neopixel control OSC->ESP added

master
Rob Canning 2023-09-14 13:39:02 +02:00
parent 3798913433
commit dc967ec68e
3 changed files with 297 additions and 63 deletions

View File

@ -38,6 +38,8 @@ const char* password = "cermozise";
// BROADCAST TO ALL IP / port // BROADCAST TO ALL IP / port
const IPAddress castIp = IPAddress(192,168,0,255); // 255 FOR BROADCAST const IPAddress castIp = IPAddress(192,168,0,255); // 255 FOR BROADCAST
const int port = 57120; // SUPERCOLLIDERS DEFAULT INCOMING OSC PORT const int port = 57120; // SUPERCOLLIDERS DEFAULT INCOMING OSC PORT
const unsigned int localPort = 8888; // local port to listen for UDP packets (here's where we send the packets)
bool connected = false; bool connected = false;
#include <WiFiUdp.h> #include <WiFiUdp.h>
WiFiUDP udp; WiFiUDP udp;
@ -49,9 +51,25 @@ WiFiUDP udp;
#include <OSCBundle.h> #include <OSCBundle.h>
#include <OSCMessage.h> #include <OSCMessage.h>
#include <OSCBoards.h> #include <OSCBoards.h>
#include <OSCData.h>
/* OSC MSG channels */ /* OSC MSG channels */
OSCBundle bundle; OSCBundle bundle;
OSCErrorCode error;
unsigned int ledState = LOW; // LOW means led is *on*
unsigned int ledNum = 0; // LOW means led is *on*
unsigned int touchBoard = 0; // LOW means led is *on*
#ifndef BUILTIN_LED
#ifdef LED_BUILTIN
#define BUILTIN_LED LED_BUILTIN
#else
#define BUILTIN_LED 13
#endif
#endif
// SERIAL ///////////////////////////////// // SERIAL /////////////////////////////////
#ifdef BOARD_HAS_USB_SERIAL #ifdef BOARD_HAS_USB_SERIAL
#include <SLIPEncodedUSBSerial.h> #include <SLIPEncodedUSBSerial.h>
@ -69,18 +87,24 @@ byte KEYLEN = 12;
void setup() { void setup() {
ws2812fx.init(); ws2812fx.init();
ws2812fx.setBrightness(10); ws2812fx.setBrightness(10);
//ws2812fx.setPixelColor(11, ws2812fx.Color(0,0,0));
//
// parameters: index, start, stop, mode, color, speed, reverse // parameters: index, start, stop, mode, color, speed, reverse
ws2812fx.setSegment(0, 0, 11, FX_MODE_BREATH, 0xFFFFFF, 1000, false); // segment 0 is leds 0 - 9 // ws2812fx.setSegment(0, 0, 11, FX_MODE_BREATH, 0xFFFFFF, 1000, false); // segment 0 is leds 0 - 9
//ws2812fx.setSegment(1, 0, 0, FX_MODE_BREATH, 0xFF0000, 300, false); // segment 1 is leds 10 - 19 //ws2812fx.setSegment(1, 0, 0, FX_MODE_BREATH, 0xFF0000, 300, false); // segment 1 is leds 10 - 19
//ws2812fx.setSegment(2, 6, 11, FX_MODE_BREATH, 0x0000FF, 400, true); // segment 2 is leds 20 - 29 //ws2812fx.setSegment(2, 6, 11, FX_MODE_BREATH, 0x0000FF, 400, true); // segment 2 is leds 20 - 29
ws2812fx.setSegment(0, 0, 11, 11, BLACK, 2000, false);
ws2812fx.start(); ws2812fx.start();
Serial.begin(115200); Serial.begin(115200);
WiFi.mode(WIFI_AP); WiFi.mode(WIFI_AP);
connectWiFi(); connectWiFi();
udp.begin(localPort); // start udp for incoming OSC messages
const String macAddress = WiFi.macAddress(); ; const String macAddress = WiFi.macAddress(); ;
// Default address is 0x5A, if tied to 3.3V its 0x5B // Default address is 0x5A, if tied to 3.3V its 0x5B
@ -111,9 +135,9 @@ void setup() {
int colorCount = 0; int colorCount = 0;
void loop() { void loop() {
ws2812fx.service(); rOSC();
//ws2812fx.service();
sendCapacitive(cap0, 0); // from the 121 sendCapacitive(cap0, 0); // from the 121
sendCapacitive(cap1, 1); // from the 121 sendCapacitive(cap1, 1); // from the 121
} }
@ -138,7 +162,101 @@ void connectWiFi(){
Serial.println(WiFi.localIP()); Serial.println(WiFi.localIP());
} }
// detect touch events and send over OSC ////////////// //NEOPIXEL COLOUR LOGIC /////////////////////////////////////////////
