soundcube-firmware/soundcube-i2s-test/codec.h

#include <cstdint>
#pragma once

#include <Wire.h>

struct CodecSettings{
  public:

    virtual void get() = 0;

    void write(){
      selectPage(page);
      cw(reg, get());
    }

    void selectPage(int page){
      cw(0x00, page);
    }

    void cw(unsigned char first, unsigned char second){
      Wire1.beginTransmission(i2c_address);
      Wire1.write(first);
      Wire1.write(second);
      int result = Wire1.endTransmission();
      if(debug){
        Serial.print(i2c_address, HEX);
        Serial.print(" ");
        Serial.print(first, HEX);
        Serial.print(" ");
        Serial.print(second, HEX);
        Serial.print(" : ");
        if(result == 0) {
          Serial.println("OK");
        } else {
          Serial.print("ERROR: ");
          Serial.println(result);
        }
      }
      delay(5);
    }

    void cr(unsigned char first, uint8_t &result, size_t len){
      Wire1.beginTransmission(i2c_address);  
      Wire1.write(first);  // set register for read
      Wire1.endTransmission(false); // false to not release the line

      Wire1.requestFrom(i2c_address, len, true);

      Wire1.readBytes(result, len);

      if(debug){
        Serial.print(first, HEX);
        Serial.print(" ");

        for (int i = 0; i < len; i++) {
          Serial.print(result[i], HEX);
          Serial.print(" ");
          Serial.println(result[i], BIN);
        }
      }
    }
};

struct ClockSettings1 : public CodecSettings{
  uint8_t page = 0x00;
  uint8_t reg = 0x04;

  enum PLLRange{
    PLL_HIGH = 0b01000000,
    PLL_LOW = 0b00000000
  };

  enum PLLInputClock{
    PLL_IN_MCLK = 0b00000000,
    PLL_IN_BCLK = 0b00000100,
    PLL_IN_GPIO = 0b00001000,
    PLL_IN_DIN  = 0b00001100
  };

  enum CodecInputClock{
    CODEC_IN_MCLK = 0b00000000,
    CODEC_IN_BCLK = 0b00000001,
    CODEC_IN_GPIO = 0b00000010,
    CODEC_IN_PLL  = 0b00000011
  };

  PLLRange pll_range = PLL_LOW;
  PLLInputClock pll_input_clock = PLL_IN_MCLK;
  CodecInputClock codec_input_clock = CODEC_IN_MCLK;

  uint8_t get(){
    return pll_range | pll_input_clock | codec_input_clock;
  }
};

class TLV320AIC3204_Settings{

  public:

    static ClockSettings1 clock_settings_1;

};

class TLV320AIC3204{

  public:
    TLV320AIC3204(){i2c = &Wire}
    TLV320AIC3204(TwoWire &wire) : i2c(&wire) {}

    uint8_t i2c_address = 0x18;

    void init();
    
    void softReset(); // 0x00 0x01
    void hardReset(); // reset pin

    void powerUp();   // power up

    void setClockMultiplexer(ClockSettings1::PLLRange range, ClockSettings1::PLLInputClock pll_input, ClockSettings1::CodecInputClock codec_input) {
      settings.clock_settings_1.pll_range = range;
      settings.clock_settings_1.pll_input_clock = pll_input;
      settings.clock_settings_1.codec_input_clock = codec_input;
      settings.clock_settings_1.write();
    }

    void setADCParameters(int nadc, int madc, int osr);
    void setDACParameters(int madc, int nadc, int osr);

    void setMicPgaGain(int gainLeft, int gainRight); // 0 - 47.5dB in 0.5dB steps
    void setMicPgaGainL(int gain);
    void setMicPgaGainR(int gain);
    
    void setLineOutVolume(int volumeLeft, int volumeRight);
    void setLineOutVolumeL(int volume);
    void setLineOutVolumeR(int volume);

    bool debug = false;

  private:
    TwoWire *i2c;

    TLV320AIC3204_Settings settings;


};


/*
  // GENERAL
  cw(0x00, 0x00); // select page 0
  cw(0x01, 0x01); // soft reset
  cw(0x1b, 0b00000000); // select I2S with 16 bit word length
  cw(0x1d, 0b00000000); // disable loopback

  // POWER and CM
  cw(0x00, 0x01); // select page 1
  cw(0x01, 0b00001000); // disable weak (crude) AVdd connection to DVdd
  cw(0x02, 0b00000001); // enable internal AVdd LDO and enable analog blocks
  cw(0x09, 0b00001100); // power up LOL, LOR, power down MAL, MAR, HPL, HPR
  cw(0x0a, 0b00001000); // set full chip CM to 0.75V
  cw(0x47, 0b00110011); // analog input quick charge time 1.6ms

