+class BlankPattern extends SCPattern {
+ BlankPattern(GLucose glucose) {
+ super(glucose);
+ }
+
+ public void run(double deltaMs) {
+ setColors(#000000);
+ }
+}
+
abstract class TestPattern extends SCPattern {
public TestPattern(GLucose glucose) {
super(glucose);
}
}
+class TestSpeakerMapping extends TestPattern {
+ TestSpeakerMapping(GLucose glucose) {
+ super(glucose);
+ }
+
+ public void run(double deltaMs) {
+ int h = 0;
+ for (Speaker speaker : model.speakers) {
+ for (Strip strip : speaker.strips) {
+ float b = 100;
+ for (Point p : strip.points) {
+ colors[p.index] = lx.hsb(h % 360, 100, b);
+ b = max(0, b - 10);
+ }
+ h += 70;
+ }
+ }
+ }
+
+}
+
+class TestBassMapping extends TestPattern {
+ TestBassMapping(GLucose glucose) {
+ super(glucose);
+ }
+
+ public void run(double deltaMs) {
+ int[] strips = { 2, 1, 0, 3, 13, 12, 15, 14, 9, 8, 11, 10, 5, 4, 7, 6 };
+ int h = 0;
+ for (int si : strips) {
+ float b = 100;
+ for (Point p : model.bassBox.strips.get(si).points) {
+ colors[p.index] = lx.hsb(h % 360, 100, b);
+ b = max(0, b - 10);
+ }
+ h += 70;
+ }
+ }
+}
+
+class TestFloorMapping extends TestPattern {
+ TestFloorMapping(GLucose glucose) {
+ super(glucose);
+ }
+
+ public void run(double deltaMs) {
+ int[] strutIndices = {6, 5, 4, 3, 2, 1, 0, 7};
+ int h = 0;
+ for (int si : strutIndices) {
+ float b = 100;
+ for (Point p : model.bassBox.struts.get(si).points) {
+ colors[p.index] = lx.hsb(h % 360, 100, b);
+ b = max(0, b - 10);
+ }
+ h += 50;
+ }
+ int[] floorIndices = {0, 1, 2, 3};
+ h = 0;
+ for (int fi : floorIndices) {
+ float b = 100;
+ for (Point p : model.boothFloor.strips.get(fi).points) {
+ colors[p.index] = lx.hsb(h, 100, b);
+ b = max(0, b - 3);
+ }
+ h += 90;
+ }
+ }
+}
+
+class TestPerformancePattern extends TestPattern {
+
+ final BasicParameter ops = new BasicParameter("OPS", 0);
+ final BasicParameter iter = new BasicParameter("ITER", 0);
+
+ TestPerformancePattern(GLucose glucose) {
+ super(glucose);
+ addParameter(ops);
+ addParameter(iter);
+ }
+
+ public void run(double deltaMs) {
+ float x = 1;
+ for (int j = 0; j < ops.getValuef() * 400000; ++j) {
+ x *= random(0, 1);
+ }
+
+ if (iter.getValuef() < 0.25) {
+ for (Point p : model.points) {
+ colors[p.index] = lx.hsb(
+ (p.x*.1 + p.y*.1) % 360,
+ 100,
+ 100
+ );
+ }
+ } else if (iter.getValuef() < 0.5) {
+ for (int i = 0; i < colors.length; ++i) {
+ colors[i] = lx.hsb(
+ (90 + model.px[i]*.1 + model.py[i]*.1) % 360,
+ 100,
+ 100
+ );
+ }
+ } else if (iter.getValuef() < 0.75) {
+ for (int i = 0; i < colors.length; ++i) {
+ colors[i] = lx.hsb(
+ (180 + model.p[3*i]*.1 + model.p[3*i+1]*.1) % 360,
+ 100,
+ 100
+ );
+ }
+ } else {
+ for (int i = 0; i < colors.length; ++i) {
+ colors[i] = lx.hsb(
+ (270 + model.x(i)*.1 + model.y(i)*.1) % 360,
+ 100,
+ 100
+ );
+ }
+ }
+ }
+}
+
class TestStripPattern extends TestPattern {
SinLFO d = new SinLFO(4, 40, 4000);
addModulator(d).trigger();
}
- public void run(int deltaMs) {
+ public void run(double deltaMs) {
for (Strip s : model.strips) {
for (Point p : s.points) {
- colors[p.index] = color(
+ colors[p.index] = lx.hsb(
lx.getBaseHuef(),
100,
max(0, 100 - d.getValuef()*dist(p.x, p.y, s.cx, s.cy))
super(glucose);
}
- public void run(int deltaMs) {
+ public void run(double deltaMs) {
// Access the core master hue via this method call
float hv = lx.getBaseHuef();
for (int i = 0; i < colors.length; ++i) {
- colors[i] = color(hv, 100, 100);
+ colors[i] = lx.hsb(hv, 100, 100);
}
}
}
super(glucose);
addModulator(xPos).trigger();
}
- public void run(int deltaMs) {
+ public void run(double deltaMs) {
float hv = lx.getBaseHuef();
for (Point p : model.points) {
// This is a common technique for modulating brightness.
