GravityHW/Software/Gravity/Gravity.ino

#include <Wire.h>
#include <RotaryEncoder.h>
#include <FlexiTimer2.h>
#include <EEPROM.h>
#include <U8g2lib.h>
#include <avr/wdt.h>

const char version[5] = "V:0.9";

#define SCREEN_ADDRESS 0x3C

#define PPQN 24
#define PULSE_LENGTH 12  //ms (with 12 ms you can't get higher than 208bpm)
#define MAXBPM 200       //250 at 24ppqn with 5ms pulse will be 50/50 square wave
#define MINBPM 20

// Rev 2 and 3 Config
#define ENC_BTN_PIN 14
#define ENC_D1_PIN 17
#define ENC_D2_PIN 4
#define START_STOP_BTN_PIN 5
#define SHIFT_BTN_PIN 12
#define EXT_INPUT_PIN 2  //needs to be an interrupt pin
#define ANALOGUE_INPUT_1_PIN A7
#define ANALOGUE_INPUT_2_PIN A6
const byte outsPins[6] = { 7, 8, 10, 6, 9, 11 };
const byte clockOutPin = 3;

int CV1Calibration = 0;
int CV2Calibration = 0;
bool rotateScreen = false;

const int subDivs[17] = { -24, -12, -8, -6, -4, -3, -2, 1, 2, 3, 4, 5, 6, 7, 8, 16, 32 };  //positive - divide, negative - multiply, 0 - off

byte bpm = 130;
byte bpmModulationChannel = 200;  //0 - CV1, 1 - CV2, 255 - OFF
byte bpmModulationRange = 0;

struct channel {
  byte mode; //0 - CLK, 1 - RND, 2 - SEQ
  byte subDiv;
  byte CV1Target; //0 - Off, 1 - Subdiv, 2 - RND, 3 - SeqPattern
  byte CV1Value;
  byte CV2Target;
  byte CV2Value;
  byte offset;
  byte random;
  byte seqPattern;
};

channel channels[6] = {  //array of channel settings
  { 0, 7, 0, 3, 0, 3, 0, 0, 0 },
  { 0, 7, 0, 3, 0, 3, 0, 0, 0 },
  { 0, 7, 0, 3, 0, 3, 0, 0, 0 },
  { 0, 7, 0, 3, 0, 3, 0, 0, 0 },
  { 0, 7, 0, 3, 0, 3, 0, 0, 0 },
  { 0, 7, 0, 3, 0, 3, 0, 0, 0 }
};

bool seqA1[16] = {1, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 1};
bool seqA2[16] = {0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0};
bool seqA3[16] = {1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 0, 0, 0};
bool seqA4[16] = {0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1};
bool seqA5[16] = {0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1};
bool seqA6[16] = {0, 0, 1, 0, 1, 0, 1, 0, 0, 0, 1, 0, 1, 0, 1, 0};
bool seqA7[16] = {1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 0};
bool seqA8[16] = {1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 1, 0, 1, 1, 0, 1};
bool seqB1[16] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
bool seqB2[16] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
bool seqB3[16] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
bool seqB4[16] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
bool seqB5[16] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
bool seqB6[16] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
bool seqB7[16] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
bool seqB8[16] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
byte currentStep = 0;
byte stepNumSelected = 0;
bool *patternToEdit;

byte memCode = 'A'; //Change to different letter if you changed the data structure

unsigned int channelPulseCount[6];
unsigned int channelPulsesPerCycle[6];
byte sixteenthPulseCount = 0;
int playingModes[6];  //actual channel modes array updated from channels object on each beat

unsigned int pulsePeriod;
bool isPlaying = false;
bool isRecording = false;
bool recordToNextStep = false;

unsigned int tickCount = 0;
unsigned int pulseCount = 0;

byte masterClockMode = 0;  // 0 - internal, 1 - external 24ppqn, 2 - external beat
unsigned long lastExtPulseTime;
unsigned long newExtPulseTime;

bool needPulseReset[6] = { true, true, true, true, true, true };

byte displayTab = 0;
bool insideTab = false;
byte menuItem = 0;
bool menuItemSelected = false;
byte lastMenuItem = 3;
byte displayScreen = 0; //0 - main, 1 - sequencer, 2 - settings

bool playBtnPushed = false;
bool shiftBtnPushed = false;

int a1Input = 0;
int a2Input = 0;

int encPositionOld = 0;
unsigned long encPressedTime;
unsigned long encReleasedTime;
unsigned long playPressedTime;
unsigned long playReleasedTime;
unsigned long shiftPressedTime;
unsigned long shiftReleasedTime;
bool encBtnPushed;

