SpotlightKid/synth.cpp

## synth.cpp
/* Arduino Synth from
https://janostman.wordpress.com/2016/01/15/how-to-build-your-very-own-string-synth/
*/
#include <avr/interrupt.h>
#include <avr/io.h>
#include <avr/pgmspace.h>
#ifndef cbi
#define cbi(sfr, bit) (_SFR_BYTE(sfr) &= ~_BV(bit))
#endif
#ifndef sbi
#define sbi(sfr, bit) (_SFR_BYTE(sfr) |= _BV(bit))
#endif
// Standard Arduino Pins
#define digitalPinToPortReg(P) \
        (((P) >= 0 && (P) <= 7) ? &PORTD : (((P) >= 8 && (P) <= 13) ? &PORTB : &PORTC))
#define digitalPinToDDRReg(P) \
        (((P) >= 0 && (P) <= 7) ? &DDRD : (((P) >= 8 && (P) <= 13) ? &DDRB : &DDRC))
#define digitalPinToPINReg(P) \
        (((P) >= 0 && (P) <= 7) ? &PIND : (((P) >= 8 && (P) <= 13) ? &PINB : &PINC))
#define digitalPinToBit(P) \
        (((P) >= 0 && (P) <= 7) ? (P) : (((P) >= 8 && (P) <= 13) ? (P) -8 : (P) -14))
#define digitalReadFast(P) bitRead(*digitalPinToPINReg(P), digitalPinToBit(P))
#define digitalWriteFast(P, V) bitWrite(*digitalPinToPortReg(P), digitalPinToBit(P), (V))
const unsigned char PS_2 = (1 << ADPS0);;
const unsigned char PS_4 = (1 << ADPS1);
const unsigned char PS_8 = (1 << ADPS1) | (1 << ADPS0);
const unsigned char PS_16 = (1 << ADPS2);
const unsigned char PS_32 = (1 << ADPS2) | (1 << ADPS0);
const unsigned char PS_64 = (1 << ADPS2) | (1 << ADPS1);
const unsigned char PS_128 = (1 << ADPS2) | (1 << ADPS1) | (1 << ADPS0);
uint32_t NOTES[12]={208065>>2,220472>>2,233516>>2,247514>>2,262149>>2,277738>>2,
  294281>>2,311779>>2,330390>>2,349956>>2,370794>>2,392746>>2};
int8_t keytable[40];
int8_t oldkeytable[40];
const uint8_t ATTrates[32]={
        1,2,3,4,5,8,12,20,32,37,43,51,64,85,128,255,0xFF,0xFF,0xFF,0xFF,0xFF,
        0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF
};
const uint8_t RELrates[32]={
        1,2,3,4,5,8,12,20,32,37,43,51,64,85,128,255,255,128,85,64,51,43,37,32,
        20,12,8,5,4,3,2,1
};
const uint8_t sinetable[256] PROGMEM = {
        127,130,133,136,139,143,146,149,152,155,158,161,164,167,170,173,176,178,
        181,184,187,190,192,195,198,200,203,205,208,210,212,215,217,219,221,
        223,225,227,229,231,233,234,236,238,239,240,
        242,243,244,245,247,248,249,249,250,251,252,252,253,253,253,254,254,254,
        254,254,254,254,253,253,253,252,252,251,250,249,249,248,247,245,244,
        243,242,240,239,238,236,234,233,231,229,227,225,223,
        221,219,217,215,212,210,208,205,203,200,198,195,192,190,187,184,181,178,
        176,173,170,167,164,161,158,155,152,149,146,143,139,136,133,130,127,
        124,121,118,115,111,108,105,102,99,96,93,90,87,84,81,78,
        76,73,70,67,64,62,59,56,54,51,49,46,44,42,39,37,35,33,31,29,27,25,23,21,
        20,18,16,15,14,12,11,10,9,7,6,5,5,4,3,2,2,1,1,1,0,0,0,0,0,0,0,1,1,1,
        2,2,3,4,5,5,6,7,9,10,11,12,14,15,16,18,20,21,23,25,27,29,31,
        33,35,37,39,42,44,46,49,51,54,56,59,62,64,67,70,73,76,78,81,84,87,90,93,
        96,99,102,105,108,111,115,118,121,124
};
volatile uint8_t lfocounter;
volatile uint8_t lfocounter2;
volatile uint16_t lfoval;
volatile uint16_t lfoval2;
volatile uint8_t GATED=1;
uint8_t OSCNOTES[4];
int16_t volume=0;
uint8_t ENVsmoothing;
uint8_t envcnt=10;
//-------- Synth parameters --------------
uint32_t FREQ[16]={0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0};  //DCO pitch
volatile uint32_t DETUNE=0;  //Osc spread or detune
volatile uint8_t CUTOFF=0;  //freq 0-255
volatile uint8_t RESONANCE=0;  //resonance=0-255
volatile uint16_t LFO=32;  //Lfo rate 0-255
volatile uint8_t VCA=255;  //VCA level 0-255
volatile uint8_t ATTACK=1;  // ENV Attack rate 0-255
volatile uint8_t RELEASE=1;  // ENV Release rate 0-255
volatile uint8_t ENVELOPE=0;  // ENV Shape
volatile uint8_t TRIG=0;  //MIDItrig 1=note ON
volatile int16_t BEND;  //Pitchbend
