color spheryvalue (float px, float py, float pz , float f1xc, float f1yc, float f1zc)
{
//switch(sShpape.cur() ) {}
- return color(constrain(huespread.getValuef()*5*px, 0, 360) , dist(px, py, pz, f1xc, f1yc, f1zc) ,
+ return lx.hsb(constrain(huespread.getValuef()*5*px, 0, 360) , dist(px, py, pz, f1xc, f1yc, f1zc) ,
max(0, 100 - 100*widthparameter.getValuef()*abs(dist(px, py, pz, f1xcenter, ybounce.getValuef(), f1zcenter)
- vibration.getValuef() ) ) );
}
color ellipsevalue(float px, float py, float pz , float f1xc, float f1yc, float f1zc, float f2xc, float f2yc, float f2zc)
{
//switch(sShpape.cur() ) {}
- return color(huespread.getValuef()*5*px, dist(model.xMax-px, model.yMax-py, model.zMax-pz, f1xc, f1yc, f1zc) ,
+ return lx.hsb(huespread.getValuef()*5*px, dist(model.xMax-px, model.yMax-py, model.zMax-pz, f1xc, f1yc, f1zc) ,
max(0, 100 - 100*widthparameter.getValuef() *
abs( (dist(px, py, pz, f1xc, ybounce.getValuef(), f1zc) +
(dist(px, py , pz, f2xc, ybounce.getValuef(), f2zc) ) )/2
SineSphere(GLucose glucose)
{
super(glucose);
- //Sshape = addPick("Shape", 0, 1);
+ //Sshape = addPick("Shape", , 1);
spherys = new Sphery[] {
new Sphery(model.xMax/4, model.yMax/2, model.zMax/2, modelrad/16, modelrad/8, 3000),
new Sphery(.75*model.xMax, model.yMax/2, model.zMax/2, modelrad/20, modelrad/10, 2000),
// spheremode++;
// }
- color CalcPoint(xyz Px)
+ color CalcPoint(PVector Px)
{
// if (spheremode == 0 )
//{
// c = blendColor(c, spherys[3].ellipsevalue(Px.x, Px.y, Px.z, model.xMax/4, model.yMax/4, model.zMax/4, 3*model.xMax/4, 3*model.yMax/4, 3*model.zMax/4),ADD);
// return c;
// }
- // return color(0,0,0);
+ // return lx.hsb(0,0,0);
// // else if(spheremode ==2)
// { color c = 0;
- // return color(CalcCone( (xyz by = new xyz(0,spherys[2].ybounce.getValuef(),0) ), Px, mid) );
+ // return lx.hsb(CalcCone( (xyz by = new xyz(0,spherys[2].ybounce.getValuef(),0) ), Px, mid) );
// }
}
class CubeCurl extends SCPattern{
-float CH, CW;
+float CH, CW, diag;
+ArrayList<PVector> cubeorigin = new ArrayList<PVector>();
+ArrayList<PVector> centerlist = new ArrayList<PVector>();
private SinLFO curl = new SinLFO(0, Cube.EDGE_HEIGHT, 5000 );
private SinLFO bg = new SinLFO(180, 220, 3000);
addModulator(bg).trigger();
this.CH = Cube.EDGE_HEIGHT;
this.CW = Cube.EDGE_WIDTH;
-final float diag = sqrt(CH*CH + CW*CW + CW*CW);
-ArrayList<PVector> centerlist = new ArrayList<PVector>();
+ this.diag = sqrt(CW*CW + CW*CW);
+
+ArrayList<PVector> centerlistrelative = new ArrayList<PVector>();
for (int i = 0; i < model.cubes.size(); i++){
+ Cube a = model.cubes.get(i);
+ cubeorigin.add(new PVector(a.x, a.y, a.z));
centerlist.add(centerofcube(i));
- }
+
+}
}
//there is definitely a better way of doing this!