//unsigned long lastInteractionTime;  // used for display timeout

U8G2_SSD1306_128X64_NONAME_2_HW_I2C u8g2(U8G2_R2, SCL, SDA, U8X8_PIN_NONE); 
RotaryEncoder encoder(ENC_D1_PIN, ENC_D2_PIN, RotaryEncoder::LatchMode::TWO03);

//Font
const uint8_t velvetscreen[437] U8G2_FONT_SECTION("velvetscreen") = 
  "\64\0\2\2\3\3\2\3\4\5\5\0\0\5\0\5\0\0\221\0\0\1\230 \4\200\134%\11\255tT"
  "R\271RI(\6\252\334T\31)\7\252\134bJ\12+\7\233\345\322J\0,\5\221T\4-\5\213"
  "f\6.\5\211T\2/\6\244\354c\33\60\10\254\354T\64\223\2\61\7\353\354\222\254\6\62\11\254l"
  "\66J*\217\0\63\11\254l\66J\32\215\4\64\10\254l\242\34\272\0\65\11\254l\206\336h$\0\66"
  "\11\254\354T^\61)\0\67\10\254lF\216u\4\70\11\254\354TL*&\5\71\11\254\354TL;"
  ")\0:\6\231UR\0A\10\254\354T\34S\6B\11\254lV\34)\216\4C\11\254\354T\324\61"
  ")\0D\10\254lV\64G\2E\10\254l\206\36z\4F\10\254l\206^\71\3G\11\254\354TN"
  "\63)\0H\10\254l\242\34S\6I\6\251T\206\0J\10\254\354k\231\24\0K\11\254l\242J\62"
  "\225\1L\7\254lr{\4M\11\255t\362ZI\353\0N\11\255t\362TI\356\0O\10\254\354T"
  "\64\223\2P\11\254lV\34)g\0Q\10\254\354T\264b\12R\10\254lV\34\251\31S\11\254\354"
  "FF\32\215\4T\7\253dVl\1U\10\254l\242\63)\0V\11\255t\262Ne\312\21W\12\255"
  "t\262J*\251.\0X\11\254l\242L*\312\0Y\12\255tr\252\63\312(\2Z\7\253df*"
  "\7p\10\255\364V\266\323\2q\7\255\364\216\257\5r\10\253d\242\32*\2t\6\255t\376#w\11"
  "\255\364V\245FN\13x\6\233dR\7\0\0\0\4\377\377\0";

const uint8_t fabryka[450] U8G2_FONT_SECTION("fabryka") = 
  "\17\0\4\4\4\5\2\1\6\17\30\1\0\30\0\0\0\1K\0\0\1\245%'\17\37\313\330R#&"
  "\32!F\14\211I\310\24!\65\204(MF\21)Cd\304\10\62b\14\215\60Vb\334\20\0/\15"
  "\376\36\357\244$\351\77\35;\26\0\60$\216\37\17*\65,\210\35\264\335\61T\42\14\11\61#\306\210"
  " \23\242\220\235\63h\303c$\330\250B\3\0\61\27\216\37\27\311\202\346\216\221\30Ed\324\230Q\202"
  "\306\316\377\263\26\35\62\33\216\37\17*\65,\210\35\64\70v\246\344\316h\203\252$\321\261s\373\340\1"
  "\3\63\35\216\37\17*\65,\210\35\64\70v(IZZKv\266\6\15\36#\301F\25\32\0\64\37"
  "\216\37\227\240\331\20\32Bj\310\260\21\304F\214\33\61n\304\70\203\366\360\301\203\20m\347\3\65\32\216"
  "\37\7\213.\306\316'\205\326\60!E\226\354\334\32<F\202\215*\64\0\66\33\216\37\17*\65,\210"
  "\35\64;/\316\60iA\354\240=<F\202\215*\64\0\67\25\216\37C\213\7m\347S\222\364\351\264"
  "C\307\16\35;)\0\70 \216\37\17*\65,\210\35\264\341\61\22\204\310\250B\245\206\20\11b\7\355"
  "\360\30\11\66\252\320\0\71\33\216\37\17*\65,\210\35\264\207\307H\64asb\354|\61\214\4\33U"
  "h\0A\30\216\37\223\71Tj\10\21\31\66d\330\210\201\366\360\301\7\3\355\17\7B&\216\37\203\242"
  "\65L\206\221\30\67b\334\210q#\306\215\30\67b\30\11&\234\14#\61\356\240\275{ \242\5\23\0"
  "x\32\336\36\303\300c$\10\221!B\12\235I\222\346P\21!C\210\4\261\203\3\0\0\0\4\377\377"
  "\0";

