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Revert "Changes to Music.h and Music.cpp"

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This reverts commit 8b24803aa2fd9792ec9507376fc52fd238742b00.
This commit is contained in:
dviid 2013-01-30 18:51:07 +01:00
parent 8b24803aa2
commit dbb6a746be
4 changed files with 788 additions and 840 deletions
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33
software/apps/Motion/Center_with_2_oscillators/Center_with_2_oscillators.ino
View File

@ -1,30 +1,25 @@
//Center
//Center two motors control two frequencies. (jb&bv 25Jan13)
//uses a variable force (pwm duty)
//If it feels like a mountain - pushing away from center, then
//reverse the motor leads
//reverse the motor leads or the sign of forceA or forceB
//or for a quick fix in the code: change if(f < 0) to if (f > 0)
//#define NUM_OSCILLATORS 3
//#include "config.h"
#include <Motor.h>
#include <Music.h>
#include <Midi.h>
// notes to me (bv)
#include "Motor.h"
#include "Music.h"
int posA, posB; // position from analogRead
int forceA, forceB; // computed from pos and k
int kA = -5; // spring constant
int kB = 1; // spring constant
int kA = 2; // spring constant
int kB = 2; // spring constant
//int duty; // pwm duty for Timer1 (range 0 - 1023) 10-bit resolution
void setup()
{
MotorA.init();
Music.init();
Music.setWaveform(1); // only works with 8bit waveforms
//Music.setGain2(0);
//Music.setGain3(0);
Midi.init();
Music.init(); // 12-bit sine default (see .cpp file)
//Music.setWaveform(0); // only works with 8bit waveforms
}
void loop()
@ -35,18 +30,12 @@ void loop()
Music.setFrequency1(posA);
Music.setFrequency2(posB);
//Music.setDetune((posB/8)/5120.0);
forceA = kA * (512 - posA);
forceA = - kA * (512 - posA); // check wiring???
forceB = kB * (512 - posB);
//duty = abs(force);
//duty = min(512, duty);
MotorA.torque(forceA);
MotorA.torque(forceA); // forceA [-512 to +511] ???
MotorB.torque(forceB);
Midi.checkMidi();
}

9
software/lib/MMM/Midi.cpp
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@ -195,16 +195,13 @@ void MMidi::controller(uint8_t channel, uint8_t number, uint8_t value) {
}
break;
case GAIN1:
//Music.setGain1(uint16_t(value * 512));
Music.setGain1(value / 127.0);
Music.setGain1(uint16_t(value * 512));
break;
case GAIN2:
//Music.setGain2(uint16_t(value * 512));
Music.setGain2(value / 127.0);
Music.setGain2(uint16_t(value * 512));
break;
case GAIN3:
//Music.setGain3(uint16_t(value * 512));
Music.setGain3(value / 127.0);
Music.setGain3(uint16_t(value * 512));
break;
case WAVEFORM:
Music.setWaveform(value / 8);

754
software/lib/MMM/Music.cpp
View File

@ -21,4 +21,756 @@
+ contact: j.bak@ciid.dk
*/
//#include "Music.h"
#include "Music.h"
#include "Wavetable.h"
// Table of MIDI note values to frequency in Hertz
prog_uint16_t hertsTable[] PROGMEM = {8,8,9,9,10,10,11,12,12,13,14,15,16,17,18,19,20,21,23,24,25,27,29,30,32,34,36,38,41,43,46,48,51,54,58,61,65,69,73,77,82,87,92,97,103,109,116,123,130,138,146,155,164,174,184,195,207,219,233,246,261,277,293,311,329,349,369,391,415,440,466,493,523,554,587,622,659,698,739,783,830,880,932,987,1046,1108,1174,1244,1318,1396,1479,1567,1661,1760,1864,1975,2093,2217,2349,2489,2637,2793,2959,3135,3322,3520,3729,3951,4186,4434,4698,4978,5274,5587,5919,6271,6644,7040,7458,7902,8372,8869,9397,9956,10548,11175,11839,12543};
prog_uint32_t envTimeTable[] PROGMEM = {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,33,34,35,36,37,38,39,41,42,43,45,46,48,49,51,53,55,57,59,61,63,65,67,70,73,75,78,81,85,88,92,96,100,104,109,114,119,125,131,138,146,154,163,172,183,195,209,225,242,261,284,310,341,379,425,482,556,654,792,998,1342,2030,4095};
float semitoneTable[] = {0.25,0.2648658,0.2806155,0.29730177,0.31498027,0.33370996,0.35355338,0.37457678,0.39685026,0.4204482,0.44544938,0.47193715,0.5,0.5297315,0.561231,0.59460354,0.62996054,0.6674199,0.70710677,0.74915355,0.7937005,0.8408964,0.8908987,0.9438743,1.0,1.0594631,1.122462,1.1892071,1.2599211,1.3348398,1.4142135,1.4983071,1.587401,1.6817929,1.7817974,1.8877486,2.0,2.1189263,2.244924,2.3784142,2.5198421,2.6696796,2.828427,2.9966142,3.174802,3.3635857,3.563595,3.7754972,4.0};
MMusic Music;
// Defining which pins the SPI interface is connected to.
