WS-1.0-Firmwares/DubSiren/DubSiren.ino

// DubSiren firmware for Sitka Instruments WS-1.0
// by Oleksiy Hrachov
// 
// Although the code designed to work on Sitka Instruments WS-1.0 synth, it should  
// be pretty easy to adapt to run on other arduino/mozzi-based setups
//
// This code is licenced under GPL v3 or later

//ToDo:
//Transform Flamingo into DubSiren :)
//✅ Square oscilator
//✅ Square/Sine pitch LFO on switch
//✅ Filter
//⬜ Delay?

#include <Mozzi.h>
#include <MIDI.h>
#include <Oscil.h>
#include <MetaOscil.h>
#include <tables/sin2048_int8.h>
#include <tables/square_no_alias_2048_int8.h>
//#include <tables/square_analogue512_int8.h>
#include <StateVariable.h>
#include <ADSR.h>
#include <mozzi_midi.h>
#include <IntMap.h>
#include <OverSample.h>
#include <FixMath.h>

//Band limited oscilator tables for aliasing-free Meta Oscilator
#include <tables/BandLimited_SQUARE/512/square_max_90_at_16384_512_int8.h> 
#include <tables/BandLimited_SQUARE/512/square_max_101_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_122_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_138_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_154_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_174_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_210_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_264_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_327_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_431_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_546_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_744_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_910_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_1170_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_1638_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_2730_at_16384_512_int8.h>
#include <tables/BandLimited_SQUARE/512/square_max_8192_at_16384_512_int8.h>
Oscil <SQUARE_MAX_90_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq90(SQUARE_MAX_90_AT_16384_512_DATA);
Oscil <SQUARE_MAX_101_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq101(SQUARE_MAX_101_AT_16384_512_DATA);
Oscil <SQUARE_MAX_122_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq122(SQUARE_MAX_122_AT_16384_512_DATA);
Oscil <SQUARE_MAX_138_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq138(SQUARE_MAX_138_AT_16384_512_DATA);
Oscil <SQUARE_MAX_154_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq154(SQUARE_MAX_154_AT_16384_512_DATA);
Oscil <SQUARE_MAX_174_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq174(SQUARE_MAX_174_AT_16384_512_DATA);
Oscil <SQUARE_MAX_210_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq210(SQUARE_MAX_210_AT_16384_512_DATA);
Oscil <SQUARE_MAX_264_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq264(SQUARE_MAX_264_AT_16384_512_DATA);
Oscil <SQUARE_MAX_327_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq327(SQUARE_MAX_327_AT_16384_512_DATA);
Oscil <SQUARE_MAX_431_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq431(SQUARE_MAX_431_AT_16384_512_DATA);
Oscil <SQUARE_MAX_546_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq546(SQUARE_MAX_546_AT_16384_512_DATA);
Oscil <SQUARE_MAX_744_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq744(SQUARE_MAX_744_AT_16384_512_DATA);
Oscil <SQUARE_MAX_910_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq910(SQUARE_MAX_910_AT_16384_512_DATA);
Oscil <SQUARE_MAX_1170_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq1170(SQUARE_MAX_1170_AT_16384_512_DATA);
Oscil <SQUARE_MAX_1638_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq1638(SQUARE_MAX_1638_AT_16384_512_DATA);
Oscil <SQUARE_MAX_2730_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq2730(SQUARE_MAX_2730_AT_16384_512_DATA);
Oscil <SQUARE_MAX_8192_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE> aSq8192(SQUARE_MAX_8192_AT_16384_512_DATA);
MetaOscil<SQUARE_MAX_90_AT_16384_512_NUM_CELLS, MOZZI_AUDIO_RATE, 16> aSquare {&aSq90, &aSq101, &aSq122, &aSq138, &aSq154, &aSq174, &aSq210, &aSq264, &aSq327, &aSq431, &aSq546, &aSq744, &aSq1170, &aSq1638, &aSq2730, &aSq8192};


//Settings
const int pitchSubSteps = 32; //set how many steps are there between semitones. set to 1 to quantize to semitones
const int driveAmount = 450;
#define MIDI_CHANNEL MIDI_CHANNEL_OMNI 
#define MOZZI_CONTROL_RATE 1024

//Hardware Definitions
#define Knob1   A6  //LFO Frequency
#define Knob2   A4  //LFO Intensity
#define Knob3   A2  //LPF Resonance
#define Knob4   A0  //LPF Cutoff
#define KnobA   A5  //Attack
#define KnobDR  A3  //Decay and Release
#define KnobS   A1  //Sustain
#define CVIn    A7  //CV input and Pitch knob
#define GateIn  10 
#define EnvSwitch 11
#define DroneSwitch 12
#define LED     5

#define MOZZI_ANALOG_READ_RESOLUTION 10

MIDI_CREATE_DEFAULT_INSTANCE();

IntMap kMapNote(   0, 4095, 24 * pitchSubSteps, 84 * pitchSubSteps );
IntMap kMapLFOSpeed(     0, 1023, 500, 20000 );
IntMap kMapFreqMod(      0, 1023, 0,   1023  );
IntMap kMapResonance(    0, 1023, 200, 1     );
IntMap kMapCutoff(       0, 1023, 60,  3600  );
IntMap kMapAttack(       0, 1023, 0,   80    );
IntMap kMapDecayRelease( 0, 1023, 8,   160   );
IntMap kMapSustain(      0, 1023, 0,   255   );