static const uint16_t fabryka_first_encoding_table[4] = {
  47, 49, 55, 65535};
static const uint16_t fabryka_index_to_second_table[4] = {
  0, 5, 6, 11};
static const uint16_t fabryka_second_encoding_table[11] = {
  47, 49, 50, 51, 55, 52, 37, 52, 65, 66, 120};
static const uint8_t fabryka_kerning_values[11] = {
  10, 6, 2, 4, 9, 5, 2, 3, 2, 2, 2};
u8g2_kerning_t fabryka_k = {
  4, 11,
  fabryka_first_encoding_table,
  fabryka_index_to_second_table,
  fabryka_second_encoding_table,
  fabryka_kerning_values};



void setup() {
  //Serial.begin(9600);

  pinMode(ENC_BTN_PIN, INPUT_PULLUP);
  pinMode(START_STOP_BTN_PIN, INPUT_PULLUP);
  pinMode(SHIFT_BTN_PIN, INPUT_PULLUP);
  pinMode(EXT_INPUT_PIN, INPUT_PULLUP);
  attachInterrupt(digitalPinToInterrupt(EXT_INPUT_PIN), externalClock, FALLING);

  for (byte i = 0; i < 6; i++) {
    pinMode(outsPins[i], OUTPUT);
  }

  pinMode(clockOutPin, OUTPUT);

  loadState();

  u8g2.begin();
  checkScreenRotation();
  updateScreen();

  calculateCycles();
  calculateBPMTiming();

  FlexiTimer2::set(1, 1.0 / 1000, clock);  // 1.0/1000 = 1ms period. If other than 1ms calculateBPMTiming() might need tweaking
  FlexiTimer2::start();
}

void loop() {
  checkInputs();
}

void clock() {
  if (isPlaying) {

    // Action on each pulse
    if (tickCount == 0) {
      sendTriggers();
      digitalWrite(clockOutPin, HIGH);
    }

    //this part gets the Pulse and Ticks ticking
    //it's placed after the triggers to avoid problems on the start (when pulseCount==0)
    tickCount++;
    if (masterClockMode == 0) {
      if (tickCount >= pulsePeriod) {
        tickCount = 0;
        if (pulseCount < (PPQN - 1)) {  //-1 is here to avoid extra IF to reset to 0
          pulseCount++;
        } else {
          pulseCount = 0;
        }
        if (bpmModulationRange != 0) {
          calculateBPMTiming();
        }
      }
    }

    // pull low all outputs after set pulse length
    if (tickCount >= PULSE_LENGTH) {
      for (byte i = 0; i < 6; i++) {
        digitalWrite(outsPins[i], LOW);
      }
      digitalWrite(clockOutPin, LOW);
    }
  }
}

void externalClock() {
  lastExtPulseTime = newExtPulseTime;
  newExtPulseTime = millis();

  if (masterClockMode == 1) {  // EXT-24
    //reset cycles if there was no pulses for a while
    if ((newExtPulseTime - lastExtPulseTime) > 125) {  //125ms is 20bpm
      for (byte i = 0; i < 6; i++) {
        channelPulseCount[i] = 0;
      }
    }

    if (!isPlaying) {
      isPlaying = true;
    }
    tickCount = 0;  //to make things happen in the main clock function
    if (pulseCount < (PPQN - 1)) {
      pulseCount++;
    } else {
      pulseCount = 0;
    }