#define SPI_SCK 5
#define SPI_MOSI 3
//////////////////////////////////////////////////////////
//
// AUDIO INTERRUPT. USE EITHER 8bit or 12bitSine VERSION
// COMMENT OUT THE ONE YOU ARE NOT USING
//
//////////////////////////////////////////////////////////
ISR(TIMER2_COMPA_vect) { // timer 2 is audio interrupt timer
OCR2A = 127; // don't change this
Music.synthInterrupt8bit();
// Music.synthInterrupt12bitSine();
}
/////////////////////////////////////
//
// INITIALIZING FUNCTION
//
/////////////////////////////////////
void MMusic::init()
{
// clear interrupts. to make sure the interrupt timer doesn't start until we've set it up.
//cli();
// set up syntheziser
// this is the timer 2 audio rate timer, fires an interrupt at 15625 Hz sampling rate
TIMSK2 = 1<<OCIE2A; // interrupt enable audio timer
OCR2A = 127;
TCCR2A = 2; // CTC mode, counts up to 127 then resets
TCCR2B = 0<<CS22 | 1<<CS21 | 0<<CS20;
// OUTPUTS
// sck + mosi + ss
DDRB |= (1 << DDB2) | (1 << DDB3) | (1 << DDB5);
// dac_cs output
DDRD |= (1 << DDD6) | (1 << DDB3);
// set up SPI port
SPCR = 0x50;
SPSR = 0x01;
// DAC frame sync HIGH, so that the SPI port doesn't start wirting straight away
PORTD |= (1<<6);
// waveform setup
//setSine();
setWaveform(0);
// frequency setup
setFrequency(440);
setSemitone1(0);
setSemitone2(0);
setSemitone3(0);
setDetune(0);
// gain setup
setGain(1.0f);
setGain1(1.0f);
setGain2(1.0f);
setGain3(1.0f);
// envelope setup
setEnvStage(0);
disableEnvelope();
env = 0;
setAttack(4);
setDecay(90);
setSustain(32);
setRelease(64);
setVelSustain(0);
//sei(); // global interrupt enable
Serial.println("MUSIC INITIALIZED!");
}
/////////////////////////////////////
//
// FREQUENCY AND DETUNE FUNCTIONS
//
/////////////////////////////////////
void MMusic::setFrequency(float freq)
{
period1 = uint16_t(((freq * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
period2 = uint16_t(((freq * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
period3 = uint16_t(((freq * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
frequency = freq;
frequency1 = freq;
frequency2 = freq;
frequency3 = freq;
}
void MMusic::setFrequency1(float freq)
{
frequency1 = freq;
period1 = uint16_t(((frequency1 * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setFrequency2(float freq)
{
frequency2 = freq;
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setFrequency3(float freq)
{
frequency3 = freq;
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setSemitone1(int8_t semi)
{
if(-25 < semi && semi < 25){
semi1 = semitoneTable[semi+24];
} else if (semi < -24) {
semi1 = semitoneTable[0];
} else {
semi1 = semitoneTable[48];
}
period1 = uint16_t(((frequency1 * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setSemitone2(int8_t semi)
{
if(-25 < semi && semi < 25){
semi2 = semitoneTable[semi+24];
} else if (semi < -24) {
semi2 = semitoneTable[0];
} else {
semi2 = semitoneTable[48];
}
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setSemitone3(int8_t semi)
{
if(-25 < semi && semi < 25){
semi3 = semitoneTable[semi+24];
} else if (semi < -24) {
semi3 = semitoneTable[0];
} else {
semi3 = semitoneTable[48];
}
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setDetune(float detune)
{
detune1 = 0.0;
detune2 = detune;
detune3 = -detune;
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setDetune1(float detune)
{
detune1 = detune;
period1 = uint16_t(((frequency1 * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setDetune2(float detune)
{
detune2 = detune;
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setDetune3(float detune)
{
detune3 = detune;
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::pitchBend(float b)
{
bend = b;
period1 = uint16_t(((frequency1 * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
/////////////////////////////////////
//
// WAVEFORM FUNCTIONS
//
/////////////////////////////////////
void MMusic::setWaveform(uint16_t waveForm)
{
waveForm1 = waveForm * 256;
waveForm2 = waveForm * 256;
waveForm3 = waveForm * 256;
}
void MMusic::setWaveform1(uint16_t waveForm)
{
waveForm1 = waveForm * 256;
}
void MMusic::setWaveform2(uint16_t waveForm)
{
waveForm2 = waveForm * 256;
}
void MMusic::setWaveform3(uint16_t waveForm)
{
waveForm3 = waveForm * 256;
}
/////////////////////////////////////
//
// GAIN FUNCTIONS
//
/////////////////////////////////////
void MMusic::setGainFloat(float value)
{
gain = uint16_t(value * 65535);
gain1 = gain;
gain2 = gain;
gain3 = gain;
}
void MMusic::setGain16bit(uint16_t value)
{
gain = value;
gain1 = value;
gain2 = value;
gain3 = value;
}
void MMusic::setGain(float value)