uint32_t colors[] = {RED, GREEN, BLUE, YELLOW, CYAN, MAGENTA,
PURPLE, ORANGE, PINK, GRAY, ULTRAWHITE, WHITE, BLACK };
void led(OSCMessage &msg) {
ledNum = msg.getInt(0); // which sensor/led
ledState = msg.getInt(1); // which state
touchBoard = msg.getInt(2); // which touch board
// increment led index based on which board input i.e. board 1 is 0-11, board 2 is 12 - 24
if (touchBoard==0){ledNum = ledNum + 0; };
if (touchBoard==1){ledNum = ledNum+6; }; // change to 12 when new strip wired! 6 for testing
switch (msg.getInt(1)) {
ws2812fx.setMode(FX_MODE_BLINK);
case 0:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
case 1:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
case 5:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
case 6:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
}
switch (msg.getInt(1)) {
ws2812fx.setMode(FX_MODE_BLINK);
case 0:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
case 1:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
case 2:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
case 3:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
case 4:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
case 5:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
case 6:
ws2812fx.setPixelColor(ledNum, colors[ledState]);
break;
ws2812fx.start();
}
//ws2812fx.start();
ws2812fx.show();
}
void flashyNeoPixel(int x){
Serial.print('asfd : ' + x);
if (x==2){
while(x==2){
ws2812fx.setPixelColor(11, ws2812fx.Color(0,222,222));
ws2812fx.show();
delay(100);
ws2812fx.setPixelColor(11, ws2812fx.Color(222,222,222));
ws2812fx.show();
delay(100);
}
}
}
void rOSC(){
//Serial.print("osc func called...");
OSCMessage msg;
int size = udp.parsePacket();
if (size > 0) {
while (size--) {
msg.fill(udp.read());
}
if (!msg.hasError()) {
msg.dispatch("/led", led);
} else {
error = msg.getError();
Serial.print("error: ");
Serial.println(error);
}
}
}
void sendCapacitive(Adafruit_MPR121 sensorboard, int index){ void sendCapacitive(Adafruit_MPR121 sensorboard, int index){
// Get the currently touched pads // Get the currently touched pads
@ -148,10 +266,9 @@ void sendCapacitive(Adafruit_MPR121 sensorboard, int index){
// it if *is* touched and *wasnt* touched before, alert! // it if *is* touched and *wasnt* touched before, alert!
if ((currtouched[index] & _BV(i)) && !(lasttouched[index] & _BV(i)) ) { if ((currtouched[index] & _BV(i)) && !(lasttouched[index] & _BV(i)) ) {
Serial.print(i); Serial.println(" touched"); Serial.print(i); Serial.println(" touched");
ws2812fx.setSegment(0, i, i, FX_MODE_STATIC, 0xFFFFFF, 700, false); // segment 0 is leds 0 - 9 // ws2812fx.setSegment(0, i, i, FX_MODE_STATIC, 0x0096FF, 700, false); // segment 0 is leds 0 - 9
//ledState = !ledState; //ledState = !ledState;
OSCMessage msg("/touch"); OSCMessage msg("/touch");
msg.add(WiFi.macAddress().c_str()); // mac address of sender esp32 msg.add(WiFi.macAddress().c_str()); // mac address of sender esp32
msg.add((int32_t)i); // send which sensor (0 - 11) was touched msg.add((int32_t)i); // send which sensor (0 - 11) was touched
@ -166,7 +283,7 @@ void sendCapacitive(Adafruit_MPR121 sensorboard, int index){
#endif #endif
String cap = "val for key num: " + String(i) + " === " + String(HIGH); String cap = "val for key num: " + String(i) + " === " + String(HIGH);
Serial.println("OSC SENT "); Serial.println(cap); //Serial.println("OSC SENT "); Serial.println(cap);
} }
// if it *was* touched and now *isnt*, alert! // if it *was* touched and now *isnt*, alert!