  }
}

void sendTriggers() {

  for (byte i = 0; i < 6; i++) {
    if (playingModes[i] != subDivs[channels[i].subDiv]) {
      needPulseReset[i] = true;
    }
  }

  //16th notes for sequencer
  if (sixteenthPulseCount == 0) {
    bool *currentSeq;

    for (byte i = 0; i < 6; i++) {

      //pattern modulation
      //todo: limit modulation within the current bank (a or b)
      int seqMod = 0;
      if (channels[i].CV2Target == 3) {
        seqMod = map(a2Input, 0, 1023, -8, 8);
      } else if (channels[i].CV1Target == 3) {
        seqMod = map(a1Input, 0, 1023, -8, 8);
      }
      byte seqPattern = channels[i].seqPattern + seqMod;

      if (seqPattern == 0) {
        currentSeq = seqA1;
      } else if (seqPattern == 1) {
        currentSeq = seqA2;
      } else if (seqPattern == 2) {
        currentSeq = seqA3;
      } else if (seqPattern == 3) {
        currentSeq = seqA4;
      } else if (seqPattern == 4) {
        currentSeq = seqA5;
      } else if (seqPattern == 5) {
        currentSeq = seqA6;
      } else if (seqPattern == 6) {
        currentSeq = seqA7;
      } else if (seqPattern == 7) {
        currentSeq = seqA8;
      } else if (seqPattern == 8) {
        currentSeq = seqB1;
      } else if (seqPattern == 9) {
        currentSeq = seqB2;
      } else if (seqPattern== 10) {
        currentSeq = seqB3;
      } else if (seqPattern == 11) {
        currentSeq = seqB4;
      } else if (seqPattern == 12) {
        currentSeq = seqB5;
      } else if (seqPattern == 13) {
        currentSeq = seqB6;
      } else if (seqPattern == 14) {
        currentSeq = seqB7;
      } else if (seqPattern == 15) {
        currentSeq = seqB8;
      }
      if (channels[i].mode == 2 && channelPulseCount[i] == 0 && currentSeq[currentStep]) {
        digitalWrite(outsPins[i], HIGH);
      }
    }
  }
  if (sixteenthPulseCount < (PPQN / 4) - 1) {
    sixteenthPulseCount++;
    if (sixteenthPulseCount > 3) { //quantization. might need fine-tuning
      recordToNextStep = true;
    }
  } else {
    sixteenthPulseCount = 0;
    if (currentStep < 15) {
      currentStep ++;
    } else {
      currentStep = 0;
    }
    recordToNextStep = false;
  }

  //switching modes on the beat and resetting channel clock
  if (pulseCount == 0) {
    calculateCycles();
    for (byte i = 0; i < 6; i++) {
      if (needPulseReset[i] == true) {
        channelPulseCount[i] = 0;
        needPulseReset[i] = false;
      }
    }
  }

  //multiplier
  for (byte i = 0; i < 6; i++) {
    
    //RND modulation
    byte randMod = 0;
    if (channels[i].CV1Target == 2) {
      randMod = randMod + a1Input;
    }
    if (channels[i].CV2Target == 2) {
      randMod = randMod + a2Input;
    }
    if (channels[i].CV1Target == 2 || channels[i].CV2Target == 2) {
      randMod = map(randMod, 0, 1023, -5, +5);
    }
    byte randAmount = channels[i].random + randMod;
    if (randAmount > 100) {
      randAmount = 0;
    } else if (randAmount > 10) {
      randAmount = 10;
    }


    if ((channels[i].mode == 0 && channelPulseCount[i] == channels[i].offset) //CLK with offset
     || (channels[i].mode == 1 && channelPulseCount[i] == 0 && (random(10) + 1) > randAmount) //RND
       ) {
        digitalWrite(outsPins[i], HIGH);
    }
    if (channelPulseCount[i] < channelPulsesPerCycle[i]) {
      channelPulseCount[i]++;
    } else {
      channelPulseCount[i] = 0;
    }
  }