{
gain = uint16_t(value * 65535);
gain1 = gain;
gain2 = gain;
gain3 = gain;
}
void MMusic::setGain(uint16_t value)
{
gain = value;
gain1 = value;
gain2 = value;
gain3 = value;
}
void MMusic::setGain1(float value)
{
gain1 = uint16_t(value * 65535);
}
void MMusic::setGain2(float value)
{
gain2 = uint16_t(value * 65535);
}
void MMusic::setGain3(float value)
{
gain3 = uint16_t(value * 65535);
}
void MMusic::setGain1(uint16_t value)
{
gain1 = value;
}
void MMusic::setGain2(uint16_t value)
{
gain2 = value;
}
void MMusic::setGain3(uint16_t value)
{
gain3 = value;
}
float MMusic::getGainFloat()
{
return float(gain)/65535.0;
}
float MMusic::getGain1Float()
{
return float(gain1)/65535.0;
}
float MMusic::getGain2Float()
{
return float(gain2)/65535.0;
}
float MMusic::getGain3Float()
{
return float(gain3)/65535.0;
}
uint16_t MMusic::getGain()
{
return gain;
}
uint16_t MMusic::getGain1()
{
return gain1;
}
uint16_t MMusic::getGain2()
{
return gain2;
}
uint16_t MMusic::getGain3()
{
return gain3;
}
/////////////////////////////////////
//
// NOTE_ON/OFF FUNCTIONS
//
/////////////////////////////////////
void MMusic::noteOn(uint8_t note, uint8_t vel)
{
envStage = 1;
setVelSustain(vel);
setVelPeak(vel);
notePlayed = note;
memcpy_P(&frequency16bit, &hertsTable[notePlayed],2);
setFrequency1(frequency16bit);
setFrequency2(frequency16bit);
setFrequency3(frequency16bit);
}
void MMusic::noteOn(uint8_t note)
{
envStage = 1;
setVelSustain(127);
setVelPeak(127);
notePlayed = note;
memcpy_P(&frequency16bit, &hertsTable[notePlayed],2);
setFrequency1(frequency16bit);
setFrequency2(frequency16bit);
setFrequency3(frequency16bit);
}
void MMusic::noteOff(uint8_t note)
{
if(notePlayed == note) {
envStage = 4;
}
}
void MMusic::noteOff()
{
envStage = 4;
}
/////////////////////////////////////
//
// ENVELOPE FUNCTIONS
//
/////////////////////////////////////
void MMusic::enableEnvelope()
{
envelopeOn = true;
}
void MMusic::disableEnvelope()
{
envelopeOn = false;
}
void MMusic::setEnvStage(uint8_t stage)
{
envStage = stage;
}
void MMusic::setAttack16bit(uint16_t att)
{
attack = att;
}
void MMusic::setDecay16bit(uint16_t dec)
{
decay = dec;
}
void MMusic::setSustain16bit(uint16_t sus)
{
sustain = sus;
}
void MMusic::setRelease16bit(uint16_t rel)
{
release = rel;
}
void MMusic::setAttack(uint8_t att)
{
if(att>127) att = 127;
memcpy_P(&attack, &envTimeTable[127 - att],2);
//attack = envTimeTable[127 - att];
}
void MMusic::setDecay(uint8_t dec)
{
if(dec>127) dec = 127;
memcpy_P(&decay, &envTimeTable[127 - dec],2);
//decay = envTimeTable[127 - dec];
}
void MMusic::setSustain(uint8_t sus)
{
sustain = ((sus * MAX_ENV_GAIN)/128);
}
void MMusic::setRelease(uint8_t rel)
{
if(rel>127) rel = 127;
memcpy_P(&release, &envTimeTable[127 - rel],2);
//release = envTimeTable[127 - rel];
}
void MMusic::setVelSustain(uint8_t vel)
{
velSustain = vel * (sustain / 128);
}
void MMusic::setVelPeak(uint8_t vel)
{
velPeak = vel * (MAX_ENV_GAIN / 128);
}
/////////////////////////////////////////////////////////
//
// 8 BIT WAVETABLE - AUDIO INTERRUPT SERVICE ROUTINE
//
/////////////////////////////////////////////////////////
void inline MMusic::synthInterrupt8bit()
{
PORTD &= ~(1<<3);
// Frame sync low for SPI (making it low here so that we can measure lenght of interrupt with scope)
PORTD &= ~(1<<6);
accumulator1 = accumulator1 + period1;
index1 = accumulator1 >> 8;
//oscil1 = 0;
memcpy_P(&oscil1, &waveTable[index1 + waveForm1],1);
sample = (oscil1 * gain1);
#if(NUM_OSCILLATORS==2 || NUM_OSCILLATORS==3)
accumulator2 = accumulator2 + period2;
index2 = accumulator2 >> 8;
//oscil2 = 0;
memcpy_P(&oscil2, &waveTable[index2 + waveForm2],1);
sample += (oscil2 * gain2);
#endif
#if NUM_OSCILLATORS==3
accumulator3 = accumulator3 + period3;
index3 = accumulator3 >> 8;
//oscil3 = 0;
memcpy_P(&oscil3, &waveTable[index3 + waveForm3],1);
sample += (oscil3 * gain3);
#endif
sample >>= 10;
// AMPLIFICATION ENVELOPE
// Amplification envelope is calculated here
if(envelopeOn) {
// Attack
if(envStage == 1) {
env += attack;
if(velPeak < env) {
env = velPeak;
envStage = 2;
}
}
// Decay
else if(envStage == 2) {
env -= decay;
if(env < velSustain || MAX_ENV_GAIN < env) {
env = velSustain;
envStage = 3;
}
}
// Sustain
else if (envStage == 3) {
env = velSustain;
}
// Release
else if (envStage == 4) {
env -= release;
if(MAX_ENV_GAIN < env) {
env = 0;
envStage = 0;
}
}
// No gain
else if (envStage == 0) {
env = 0;
accumulator1 = 0;
accumulator2 = 0;
accumulator3 = 0;
}
} else {
env = 65535;
}
// Adding the amplification envelope (16bit) we bring it back to the 16bit frame again afterwards.
