void run(int deltaMs) {
angle += deltaMs * 0.0007;
- float sVal1 = Strip.list.size() * (0.5 + 0.5*sin(angle));
- float sVal2 = Strip.list.size() * (0.5 + 0.5*cos(angle));
+ float sVal1 = model.strips.size() * (0.5 + 0.5*sin(angle));
+ float sVal2 = model.strips.size() * (0.5 + 0.5*cos(angle));
float pVal = pos.getValuef();
float fVal = falloff.getValuef();
int s = 0;
- for (Strip strip : Strip.list) {
+ for (Strip strip : model.strips) {
int i = 0;
for (Point p : strip.points) {
colors[p.index] = color(
- (lx.getBaseHuef() + 360 - p.fy*.2 + p.fz * .3) % 360,
+ (lx.getBaseHuef() + 360 - p.fx*.2 + p.fy * .3) % 360,
constrain(.4 * min(abs(s - sVal1), abs(s - sVal2)), 20, 100),
max(0, 100 - fVal*abs(i - pVal))
);
SawLFO offset = new SawLFO(0, 16, 1000);
SinLFO rate = new SinLFO(350, 1200, 63000);
SinLFO falloff = new SinLFO(15, 50, 17000);
- SinLFO fY = new SinLFO(0, 250, 19000);
- SinLFO fZ = new SinLFO(0, 127, 11000);
- SinLFO hOffY = new SinLFO(0, 255, 13000);
+ SinLFO fX = new SinLFO(0, model.xMax, 19000);
+ SinLFO fY = new SinLFO(0, model.yMax, 11000);
+ SinLFO hOffX = new SinLFO(0, model.xMax, 13000);
public Swarm(GLucose glucose) {
super(glucose);
addModulator(offset).trigger();
addModulator(rate).trigger();
addModulator(falloff).trigger();
+ addModulator(fX).trigger();
addModulator(fY).trigger();
- addModulator(fZ).trigger();
- addModulator(hOffY).trigger();
+ addModulator(hOffX).trigger();
offset.modulateDurationBy(rate);
}
void run(int deltaMs) {
float s = 0;
- for (Strip strip : Strip.list) {
+ for (Strip strip : model.strips) {
int i = 0;
for (Point p : strip.points) {
- float fV = max(-1, 1 - dist(p.fy/2., p.fz, fY.getValuef()/2., fZ.getValuef()) / 64.);
+ float fV = max(-1, 1 - dist(p.fx/2., p.fy, fX.getValuef()/2., fY.getValuef()) / 64.);
colors[p.index] = color(
- (lx.getBaseHuef() + 0.3 * abs(p.fy - hOffY.getValuef())) % 360,
+ (lx.getBaseHuef() + 0.3 * abs(p.fx - hOffX.getValuef())) % 360,
constrain(80 + 40 * fV, 0, 100),
constrain(100 - (30 - fV * falloff.getValuef()) * modDist(i + (s*63)%61, offset.getValuef(), 16), 0, 100)
);
void computeBlend(int[] c1, int[] c2, double progress) {
float bleedf = 10 + bleed.getValuef() * 200.;
- float yPos = (float) (-bleedf + progress * (255. + bleedf));
- for (Point p : Point.list) {
- float d = (p.fy - yPos) / bleedf;
+ float xPos = (float) (-bleedf + progress * (model.xMax + bleedf));
+ for (Point p : model.points) {
+ float d = (p.fx - xPos) / bleedf;
if (d < 0) {
colors[p.index] = c2[p.index];
- }
- else if (d > 1) {
+ } else if (d > 1) {
colors[p.index] = c1[p.index];
- }
- else {
+ } else {
colors[p.index] = lerpColor(c2[p.index], c1[p.index], d, RGB);
}
}
float jConst = 300.*(1-range.getValuef());
float clrConst = 1.1 + clr.getValuef();
- for (Point p : Point.list) {
- float avgIndex = constrain((p.fy / 256. * avgSize), 0, avgSize-2);
+ for (Point p : model.points) {
+ float avgIndex = constrain((p.fx / model.xMax * avgSize), 0, avgSize-2);
