nrf: Add i2s audio output

Testing performed: I used a Particle Xenon with a HDA1334 I2S DAC. I played a variety of mono 16-bit samples at 11025 and 22050Hz nominal bit rates. With this setup, all the 11025Hz samples sound good. I tested play, pause, and loop functionality. During some runs with 22050Hz samples, there were glitches. However, these may have only occurred during runs where I had set breakpoints and watchpoints in gdb. I also tested with a MAX98357A I2S amplifier. On this device, everything sounded "scratchy". I was powering it from 5V and the 5V rail seemed steady, so I don't have an explanation for this. However, I haven't tried it with a SAMD board.
2019-09-08 13:08:15 -05:00 · 2019-09-08 13:08:15 -05:00 · f38ee42874
commit f38ee42874
parent bd7b03fc7e
4 changed files with 297 additions and 9 deletions
--- a/ports/nrf/background.c
+++ b/ports/nrf/background.c
@ -33,6 +33,10 @@
 #include "shared-module/displayio/__init__.h"
 #endif
 #if CIRCUITPY_AUDIOBUSIO
 #include "common-hal/audiobusio/I2SOut.h"
 #endif
 #if CIRCUITPY_AUDIOPWMIO
 #include "common-hal/audiopwmio/PWMAudioOut.h"
 #endif
@ -54,6 +58,10 @@ void run_background_tasks(void) {
 #if CIRCUITPY_AUDIOPWMIO
    audiopwmout_background();
 #endif
 #if CIRCUITPY_AUDIOBUSIO
    i2s_background();
 #endif
    #if CIRCUITPY_DISPLAYIO
    displayio_background();
--- a/ports/nrf/common-hal/audiobusio/I2SOut.c
+++ b/ports/nrf/common-hal/audiobusio/I2SOut.c
@ -24,47 +24,291 @@
 * THE SOFTWARE.
 */
 #include <math.h>
 #include <string.h>
 #include "common-hal/microcontroller/Pin.h"
 #include "common-hal/audiobusio/I2SOut.h"
 #include "shared-bindings/audiobusio/I2SOut.h"
 #include "shared-module/audiocore/__init__.h"
 #include "py/obj.h"
 #include "py/runtime.h"
 static audiobusio_i2sout_obj_t *instance;
 struct { int16_t l, r; } static_sample16 = {0x8000, 0x8000};
 struct { uint8_t l1, r1, l2, r2; } static_sample8 = {0x80, 0x80, 0x80, 0x80};
 struct frequency_info { uint32_t RATIO; uint32_t MCKFREQ; int sample_rate; float abserr; };
 struct ratio_info { uint32_t RATIO; int16_t divisor; bool can_16bit; };
 struct ratio_info ratios[] = {
    { I2S_CONFIG_RATIO_RATIO_32X,   32,  true },
    { I2S_CONFIG_RATIO_RATIO_48X,   48, false },
    { I2S_CONFIG_RATIO_RATIO_64X,   64,  true },
    { I2S_CONFIG_RATIO_RATIO_96X,   96,  true },
    { I2S_CONFIG_RATIO_RATIO_128X, 128,  true },
    { I2S_CONFIG_RATIO_RATIO_192X, 192,  true },
    { I2S_CONFIG_RATIO_RATIO_256X, 256,  true },
    { I2S_CONFIG_RATIO_RATIO_384X, 384,  true },
    { I2S_CONFIG_RATIO_RATIO_512X, 512,  true },
 };
 struct mclk_info { uint32_t MCKFREQ; int divisor; };
 struct mclk_info mclks[] = {
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV8,     8 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV10,   10 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV11,   11 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV15,   15 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV16,   16 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV21,   21 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV23,   23 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV31,   31 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV42,   42 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV63,   63 },
    { I2S_CONFIG_MCKFREQ_MCKFREQ_32MDIV125, 125 },
 };
 static void calculate_ratio_info(uint32_t target_sample_rate, struct frequency_info *info,