sample = (env * sample) >> 16;
// Formatting the samples to be transfered to the MCP4921 DAC
dacSPI0 = sample >> 8;
dacSPI0 >>= 4;
dacSPI0 |= 0x30;
dacSPI1 = sample >> 4;
SPCR |= (1 << MSTR);
// transmit value out the SPI port
SPDR = dacSPI0;
while (!(SPSR & (1<<SPIF))); // Maybe this can be optimised
SPDR = dacSPI1;
while (!(SPSR & (1<<SPIF))); // Maybe this can be optimised
// Frame sync high
PORTD |= (1<<6);
}
/////////////////////////////////////////////////////////
//
// 12 BIT SINEWAVE - AUDIO INTERRUPT SERVICE ROUTINE
//
/////////////////////////////////////////////////////////
void MMusic::synthInterrupt12bitSine()
{
// Frame sync low for SPI (making it low here so that we can measure lenght of interrupt with scope)
PORTD &= ~(1<<6);
accumulator1 = accumulator1 + period1;
index1 = accumulator1 >> 4;
memcpy_P(&oscil1, &sineTable[index1],2);
sample = (oscil1 * gain1) << 2;
#if(NUM_OSCILLATORS==2 || NUM_OSCILLATORS==3)
accumulator2 = accumulator2 + period2;
index2 = accumulator2 >> 4;
memcpy_P(&oscil2, &sineTable[index2],2);
sample += (oscil2 * gain2) << 2;
#endif
#if NUM_OSCILLATORS==3
accumulator3 = accumulator3 + period3;
index3 = accumulator3 >> 4;
memcpy_P(&oscil3, &sineTable[index3],2);
sample += (oscil3 * gain3) << 2;
#endif
sample >>= 16;
// AMPLIFICATION ENVELOPE
// Amplification envelope is calculated here
if(envelopeOn) {
// Attack
if(envStage == 1) {
env += attack;
if(velPeak < env) {
env = velPeak;
envStage = 2;
}
}
// Decay
else if(envStage == 2) {
env -= decay;
if(env < velSustain || MAX_ENV_GAIN < env) {
env = velSustain;
envStage = 3;
}
}
// Sustain
else if (envStage == 3) {
env = velSustain;
}
// Release
else if (envStage == 4) {
env -= release;
if(MAX_ENV_GAIN < env) {
env = 0;
envStage = 0;
}
}
/*
// No gain
else if (envStage == 0) {
env = 0;
//accumulator1 = 0;
//accumulator2 = 0;
//accumulator3 = 0;
}
*/
} else {
env = 65535;
}
// Adding the amplification envelope (16bit) we bring it back to the 16bit frame again afterwards.
sample = (env * sample) >> 16;
// Formatting the samples to be transfered to the MCP4921 DAC
dacSPI0 = sample >> 8;
dacSPI0 >>= 4;
dacSPI0 |= 0x30;
dacSPI1 = sample >> 4;
SPCR |= (1 << MSTR);
// transmit value out the SPI port
SPDR = dacSPI0;
while (!(SPSR & (1<<SPIF))); // Maybe this can be optimised
SPDR = dacSPI1;
while (!(SPSR & (1<<SPIF))); // Maybe this can be optimised
// Frame sync high
PORTD |= (1<<6);
// Frame sync high
PORTD |= (1<<3);
}

830
software/lib/MMM/Music.h
View File

@ -25,28 +25,20 @@
#ifndef Music_h // include guard
#define Music_h
#include "Arduino.h"
#include <avr/interrupt.h>
#include <avr/pgmspace.h>
#include <hardwareSerial.h>
#include "Wavetable.h"
////////////////////////////////////
//
// SET NUMBER OF OSCILLATORS HERE.
// SHOULD BE 1, 2 or 3
//
////////////////////////////////////
//#define NUM_OSCILLATORS 3 //edited BV 29Jan13.
#define NUM_OSCILLATORS 3 //edited BV 29Jan13.