int avgFloor = (int) avgIndex;
- float j = jBase + jConst * (p.fz / 128.);
+ float j = jBase + jConst * (p.fy / model.yMax);
float value = lerp(
this.bandVals[avgFloor].getValuef(),
this.bandVals[avgFloor+1].getValuef(),
float b = constrain(edgeConst * (value - j), 0, 100);
colors[p.index] = color(
- (480 + lx.getBaseHuef() - min(clrConst*p.fz, 120)) % 360,
+ (480 + lx.getBaseHuef() - min(clrConst*p.fy, 120)) % 360,
100,
b);
}
final BasicParameter bright = new BasicParameter("BRT", 1.0);
final BasicParameter sat = new BasicParameter("SAT", 0.2);
List<Layer> layers = new ArrayList<Layer>();
+ final float maxr = sqrt(model.xMax*model.xMax + model.yMax*model.yMax + model.zMax*model.zMax) + 10;
class Layer {
LinearEnvelope boom = new LinearEnvelope(-40, 500, 1300);
void trigger() {
float falloffv = falloffv();
- boom.setRange(-100 / falloffv, 500 + 100/falloffv, 4000 - speed.getValuef() * 3300);
+ boom.setRange(-100 / falloffv, maxr + 100/falloffv, 4000 - speed.getValuef() * 3300);
boom.trigger();
}
float falloffv = falloffv();
float satv = sat.getValuef() * 100;
float huev = lx.getBaseHuef();
- for (Point p : Point.list) {
+ for (Point p : model.points) {
colors[p.index] = blendColor(
colors[p.index],
- color(huev, satv, constrain(brightv - falloffv*abs(boom.getValuef() - dist(2*p.fx, p.fy, 2*p.fz, 128, 128, 128)), 0, 100)),
+ color(huev, satv, constrain(brightv - falloffv*abs(boom.getValuef() - dist(p.fx, 2*p.fy, 3*p.fz, model.xMax/2, model.yMax, model.zMax*1.5)), 0, 100)),
ADD);
}
}
addParameter(attack);
addParameter(release);
addParameter(level);
- cubeBrt = new LinearEnvelope[Cube.list.size() / 4];
+ cubeBrt = new LinearEnvelope[model.cubes.size() / 4];
for (int i = 0; i < cubeBrt.length; ++i) {
addModulator(cubeBrt[i] = new LinearEnvelope(0, 0, 100));
}
- base = new SinLFO[Cube.list.size() / 12];
+ base = new SinLFO[model.cubes.size() / 12];
for (int i = 0; i < base.length; ++i) {
addModulator(base[i] = new SinLFO(0, 1, 7000 + 1000*i)).trigger();
}
int i = 0;
float huef = lx.getBaseHuef();
float levelf = level.getValuef();
- for (Cube c : Cube.list) {
+ for (Cube c : model.cubes) {
float v = max(getBase(i).getValuef() * levelf/4., getEnvelope(i++).getValuef());
setColor(c, color(
- (huef + 20*v + abs(c.fy-128.)*.3 + c.fz) % 360,
+ (huef + 20*v + abs(c.cx-model.xMax/2.)*.3 + c.cy) % 360,
min(100, 120*v),
100*v
));
class CrossSections extends SCPattern {
- final SinLFO y = new SinLFO(0, 255, 5000);
- final SinLFO z = new SinLFO(0, 127, 6000);
- final SinLFO x = new SinLFO(0, 127, 7000);
+ final SinLFO x = new SinLFO(0, model.xMax, 5000);
+ final SinLFO y = new SinLFO(0, model.yMax, 6000);
+ final SinLFO z = new SinLFO(0, model.zMax, 7000);
final BasicParameter xw = new BasicParameter("XWID", 0.3);
final BasicParameter yw = new BasicParameter("YWID", 0.3);
final BasicParameter zw = new BasicParameter("ZWID", 0.3);
- final BasicParameter xr = new BasicParameter("XRAT", 0.5);