if (!(currtouched[index] & _BV(i)) && (lasttouched[index] & _BV(i)) ) { if (!(currtouched[index] & _BV(i)) && (lasttouched[index] & _BV(i)) ) {
@ -187,8 +304,8 @@ void sendCapacitive(Adafruit_MPR121 sensorboard, int index){
udp.endPacket(); udp.endPacket();
#endif #endif
String cap = "val for key num: " + String(i) + " === " + String(LOW); // String cap = "val for key num: " + String(i) + " === " + String(LOW);
Serial.println("OSC SENT "); Serial.println(cap); // Serial.println("OSC SENT "); Serial.println(cap);
} }
} }

View File

@ -3,6 +3,9 @@
s.options.numInputBusChannels = 4; s.options.numInputBusChannels = 4;
s.options.numOutputBusChannels = 4; s.options.numOutputBusChannels = 4;
b = NetAddr.new("192.168.0.116", 8888); // create the NetAddr
//b.sendMsg("/led", [0,1].choose); // send the application the message "hello" with the parameter "there"
//OSCFunc.trace(true); // Turn posting on //OSCFunc.trace(true); // Turn posting on
//OSCFunc.trace(false); // Turn posting off //OSCFunc.trace(false); // Turn posting off
@ -33,15 +36,18 @@ s.waitForBoot{
// create group order // create group order
~sGA = Group.new; ~sGB = Group.new; ~sGC = Group.new; ~sGD = Group.new; ~sGA = Group.new; ~sGB = Group.new; ~sGC = Group.new; ~sGD = Group.new;
s.sync; s.sync;
//// SYNTHS ////////////////////////////////// //// SYNTHS //////////////////////////////////
SynthDef.new(\splay, {| out=0, bufnum=0, t_trig=0, amp=0.5, rate=1, SynthDef.new(\splay, {| out=0, bufnum=0, tpse=1, t_trig=0, amp=0.8, rate=1,
atk=1, rel=1, loop=0, spos=0, gate=0, panRate=0.2 | atk=1, rel=1, loop=0, spos=0, gate=0, panRate=0.2 |
var env, sig; var env, sig;
env= EnvGen.kr(Env.asr(atk,1,rel),gate, doneAction:2); env= EnvGen.kr(Env.asr(atk,1,rel),gate, doneAction:2);
sig = PlayBuf.ar(1, bufnum, rate, t_trig, startPos: spos, loop:loop, doneAction: 0); sig = PlayBuf.ar(1, bufnum, rate*tpse, t_trig, startPos: spos, loop:loop, doneAction: 0);
sig = sig * env * amp; sig = sig * env * amp;
sig = Pan2.ar(sig, FSinOsc.kr(panRate)); sig = Pan2.ar(sig, FSinOsc.kr(panRate));
Out.ar(out, sig); Out.ar(out, sig);
@ -51,21 +57,41 @@ s.waitForBoot{
~oPA = 8.collect({ ~oPA = 8.collect({
arg itt, rate=1, out=0, sdir=\bowl, arg itt, rate=1, out=0, sdir=\bowl,
amp=0.5, loop=1, panRate=rrand(0.05,0.75), group=~sGA; amp=0.9, loop=1, panRate=rrand(0.05,0.75), group=~sGA;
Synth.new(\splay, [\bufnum, ~smp[sdir][rrand(0,~smp[sdir].size-1)], \out, out, \loop, loop, panRate: panRate], group); Synth.new(\splay, [\bufnum, ~smp[sdir][rrand(0,~smp[sdir].size-1)], \out, out, \loop, loop, panRate: panRate], group);
}); });
~oPB = 8.collect({ ~oPB = 8.collect({