// current sample rate is 15625 as defined in the init() section
#define SAMPLE_RATE 15625
#ifndef NUM_OSCILLATORS
#define NUM_OSCILLATORS 1
#error NUM_OSCILLATORS should be defined in the Music.h file in the libraries/MMM folder.
#elif (NUM_OSCILLATORS == 1)||(NUM_OSCILLATORS == 2)||(NUM_OSCILLATORS == 3)
#else
#error NUM_OSCILLATORS shall be 1, 2 or 3
@ -55,21 +47,10 @@
// Maximum possible value for amplification envelope
#define MAX_ENV_GAIN 65535
// Table of MIDI note values to frequency in Hertz
prog_uint16_t hertsTable[] PROGMEM = {8,8,9,9,10,10,11,12,12,13,14,15,16,17,18,19,20,21,23,24,25,27,29,30,32,34,36,38,41,43,46,48,51,54,58,61,65,69,73,77,82,87,92,97,103,109,116,123,130,138,146,155,164,174,184,195,207,219,233,246,261,277,293,311,329,349,369,391,415,440,466,493,523,554,587,622,659,698,739,783,830,880,932,987,1046,1108,1174,1244,1318,1396,1479,1567,1661,1760,1864,1975,2093,2217,2349,2489,2637,2793,2959,3135,3322,3520,3729,3951,4186,4434,4698,4978,5274,5587,5919,6271,6644,7040,7458,7902,8372,8869,9397,9956,10548,11175,11839,12543};
prog_uint32_t envTimeTable[] PROGMEM = {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,33,34,35,36,37,38,39,41,42,43,45,46,48,49,51,53,55,57,59,61,63,65,67,70,73,75,78,81,85,88,92,96,100,104,109,114,119,125,131,138,146,154,163,172,183,195,209,225,242,261,284,310,341,379,425,482,556,654,792,998,1342,2030,4095};
float semitoneTable[] = {0.25,0.2648658,0.2806155,0.29730177,0.31498027,0.33370996,0.35355338,0.37457678,0.39685026,0.4204482,0.44544938,0.47193715,0.5,0.5297315,0.561231,0.59460354,0.62996054,0.6674199,0.70710677,0.74915355,0.7937005,0.8408964,0.8908987,0.9438743,1.0,1.0594631,1.122462,1.1892071,1.2599211,1.3348398,1.4142135,1.4983071,1.587401,1.6817929,1.7817974,1.8877486,2.0,2.1189263,2.244924,2.3784142,2.5198421,2.6696796,2.828427,2.9966142,3.174802,3.3635857,3.563595,3.7754972,4.0};
// Defining which pins the SPI interface is connected to.
#define SPI_SCK 5
#define SPI_MOSI 3
#include "Arduino.h"
#include <avr/interrupt.h>
#include <avr/pgmspace.h>
#include <hardwareSerial.h>
class MMusic {
public:
@ -102,28 +83,24 @@ public:
void setWaveform3(uint16_t waveForm); //
// GAIN FUNCTIONS
//void setGainFloat(float value); // 0.0 - 1.0
//void setGain16bit(uint16_t value); // 0 - 65535
//void setGain(uint16_t value); // 0 - 65535
void setGainFloat(float value); // 0.0 - 1.0
void setGain16bit(uint16_t value); // 0 - 65535
void setGain(uint16_t value); // 0 - 65535
void setGain(float value); // 0.0 - 1.0 USE THIS
//void setGain1(uint16_t value); // 0 - 65535
//void setGain2(uint16_t value); // 0 - 65535
//void setGain3(uint16_t value); // 0 - 65535
//float getGainFloat(); // 0.0 - 1.0 USE THIS
void setGain1(uint16_t value); // 0 - 65535
void setGain2(uint16_t value); // 0 - 65535
void setGain3(uint16_t value); // 0 - 65535
void setGain1(float value); // 0.0 - 1.0 USE THIS
void setGain2(float value); // 0.0 - 1.0 USE THIS
void setGain3(float value); // 0.0 - 1.0 USE THIS
//float getGain1Float(); // 0.0 - 1.0 USE THIS
//float getGain2Float(); // 0.0 - 1.0 USE THIS
//float getGain3Float(); // 0.0 - 1.0 USE THIS
float getGain(); // 0.0 - 1.0 USE THIS
float getGain1(); // 0.0 - 1.0 USE THIS
float getGain2(); // 0.0 - 1.0 USE THIS
float getGain3(); // 0.0 - 1.0 USE THIS
//uint16_t getGain();
//uint16_t getGain1();
//uint16_t getGain2();
//uint16_t getGain3();
float getGain1Float(); // 0.0 - 1.0 USE THIS
float getGain2Float(); // 0.0 - 1.0 USE THIS
float getGain3Float(); // 0.0 - 1.0 USE THIS
float getGainFloat(); // 0.0 - 1.0 USE THIS
uint16_t getGain();
uint16_t getGain1();
uint16_t getGain2();
uint16_t getGain3();
// NOTE FUNCTIONS
void noteOn(uint8_t note, uint8_t vel); // 0 - 255