+ final BasicParameter xr = new BasicParameter("XRAT", 0.7);
final BasicParameter yr = new BasicParameter("YRAT", 0.6);
- final BasicParameter zr = new BasicParameter("ZRAT", 0.7);
- final BasicParameter xl = new BasicParameter("XLEV", 0.5);
+ final BasicParameter zr = new BasicParameter("ZRAT", 0.5);
+ final BasicParameter xl = new BasicParameter("XLEV", 1);
final BasicParameter yl = new BasicParameter("YLEV", 1);
- final BasicParameter zl = new BasicParameter("ZLEV", 1);
+ final BasicParameter zl = new BasicParameter("ZLEV", 0.5);
CrossSections(GLucose glucose) {
addParameter(xr);
addParameter(yr);
addParameter(zr);
- addParameter(yw);
+ addParameter(xw);
addParameter(xl);
addParameter(yl);
addParameter(zl);
- addParameter(zw);
- addParameter(xw);
+ addParameter(yw);
+ addParameter(zw);
}
void onParameterChanged(LXParameter p) {
if (p == xr) {
- x.setDuration(10000 - 9000*p.getValuef());
+ x.setDuration(10000 - 8800*p.getValuef());
} else if (p == yr) {
- y.setDuration(10000 - 8800*p.getValuef());
+ y.setDuration(10000 - 9000*p.getValuef());
} else if (p == zr) {
z.setDuration(10000 - 9000*p.getValuef());
}
-
}
public void run(int deltaMs) {
float ywv = 100. / (10 + 40*yw.getValuef());
float zwv = 100. / (10 + 40*zw.getValuef());
- for (Point p : Point.list) {
+ for (Point p : model.points) {
color c = 0;
c = blendColor(c, color(
- (lx.getBaseHuef() + p.fy/10 + p.fz/3) % 360,
- constrain(140 - 1.1*abs(p.fy - 127), 0, 100),
- max(0, ylv - ywv*abs(p.fy - yv))
+ (lx.getBaseHuef() + p.fx/10 + p.fy/3) % 360,
+ constrain(140 - 1.1*abs(p.fx - model.xMax/2.), 0, 100),
+ max(0, xlv - xwv*abs(p.fx - xv))
), ADD);
c = blendColor(c, color(
- (lx.getBaseHuef() + 80 + p.fz/10) % 360,
- constrain(140 - 2.2*abs(p.fz - 64), 0, 100),
- max(0, zlv - zwv*abs(p.fz - zv))
+ (lx.getBaseHuef() + 80 + p.fy/10) % 360,
+ constrain(140 - 2.2*abs(p.fy - model.yMax/2.), 0, 100),
+ max(0, ylv - ywv*abs(p.fy - yv))
), ADD);
c = blendColor(c, color(
- (lx.getBaseHuef() + 160 + p.fx / 10 + p.fz/2) % 360,
- constrain(140 - 2.2*abs(p.fx - 64), 0, 100),
- max(0, xlv - xwv*abs(p.fx - xv))
+ (lx.getBaseHuef() + 160 + p.fz / 10 + p.fy/2) % 360,
+ constrain(140 - 2.2*abs(p.fz - model.zMax/2.), 0, 100),
+ max(0, zlv - zwv*abs(p.fz - zv))
), ADD);
colors[p.index] = c;
}
public void run(int deltaMs) {
float hv = lx.getBaseHuef();
int si = 0;
- for (Strip strip : Strip.list) {
+ for (Strip strip : model.strips) {
int i = 0;
float mv = m[si % m.length].getValuef();
for (Point p : strip.points) {
colors[p.index] = color(
- (hv + p.fx + p.fz*hs.getValuef()) % 360,
- min(100, abs(p.fy - s.getValuef())/2.),
- max(0, 100 - mv * abs(i - 7.5))
+ (hv + p.fz + p.fy*hs.getValuef()) % 360,
+ min(100, abs(p.fx - s.getValuef())/2.),
+ max(0, 100 - mv/2. - mv * abs(i - 7.5))
);
++i;
}
}
}
+class Psychedelia extends SCPattern {
+
+ final int NUM = 3;
+ SinLFO m = new SinLFO(-0.5, NUM-0.5, 9000);
+ SinLFO s = new SinLFO(-20, 147, 11000);
+ TriangleLFO h = new TriangleLFO(0, 240, 19000);