volatile int16_t MOD;  //MODwheel
//-----------------------------------------
volatile int16_t BENDoffset;  //Pitchbend center
volatile uint32_t olddetune;
uint32_t DCOPH[16];
uint8_t integrators[16];
uint8_t delayline[256];
volatile uint8_t writepointer;
volatile uint8_t PHASERMIX;
uint8_t DCO;
int16_t DCF;
int16_t ENV;
int16_t M0;
int16_t M1;
int16_t M2;
int16_t M3;
int16_t M4;
int16_t M5;
int16_t M6;
int16_t MX1;
int16_t MX2;
int8_t coefficient;
ISR(TIMER1_COMPA_vect) {
        //-------------------- 8 DCO block ------------------------------------------
        DCO=0;
        for (uint8_t i=0; i<8; i++) {
                if (integrators[i]) integrators[i]--; //Decrement integrators
                DCOPH[i] += FREQ[i]; //Add freq to phaseacc's
                if (DCOPH[i]&0x800000) { //Check for integrator reset
                        DCOPH[i]&=0x7FFFFF; //Trim NCO
                        integrators[i]=28; //Reset integrator
                }
                DCO+=integrators[i];
        }
        writepointer++;
        delayline[writepointer]=DCO;
        DCO+=(delayline[(writepointer-lfoval2)&255]*PHASERMIX)>>8;
        //-----------------------------------------------------------------
        //------------------ VCA block ------------------------------------
 #define M(MX, MX1, MX2) \
        asm volatile ( \
                "clr r26 \n\t" \
                "mulsu %B1, %A2 \n\t" \
                "movw %A0, r0 \n\t" \
                "mul %A1, %A2 \n\t" \
                "add %A0, r1 \n\t" \
                "adc %B0, r26 \n\t" \
                "clr r1 \n\t" \
                : \
                "=&r" (MX) \
                : \
                "a" (MX1), \
                "a" (MX2) \
                : \
                "r26" \
                )
        if ((ATTACK==255)&&(TRIG==1)) VCA=255;
        if (!(envcnt--)) {
                envcnt=20;
                if (VCA<volume) VCA++;
                if (VCA>volume) VCA--;
        }
        M(ENV, (int16_t)DCO, VCA);
        OCR2A = ENV;
        //-----------------------------------------------------------------
        //-------------- Calc Sample freq ---------------------------------
        OCR1A = 758-lfoval;
        //-----------------------------------------------------------------
}
ISR(TIMER0_COMPA_vect) {
        //------------------------------ LFO Block -----------------------
        lfocounter+=LFO;
        lfoval=(pgm_read_byte_near( sinetable + lfocounter ) * MOD)>>10; //LFO for pitch
        lfoval2=pgm_read_byte_near( sinetable + (lfocounter2++) ); //LFO for the Phaser
        //-----------------------------------------------------------------
        //--------------------- ENV block ---------------------------------
        if ((TRIG==1)&&(volume<255)) {
                volume+=ATTACK;
                if (volume>255) volume=255;
        }
        if ((TRIG==0)&&(volume>0)) {
                volume-=RELEASE;
                if (volume<0) volume=0;
        }
        //-----------------------------------------------------------------
}
/*
   ISR(USART_RX_vect)
   {
   //Midiin.sendByte(UDR0);
   }
 */
void setup() {
        //Keyscanner inputs
        pinMode(2,INPUT_PULLUP);
        pinMode(3,INPUT_PULLUP);
        pinMode(4,INPUT_PULLUP);
        pinMode(5,INPUT_PULLUP);
        pinMode(6,INPUT_PULLUP);
        pinMode(7,INPUT_PULLUP);
        pinMode(8,INPUT_PULLUP);
        pinMode(9,INPUT_PULLUP);
        //Keyscanner outputs
        pinMode(14, OUTPUT);
        pinMode(15, OUTPUT);
        pinMode(16, OUTPUT);
        pinMode(17, OUTPUT);
        pinMode(18, OUTPUT);
        //PWM and GATE outputs
        pinMode(11, OUTPUT);
        pinMode(10, OUTPUT);
        // Set up Timer 1 to send a sample every interrupt.