@ -221,771 +198,4 @@ private:
extern MMusic Music;
/////////////////////////////////////////////////////////
//
// 8 BIT WAVETABLE - AUDIO INTERRUPT SERVICE ROUTINE
//
/////////////////////////////////////////////////////////
void inline MMusic::synthInterrupt8bit()
{
PORTD &= ~(1<<3);
// Frame sync low for SPI (making it low here so that we can measure lenght of interrupt with scope)
PORTD &= ~(1<<6);
accumulator1 = accumulator1 + period1;
index1 = accumulator1 >> 8;
//oscil1 = 0;
memcpy_P(&oscil1, &waveTable[index1 + waveForm1],1);
sample = (oscil1 * gain1);
#if (NUM_OSCILLATORS==2) || (NUM_OSCILLATORS==3)
accumulator2 = accumulator2 + period2;
index2 = accumulator2 >> 8;
//oscil2 = 0;
memcpy_P(&oscil2, &waveTable[index2 + waveForm2],1);
sample += (oscil2 * gain2);
#endif
#if NUM_OSCILLATORS==3
accumulator3 = accumulator3 + period3;
index3 = accumulator3 >> 8;
//oscil3 = 0;
memcpy_P(&oscil3, &waveTable[index3 + waveForm3],1);
sample += (oscil3 * gain3);
#endif
sample >>= 10;
// AMPLIFICATION ENVELOPE
// Amplification envelope is calculated here
if(envelopeOn) {
// Attack
if(envStage == 1) {
env += attack;
if(velPeak < env) {
env = velPeak;
envStage = 2;
}
}
// Decay
else if(envStage == 2) {
env -= decay;
if(env < velSustain || MAX_ENV_GAIN < env) {
env = velSustain;
envStage = 3;
}
}
// Sustain
else if (envStage == 3) {
env = velSustain;
}
// Release
else if (envStage == 4) {
env -= release;
if(MAX_ENV_GAIN < env) {
env = 0;
envStage = 0;
}
}
// No gain
else if (envStage == 0) {
env = 0;
accumulator1 = 0;
accumulator2 = 0;
accumulator3 = 0;
}
} else {
env = 65535;
}
// Adding the amplification envelope (16bit) we bring it back to the 16bit frame again afterwards.
sample = (env * sample) >> 16;
// Formatting the samples to be transfered to the MCP4921 DAC
dacSPI0 = sample >> 8;
dacSPI0 >>= 4;
dacSPI0 |= 0x30;
dacSPI1 = sample >> 4;
SPCR |= (1 << MSTR);
// transmit value out the SPI port
SPDR = dacSPI0;
while (!(SPSR & (1<<SPIF))); // Maybe this can be optimised
SPDR = dacSPI1;
while (!(SPSR & (1<<SPIF))); // Maybe this can be optimised
// Frame sync high
PORTD |= (1<<6);
}
/////////////////////////////////////////////////////////
//
// 12 BIT SINEWAVE - AUDIO INTERRUPT SERVICE ROUTINE
//
/////////////////////////////////////////////////////////
void MMusic::synthInterrupt12bitSine()
{
// Frame sync low for SPI (making it low here so that we can measure lenght of interrupt with scope)
PORTD &= ~(1<<6);
accumulator1 = accumulator1 + period1;
index1 = accumulator1 >> 4;
memcpy_P(&oscil1, &sineTable[index1],2);
sample = (oscil1 * gain1) << 2;
#if (NUM_OSCILLATORS==2) || (NUM_OSCILLATORS==3)
accumulator2 = accumulator2 + period2;
index2 = accumulator2 >> 4;
memcpy_P(&oscil2, &sineTable[index2],2);
sample += (oscil2 * gain2) << 2;
#endif
#if NUM_OSCILLATORS==3
accumulator3 = accumulator3 + period3;
index3 = accumulator3 >> 4;
memcpy_P(&oscil3, &sineTable[index3],2);
sample += (oscil3 * gain3) << 2;
#endif
sample >>= 16;
// AMPLIFICATION ENVELOPE
// Amplification envelope is calculated here
if(envelopeOn) {
// Attack
if(envStage == 1) {
env += attack;
if(velPeak < env) {
env = velPeak;
envStage = 2;
}
}
// Decay
else if(envStage == 2) {
env -= decay;
if(env < velSustain || MAX_ENV_GAIN < env) {
env = velSustain;
envStage = 3;
}
}
// Sustain
else if (envStage == 3) {
env = velSustain;
}
// Release
else if (envStage == 4) {
env -= release;
if(MAX_ENV_GAIN < env) {
env = 0;
envStage = 0;
}
}
/*
// No gain
else if (envStage == 0) {
env = 0;
//accumulator1 = 0;
//accumulator2 = 0;
//accumulator3 = 0;
}
*/
} else {
env = 65535;
}
// Adding the amplification envelope (16bit) we bring it back to the 16bit frame again afterwards.