+ SinLFO c = new SinLFO(-.2, .8, 31000);
+
+ Psychedelia(GLucose glucose) {
+ super(glucose);
+ addModulator(m).trigger();
+ addModulator(s).trigger();
+ addModulator(h).trigger();
+ addModulator(c).trigger();
+ }
+
+ void run(int deltaMs) {
+ float huev = h.getValuef();
+ float cv = c.getValuef();
+ float sv = s.getValuef();
+ float mv = m.getValuef();
+ int i = 0;
+ for (Strip strip : model.strips) {
+ for (Point p : strip.points) {
+ colors[p.index] = color(
+ (huev + i*constrain(cv, 0, 2) + p.fz/2. + p.fx/4.) % 360,
+ min(100, abs(p.fy-sv)),
+ max(0, 100 - 50*abs((i%NUM) - mv))
+ );
+ }
+ ++i;
+ }
+ }
+}
+
+class AskewPlanes extends SCPattern {
+
+ class Plane {
+ private final SinLFO a;
+ private final SinLFO b;
+ private final SinLFO c;
+ float av;
+ float bv;
+ float cv;
+ float denom;
+
+ Plane(int i) {
+ addModulator(a = new SinLFO(-1, 1, 4000 + 1029*i)).trigger();
+ addModulator(b = new SinLFO(-1, 1, 11000 - 1104*i)).trigger();
+ addModulator(c = new SinLFO(-50, 50, 4000 + 1000*i * ((i % 2 == 0) ? 1 : -1))).trigger();
+ }
+
+ void run(int deltaMs) {
+ av = a.getValuef();
+ bv = b.getValuef();
+ cv = c.getValuef();
+ denom = sqrt(av*av + bv*bv);
+ }
+ }
+
+ final Plane[] planes;
+ final int NUM_PLANES = 3;
+
+ AskewPlanes(GLucose glucose) {
+ super(glucose);
+ planes = new Plane[NUM_PLANES];
+ for (int i = 0; i < planes.length; ++i) {
+ planes[i] = new Plane(i);
+ }
+ }
+
+ private final float denoms[] = new float[NUM_PLANES];
+
+ public void run(int deltaMs) {
+ float huev = lx.getBaseHuef();
+ int i = 0;
+ for (Plane p : planes) {
+ p.run(deltaMs);
+ }
+ for (Point p : model.points) {
+ float d = MAX_FLOAT;
+ for (Plane plane : planes) {
+ d = min(d, abs(plane.av*(p.fx-model.xMax/2.) + plane.bv*(p.fy-model.yMax/2.) + plane.cv) / plane.denom);
+ }
+ colors[p.index] = color(
+ (lx.getBaseHuef() + abs(p.fx-model.xMax/2.)*.3 + p.fy*.8) % 360,
+ max(0, 100 - .8*abs(p.fx - model.xMax/2.)),
+ constrain(140 - 10.*d, 0, 100)
+ );
+ }
+ }
+}
+
+class ShiftingPlane extends SCPattern {
+
+ final SinLFO a = new SinLFO(-.2, .2, 5300);
+ final SinLFO b = new SinLFO(1, -1, 13300);
+ final SinLFO c = new SinLFO(-1.4, 1.4, 5700);
+ final SinLFO d = new SinLFO(-10, 10, 9500);
+
+ ShiftingPlane(GLucose glucose) {
+ super(glucose);
+ addModulator(a).trigger();
+ addModulator(b).trigger();
+ addModulator(c).trigger();
+ addModulator(d).trigger();
+ }
+
+ public void run(int deltaMs) {
+ float hv = lx.getBaseHuef();
+ float av = a.getValuef();
+ float bv = b.getValuef();
+ float cv = c.getValuef();
+ float dv = d.getValuef();
+ float denom = sqrt(av*av + bv*bv + cv*cv);
+ for (Point p : model.points) {
+ float d = abs(av*(p.fx-model.xMax/2.) + bv*(p.fy-model.yMax/2.) + cv*(p.fz-model.zMax/2.) + dv) / denom;
+ colors[p.index] = color(
+ (hv + abs(p.fx-model.xMax/2.)*.6 + abs(p.fy-model.yMax/2)*.9 + abs(p.fz - model.zMax/2.)) % 360,
+ constrain(110 - d*6, 0, 100),
+ constrain(130 - 7*d, 0, 100)
+ );
+ }
+ }
+}