}

void calculateCycles() {

  for (byte i = 0; i < 6; i++) {
    if (channels[i].CV1Target != 1 && channels[i].CV2Target != 1)  {
      playingModes[i] = subDivs[channels[i].subDiv];
    } else if (channels[i].CV1Target == 1) { //subdiv modulation happens here
      int mod;
      mod = a1Input;
      mod = map(mod, 0, 1023, (channels[i].CV1Value * -1), channels[i].CV1Value);
      playingModes[i] = subDivs[channels[i].subDiv - mod];  //subtracting because the innitial array is backwards
    } else if (channels[i].CV2Target == 1) {
      int mod;
      mod = a2Input;
      mod = map(mod, 0, 1023, (channels[i].CV2Value * -1), channels[i].CV2Value);
      playingModes[i] = subDivs[channels[i].subDiv - mod];
    }

    if (playingModes[i] > 0 && channels[i].mode != 2) {
      channelPulsesPerCycle[i] = (playingModes[i] * PPQN) - 1;
    } else if (playingModes[i] <= 0 && channels[i].mode != 2) {
      channelPulsesPerCycle[i] = (PPQN / abs(playingModes[i])) - 1;
    } else if (channels[i].mode == 2) { //Sequencer plays 1/16th
      channelPulsesPerCycle[i] = (PPQN / 4) - 1;
    }
    if (channels[i].offset > channelPulsesPerCycle[i]) {
      channels[i].offset = channelPulsesPerCycle[i];
    }
  }
}

void calculateBPMTiming() {
  int mod = 0;
  if (masterClockMode == 0) {  //Internal clock
    if (bpmModulationRange != 0 && bpmModulationChannel == 0) {
      mod = map(a1Input, 0, 1023, bpmModulationRange * -10, bpmModulationRange * 10);
    } else if (bpmModulationRange != 0 && bpmModulationChannel == 1) {
      mod = map(a2Input, 0, 1023, bpmModulationRange * -10, bpmModulationRange * 10);
    }
    pulsePeriod = 60000 / ((bpm + mod) * PPQN);

  } else if (masterClockMode == 2) {  //for external beat clock
    pulsePeriod = (newExtPulseTime - lastExtPulseTime) / PPQN;

  } else if (masterClockMode == 3) {  //for ext 1/16 clock (hardcoded)
    pulsePeriod = (newExtPulseTime - lastExtPulseTime) / 6;
  }
}

void resetClocks() {
  for (byte i = 0; i < 6; i++) {
    channelPulseCount[i] = 0;
    digitalWrite(outsPins[i], LOW);  //to avoid stuck leds
  }
  pulseCount = 0;
  tickCount = 0;
  sixteenthPulseCount = 0;
}

void saveState() {
  int addr = 0;
  EEPROM.put(addr, bpm);
  addr = addr + sizeof(bpm);
  EEPROM.put(addr, bpmModulationChannel);
  addr = addr + sizeof(bpmModulationChannel);
  EEPROM.put(addr, bpmModulationRange);
  addr = addr + sizeof(bpmModulationRange);
  EEPROM.put(addr, masterClockMode);
  addr = addr + sizeof(masterClockMode);
  EEPROM.put(addr, channels);
  addr = addr + sizeof(channels);
  EEPROM.put(addr, seqA1);
  addr = addr + sizeof(seqA1);
  EEPROM.put(addr, seqA2);
  addr = addr + sizeof(seqA2);
  EEPROM.put(addr, seqA3);
  addr = addr + sizeof(seqA3);
  EEPROM.put(addr, seqA4);
  addr = addr + sizeof(seqA4);
  EEPROM.put(addr, seqA5);
  addr = addr + sizeof(seqA5);
  EEPROM.put(addr, seqA6);
  addr = addr + sizeof(seqA6);
  EEPROM.put(addr, seqA7);
  addr = addr + sizeof(seqA7);
  EEPROM.put(addr, seqA8);
  addr = addr + sizeof(seqA8);
  EEPROM.put(addr, seqB1);
  addr = addr + sizeof(seqB1);
  EEPROM.put(addr, seqB2);
  addr = addr + sizeof(seqB2);
  EEPROM.put(addr, seqB3);
  addr = addr + sizeof(seqB3);
  EEPROM.put(addr, seqB4);
  addr = addr + sizeof(seqB4);
  EEPROM.put(addr, seqB5);
  addr = addr + sizeof(seqB5);
  EEPROM.put(addr, seqB6);
  addr = addr + sizeof(seqB6);
  EEPROM.put(addr, seqB7);
  addr = addr + sizeof(seqB7);
  EEPROM.put(addr, seqB8);
  addr = addr + sizeof(seqB8);
  EEPROM.put(addr, CV1Calibration);
  addr = addr + sizeof(CV1Calibration);
  EEPROM.put(addr, CV2Calibration);
  addr = addr + sizeof(CV2Calibration);
  EEPROM.put(addr, rotateScreen);
}