arg itt, rate=1, out=0, sdir=\green, arg itt, rate=1, out=0, sdir=\green,
amp=0.1, loop=1, panRate=rrand(0.05,0.75), group=~sGA; amp=0.5, loop=1, panRate=rrand(0.05,0.75), group=~sGB;
Synth.new(\splay, [\bufnum, ~smp[sdir][rrand(0,~smp[sdir].size-1)], \out, out, \loop, loop, panRate: panRate], group); Synth.new(\splay, [\bufnum, ~smp[sdir][rrand(0,~smp[sdir].size-1)], \out, out, \loop, loop, panRate: panRate], group);
}); });
// RECEIVE OSC MESSAGES FROM ESP32s // RECEIVE OSC MESSAGES FROM ESP32s
~modeA = 0;
~modeB = 0;
~modeC = 0;
~modeD = 0;
~shiftA = 0; // shift state
~shiftB = 0; // shift state
~shiftC = 0; // shift state
~shiftD = 0; // shift state
~scaleMode = [Scale.partch_o1, Scale.major, Scale.minor, Scale.chromatic];
~scaleA = ~scaleMode[0];
~scaleB = ~scaleMode[3];
~lsA=1; // loop state
~lsB=1; // loop state
~ssA = 0;
~ssB = 0;
//~scales[2].tuning; ~scales[2].size; ~scales[2].pitchesPerOcatave;
~shift = 0; // shift state
~ls0=1; // loop state
s.sync; s.sync;
~esp32Receive = { arg name ,mac; OSCdef(name, { arg msg, time; ~esp32Receive = { arg name ,mac; OSCdef(name, { arg msg, time;
@ -75,42 +101,135 @@ s.waitForBoot{
// msg[3] is it a touch [1] or a release [0] // msg[3] is it a touch [1] or a release [0]
// msg[4] which of the connected mpr121 boards is sending // msg[4] which of the connected mpr121 boards is sending
if (msg[1] == mac && msg[3] == 1 && msg[4] == 0 && ~shift == 0 ) { if (msg[1] == mac && msg[3] == 1 && msg[4] == 0 && ~shiftA == 0 ) {
postln("first board" + msg[2]); //12.0.rand.round;
~scale = Scale.partch_o1; // use an array to spread different patterns over the keys
w = case ~rpitch = rrand(0,~scaleA.size -1);
{ msg[2] == 0} { ~oPA[0].set(\rate, ~scale[rrand(0,47)].midiratio, \t_trig, 1, \loop, 1, \gate, 1); } postln("first board" + msg[2] + "pitchclass: " + ~rpitch );
{ msg[2] == 1} { ~oPA[1].set(\rate, ~scale[rrand(0,47)].midiratio, \t_trig, 1, \gate, 1); } b.sendMsg("/led", msg[2], ~rpitch, msg[4]);
{ msg[2] == 2} { ~oPA[2].set(\rate, ~scale[rrand(0,47)].midiratio, \t_trig, 1, \gate, 1); }
{ msg[2] == 3} { ~oPA[3].set(\rate, ~scale[rrand(0,47)].midiratio, \t_trig, 1, \gate, 1); }
{ msg[2] == 4} { ~oPA[4].set(\rate, ~scale[rrand(0,47)].midiratio, \t_trig, 1, \gate, 1); }
{ msg[2] == 5} { ~oPA[5].set(\rate, ~scale[rrand(0,47)].midiratio, \t_trig, 1, \gate, 1); }
{ msg[2] == 6} { ~oPA[6].set(\rate, ~scale[rrand(0,47)].midiratio, \t_trig, 1, \gate, 1); }
{ msg[2] == 7} { ~oPA[7].set(\rate, ~scale[rrand(0,47)].midiratio + 1 , \t_trig, 1, \gate, 1); }
w = case
{ msg[2] == 0} { ~oPA[0].set(\rate, ~scaleA[~rpitch].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
