializer);
i2s_clock_unit_disable(&self->i2s_instance, self->clock_unit);
// Shutdown the DMA
tc_stop_counter(MP_STATE_VM(audiodma_block_counter));
dma_abort_job(&audio_dma);
}
static const uint16_t sinc_filter[64] = {
0, 1, 6, 16, 29, 49, 75, 108,
149, 200, 261, 334, 418, 514, 622, 742,
872, 1012, 1161, 1315, 1472, 1631, 1787, 1938,
2081, 2212, 2329, 2429, 2509, 2568, 2604, 2616,
2604, 2568, 2509, 2429, 2329, 2212, 2081, 1938,
1787, 1631, 1472, 1315, 1161, 1012, 872, 742,
622, 514, 418, 334, 261, 200, 149, 108,
75, 49, 29, 16, 6, 1, 0, 0
};
static uint16_t filter_sample(uint32_t pdm_samples[4]) {
uint16_t sample = 0;
for (uint8_t i = 0; i < 4; i++) {
uint16_t pdm = pdm_samples[i] & 0xffff;
for (uint8_t j = 0; j < 16; j++) {
if ((pdm & 0x8000) != 0) {
sample += sinc_filter[i * 16 + j];
}
pdm <<= 1;
}
}
return sample;
}
uint32_t common_hal_audiobusio_pdmin_record_to_buffer(audiobusio_pdmin_obj_t* self,
uint16_t* output_buffer, uint32_t length) {
// Write the wave file header.
// We allocate two 256 byte buffers on the stack to use for double buffering.
// Our oversample rate is 64 (bits) so each buffer produces 32 samples.
// TODO(tannewt): Can the compiler optimize better if we fix the size of
// these buffers?
uint8_t samples_per_buffer = 32;
// For every word we record, we throw away 2 bytes of a phantom second channel.
uint8_t words_per_sample = self->bytes_per_sample / 2;
uint8_t words_per_buffer = samples_per_buffer * words_per_sample;
uint32_t first_buffer[words_per_buffer];
uint32_t second_buffer[words_per_buffer];
COMPILER_ALIGNED(16) DmacDescriptor second_descriptor;
setup_dma(self, length, &second_descriptor, words_per_buffer,
words_per_sample, first_buffer, second_buffer);
start_dma(self);
// Record
uint32_t buffers_processed = 0;
uint32_t total_bytes = 0;
uint64_t start_ticks = ticks_ms;
while (total_bytes < length) {
// Wait for the next buffer to fill
while (tc_get_count_value(MP_STATE_VM(audiodma_block_counter)) == buffers_processed) {
#ifdef MICROPY_VM_HOOK_LOOP
MICROPY_VM_HOOK_LOOP
#endif
}
if (tc_get_count_value(MP_STATE_VM(audiodma_block_counter)) != (buffers_processed + 1)) {
break;
}
// Throw away the first ~10ms of data because thats during mic start up.
if (ticks_ms - start_ticks < 10) {
buffers_processed++;
continue;
}
uint32_t* buffer = first_buffer;
DmacDescriptor* descriptor = audio_dma.descriptor;
if (buffers_processed % 2 == 1) {
buffer = second_buffer;
descriptor = &second_descriptor;
}
// Decimate and filter the last buffer
int32_t samples_gathered = descriptor->BTCNT.reg / words_per_sample;
for (uint16_t i = 0; i < samples_gathered; i++) {
if (self->bit_depth == 8) {
((uint8_t*) output_buffer)[total_bytes] = filter_sample(buffer + i * words_per_sample) >> 8;
total_bytes += 1;
} else if (self->bit_depth == 16) {
output_buffer[total_bytes / 2] = filter_sample(buffer + i * words_per_sample);
total_bytes += 2;
}
}
buffers_processed++;
if (length - total_bytes < samples_per_buffer) {
descriptor->BTCNT.reg = (length - total_bytes) * words_per_sample;
descriptor->DSTADDR.reg = ((uint32_t) buffer) + (length - total_bytes) * self->bytes_per_sample;
descriptor->DESCADDR.reg = 0;
}
}
stop_dma(self);
return total_bytes;
}
void common_hal_audiobusio_pdmin_record_to_file(audiobusio_pdmin_obj_t* self, uint8_t* buffer, uint32_t length) {
}