// You can use abs() to determine the distance between two
// values. The further away this point is from an exact
// point, the more we decrease its brightness
- float bv = max(0, 100 - abs(p.fx - xPos.getValuef()));
- colors[p.index] = color(hv, 100, bv);
+ float bv = max(0, 100 - abs(p.x - xPos.getValuef()));
+ colors[p.index] = lx.hsb(hv, 100, bv);
}
}
}
super(glucose);
addModulator(yPos).trigger();
}
- public void run(int deltaMs) {
+ public void run(double deltaMs) {
float hv = lx.getBaseHuef();
for (Point p : model.points) {
- float bv = max(0, 100 - abs(p.fy - yPos.getValuef()));
- colors[p.index] = color(hv, 100, bv);
+ float bv = max(0, 100 - abs(p.y - yPos.getValuef()));
+ colors[p.index] = lx.hsb(hv, 100, bv);
}
}
}
super(glucose);
addModulator(zPos).trigger();
}
- public void run(int deltaMs) {
+ public void run(double deltaMs) {
float hv = lx.getBaseHuef();
for (Point p : model.points) {
- float bv = max(0, 100 - abs(p.fz - zPos.getValuef()));
- colors[p.index] = color(hv, 100, bv);
+ float bv = max(0, 100 - abs(p.z - zPos.getValuef()));
+ colors[p.index] = lx.hsb(hv, 100, bv);
}
}
}
addModulator(towerIndex).trigger();
}
- public void run(int deltaMs) {
+ public void run(double deltaMs) {
int ti = 0;
for (Tower t : model.towers) {
for (Point p : t.points) {
- colors[p.index] = color(
+ colors[p.index] = lx.hsb(
lx.getBaseHuef(),
100,
max(0, 100 - 80*LXUtils.wrapdistf(ti, towerIndex.getValuef(), model.towers.size()))
addModulator(yPos).trigger();
}
- public void run(int deltaMs) {
+ public void run(double deltaMs) {
// For the same reasons described above, it may logically feel to you that
// some of these operations are in reverse order. Again, just keep in mind that
// the car itself is what's moving, not the object
float d = sqrt(c.x*c.x + c.y*c.y + c.z*c.z); // distance from origin
// d = abs(d-60) + max(0, abs(c.z) - 20); // life saver / ring thing
d = max(0, abs(c.y) - 10 + .1*abs(c.z) + .02*abs(c.x)); // plane / spear thing
- colors[c.index] = color(
+ colors[c.index] = lx.hsb(
(hv + .6*abs(c.x) + abs(c.z)) % 360,
100,
constrain(140 - 40*d, 0, 100)
addModulator(index).start();
}
- public void run(int deltaMs) {
+ public void run(double deltaMs) {
for (Cube c : model.cubes) {
int i = 0;
for (Point p : c.points) {
- colors[p.index] = color(
+ colors[p.index] = lx.hsb(
lx.getBaseHuef(),
100,
max(0, 100 - 80.*abs(i - index.getValuef()))
numChannels = pandaMappings.length * PandaMapping.CHANNELS_PER_BOARD;
setChannel();
}
+
+ public int numChannels() {
+ return numChannels;
+ }
private void setChannel() {
activePanda = pandaMappings[channelIndex / PandaMapping.CHANNELS_PER_BOARD];
printInfo();
}
- public void run(int deltaMs) {
- color off = color(0, 0, 0);
+ public void run(double deltaMs) {
+ color off = #000000;
color c = off;
color r = #FF0000;
color g = #00FF00;
switch (mappingMode) {
case MAPPING_MODE_ALL: cubeOn = true; break;
case MAPPING_MODE_SINGLE_CUBE: cubeOn = (cubeIndex == ci); break;
- case MAPPING_MODE_CHANNEL: cubeOn = (channelIndex > 0); break;
+ case MAPPING_MODE_CHANNEL: cubeOn = (indexOfCubeInChannel > 0); break;
}
if (cubeOn) {
if (mappingMode == MAPPING_MODE_CHANNEL) {
}
++ci;
}
-
+ }
+
+ public void setCube(int index) {
+ cubeIndex = index % model.cubes.size();
}
public void incCube() {
cubeIndex += model.cubes.size();
}
}
+
+ public void setChannel(int index) {
+ channelIndex = index % numChannels;
+ setChannel();
+ }
public void incChannel() {
channelIndex = (channelIndex + 1) % numChannels;
setChannel();
}
+ public void setStrip(int index) {
+ stripIndex = index % Cube.STRIPS_PER_CUBE;
+ }
+
public void incStrip() {
stripIndex = (stripIndex + 1) % Cube.STRIPS_PER_CUBE;
}
stripIndex = (stripIndex + Cube.STRIPS_PER_CUBE - 1) % Cube.STRIPS_PER_CUBE;
}
- public void keyPressed() {
+ public void keyPressed(UIMapping uiMapping) {
switch (keyCode) {
case UP: if (mappingMode == MAPPING_MODE_CHANNEL) incChannel(); else incCube(); break;
case DOWN: if (mappingMode == MAPPING_MODE_CHANNEL) decChannel(); else decCube(); break;
case 'g': channelModeGreen = !channelModeGreen; break;
case 'b': channelModeBlue = !channelModeBlue; break;
}
+ uiMapping.setChannelID(channelIndex+1);
+ uiMapping.setCubeID(cubeIndex+1);
+ uiMapping.setStripID(stripIndex+1);
+ uiMapping.redraw();
}
+
}