{ msg[2] == 1} { ~oPA[1].set(\rate, ~scaleA[0].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
// always have a know root
{ msg[2] == 2} { ~oPA[2].set(\rate, ~scaleA[~rpitch].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
{ msg[2] == 3} { ~oPA[3].set(\rate, ~scaleA[~rpitch].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
{ msg[2] == 4} { ~oPA[4].set(\rate, ~scaleA[~rpitch].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
{ msg[2] == 5} { ~oPA[5].set(\rate, ~scaleA[~rpitch].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
{ msg[2] == 6} { ~oPA[6].set(\rate, ~scaleA[~rpitch].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
{ msg[2] == 7} { ~oPA[7].set(\rate, ~scaleA[~rpitch].midiratio + 1 , \t_trig, 1, \gate, 1); }
// LOOP mode on off
{ msg[2] == 8 } { // touch 7 = toggle looping of all samplers { msg[2] == 8 } { // touch 7 = toggle looping of all samplers
~ls0 = (~ls0 + 1)% 2; ~lsA = (~lsA + 1)% 2;
~sGA.set(\loop, ~ls0 ); // toggle this ~sGA.set(\loop, ~lsA ); // toggle this
postln("loop state set as:" + ~ls0 + " 7 " + msg[2] ); b.sendMsg("/led", msg[2], ~lsA, msg[4]);
postln("loop state set as:" + ~lsA + " 7 " + msg[2] );
}; };
}; };
// SHIFT logic for board A - 3 function= shift off on extra
///if SHIFT IS DEPRESSED on board 0 - shift enabled while 11 depressed
if (msg[1] == mac && msg[2] == 11 && msg[4] == 0 ) {
if (msg[3]==1){
~shiftA = (~shiftA + 1)% 3;
postln("SHIFT is: " + ~shiftA);
b.sendMsg("/led", msg[2], ~shiftA, msg[4]);
};
};
if (~shiftA==1 && msg[3]==1) {
postln(" shift is pressed " + msg[2]);
w = case
{ msg[2] == 0} { ~oPA[0].set(\tpse, 2, \t_trig, 1); }
{ msg[2] == 1} { ~oPA[1].set(\tpse, 2, \t_trig, 1); }
{ msg[2] == 2} { ~oPA[2].set(\tpse, 2, \t_trig, 1); }
{ msg[2] == 3} { ~oPA[3].set(\tpse, 2, \t_trig, 1); }
{ msg[2] == 4} { ~oPA[4].set(\tpse, 2, \t_trig, 1); }
{ msg[2] == 5} { ~oPA[5].set(\tpse, 2, \t_trig, 1); }
{ msg[2] == 6} { ~oPA[6].set(\tpse, 2, \t_trig, 1); }
{ msg[2] == 7} { ~oPA[7].set(\tpse, 2, \t_trig, 1); }
};
// SCALE CHANGER
if (~shiftA==1 && msg[2] == 8 && msg[3] == 1) {
~ssA = (~ssA + 1) % 4;
// use key release to
~scaleA = ~scaleMode[~ssA];
postln(" shift is pressed - scale changed to: " + ~ssA);
b.sendMsg("/led", 9, ~ssA, msg[4]);
};
//////////////////////////////////////////////////////////////////////////
// MODE logic for board A
if (msg[1] == mac && msg[2] == 10 && msg[4] == 0 ) {
if (msg[3]==1){
// send the esp32 an osc message
~modeA = ~modeA+1 % 3;
b.sendMsg("/led", msg[2], ~modeA, msg[4]); postln(~modeA); };
};
if (msg[1] == mac && msg[3] == 1 && msg[4] == 0 && ~modeA == 1 ) {
w = case
{ msg[2] == 0} { ~oPA[0].set(\tpse, -1); }