//Oscil<SQUARE_ANALOGUE512_NUM_CELLS, MOZZI_AUDIO_RATE> aSquare(SQUARE_ANALOGUE512_DATA);
Oscil<SQUARE_NO_ALIAS_2048_NUM_CELLS, MOZZI_CONTROL_RATE> kSquareLFO(SQUARE_NO_ALIAS_2048_DATA);
Oscil<SIN2048_NUM_CELLS, MOZZI_CONTROL_RATE> kSineLFO(SIN2048_DATA);

ADSR <MOZZI_CONTROL_RATE, MOZZI_CONTROL_RATE> envelope;
StateVariable <LOWPASS> lpf;
OverSample <unsigned int, 2> kOverSamplePitch;

//Global variables
byte gain;
bool MIDINotePlaying;
bool gateIsHigh = false;
float noteFreq;

void MIDINoteOn(byte channel, byte note, byte velocity) {
  noteFreq = mtof((int) note);
  envelope.noteOn();
  MIDINotePlaying = true;
  digitalWrite(LED, LOW);
}

void MIDINoteOff(byte channel, byte note, byte velocity) {
  envelope.noteOff();
  digitalWrite(LED, HIGH);
}

long softClip(long input) {
  int threshold = 2048;
  if (input < -threshold) {
    return -threshold + (input + threshold) / 4;
  } else if (input > threshold) {
    return threshold + (input - threshold) / 4;
  } else {
    return input;
  }
}

void setup(){
  pinMode(LED, OUTPUT);
  pinMode(GateIn, INPUT_PULLUP);
  pinMode(EnvSwitch, INPUT_PULLUP);
  pinMode(DroneSwitch, INPUT_PULLUP);

  MIDI.setHandleNoteOn(MIDINoteOn);
  MIDI.setHandleNoteOff(MIDINoteOff);
  MIDI.begin(MIDI_CHANNEL);

  aSquare.setCutoffFreqs(90, 101, 122, 138, 154, 174, 210, 264, 327, 431, 546, 744, 1170, 1638, 2730, 8192);

  startMozzi();

  envelope.setAttackLevel(255);

  digitalWrite(LED, HIGH);
}

void updateControl(){
  //Get Control Values
  int CVInVal = mozziAnalogRead(CVIn);
  int knob1Val = mozziAnalogRead(Knob1);
  int knob2Val = mozziAnalogRead(Knob2);
  int knob3Val = mozziAnalogRead(Knob3);
  int knob4Val = mozziAnalogRead(Knob4);
  int knobAVal = mozziAnalogRead(KnobA);
  int knobDRVal = mozziAnalogRead(KnobDR);
  int knobSVal = mozziAnalogRead(KnobS);
  bool droneSwitchVal = digitalRead(DroneSwitch);
  bool envSwitchVal = digitalRead(EnvSwitch);
  bool gateInVal = !digitalRead(GateIn);

  //Remap the values and assign to parameter
  float LFOSpeed = kMapLFOSpeed(knob1Val) / 100;
  float expLFOSpeed = (float) LFOSpeed * LFOSpeed / 800000;
  float freqMod = (float) kMapFreqMod(knob2Val) / 1023;
  float modSpeed = LFOSpeed;
  int resonance = kMapResonance(knob3Val);
  int cutoff = kMapCutoff(knob4Val);

  //Set pitch and play notes on trigger
  if (!MIDINotePlaying) {
    int oversampledCVInVal = kOverSamplePitch.next(CVInVal);
    noteFreq = mtof((float) kMapNote(oversampledCVInVal) / pitchSubSteps);
    //noteFreq = mtof((float) kMapNote(CVInVal << 2) / pitchSubSteps);
    digitalWrite(LED, !gateInVal);
    if (gateInVal && !gateIsHigh) {
      gateIsHigh = true;
      envelope.noteOn();
    } else if (!gateInVal && gateIsHigh) {
      gateIsHigh = false;
      envelope.noteOff();
    }
  } else if (MIDINotePlaying && !envelope.playing()) {
    MIDINotePlaying = false;
  }

  //Update Filter settings
  lpf.setResonance(resonance);
  lpf.setCentreFreq(cutoff);

  //Update Envelope Settings
  int attackTime = kMapAttack(knobAVal);
  int decayReleaseTime = kMapDecayRelease(knobDRVal);
  int sustainLevel = kMapSustain(knobSVal);
  envelope.setDecayLevel(sustainLevel);
  envelope.setTimes(attackTime, decayReleaseTime, 30000, decayReleaseTime); //30000 is so the note will sustain 30 seconds unless a noteOff comes

  //LFO stuff
  //Set oscillator frequencies
  kSquareLFO.setFreq(modSpeed);
  kSineLFO.setFreq(modSpeed);
  int LFOValue;
  if(envSwitchVal) {
    LFOValue = kSquareLFO.next()-127; //-109 to bring the rangt to ~ 0-192
  } else {
    LFOValue = kSineLFO.next()-127;
  }

  //Set Oscilator Frequency
  float oscFreq = noteFreq - noteFreq * LFOValue * freqMod * 3 / 256;
  //UFix<16,16> oscFreq = 
  aSquare.setFreq(oscFreq); 
  
  envelope.update();

  int env = envelope.next();

  if(!droneSwitchVal) {
    gain = env;
  } else {
    gain = 255;
  }

  MIDI.read();
}

AudioOutput updateAudio(){
  long signal = aSquare.next();
  signal = lpf.next(signal); //filter
  signal = (signal * gain); //envelope
  //signal = softClip((signal * (127 + driveAmount)) >> 8); //overdrive
  return MonoOutput::fromNBit(17, signal).clip();
}

void loop(){
  audioHook();
}