void loadState() {
  //check last bit in eeprom to know if the correct settings were stored
  if (EEPROM.read(1023) == memCode) {
    int addr = 0;
    EEPROM.get(addr, bpm);
    addr = addr + sizeof(bpm);
    EEPROM.get(addr, bpmModulationChannel);
    addr = addr + sizeof(bpmModulationChannel);
    EEPROM.get(addr, bpmModulationRange);
    addr = addr + sizeof(bpmModulationRange);
    EEPROM.get(addr, masterClockMode);
    addr = addr + sizeof(masterClockMode);
    EEPROM.get(addr, channels);
    addr = addr + sizeof(channels);
    EEPROM.get(addr, seqA1);
    addr = addr + sizeof(seqA1);
    EEPROM.get(addr, seqA2);
    addr = addr + sizeof(seqA2);
    EEPROM.get(addr, seqA3);
    addr = addr + sizeof(seqA3);
    EEPROM.get(addr, seqA4);
    addr = addr + sizeof(seqA4);
    EEPROM.get(addr, seqA5);
    addr = addr + sizeof(seqA5);
    EEPROM.get(addr, seqA6);
    addr = addr + sizeof(seqA6);
    EEPROM.get(addr, seqA7);
    addr = addr + sizeof(seqA7);
    EEPROM.get(addr, seqA8);
    addr = addr + sizeof(seqA8);
    EEPROM.get(addr, seqB1);
    addr = addr + sizeof(seqB1);
    EEPROM.get(addr, seqB2);
    addr = addr + sizeof(seqB2);
    EEPROM.get(addr, seqB3);
    addr = addr + sizeof(seqB3);
    EEPROM.get(addr, seqB4);
    addr = addr + sizeof(seqB4);
    EEPROM.get(addr, seqB5);
    addr = addr + sizeof(seqB5);
    EEPROM.get(addr, seqB6);
    addr = addr + sizeof(seqB6);
    EEPROM.get(addr, seqB7);
    addr = addr + sizeof(seqB7);
    EEPROM.get(addr, seqB8);
    addr = addr + sizeof(seqB8);
    EEPROM.get(addr, CV1Calibration);
    addr = addr + sizeof(CV1Calibration);
    EEPROM.get(addr, CV2Calibration);
    addr = addr + sizeof(CV2Calibration);
    EEPROM.get(addr, rotateScreen);
  } else {
    //calibrateCVs();
    saveState();
    EEPROM.write(1023, memCode);
  }
}

void reboot() {
  wdt_enable(WDTO_15MS); //reboot after 15ms
  while(true);
}

void calibrateCVs() {
  //CV1Calibration = 511 - analogRead(ANALOGUE_INPUT_1_PIN);
  //CV2Calibration = 511 - analogRead(ANALOGUE_INPUT_2_PIN);
  CV1Calibration = 255 - (analogRead(ANALOGUE_INPUT_1_PIN) / 2);
  CV2Calibration = 255 - (analogRead(ANALOGUE_INPUT_2_PIN) / 2);
}

void checkScreenRotation() {
  if (rotateScreen) {
    u8g2.setDisplayRotation(U8G2_R0);
  } else {
    u8g2.setDisplayRotation(U8G2_R2);
  }
}