        int ratio_index, int mclk_index) {
    info->RATIO = ratios[ratio_index].RATIO;
    info->MCKFREQ = mclks[mclk_index].MCKFREQ;
    info->sample_rate = 32000000
        / ratios[ratio_index].divisor / mclks[mclk_index].divisor;
    info->abserr = fabsf(1.0f * target_sample_rate - info->sample_rate)
        / target_sample_rate;
 }
 void choose_i2s_clocking(audiobusio_i2sout_obj_t *self, uint32_t sample_rate) {
    struct frequency_info best = {0, 0, 0, 1.0};
    for (size_t ri=0; ri<sizeof(ratios) / sizeof(ratios[0]); ri++) {
        if (NRF_I2S->CONFIG.SWIDTH == I2S_CONFIG_SWIDTH_SWIDTH_16Bit
                && !ratios[ri].can_16bit) {
            continue;
        }
        for (size_t mi=0; mi<sizeof(mclks) / sizeof(mclks[0]); mi++) {
            struct frequency_info info = {0, 0, 1.0};
            calculate_ratio_info(sample_rate, &info, ri, mi);
            if (info.abserr < best.abserr) {
                best = info;
            }
 #ifdef DEBUG_CLOCKING
            mp_printf(&mp_plat_print,
                    "RATIO=%3d MCKFREQ=%08x rate=%d abserr=%.4f\n",
                    info.RATIO, info.MCKFREQ, info.sample_rate,
                    (double)info.abserr);
 #endif
        }
    }
    NRF_I2S->CONFIG.RATIO = best.RATIO;
    NRF_I2S->CONFIG.MCKFREQ = best.MCKFREQ;
    self->sample_rate = best.sample_rate;
 }
 static void i2s_buffer_fill(audiobusio_i2sout_obj_t* self) {
    void *buffer = self->buffers[self->next_buffer];
    NRF_I2S->TXD.PTR = (uintptr_t)buffer;
    self->next_buffer = !self->next_buffer;
    size_t bytesleft = self->buffer_length;
    if (self->paused || self->stopping) {
        if (self->stopping) {
            NRF_I2S->TASKS_STOP = 1;
            self->playing = false;
        }
 stopping: ;
        uint32_t *bp = (uint32_t*)buffer;
        uint32_t *be = (uint32_t*)(buffer + bytesleft);
        for (; bp != be; )
            *bp++ = self->hold_value;
        return;
    }
    while (bytesleft) {
        if (self->sample_data == self->sample_end) {
            uint32_t sample_buffer_length;
            audioio_get_buffer_result_t get_buffer_result =
                audiosample_get_buffer(self->sample, false, 0,
                                       &self->sample_data, &sample_buffer_length);
            self->sample_end = self->sample_data + sample_buffer_length;
            if (get_buffer_result == GET_BUFFER_DONE) {
                if (self->loop) {
                    audiosample_reset_buffer(self->sample, false, 0);
                } else {
                    self->stopping = true;
                    goto stopping;
                }
            }
        }
        uint16_t bytecount = MIN(bytesleft, (size_t)(self->sample_end - self->sample_data));
        if (self->samples_signed) {
            memcpy(buffer, self->sample_data, bytecount);
        } else if (self->bytes_per_sample == 2) {
            uint16_t *bp = (uint16_t*)buffer;
            uint16_t *be = (uint16_t*)(buffer + bytecount);
            uint16_t *sp = (uint16_t*)self->sample_data;
            for (; bp != be; bp++) {
                *bp++ = *sp++ + 0x8000;
            }
        } else {
            uint8_t *bp = (uint8_t*)buffer;
            uint8_t *be = (uint8_t*)(buffer + bytecount);
            uint8_t *sp = (uint8_t*)self->sample_data;
            for (; bp != be; bp++) {
                *bp++ = *sp++ + 0x80;