        cli();
        // Set CTC mode
        // Have to set OCR1A *after*, otherwise it gets reset to 0!
        TCCR1B = (TCCR1B & ~_BV(WGM13)) | _BV(WGM12);
        TCCR1A = TCCR1A & ~(_BV(WGM11) | _BV(WGM10));
        // No prescaler
        TCCR1B = (TCCR1B & ~(_BV(CS12) | _BV(CS11))) | _BV(CS10);
        // Set the compare register (OCR1A).
        // OCR1A is a 16-bit register, so we have to do this with
        // interrupts disabled to be safe.
        OCR1A = 758;//F_CPU / SAMPLE_RATE;
        // Enable interrupt when TCNT1 == OCR1A
        TIMSK1 |= _BV(OCIE1A);
        //set timer0 interrupt at 61Hz
        TCCR0A = 0;// set entire TCCR0A register to 0
        TCCR0B = 0;// same for TCCR0B
        TCNT0 = 0;//initialize counter value to 0
        // set compare match register for 62hz increments
        OCR0A = 255;// = 61Hz
        // turn on CTC mode
        TCCR0A |= (1 << WGM01);
        // Set CS01 and CS00 bits for prescaler 1024
        TCCR0B |= (1 << CS02) | (0 << CS01) | (1 << CS00); //1024 prescaler
        // enable timer compare interrupt
        TIMSK0 |= (1 << OCIE0A);
        sei();
        // Set baud rate to 31,250. Requires modification if clock speed is not 16MHz.
        UBRR0H = ((F_CPU / 16 + 31250 / 2) / 31250 - 1) >> 8;
        UBRR0L = ((F_CPU / 16 + 31250 / 2) / 31250 - 1);
        // Set frame format to 8 data bits, no parity, 1 stop bit
        UCSR0C |= (1<<UCSZ01)|(1<<UCSZ00);
        // enable rx
        UCSR0B |= _BV(RXEN0);
        // USART RX interrupt enable bit on
        UCSR0B |= _BV(RXCIE0);
        // Set up Timer 2 to do pulse width modulation on the speaker
        // pin.
        // Use internal clock (datasheet p.160)
        ASSR &= ~(_BV(EXCLK) | _BV(AS2));
        // Set fast PWM mode (p.157)
        TCCR2A |= _BV(WGM21) | _BV(WGM20);
        TCCR2B &= ~_BV(WGM22);
        // Do non-inverting PWM on pin OC2A (p.155)
        // On the Arduino this is pin 11.
        TCCR2A = (TCCR2A | _BV(COM2A1)) & ~_BV(COM2A0);
        TCCR2A &= ~(_BV(COM2B1) | _BV(COM2B0));
        // No prescaler (p.158)
        TCCR2B = (TCCR2B & ~(_BV(CS12) | _BV(CS11))) | _BV(CS10);
        // Set initial pulse width to the first sample.
        OCR2A = 128;
        // set up the ADC
        BENDoffset=analogRead(7);
        ADCSRA &= ~PS_128; // remove bits set by Arduino library
        // you can choose a prescaler from above.