  // ROUTING
  cw(0x00, 0x01); // select page 1
  cw(0x34, 0b10000000); // LEFT MICPGA P route IN1L to LEFT_P with 40k input impedance
  //cw(0x36, 0b11000000); // LEFT MICPGA M route CM to LEFT_M with 20k input impedance
  //cw(0x36, 0b00000011); // LEFT MICPGA M route CM to LEFT_M with 20k input impedance
  cw(0x37, 0b10000000); // RIGHT MICPGA P route IN1R to RIGHT_P with 20k input impedance
  //cw(0x39, 0b11000000); // RIGHT MICPGA M route CM to RIGHT_M with 20k input impedance
  //cw(0x39, 0b00000011); // RIGHT MICPGA M route CM to RIGHT_M with 20k input impedance
  cw(0x3a, 0b00111100); // connect IN2, IN3 weakly to CM

  // GAIN
  cw(0x00, 0x01); // select page 1
  cw(0x3b, 0b00000000); // unmute left MICPGA, set gain to 0db
  cw(0x3c, 0b00000000); // unmute right MICPGA, set gain to 0db

  // VOLUME
  cw(0x00, 0x01); // select page 1
  cw(0x16, 0b01110101); // MUTE IN1L to HPL
  cw(0x17, 0b01110101); // MUTE IN1R to HPR

  // ADC
  cw(0x00, 0x00); // select page 0
  cw(0x12, 0x81); // NADC 1
  cw(0x13, 0x82); // MADC 2
  cw(0x14, 0b10000000); // OSR ADC 128
  //cw(0x14, 0b01000000); // OSR ADC 128
  cw(0x3d, 0b00000001); // ADC PRB_R3 = 11, PRB_R2 = 10, PRB_R1 = 01

  cw(0x00, 0x01); // select page 1
  cw(0x3d, 0b00000000); // ADC PTM_R4

  // DAC
  cw(0x00, 0x00); // select page 0
  cw(0x0b, 0x81); // NDAC 1
  cw(0x0c, 0x82); // MDAC 2
  cw(0x0d, 0x00); // OSR DAC 128
  cw(0x0e, 0x80); // OSR DAC 128
  cw(0x1b, 0b00000000); // word length 16bits
  cw(0x3c, 0b00000001); // PRB_P3

  cw(0x00, 0x01); // select page 1
  cw(0x7b, 0b00000001); // set REF charging time to 40ms
  
  // ROUTING
  cw(0x00, 0x01); // select page 1
  cw(0x0e, 0b00001000); // left DAC reconstruction filter routed to LOL
  cw(0x0f, 0b00001000); // right DAC reconstruction filter routed to LOR
  cw(0x03, 0b00000000); // DAC PTM_P3/4
  cw(0x04, 0b00000000); // DAC PTM_P3/4

  // LO GAIN
  cw(0x00, 0x01);
  cw(0x12, 0b00000001); // LOL gain 0dB
  cw(0x13, 0b00000001); // LOR gain 0dB

  // POWER UP
  // ADC
  cw(0x00, 0x00); // select page 0
  cw(0x51, 0b11000000); // power up ADC
  cw(0x52, 0b00000000); // unmute ADC
  cw(0x3f, 0b11010100); // power up and route left digital audio to left dac channel and right to right
  cw(0x40, 0x00); // unmute DAC digital volume

  // DAC VOLUME 0b00000000 = 0dB, 10000001 = -63.5dB, 0b00110000 = +24dB
  cw(0x00, 0x00); // select page 0
  cw(0x41, 0b11111001); // LEFT 
  cw(0x42, 0b11111001); // RIGHT
  
  // ADC VOLUME 0b1101000 = -12dB, 0b00000000 = 0dB, 0b0101000 = +20dB
  cw(0x00, 0x00); // select page 0
  cw(0x53, 0b01110000); // LEFT
  cw(0x54, 0b01110000); // RIGHT

*/
The beginnings of codec.h 2025-06-01 01:09:35 +02:00			`#include <cstdint>`
			`#pragma once`