sample = (env * sample) >> 16;
// Formatting the samples to be transfered to the MCP4921 DAC
dacSPI0 = sample >> 8;
dacSPI0 >>= 4;
dacSPI0 |= 0x30;
dacSPI1 = sample >> 4;
SPCR |= (1 << MSTR);
// transmit value out the SPI port
SPDR = dacSPI0;
while (!(SPSR & (1<<SPIF))); // Maybe this can be optimised
SPDR = dacSPI1;
while (!(SPSR & (1<<SPIF))); // Maybe this can be optimised
// Frame sync high
PORTD |= (1<<6);
// Frame sync high
PORTD |= (1<<3);
}
MMusic Music;
//////////////////////////////////////////////////////////
//
// AUDIO INTERRUPT. USE EITHER 8bit or 12bitSine VERSION
// COMMENT OUT THE ONE YOU ARE NOT USING
//
//////////////////////////////////////////////////////////
ISR(TIMER2_COMPA_vect) { // timer 2 is audio interrupt timer
OCR2A = 127; // don't change this
Music.synthInterrupt8bit();
// Music.synthInterrupt12bitSine();
}
/////////////////////////////////////
//
// INITIALIZING FUNCTION
//
/////////////////////////////////////
void MMusic::init()
{
// clear interrupts. to make sure the interrupt timer doesn't start until we've set it up.
//cli();
// set up syntheziser
// this is the timer 2 audio rate timer, fires an interrupt at 15625 Hz sampling rate
TIMSK2 = 1<<OCIE2A; // interrupt enable audio timer
OCR2A = 127;
TCCR2A = 2; // CTC mode, counts up to 127 then resets
TCCR2B = 0<<CS22 | 1<<CS21 | 0<<CS20;
// OUTPUTS
// sck + mosi + ss
DDRB |= (1 << DDB2) | (1 << DDB3) | (1 << DDB5);
// dac_cs output
DDRD |= (1 << DDD6) | (1 << DDB3);
// set up SPI port
SPCR = 0x50;
SPSR = 0x01;
// DAC frame sync HIGH, so that the SPI port doesn't start wirting straight away
PORTD |= (1<<6);
// waveform setup
//setSine();
setWaveform(0);
// frequency setup
setFrequency(440);
setSemitone1(0);
setSemitone2(0);
setSemitone3(0);
setDetune(0);
// gain setup
setGain(1.0f);
setGain1(1.0f);
setGain2(1.0f);
setGain3(1.0f);
// envelope setup
setEnvStage(0);
disableEnvelope();
env = 0;
setAttack(4);
setDecay(90);
setSustain(32);
setRelease(64);
setVelSustain(0);
//sei(); // global interrupt enable
//Serial.println("MUSIC INITIALIZED!");
}
/////////////////////////////////////
//
// FREQUENCY AND DETUNE FUNCTIONS
//
/////////////////////////////////////
void MMusic::setFrequency(float freq)
{
period1 = uint16_t(((freq * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
period2 = uint16_t(((freq * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
period3 = uint16_t(((freq * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
frequency = freq;
frequency1 = freq;
frequency2 = freq;
frequency3 = freq;
}
void MMusic::setFrequency1(float freq)
{
frequency1 = freq;
period1 = uint16_t(((frequency1 * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setFrequency2(float freq)
{
frequency2 = freq;
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setFrequency3(float freq)
{
frequency3 = freq;
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setSemitone1(int8_t semi)
{
if(-25 < semi && semi < 25){
semi1 = semitoneTable[semi+24];
} else if (semi < -24) {
semi1 = semitoneTable[0];
} else {
semi1 = semitoneTable[48];
}
period1 = uint16_t(((frequency1 * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setSemitone2(int8_t semi)
{
if(-25 < semi && semi < 25){
semi2 = semitoneTable[semi+24];
} else if (semi < -24) {
semi2 = semitoneTable[0];
} else {
semi2 = semitoneTable[48];
}
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setSemitone3(int8_t semi)
{
if(-25 < semi && semi < 25){
semi3 = semitoneTable[semi+24];
} else if (semi < -24) {
semi3 = semitoneTable[0];
} else {
semi3 = semitoneTable[48];
}
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setDetune(float detune)
{
detune1 = 0.0;
detune2 = detune;
detune3 = -detune;
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setDetune1(float detune)
{
detune1 = detune;
period1 = uint16_t(((frequency1 * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setDetune2(float detune)
{
detune2 = detune;
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::setDetune3(float detune)
{
detune3 = detune;
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
void MMusic::pitchBend(float b)
{
bend = b;
period1 = uint16_t(((frequency1 * semi1 * (1 + detune1 + bend)) * 65536.0) / SAMPLE_RATE);