        // PS_16, PS_32, PS_64 or PS_128
        ADCSRA |= PS_128; // set our own prescaler to 16
        ADMUX = 69;
        sbi(ADCSRA, ADSC);
}
//---------------- Get the base frequency for the MIDI note ---------------
uint32_t MIDI2FREQ(uint8_t note) {
        uint8_t key=note%12;
        if (note<36) return (NOTES[key]>>(1+(35-note)/12));
        if (note>47) return (NOTES[key]<<((note-36)/12));
        return NOTES[key];
}
//--------------------------------------------------------------------
//---------------- Handle Notes---------------------------------------
void handleMIDINOTE(uint8_t status,uint8_t note,uint8_t vel) {
        uint8_t i;
        uint32_t freq;
        if ((!vel)&&(status==0x90)) status=0x80;
        if (status==0x80) {
                for (i=0; i<4; i++) {
                        if (OSCNOTES[i]==note) {
                                if (!GATED) {
                                        FREQ[i<<1]=0;
                                        FREQ[(i<<1)|1]=0;
                                }
                                OSCNOTES[i]=0;
                        }
                }
                if (!(OSCNOTES[0]|OSCNOTES[1]|OSCNOTES[2]|OSCNOTES[3])) TRIG=0;
                return;
        }
        if (status==0x90) {
                if ((!TRIG)&&(GATED)) {
                        for (i=0; i<8; i++) {
                                FREQ[i]=0;
                        }
                }
                i=0;
                while (i<4) {
                        if (!OSCNOTES[i]) {
                                freq=MIDI2FREQ(note);
                                FREQ[i<<1]=freq;
                                FREQ[(i<<1)|1]=FREQ[i<<1]+(((FREQ[i<<1]/50)>>0)*DETUNE/127);
                                OSCNOTES[i]=note;
                                if (!TRIG) {
                                        TRIG=1;
                                }
                                return;
                        }
                        i++;
                }
        }
}
//-------------------------------------------------------------------------
void loop() {
        //Serial.begin(9600);
        uint8_t k=0;
        uint8_t z;
        uint8_t w=0;
        int8_t MUX=5;
        while(1) {
                //------------------ Key scanner -----------------------------
                PORTC|=0x1F;
                if ((k&0x38)==(0x00<<3)) PORTC&=B11111110;
                if ((k&0x38)==(0x01<<3)) PORTC&=B11111101;
                if ((k&0x38)==(0x02<<3)) PORTC&=B11111011;
                if ((k&0x38)==(0x03<<3)) PORTC&=B11110111;
                if ((k&0x38)==(0x04<<3)) PORTC&=B11101111;
                keytable[k]=digitalReadFast((k&7)+2);
                if (oldkeytable[k]!=keytable[k]) { //Handle keyevent
                        oldkeytable[k]=keytable[k];
                        if (keytable[k]==0) {
                                handleMIDINOTE(0x90,k+21,127);
                        }
                        else {
                                handleMIDINOTE(0x80,k+21,0);
                        }
                }
                k++;
                if (k==40) {
                        k=0;
                }
                digitalWriteFast(10,TRIG);
                //---------------------------------------------------------------
                //--------------- ADC block -------------------------------------
                while (bit_is_set(ADCSRA, ADSC)) ; //Wait for ADC EOC
                if (MUX==7) DETUNE=((ADCL+(ADCH<<8))>>3);
                if (MUX==7) MOD=((ADCL+(ADCH<<8))>>2);
                if (MUX==6) PHASERMIX=((ADCL+(ADCH<<8))>>2);
                if (MUX==5) ENVELOPE=((ADCL+(ADCH<<8))>>5);
                if (MUX==5) ATTACK=ATTrates[ENVELOPE];