			`#include <Wire.h>`

			`struct CodecSettings{`
			`public:`

			`virtual void get() = 0;`

			`void write(){`
			`selectPage(page);`
			`cw(reg, get());`
			`}`

			`void selectPage(int page){`
			`cw(0x00, page);`
			`}`

			`void cw(unsigned char first, unsigned char second){`
			`Wire1.beginTransmission(i2c_address);`
			`Wire1.write(first);`
			`Wire1.write(second);`
			`int result = Wire1.endTransmission();`
			`if(debug){`
			`Serial.print(i2c_address, HEX);`
			`Serial.print(" ");`
			`Serial.print(first, HEX);`
			`Serial.print(" ");`
			`Serial.print(second, HEX);`
			`Serial.print(" : ");`
			`if(result == 0) {`
			`Serial.println("OK");`
			`} else {`
			`Serial.print("ERROR: ");`
			`Serial.println(result);`
			`}`
			`}`
			`delay(5);`
			`}`

			`void cr(unsigned char first, uint8_t &result, size_t len){`
			`Wire1.beginTransmission(i2c_address);`
			`Wire1.write(first); // set register for read`
			`Wire1.endTransmission(false); // false to not release the line`

			`Wire1.requestFrom(i2c_address, len, true);`

			`Wire1.readBytes(result, len);`

			`if(debug){`
			`Serial.print(first, HEX);`
			`Serial.print(" ");`

			`for (int i = 0; i < len; i++) {`
			`Serial.print(result[i], HEX);`
			`Serial.print(" ");`
			`Serial.println(result[i], BIN);`
			`}`
			`}`
			`}`
			`};`

			`struct ClockSettings1 : public CodecSettings{`
			`uint8_t page = 0x00;`
			`uint8_t reg = 0x04;`

			`enum PLLRange{`
			`PLL_HIGH = 0b01000000,`
			`PLL_LOW = 0b00000000`
			`};`

			`enum PLLInputClock{`
			`PLL_IN_MCLK = 0b00000000,`
			`PLL_IN_BCLK = 0b00000100,`
			`PLL_IN_GPIO = 0b00001000,`
			`PLL_IN_DIN = 0b00001100`
			`};`

			`enum CodecInputClock{`
			`CODEC_IN_MCLK = 0b00000000,`
			`CODEC_IN_BCLK = 0b00000001,`
			`CODEC_IN_GPIO = 0b00000010,`
			`CODEC_IN_PLL = 0b00000011`
			`};`

			`PLLRange pll_range = PLL_LOW;`
			`PLLInputClock pll_input_clock = PLL_IN_MCLK;`
			`CodecInputClock codec_input_clock = CODEC_IN_MCLK;`

			`uint8_t get(){`
			`return pll_range \| pll_input_clock \| codec_input_clock;`
			`}`
			`};`

			`class TLV320AIC3204_Settings{`

			`public:`

			`static ClockSettings1 clock_settings_1;`

			`};`

			`class TLV320AIC3204{`

			`public:`
			`TLV320AIC3204(){i2c = &Wire}`
			`TLV320AIC3204(TwoWire &wire) : i2c(&wire) {}`

			`uint8_t i2c_address = 0x18;`

			`void init();`

			`void softReset(); // 0x00 0x01`
			`void hardReset(); // reset pin`

			`void powerUp(); // power up`

			`void setClockMultiplexer(ClockSettings1::PLLRange range, ClockSettings1::PLLInputClock pll_input, ClockSettings1::CodecInputClock codec_input) {`
			`settings.clock_settings_1.pll_range = range;`
			`settings.clock_settings_1.pll_input_clock = pll_input;`
			`settings.clock_settings_1.codec_input_clock = codec_input;`
			`settings.clock_settings_1.write();`
			`}`

			`void setADCParameters(int nadc, int madc, int osr);`
			`void setDACParameters(int madc, int nadc, int osr);`

			`void setMicPgaGain(int gainLeft, int gainRight); // 0 - 47.5dB in 0.5dB steps`
			`void setMicPgaGainL(int gain);`
			`void setMicPgaGainR(int gain);`

			`void setLineOutVolume(int volumeLeft, int volumeRight);`
			`void setLineOutVolumeL(int volume);`
			`void setLineOutVolumeR(int volume);`

			`bool debug = false;`

			`private:`
			`TwoWire *i2c;`

			`TLV320AIC3204_Settings settings;`




			`};`


			`/*`
			`// GENERAL`
			`cw(0x00, 0x00); // select page 0`
			`cw(0x01, 0x01); // soft reset`
			`cw(0x1b, 0b00000000); // select I2S with 16 bit word length`
			`cw(0x1d, 0b00000000); // disable loopback`