{ msg[2] == 1} { ~oPA[1].set(\tpse, -1 ); }
{ msg[2] == 2} { ~oPA[1].set(\tpse, -1 ); }
{ msg[2] == 3} { ~oPA[1].set(\tpse, -1 ); }
{ msg[2] == 4} { ~oPA[1].set(\tpse, -1 ); }
{ msg[2] == 5} { ~oPA[1].set(\tpse, -1 ); }
{ msg[2] == 6} { ~oPA[1].set(\tpse, -1 ); }
{ msg[2] == 7} { ~oPA[1].set(\tpse, -1 ); }
};
// mode 2 randomize transposition
if (msg[1] == mac && msg[3] == 1 && msg[4] == 0 && ~modeA == 2 ) {
w = case
{ msg[2] == 0} { ~oPA[0].set(\tpse, [0.25].choose); }
{ msg[2] == 1} { ~oPA[1].set(\tpse, [0.25].choose ); }
{ msg[2] == 2} { ~oPA[2].set(\tpse, [0.25].choose); }
{ msg[2] == 3} { ~oPA[3].set(\tpse, [0.25].choose ); }
{ msg[2] == 4} { ~oPA[4].set(\tpse, [0.25].choose ); }
{ msg[2] == 5} { ~oPA[5].set(\tpse, [0.25].choose ); }
{ msg[2] == 6} { ~oPA[6].set(\tpse, [0.25].choose ); }
{ msg[2] == 7} { ~oPA[7].set(\tpse, [0.25].choose ); }
};
//////////////////////////////////////////////////////////////////////////
//////////// second board
if (msg[1] == mac && msg[3] == 1 && msg[4] == 1) { if (msg[1] == mac && msg[3] == 1 && msg[4] == 1) {
postln("second board" + msg[2]);
~rpitch = rrand(0,47);
~rpitch = ~rpitch%11; postln("second board" + msg[2] + "color: " + ~rpitch );
b.sendMsg("/led", msg[2], ~rpitch, msg[4]);
w = case w = case
{ msg[2] == 0} { ~oPB[0].set(\rate, Scale.major[0].midiratio, \t_trig, 1, \gate, 1); } { msg[2] == 0} { ~oPB[0].set(\rate, Scale.major[0].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
{ msg[2] == 1} { ~oPB[1].set(\rate, Scale.major[1].midiratio, \t_trig, 1, \gate, 1); } { msg[2] == 1} { ~oPB[1].set(\rate, Scale.major[1].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
{ msg[2] == 2} { ~oPB[2].set(\rate, Scale.major[2].midiratio, \t_trig, 1, \gate, 1); } { msg[2] == 2} { ~oPB[2].set(\rate, Scale.major[2].midiratio, \t_trig, 1, \gate, 1, \tpse, 1); }
{ msg[2] == 3} { ~oPB[3].set(\rate, Scale.major[3].midiratio, \t_trig, 1, \gate, 1); } { msg[2] == 3} { ~oPB[3].set(\rate, Scale.major[3].midiratio, \t_trig, 1, \gate, 1,\tpse, 1); }
{ msg[2] == 4} { ~oPB[4].set(\rate, Scale.major[4].midiratio, \t_trig, 1, \gate, 1); } { msg[2] == 4} { ~oPB[4].set(\rate, Scale.major[4].midiratio, \t_trig, 1, \gate, 1,\tpse, 1); }
{ msg[2] == 5} { ~oPB[5].set(\rate, Scale.major[5].midiratio, \t_trig, 1, \gate, 1); } { msg[2] == 5} { ~oPB[5].set(\rate, Scale.major[5].midiratio, \t_trig, 1, \gate, 1,\tpse, 1); }
{ msg[2] == 6} { ~oPB[6].set(\rate, Scale.major[6].midiratio, \t_trig, 1, \gate, 1); } { msg[2] == 6} { ~oPB[6].set(\rate, Scale.major[6].midiratio, \t_trig, 1, \gate, 1,\tpse, 1); }