                if (MUX==5) RELEASE=RELrates[ENVELOPE];
                if (RELEASE==255) GATED=0;
                if (RELEASE!=255) GATED=1;
                if (DETUNE!=olddetune) {
                        olddetune=DETUNE;
                        for (uint8_t i=0; i<4; i++) {
                                if (FREQ[i<<1]) {
                                        FREQ[(i<<1)|1]=FREQ[i<<1]+(((FREQ[i<<1]/50)>>0)*DETUNE/127);
                                }
                        }
                }
                //Serial.print(CUTOFF,DEC);
                //Serial.print("\n");
                MUX++;
                if (MUX>7) MUX=5;
                ADMUX = 64 | MUX; //Select MUX
                sbi(ADCSRA, ADSC); //start next conversation
                //--------------------------------------------------------------------
        }
}
	/* Arduino Synth from
	https://janostman.wordpress.com/2016/01/15/how-to-build-your-very-own-string-synth/
	*/
	#include <avr/interrupt.h>
	#include <avr/io.h>
	#include <avr/pgmspace.h>
	#ifndef cbi
	#define cbi(sfr, bit) (_SFR_BYTE(sfr) &= ~_BV(bit))
	#endif
	#ifndef sbi
	#define sbi(sfr, bit) (_SFR_BYTE(sfr) \|= _BV(bit))
	#endif
	// Standard Arduino Pins
	#define digitalPinToPortReg(P) \
	(((P) >= 0 && (P) <= 7) ? &PORTD : (((P) >= 8 && (P) <= 13) ? &PORTB : &PORTC))
	#define digitalPinToDDRReg(P) \
	(((P) >= 0 && (P) <= 7) ? &DDRD : (((P) >= 8 && (P) <= 13) ? &DDRB : &DDRC))
	#define digitalPinToPINReg(P) \
	(((P) >= 0 && (P) <= 7) ? &PIND : (((P) >= 8 && (P) <= 13) ? &PINB : &PINC))
	#define digitalPinToBit(P) \
	(((P) >= 0 && (P) <= 7) ? (P) : (((P) >= 8 && (P) <= 13) ? (P) -8 : (P) -14))
	#define digitalReadFast(P) bitRead(*digitalPinToPINReg(P), digitalPinToBit(P))
	#define digitalWriteFast(P, V) bitWrite(*digitalPinToPortReg(P), digitalPinToBit(P), (V))
	const unsigned char PS_2 = (1 << ADPS0);;
	const unsigned char PS_4 = (1 << ADPS1);
	const unsigned char PS_8 = (1 << ADPS1) \| (1 << ADPS0);
	const unsigned char PS_16 = (1 << ADPS2);
	const unsigned char PS_32 = (1 << ADPS2) \| (1 << ADPS0);
	const unsigned char PS_64 = (1 << ADPS2) \| (1 << ADPS1);
	const unsigned char PS_128 = (1 << ADPS2) \| (1 << ADPS1) \| (1 << ADPS0);
	uint32_t NOTES[12]={208065>>2,220472>>2,233516>>2,247514>>2,262149>>2,277738>>2,
	294281>>2,311779>>2,330390>>2,349956>>2,370794>>2,392746>>2};
	int8_t keytable[40];
	int8_t oldkeytable[40];
	const uint8_t ATTrates[32]={
	1,2,3,4,5,8,12,20,32,37,43,51,64,85,128,255,0xFF,0xFF,0xFF,0xFF,0xFF,
	0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF
	};
	const uint8_t RELrates[32]={
	1,2,3,4,5,8,12,20,32,37,43,51,64,85,128,255,255,128,85,64,51,43,37,32,
	20,12,8,5,4,3,2,1
	};
	const uint8_t sinetable[256] PROGMEM = {
	127,130,133,136,139,143,146,149,152,155,158,161,164,167,170,173,176,178,
	181,184,187,190,192,195,198,200,203,205,208,210,212,215,217,219,221,
	223,225,227,229,231,233,234,236,238,239,240,
	242,243,244,245,247,248,249,249,250,251,252,252,253,253,253,254,254,254,
	254,254,254,254,253,253,253,252,252,251,250,249,249,248,247,245,244,
	243,242,240,239,238,236,234,233,231,229,227,225,223,
	221,219,217,215,212,210,208,205,203,200,198,195,192,190,187,184,181,178,
	176,173,170,167,164,161,158,155,152,149,146,143,139,136,133,130,127,
	124,121,118,115,111,108,105,102,99,96,93,90,87,84,81,78,
	76,73,70,67,64,62,59,56,54,51,49,46,44,42,39,37,35,33,31,29,27,25,23,21,
	20,18,16,15,14,12,11,10,9,7,6,5,5,4,3,2,2,1,1,1,0,0,0,0,0,0,0,1,1,1,
	2,2,3,4,5,5,6,7,9,10,11,12,14,15,16,18,20,21,23,25,27,29,31,
	33,35,37,39,42,44,46,49,51,54,56,59,62,64,67,70,73,76,78,81,84,87,90,93,
	96,99,102,105,108,111,115,118,121,124
	};
	volatile uint8_t lfocounter;
	volatile uint8_t lfocounter2;