			`// POWER and CM`
			`cw(0x00, 0x01); // select page 1`
			`cw(0x01, 0b00001000); // disable weak (crude) AVdd connection to DVdd`
			`cw(0x02, 0b00000001); // enable internal AVdd LDO and enable analog blocks`
			`cw(0x09, 0b00001100); // power up LOL, LOR, power down MAL, MAR, HPL, HPR`
			`cw(0x0a, 0b00001000); // set full chip CM to 0.75V`
			`cw(0x47, 0b00110011); // analog input quick charge time 1.6ms`

			`// ROUTING`
			`cw(0x00, 0x01); // select page 1`
			`cw(0x34, 0b10000000); // LEFT MICPGA P route IN1L to LEFT_P with 40k input impedance`
			`//cw(0x36, 0b11000000); // LEFT MICPGA M route CM to LEFT_M with 20k input impedance`
			`//cw(0x36, 0b00000011); // LEFT MICPGA M route CM to LEFT_M with 20k input impedance`
			`cw(0x37, 0b10000000); // RIGHT MICPGA P route IN1R to RIGHT_P with 20k input impedance`
			`//cw(0x39, 0b11000000); // RIGHT MICPGA M route CM to RIGHT_M with 20k input impedance`
			`//cw(0x39, 0b00000011); // RIGHT MICPGA M route CM to RIGHT_M with 20k input impedance`
			`cw(0x3a, 0b00111100); // connect IN2, IN3 weakly to CM`

			`// GAIN`
			`cw(0x00, 0x01); // select page 1`
			`cw(0x3b, 0b00000000); // unmute left MICPGA, set gain to 0db`
			`cw(0x3c, 0b00000000); // unmute right MICPGA, set gain to 0db`

			`// VOLUME`
			`cw(0x00, 0x01); // select page 1`
			`cw(0x16, 0b01110101); // MUTE IN1L to HPL`
			`cw(0x17, 0b01110101); // MUTE IN1R to HPR`

			`// ADC`
			`cw(0x00, 0x00); // select page 0`
			`cw(0x12, 0x81); // NADC 1`
			`cw(0x13, 0x82); // MADC 2`
			`cw(0x14, 0b10000000); // OSR ADC 128`
			`//cw(0x14, 0b01000000); // OSR ADC 128`
			`cw(0x3d, 0b00000001); // ADC PRB_R3 = 11, PRB_R2 = 10, PRB_R1 = 01`

			`cw(0x00, 0x01); // select page 1`
			`cw(0x3d, 0b00000000); // ADC PTM_R4`

			`// DAC`
			`cw(0x00, 0x00); // select page 0`
			`cw(0x0b, 0x81); // NDAC 1`
			`cw(0x0c, 0x82); // MDAC 2`
			`cw(0x0d, 0x00); // OSR DAC 128`
			`cw(0x0e, 0x80); // OSR DAC 128`
			`cw(0x1b, 0b00000000); // word length 16bits`
			`cw(0x3c, 0b00000001); // PRB_P3`

			`cw(0x00, 0x01); // select page 1`
			`cw(0x7b, 0b00000001); // set REF charging time to 40ms`

			`// ROUTING`
			`cw(0x00, 0x01); // select page 1`
			`cw(0x0e, 0b00001000); // left DAC reconstruction filter routed to LOL`
			`cw(0x0f, 0b00001000); // right DAC reconstruction filter routed to LOR`
			`cw(0x03, 0b00000000); // DAC PTM_P3/4`
			`cw(0x04, 0b00000000); // DAC PTM_P3/4`

			`// LO GAIN`
			`cw(0x00, 0x01);`
			`cw(0x12, 0b00000001); // LOL gain 0dB`
			`cw(0x13, 0b00000001); // LOR gain 0dB`

			`// POWER UP`
			`// ADC`
			`cw(0x00, 0x00); // select page 0`
			`cw(0x51, 0b11000000); // power up ADC`
			`cw(0x52, 0b00000000); // unmute ADC`
			`cw(0x3f, 0b11010100); // power up and route left digital audio to left dac channel and right to right`
			`cw(0x40, 0x00); // unmute DAC digital volume`

			`// DAC VOLUME 0b00000000 = 0dB, 10000001 = -63.5dB, 0b00110000 = +24dB`
			`cw(0x00, 0x00); // select page 0`
			`cw(0x41, 0b11111001); // LEFT`
			`cw(0x42, 0b11111001); // RIGHT`

			`// ADC VOLUME 0b1101000 = -12dB, 0b00000000 = 0dB, 0b0101000 = +20dB`
			`cw(0x00, 0x00); // select page 0`
			`cw(0x53, 0b01110000); // LEFT`
			`cw(0x54, 0b01110000); // RIGHT`

			`*/`