            }
        }
        buffer += bytecount;
        self->sample_data += bytecount;
        bytesleft -= bytecount;
    }
    if (self->bytes_per_sample == 1 && self->channel_count == 1) {
            self->hold_value = 0x01010101 * *(uint8_t*)(buffer-1);
    } else if (self->bytes_per_sample == 2 && self->channel_count == 2) {
        self->hold_value = *(uint32_t*)(buffer-4);
    } else {
        self->hold_value = 0x00010001 * *(uint16_t*)(buffer-2);
    }
 }
 void common_hal_audiobusio_i2sout_construct(audiobusio_i2sout_obj_t* self,
        const mcu_pin_obj_t* bit_clock, const mcu_pin_obj_t* word_select,
        const mcu_pin_obj_t* data, bool left_justified) {
-    mp_raise_NotImplementedError(NULL);
+    if (instance)
        mp_raise_RuntimeError(translate("Device in use"));
    instance = self;
    claim_pin(bit_clock);
    claim_pin(word_select);
    claim_pin(data);
    NRF_I2S->PSEL.SCK = self->bit_clock_pin_number = bit_clock->number;
    NRF_I2S->PSEL.LRCK = self->word_select_pin_number = word_select->number;
    NRF_I2S->PSEL.SDOUT = self->data_pin_number = data->number;
    NRF_I2S->CONFIG.MODE = I2S_CONFIG_MODE_MODE_Master;
    NRF_I2S->CONFIG.RXEN = I2S_CONFIG_RXEN_RXEN_Disabled;
    NRF_I2S->CONFIG.TXEN = I2S_CONFIG_TXEN_TXEN_Enabled;
    NRF_I2S->CONFIG.MCKEN = I2S_CONFIG_MCKEN_MCKEN_Enabled;
    NRF_I2S->CONFIG.SWIDTH = I2S_CONFIG_SWIDTH_SWIDTH_16Bit;
    NRF_I2S->CONFIG.ALIGN = I2S_CONFIG_ALIGN_ALIGN_Left;
    NRF_I2S->CONFIG.FORMAT = left_justified ? I2S_CONFIG_FORMAT_FORMAT_Aligned
                                    : I2S_CONFIG_FORMAT_FORMAT_I2S;
 }
 bool common_hal_audiobusio_i2sout_deinited(audiobusio_i2sout_obj_t* self) {
-    mp_raise_NotImplementedError(NULL);
+    return self->data_pin_number == 0xff;
 }
 void common_hal_audiobusio_i2sout_deinit(audiobusio_i2sout_obj_t* self) {
-    mp_raise_NotImplementedError(NULL);
+    if (common_hal_audiobusio_i2sout_deinited(self)) {
        return;
    }
    reset_pin_number(self->bit_clock_pin_number);
    self->bit_clock_pin_number = 0xff;
    reset_pin_number(self->word_select_pin_number);
    self->word_select_pin_number = 0xff;
    reset_pin_number(self->data_pin_number);
    self->data_pin_number = 0xff;
    instance = NULL;
 }
 void common_hal_audiobusio_i2sout_play(audiobusio_i2sout_obj_t* self,
                                       mp_obj_t sample, bool loop) {
-    mp_raise_NotImplementedError(NULL);
+    if (common_hal_audiobusio_i2sout_get_playing(self)) {
        common_hal_audiobusio_i2sout_stop(self);
    }
    self->sample = sample;
    self->loop = loop;
    uint32_t sample_rate = audiosample_sample_rate(sample);
    self->bytes_per_sample = audiosample_bits_per_sample(sample) / 8;
    uint32_t max_buffer_length;
    bool single_buffer, samples_signed;
    audiosample_get_buffer_structure(sample, /* single channel */ false,
        &single_buffer, &samples_signed, &max_buffer_length,
        &self->channel_count);
    self->single_buffer = single_buffer;
    self->samples_signed = samples_signed;
    choose_i2s_clocking(self, sample_rate);
    /* Allocate buffers based on a maximum duration */
    enum { buffer_length_ms = 8 };
    self->buffer_length = MAX(
        2*max_buffer_length,
        sample_rate * buffer_length_ms * self->bytes_per_sample
            * self->channel_count / 1000);
    self->buffer_length = (self->buffer_length + 3) & ~3;