	volatile uint16_t lfoval;
	volatile uint16_t lfoval2;
	volatile uint8_t GATED=1;
	uint8_t OSCNOTES[4];
	int16_t volume=0;
	uint8_t ENVsmoothing;
	uint8_t envcnt=10;
	//-------- Synth parameters --------------
	uint32_t FREQ[16]={0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0}; //DCO pitch
	volatile uint32_t DETUNE=0; //Osc spread or detune
	volatile uint8_t CUTOFF=0; //freq 0-255
	volatile uint8_t RESONANCE=0; //resonance=0-255
	volatile uint16_t LFO=32; //Lfo rate 0-255
	volatile uint8_t VCA=255; //VCA level 0-255
	volatile uint8_t ATTACK=1; // ENV Attack rate 0-255
	volatile uint8_t RELEASE=1; // ENV Release rate 0-255
	volatile uint8_t ENVELOPE=0; // ENV Shape
	volatile uint8_t TRIG=0; //MIDItrig 1=note ON
	volatile int16_t BEND; //Pitchbend
	volatile int16_t MOD; //MODwheel
	//-----------------------------------------
	volatile int16_t BENDoffset; //Pitchbend center
	volatile uint32_t olddetune;
	uint32_t DCOPH[16];
	uint8_t integrators[16];
	uint8_t delayline[256];
	volatile uint8_t writepointer;
	volatile uint8_t PHASERMIX;
	uint8_t DCO;
	int16_t DCF;
	int16_t ENV;
	int16_t M0;
	int16_t M1;
	int16_t M2;
	int16_t M3;
	int16_t M4;
	int16_t M5;
	int16_t M6;
	int16_t MX1;
	int16_t MX2;
	int8_t coefficient;
	ISR(TIMER1_COMPA_vect) {
	//-------------------- 8 DCO block ------------------------------------------
	DCO=0;
	for (uint8_t i=0; i<8; i++) {
	if (integrators[i]) integrators[i]--; //Decrement integrators
	DCOPH[i] += FREQ[i]; //Add freq to phaseacc's
	if (DCOPH[i]&0x800000) { //Check for integrator reset
	DCOPH[i]&=0x7FFFFF; //Trim NCO
	integrators[i]=28; //Reset integrator
	}
	DCO+=integrators[i];
	}
	writepointer++;
	delayline[writepointer]=DCO;
	DCO+=(delayline[(writepointer-lfoval2)&255]*PHASERMIX)>>8;
	//-----------------------------------------------------------------
	//------------------ VCA block ------------------------------------
	#define M(MX, MX1, MX2) \
	asm volatile ( \
	"clr r26 \n\t" \
	"mulsu %B1, %A2 \n\t" \
	"movw %A0, r0 \n\t" \
	"mul %A1, %A2 \n\t" \
	"add %A0, r1 \n\t" \
	"adc %B0, r26 \n\t" \
	"clr r1 \n\t" \
	: \
	"=&r" (MX) \
	: \
	"a" (MX1), \
	"a" (MX2) \
	: \
	"r26" \
	)
	if ((ATTACK==255)&&(TRIG==1)) VCA=255;
	if (!(envcnt--)) {
	envcnt=20;
	if (VCA<volume) VCA++;
	if (VCA>volume) VCA--;
	}
	M(ENV, (int16_t)DCO, VCA);
	OCR2A = ENV;
	//-----------------------------------------------------------------
	//-------------- Calc Sample freq ---------------------------------
	OCR1A = 758-lfoval;
	//-----------------------------------------------------------------
	}
	ISR(TIMER0_COMPA_vect) {
	//------------------------------ LFO Block -----------------------
	lfocounter+=LFO;
	lfoval=(pgm_read_byte_near( sinetable + lfocounter ) * MOD)>>10; //LFO for pitch
	lfoval2=pgm_read_byte_near( sinetable + (lfocounter2++) ); //LFO for the Phaser
	//-----------------------------------------------------------------
	//--------------------- ENV block ---------------------------------
	if ((TRIG==1)&&(volume<255)) {
	volume+=ATTACK;
	if (volume>255) volume=255;
	}
	if ((TRIG==0)&&(volume>0)) {
	volume-=RELEASE;
	if (volume<0) volume=0;
	}
	//-----------------------------------------------------------------
	}
	/*
	ISR(USART_RX_vect)
	{
	//Midiin.sendByte(UDR0);
	}
	*/
	void setup() {
	//Keyscanner inputs
	pinMode(2,INPUT_PULLUP);
	pinMode(3,INPUT_PULLUP);
	pinMode(4,INPUT_PULLUP);
	pinMode(5,INPUT_PULLUP);
	pinMode(6,INPUT_PULLUP);
	pinMode(7,INPUT_PULLUP);
	pinMode(8,INPUT_PULLUP);
	pinMode(9,INPUT_PULLUP);
	//Keyscanner outputs
	pinMode(14, OUTPUT);
	pinMode(15, OUTPUT);
	pinMode(16, OUTPUT);
	pinMode(17, OUTPUT);
	pinMode(18, OUTPUT);
	//PWM and GATE outputs
	pinMode(11, OUTPUT);
	pinMode(10, OUTPUT);
	// Set up Timer 1 to send a sample every interrupt.