period2 = uint16_t(((frequency2 * semi2 * (1 + detune2 + bend)) * 65536.0) / SAMPLE_RATE);
period3 = uint16_t(((frequency3 * semi3 * (1 + detune3 + bend)) * 65536.0) / SAMPLE_RATE);
}
/////////////////////////////////////
//
// WAVEFORM FUNCTIONS
//
/////////////////////////////////////
void MMusic::setWaveform(uint16_t waveForm)
{
waveForm1 = waveForm * 256;
waveForm2 = waveForm * 256;
waveForm3 = waveForm * 256;
}
void MMusic::setWaveform1(uint16_t waveForm)
{
waveForm1 = waveForm * 256;
}
void MMusic::setWaveform2(uint16_t waveForm)
{
waveForm2 = waveForm * 256;
}
void MMusic::setWaveform3(uint16_t waveForm)
{
waveForm3 = waveForm * 256;
}
/////////////////////////////////////
//
// GAIN FUNCTIONS
//
/////////////////////////////////////
/*
void MMusic::setGainFloat(float value)
{
gain = uint16_t(value * 65535);
gain1 = gain;
gain2 = gain;
gain3 = gain;
}
void MMusic::setGain16bit(uint16_t value)
{
gain = value;
gain1 = value;
gain2 = value;
gain3 = value;
}
*/
void MMusic::setGain(float value)
{
gain = uint16_t(value * 65535);
gain1 = gain;
gain2 = gain;
gain3 = gain;
}
/*
void MMusic::setGain(uint16_t value)
{
gain = value;
gain1 = value;
gain2 = value;
gain3 = value;
}
*/
void MMusic::setGain1(float value)
{
gain1 = uint16_t(value * 65535);
}
void MMusic::setGain2(float value)
{
gain2 = uint16_t(value * 65535);
}
void MMusic::setGain3(float value)
{
gain3 = uint16_t(value * 65535);
}
/*
void MMusic::setGain1(uint16_t value)
{
gain1 = value;
}
void MMusic::setGain2(uint16_t value)
{
gain2 = value;
}
void MMusic::setGain3(uint16_t value)
{
gain3 = value;
}
*/
float MMusic::getGain()
{
return float(gain)/65535.0;
}
float MMusic::getGain1()
{
return float(gain1)/65535.0;
}
float MMusic::getGain2()
{
return float(gain2)/65535.0;
}
float MMusic::getGain3()
{
return float(gain3)/65535.0;
}
/*
float MMusic::getGainFloat()
{
return float(gain)/65535.0;
}
float MMusic::getGain1Float()
{
return float(gain1)/65535.0;
}
float MMusic::getGain2Float()
{
return float(gain2)/65535.0;
}
float MMusic::getGain3Float()
{
return float(gain3)/65535.0;
}
uint16_t MMusic::getGain()
{
return gain;
}
uint16_t MMusic::getGain1()
{
return gain1;
}
uint16_t MMusic::getGain2()
{
return gain2;
}
uint16_t MMusic::getGain3()
{
return gain3;
}
*/
/////////////////////////////////////
//
// NOTE_ON/OFF FUNCTIONS
//
/////////////////////////////////////
void MMusic::noteOn(uint8_t note, uint8_t vel)
{
envStage = 1;
setVelSustain(vel);
setVelPeak(vel);
notePlayed = note;
memcpy_P(&frequency16bit, &hertsTable[notePlayed],2);
setFrequency1(frequency16bit);
setFrequency2(frequency16bit);
setFrequency3(frequency16bit);
}
void MMusic::noteOn(uint8_t note)
{
envStage = 1;
setVelSustain(127);
setVelPeak(127);
notePlayed = note;
memcpy_P(&frequency16bit, &hertsTable[notePlayed],2);
setFrequency1(frequency16bit);
setFrequency2(frequency16bit);
setFrequency3(frequency16bit);
}
void MMusic::noteOff(uint8_t note)
{
if(notePlayed == note) {
envStage = 4;
}
}
void MMusic::noteOff()
{
envStage = 4;
}
/////////////////////////////////////
//
// ENVELOPE FUNCTIONS
//
/////////////////////////////////////
void MMusic::enableEnvelope()
{
envelopeOn = true;
}
void MMusic::disableEnvelope()
{
envelopeOn = false;
}
void MMusic::setEnvStage(uint8_t stage)
{
envStage = stage;
}
void MMusic::setAttack16bit(uint16_t att)
{
attack = att;
}
void MMusic::setDecay16bit(uint16_t dec)
{
decay = dec;
}
void MMusic::setSustain16bit(uint16_t sus)
{
sustain = sus;
}
void MMusic::setRelease16bit(uint16_t rel)
{
release = rel;
}
void MMusic::setAttack(uint8_t att)
{
if(att>127) att = 127;
memcpy_P(&attack, &envTimeTable[127 - att],2);
//attack = envTimeTable[127 - att];
}
void MMusic::setDecay(uint8_t dec)
{
if(dec>127) dec = 127;
memcpy_P(&decay, &envTimeTable[127 - dec],2);
//decay = envTimeTable[127 - dec];
}
void MMusic::setSustain(uint8_t sus)
{
sustain = ((sus * MAX_ENV_GAIN)/128);
}
void MMusic::setRelease(uint8_t rel)
{
if(rel>127) rel = 127;
memcpy_P(&release, &envTimeTable[127 - rel],2);
//release = envTimeTable[127 - rel];
}
void MMusic::setVelSustain(uint8_t vel)
{
velSustain = vel * (sustain / 128);
}
void MMusic::setVelPeak(uint8_t vel)
{
velPeak = vel * (MAX_ENV_GAIN / 128);
}
#endif // close guard