}
}
+/**
+ * This shows how to iterate over towers, enumerated in the model.
+ */
+class TestTowerPattern extends SCPattern {
+ private final SawLFO towerIndex = new SawLFO(0, model.towers.size(), 1000*model.towers.size());
+
+ public TestTowerPattern(GLucose glucose) {
+ super(glucose);
+ addModulator(towerIndex).trigger();
+ towerIndex.setValue(9);
+ }
+
+ public void run(int deltaMs) {
+ println((int)towerIndex.getValuef());
+ int ti = 0;
+ for (Tower t : model.towers) {
+ for (Point p : t.points) {
+ colors[p.index] = color(
+ lx.getBaseHuef(),
+ 100,
+ max(0, 100 - 80*abs(ti - towerIndex.getValuef()))
+ );
+ }
+ ++ti;
+ }
+ }
+
+}
+
/**
* This is a demonstration of how to use the projection library. A projection
* creates a mutation of the coordinates of all the points in the model, creating
class TestCubePattern extends SCPattern {
- private int POINTS_PER_CUBE = Cube.FACES_PER_CUBE * Face.STRIPS_PER_FACE * Strip.POINTS_PER_STRIP;
- private SawLFO index = new SawLFO(0, POINTS_PER_CUBE, POINTS_PER_CUBE*60);
+ private SawLFO index = new SawLFO(0, Cube.POINTS_PER_CUBE, Cube.POINTS_PER_CUBE*60);
TestCubePattern(GLucose glucose) {
super(glucose);
public boolean channelModeGreen = false;
public boolean channelModeBlue = false;
- private final static int NUM_CHANNELS = 16;
+ private final int numChannels;
- private final int[][] frontChannels;
- private final int[][] rearChannels;
- private int[] activeChannels;
+ private final PandaMapping[] pandaMappings;
+ private PandaMapping activeMapping;
+ private int mappingChannelIndex;
- MappingTool(GLucose glucose, int[][]frontChannels, int[][]rearChannels) {
+ MappingTool(GLucose glucose, PandaMapping[] pandaMappings) {
super(glucose);
- this.frontChannels = frontChannels;
- this.rearChannels = rearChannels;
+ this.pandaMappings = pandaMappings;
+ numChannels = pandaMappings.length * PandaMapping.CHANNELS_PER_BOARD;
setChannel();
}
private void setChannel() {
- if (channelIndex < frontChannels.length) {
- activeChannels = frontChannels[channelIndex];
- } else {
- activeChannels = rearChannels[channelIndex - frontChannels.length];
- }
+ mappingChannelIndex = channelIndex % PandaMapping.CHANNELS_PER_BOARD;
+ activeMapping = pandaMappings[channelIndex / PandaMapping.CHANNELS_PER_BOARD];
}
private int cubeInChannel(Cube c) {
int i = 1;
- for (int index : activeChannels) {
+ for (int index : activeMapping.channelList[mappingChannelIndex]) {
if (c == model.getCubeByRawIndex(index)) {
return i;
}
}
public void strip(int delta) {
- int len = Cube.FACES_PER_CUBE * Face.STRIPS_PER_FACE;
+ int len = Cube.STRIPS_PER_CUBE;
stripIndex = (len + stripIndex + delta) % len;
printInfo();
}
}
public void incChannel() {
- channelIndex = (channelIndex + 1) % NUM_CHANNELS;
+ channelIndex = (channelIndex + 1) % numChannels;
setChannel();
}
public void decChannel() {
--channelIndex;
if (channelIndex < 0) {
- channelIndex += NUM_CHANNELS;
+ channelIndex += numChannels;
}
setChannel();
}