	cli();
	// Set CTC mode
	// Have to set OCR1A after, otherwise it gets reset to 0!
	TCCR1B = (TCCR1B & ~_BV(WGM13)) \| _BV(WGM12);
	TCCR1A = TCCR1A & ~(_BV(WGM11) \| _BV(WGM10));
	// No prescaler
	TCCR1B = (TCCR1B & ~(_BV(CS12) \| _BV(CS11))) \| _BV(CS10);
	// Set the compare register (OCR1A).
	// OCR1A is a 16-bit register, so we have to do this with
	// interrupts disabled to be safe.
	OCR1A = 758;//F_CPU / SAMPLE_RATE;
	// Enable interrupt when TCNT1 == OCR1A
	TIMSK1 \|= _BV(OCIE1A);
	//set timer0 interrupt at 61Hz
	TCCR0A = 0;// set entire TCCR0A register to 0
	TCCR0B = 0;// same for TCCR0B
	TCNT0 = 0;//initialize counter value to 0
	// set compare match register for 62hz increments
	OCR0A = 255;// = 61Hz
	// turn on CTC mode
	TCCR0A \|= (1 << WGM01);
	// Set CS01 and CS00 bits for prescaler 1024
	TCCR0B \|= (1 << CS02) \| (0 << CS01) \| (1 << CS00); //1024 prescaler
	// enable timer compare interrupt
	TIMSK0 \|= (1 << OCIE0A);
	sei();
	// Set baud rate to 31,250. Requires modification if clock speed is not 16MHz.
	UBRR0H = ((F_CPU / 16 + 31250 / 2) / 31250 - 1) >> 8;
	UBRR0L = ((F_CPU / 16 + 31250 / 2) / 31250 - 1);
	// Set frame format to 8 data bits, no parity, 1 stop bit
	UCSR0C \|= (1<<UCSZ01)\|(1<<UCSZ00);
	// enable rx
	UCSR0B \|= _BV(RXEN0);
	// USART RX interrupt enable bit on
	UCSR0B \|= _BV(RXCIE0);
	// Set up Timer 2 to do pulse width modulation on the speaker
	// pin.
	// Use internal clock (datasheet p.160)
	ASSR &= ~(_BV(EXCLK) \| _BV(AS2));
	// Set fast PWM mode (p.157)
	TCCR2A \|= _BV(WGM21) \| _BV(WGM20);
	TCCR2B &= ~_BV(WGM22);
	// Do non-inverting PWM on pin OC2A (p.155)
	// On the Arduino this is pin 11.
	TCCR2A = (TCCR2A \| _BV(COM2A1)) & ~_BV(COM2A0);
	TCCR2A &= ~(_BV(COM2B1) \| _BV(COM2B0));
	// No prescaler (p.158)
	TCCR2B = (TCCR2B & ~(_BV(CS12) \| _BV(CS11))) \| _BV(CS10);
	// Set initial pulse width to the first sample.
	OCR2A = 128;
	// set up the ADC
	BENDoffset=analogRead(7);
	ADCSRA &= ~PS_128; // remove bits set by Arduino library
	// you can choose a prescaler from above.