{ msg[2] == 7} { ~oPB[7].set(\rate, Scale.major[7].midiratio, \t_trig, 1, \gate, 1); } { msg[2] == 7} { ~oPB[7].set(\rate, Scale.major[7].midiratio, \t_trig, 1, \gate, 1,\tpse, 1); }
{ msg[2] == 8 } { // touch 7 = toggle looping of all samplers { msg[2] == 8 } { // touch 7 = toggle looping of all samplers
~ls0 = (~ls0 + 1)% 2; ~lsB = (~lsB + 1)% 2;
~sGB.set(\loop, ~ls0 ); // toggle this ~sGB.set(\loop, ~lsB ); // toggle this
postln("loop state set as:" + ~ls0 + " 7 " + msg[2] ); b.sendMsg("/led", msg[2], ~lsB, msg[4]);
postln("loop state set as:" + ~lsB + " 7 " + msg[2] );
}; };
}; };
@ -122,43 +241,41 @@ s.waitForBoot{
// msg[3] is it a touch [1] or a release [0] // msg[3] is it a touch [1] or a release [0]
// msg[4] which of the connected mpr121 boards is sending // msg[4] which of the connected mpr121 boards is sending
// if SHIFT IS DEPRESSED on board 1 - shift enabled while 11 depressed
if (msg[1] == mac && msg[2] == 11 && msg[4] == 0 ) {
if (msg[3]==1){
~shift = 1; postln("shift is enabled" )}
{ ~shift = 0; postln("shift is disabled" )}
};
// when finished apply effect/change and set state to unselected
// if SHIFT IS DEPRESSED on board 1 - shift enabled while 11 depressed
if (msg[1] == mac && msg[2] == 11 && msg[4] == 1 ) {
if (msg[3]==1){
~shiftB = 1; postln("shift is enabled" )}
{ ~shiftB = 0; postln("shift is disabled" )}
};
if (~shift==1) { if (~shift==1) {
postln(" shift is pressed " + msg[2]); postln(" shift is pressed " + msg[2]);
w = case w = case
{ msg[2] == 0} { ~oPA[0].set(\rate, 16); } { msg[2] == 0} { ~oPB[0].set(\rate, 16); }
{ msg[2] == 1} { ~oPA[1].set(\rate, 14); } { msg[2] == 1} { ~oPB[1].set(\rate, 14); }
{ msg[2] == 2} { ~oPA[2].set(\rate, 12); } { msg[2] == 2} { ~oPB[2].set(\rate, 12); }
{ msg[2] == 3} { ~oPA[3].set(\rate, 10); } { msg[2] == 3} { ~oPB[3].set(\rate, 10); }
{ msg[2] == 4} { ~oPA[4].set(\rate, 8); } { msg[2] == 4} { ~oPB[4].set(\rate, 8); }
{ msg[2] == 5} { ~oPA[5].set(\rate, 6); } { msg[2] == 5} { ~oPB[5].set(\rate, 6); }
{ msg[2] == 6} { ~oPA[6].set(\rate, 4); } { msg[2] == 6} { ~oPB[6].set(\rate, 4); }
{ msg[2] == 7} { ~oPA[7].set(\rate, 2); } { msg[2] == 7} { ~oPB[7].set(\rate, 2); }
} }
//~oPA[0].get(\rate.poll).poll
//////////////////////////////////////////////////////////////////////////
},'/touch') } ; },'/touch') } ;
~oPA[0].get(\rate).value;
s.sync; s.sync;
~esp32Receive.('anything', '3C:E9:0E:AD:A5:48'); ~esp32Receive.('anything', '3C:E9:0E:AD:A5:48');
~sG.set(\amp, 1); ~sG.set(\amp, 1);
~sG.set(\rate, -1); ~sG.set(\rate, -1);
~sGB.set(\amp, 0.2); ~sGB.set(\amp, 0.2);
"patch loaded and ready...".postln; "patch loaded and ready...".postln;
}; };

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