PVector centerofcube(int i) {
Cube c = model.cubes.get(i);
-PVector cubeorigin = new PVector(c.x, c.y, c.z);
-PVector cubecenter = new PVector(c.x+ CW/2, c.y + CH/2, c.z + CW/2);
+
+println(" cube #: " + i + " c.x " + c.x + " c.y " + c.y + " c.z " + c.z );
PVector cubeangle = new PVector(c.rx, c.ry, c.rz);
-cubeangle.normalize();
-println( cubeangle.x + cubeangle.y + cubeangle.z);
-PVector cubecenterf = new PVector(cubecenter.x + tan(c.rx)*CW/2, cubecenter.y + tan(c.ry)*CH/2, cubecenter.z + tan(c.rz)*CW/2);
+//println("raw x" + cubeangle.x + "raw y" + cubeangle.y + "raw z" + cubeangle.z);
+PVector cubecenter = new PVector(c.x + CW/2, c.y + CH/2, c.z + CW/2);
+println("cubecenter unrotated: " + cubecenter.x + " " +cubecenter.y + " " +cubecenter.z );
+PVector centerrot = new PVector(cos(c.rx)*CW/2 - sin(c.rx)*CW/2, 0, cos(c.rz)*CW/2 + sin(c.rz)*CW/2);
+ // nCos*(y-o.y) - nSin*(z-o.z) + o.y
+cubecenter = PVector.add(cubecenter, centerrot);
+println( " cubecenter.x " + cubecenter.x + " cubecenter.y " + cubecenter.y + " cubecenter.z " + cubecenter.z + " ");
+
-return cubecenterf;
+return cubecenter;
}
Cube c = model.cubes.get(i);
float cfloor = c.y;
-if (i%3 == 0){
+// if (i%3 == 0){
-for (Point p : c.points ){
- // colors[p.index]=color(0,0,0);
- //float dif = (p.y - c.y);
- //colors[p.index] = color( bg.getValuef() , 80 , dif < curl.getValuef() ? 80 : 0, ADD);
- }
- }
+// for (Point p : c.points ){
+// // colors[p.index]=color(0,0,0);
+// //float dif = (p.y - c.y);
+// //colors[p.index] = color( bg.getValuef() , 80 , dif < curl.getValuef() ? 80 : 0, ADD);
+// }
+// }
-else if (i%3 == 1) {
+// else if (i%3 == 1) {
- for (Point p: c.points){
- colors[p.index]=color(0,0,0);
- float dif = (p.y - c.y);
- // colors[p.index] =
- // color(bg.getValuef(),
- // map(curl.getValuef(), 0, Cube.EDGE_HEIGHT, 20, 100),
- // 100 - 10*abs(dif - curl.getValuef()), ADD );
- }
- }
-else if (i%3 == 2){
+// for (Point p: c.points){
+// colors[p.index]=color(0,0,0);
+// float dif = (p.y - c.y);
+// // colors[p.index] =
+// // color(bg.getValuef(),
+// // map(curl.getValuef(), 0, Cube.EDGE_HEIGHT, 20, 100),
+// // 100 - 10*abs(dif - curl.getValuef()), ADD );
+// }
+// }
+// else if (i%3 == 2){
+ // centerlist[i].sub(cubeorigin(i);
for (Point p: c.points) {
-
+ PVector pv = new PVector(p.x, p.y, p.z);
+ colors[p.index] =color( constrain(4* pv.dist(centerlist.get(i)), 0, 360) , 50, 100 );
+ // colors[p.index] =color(constrain(centerlist[i].x, 0, 360), constrain(centerlist[i].y, 0, 100), );
- }
+ }
-}
+ //}
}
}
for (Point p : model.points) {
color c = 0;
- c = blendColor(c, color(360*HueT.getValuef(), 100*SatT.getValuef(), 100*BriT.getValuef()), ADD);
+ c = blendColor(c, lx.hsb(360*HueT.getValuef(), 100*SatT.getValuef(), 100*BriT.getValuef()), ADD);
colors[p.index]= c;
}
int now= millis();
}
}
- }
\ No newline at end of file
+ }