	// PS_16, PS_32, PS_64 or PS_128
	ADCSRA \|= PS_128; // set our own prescaler to 16
	ADMUX = 69;
	sbi(ADCSRA, ADSC);
	}
	//---------------- Get the base frequency for the MIDI note ---------------
	uint32_t MIDI2FREQ(uint8_t note) {
	uint8_t key=note%12;
	if (note<36) return (NOTES[key]>>(1+(35-note)/12));
	if (note>47) return (NOTES[key]<<((note-36)/12));
	return NOTES[key];
	}
	//--------------------------------------------------------------------
	//---------------- Handle Notes---------------------------------------
	void handleMIDINOTE(uint8_t status,uint8_t note,uint8_t vel) {
	uint8_t i;
	uint32_t freq;
	if ((!vel)&&(status==0x90)) status=0x80;
	if (status==0x80) {
	for (i=0; i<4; i++) {
	if (OSCNOTES[i]==note) {
	if (!GATED) {
	FREQ[i<<1]=0;
	FREQ[(i<<1)\|1]=0;
	}
	OSCNOTES[i]=0;
	}
	}
	if (!(OSCNOTES[0]\|OSCNOTES[1]\|OSCNOTES[2]\|OSCNOTES[3])) TRIG=0;
	return;
	}
	if (status==0x90) {
	if ((!TRIG)&&(GATED)) {
	for (i=0; i<8; i++) {
	FREQ[i]=0;
	}
	}
	i=0;
	while (i<4) {
	if (!OSCNOTES[i]) {
	freq=MIDI2FREQ(note);
	FREQ[i<<1]=freq;
	FREQ[(i<<1)\|1]=FREQ[i<<1]+(((FREQ[i<<1]/50)>>0)*DETUNE/127);
	OSCNOTES[i]=note;
	if (!TRIG) {
	TRIG=1;
	}
	return;
	}
	i++;
	}
	}
	}
	//-------------------------------------------------------------------------
	void loop() {
	//Serial.begin(9600);
	uint8_t k=0;
	uint8_t z;
	uint8_t w=0;
	int8_t MUX=5;
	while(1) {
	//------------------ Key scanner -----------------------------
	PORTC\|=0x1F;
	if ((k&0x38)==(0x00<<3)) PORTC&=B11111110;
	if ((k&0x38)==(0x01<<3)) PORTC&=B11111101;
	if ((k&0x38)==(0x02<<3)) PORTC&=B11111011;
	if ((k&0x38)==(0x03<<3)) PORTC&=B11110111;
	if ((k&0x38)==(0x04<<3)) PORTC&=B11101111;
	keytable[k]=digitalReadFast((k&7)+2);
	if (oldkeytable[k]!=keytable[k]) { //Handle keyevent
	oldkeytable[k]=keytable[k];
	if (keytable[k]==0) {
	handleMIDINOTE(0x90,k+21,127);
	}
	else {
	handleMIDINOTE(0x80,k+21,0);
	}
	}
	k++;
	if (k==40) {
	k=0;
	}
	digitalWriteFast(10,TRIG);
	//---------------------------------------------------------------
	//--------------- ADC block -------------------------------------
	while (bit_is_set(ADCSRA, ADSC)) ; //Wait for ADC EOC
	if (MUX==7) DETUNE=((ADCL+(ADCH<<8))>>3);
	if (MUX==7) MOD=((ADCL+(ADCH<<8))>>2);
	if (MUX==6) PHASERMIX=((ADCL+(ADCH<<8))>>2);
	if (MUX==5) ENVELOPE=((ADCL+(ADCH<<8))>>5);
	if (MUX==5) ATTACK=ATTrates[ENVELOPE];
	if (MUX==5) RELEASE=RELrates[ENVELOPE];
	if (RELEASE==255) GATED=0;
	if (RELEASE!=255) GATED=1;
	if (DETUNE!=olddetune) {
	olddetune=DETUNE;
	for (uint8_t i=0; i<4; i++) {
	if (FREQ[i<<1]) {
	FREQ[(i<<1)\|1]=FREQ[i<<1]+(((FREQ[i<<1]/50)>>0)*DETUNE/127);
	}
	}
	}
	//Serial.print(CUTOFF,DEC);
	//Serial.print("\n");
	MUX++;
	if (MUX>7) MUX=5;
	ADMUX = 64 \| MUX; //Select MUX
	sbi(ADCSRA, ADSC); //start next conversation
	//--------------------------------------------------------------------
	}
	}