    self->buffers[0] = m_malloc(self->buffer_length, false);
    self->buffers[1] = m_malloc(self->buffer_length, false);
    audiosample_reset_buffer(self->sample, false, 0);
    self->next_buffer = 0;
    self->sample_data = self->sample_end = 0;
    self->playing = true;
    self->paused = false;
    self->stopping = false;
    i2s_buffer_fill(self);
    NRF_I2S->CONFIG.CHANNELS = self->channel_count == 1 ? I2S_CONFIG_CHANNELS_CHANNELS_Left : I2S_CONFIG_CHANNELS_CHANNELS_Stereo;
    NRF_I2S->RXTXD.MAXCNT = self->buffer_length / 4;
    NRF_I2S->ENABLE = I2S_ENABLE_ENABLE_Enabled;
    NRF_I2S->TASKS_START = 1;
    i2s_background();
 }
 void common_hal_audiobusio_i2sout_pause(audiobusio_i2sout_obj_t* self) {
-    mp_raise_NotImplementedError(NULL);
+    self->paused = true;
 }
 void common_hal_audiobusio_i2sout_resume(audiobusio_i2sout_obj_t* self) {
-    mp_raise_NotImplementedError(NULL);
+    self->paused = false;
 }
 bool common_hal_audiobusio_i2sout_get_paused(audiobusio_i2sout_obj_t* self) {
-    mp_raise_NotImplementedError(NULL);
+    return self->paused;
 }
 void common_hal_audiobusio_i2sout_stop(audiobusio_i2sout_obj_t* self) {
-    mp_raise_NotImplementedError(NULL);
+    NRF_I2S->TASKS_STOP = 1;
    self->stopping = true;
 }
 bool common_hal_audiobusio_i2sout_get_playing(audiobusio_i2sout_obj_t* self) {
-    mp_raise_NotImplementedError(NULL);
+    if (NRF_I2S->EVENTS_STOPPED) {
        self->playing = false;
        NRF_I2S->EVENTS_STOPPED = 0;
    }
    return self->playing;
 }
 void i2s_background(void) {
    if (NRF_I2S->EVENTS_TXPTRUPD) {
        NRF_I2S->EVENTS_TXPTRUPD = 0;
        if (instance) {
            i2s_buffer_fill(instance);
        } else {
            NRF_I2S->TASKS_STOP = 1;
        }
    }
 }
 void i2s_reset(void) {
    NRF_I2S->TASKS_STOP = 1;
    NRF_I2S->ENABLE = I2S_ENABLE_ENABLE_Disabled;
    NRF_I2S->PSEL.MCK = 0xFFFFFFFF;
    NRF_I2S->PSEL.SCK = 0xFFFFFFFF;
    NRF_I2S->PSEL.LRCK = 0xFFFFFFFF;
    NRF_I2S->PSEL.SDOUT = 0xFFFFFFFF;
    NRF_I2S->PSEL.SDIN = 0xFFFFFFFF;
    instance = NULL;
 }
--- a/ports/nrf/common-hal/audiobusio/I2SOut.h
+++ b/ports/nrf/common-hal/audiobusio/I2SOut.h
@ -31,6 +31,33 @@
 typedef struct {
    mp_obj_base_t base;
    mp_obj_t *sample;
    uint8_t *buffers[2];
    uint8_t *sample_data, *sample_end;
    uint16_t buffer_length;
    uint16_t sample_rate;
    uint32_t hold_value;
    uint8_t next_buffer;
    uint8_t bit_clock_pin_number;
    uint8_t word_select_pin_number;
    uint8_t data_pin_number;
    uint8_t channel_count;
    uint8_t bytes_per_sample;
    bool left_justified : 1;
    bool playing : 1;
    bool stopping : 1;
    bool paused : 1;
    bool loop : 1;
    bool samples_signed : 1;
    bool single_buffer : 1;
 } audiobusio_i2sout_obj_t;
 void i2s_reset(void);
 void i2s_background(void);
 #endif // MICROPY_INCLUDED_NRF_COMMON_HAL_AUDIOBUSIO_I2SOUT_H
--- a/ports/nrf/supervisor/port.c
+++ b/ports/nrf/supervisor/port.c
@ -50,6 +50,10 @@
 #include "shared-bindings/rtc/__init__.h"
 #ifdef CIRCUITPY_AUDIOBUSIO
 #include "common-hal/audiobusio/I2SOut.h"
 #endif
 #ifdef CIRCUITPY_AUDIOPWMIO
 #include "common-hal/audiopwmio/PWMAudioOut.h"
 #endif
@ -98,10 +102,15 @@ void reset_port(void) {
    spi_reset();
    uart_reset();
 #ifdef CIRCUITPY_AUDIOBUSIO
    i2s_reset();
 #endif
 #ifdef CIRCUITPY_AUDIOPWMIO
    audiopwmout_reset();
 #endif
 #if CIRCUITPY_PULSEIO
    pwmout_reset();
    pulseout_reset();