class L8onLife extends SCPattern { // Controls the rate of life algorithm ticks, in milliseconds private BasicParameter rateParameter = new BasicParameter("DELAY", 112.5, 0.0, 1000.0); // Controls the probability of a mutation in the cycleOfLife private BasicParameter mutationParameter = new BasicParameter("MUT", 0.000000011, 0.0, 0.1); // Controls the saturation. private BasicParameter saturationParameter = new BasicParameter("SAT", 90.0, 0.0, 100.0); public final double MIN_ALIVE_PROBABILITY = 0.2; public final double MAX_ALIVE_PROBABILITY = 0.9; public final float MAX_ALIVE_BRIGHTNESS = 90.0; private final SawLFO cubePos = new SawLFO(0, model.cubes.size(), 4000); class CubeState { // Index of cube in glucose.model.cubes public Integer index; // Boolean which describes if cube is alive. public boolean alive; // Boolean which describes if strip was just changed; public boolean just_changed; // Current brightness public float current_brightness; // List of this cubes neighbors public List neighbors; public CubeState(Integer index, boolean alive, float current_brightness, List neighbors) { this.index = index; this.alive = alive; this.current_brightness = current_brightness; this.neighbors = neighbors; } } // Contains the state of all cubes by index. private List cube_states; // Contains the amount of time since the last cycle of life. private int time_since_last_run; // Boolean describing if life changes were made during the current run. private boolean any_changes_this_run; // Hold the new lives private List new_lives; public L8onLife(GLucose glucose) { super(glucose); //Print debug info about the cubes. //outputCubeInfo(); initCubeStates(); time_since_last_run = 0; any_changes_this_run = false; new_lives = new ArrayList(); addParameter(rateParameter); addParameter(mutationParameter); addParameter(saturationParameter); addModulator(cubePos).trigger(); } public void run(double deltaMs) { Integer i = 0; CubeState cube_state; any_changes_this_run = false; new_lives.clear(); time_since_last_run += deltaMs; for (Cube cube : model.cubes) { cube_state = this.cube_states.get(i); if(shouldLightCube(cube_state)) { lightLiveCube(cube, cube_state, deltaMs); } else { lightDeadCube(cube, cube_state, deltaMs); } i++; } if(!any_changes_this_run) { randomizeCubeStates(); } else { applyNewLives(); } if(time_since_last_run >= rateParameter.getValuef()) { time_since_last_run = 0; } } public void lightLiveCube(Cube cube, CubeState cube_state, double deltaMs) { float cube_dist = LXUtils.wrapdistf((float) cube_state.index, cubePos.getValuef(), model.cubes.size()); float hv = (cube_dist / model.cubes.size()) * 360; float bv = cube_state.current_brightness; if(!cube_state.just_changed || deltaMs >= rateParameter.getValuef()) { float bright_prop = min(((float) time_since_last_run / rateParameter.getValuef()), 1.0); bv = min(MAX_ALIVE_BRIGHTNESS, bright_prop * MAX_ALIVE_BRIGHTNESS); if(cube_state.current_brightness < bv) { cube_state.current_brightness = bv; } else { bv = cube_state.current_brightness; } } for (LXPoint p : cube.points) { colors[p.index] = lx.hsb( hv, saturationParameter.getValuef(), bv ); } } public void lightDeadCube(Cube cube, CubeState cube_state, double deltaMs) { float cube_dist = LXUtils.wrapdistf((float) cube_state.index, cubePos.getValuef(), model.cubes.size()); float hv = (cube_dist / (float) model.cubes.size()) * 360; float bv = cube_state.current_brightness; if(!cube_state.just_changed || deltaMs >= rateParameter.getValuef()) { float bright_prop = 1.0 - min(((float) time_since_last_run / rateParameter.getValuef()), 1.0); bv = max(0.0, bright_prop * MAX_ALIVE_BRIGHTNESS); if(cube_state.current_brightness > bv) { cube_state.current_brightness = bv; } else { bv = cube_state.current_brightness; } } for (LXPoint p : cube.points) { colors[p.index] = lx.hsb( hv, saturationParameter.getValuef(), bv ); } } public void outputCubeInfo() { int i = 0; for (Cube c : model.cubes) { print("Cube " + i + ": " + c.x + "," + c.y + "," + c.z + "\n"); ++i; } print("Edgeheight: " + Cube.EDGE_HEIGHT + "\n"); print("Edgewidth: " + Cube.EDGE_WIDTH + "\n"); print("Channelwidth: " + Cube.CHANNEL_WIDTH + "\n"); } private void initCubeStates() { List neighbors; boolean alive = false; CubeState cube_state; this.cube_states = new ArrayList(); float current_brightness = 0.0; Integer i = 0; for (Cube c : model.cubes) { neighbors = findCubeNeighbors(c, i); alive = true; cube_state = new CubeState(i, alive, current_brightness, neighbors); this.cube_states.add(cube_state); ++i; } } private void randomizeCubeStates() { double prob_range = (1.0 - MIN_ALIVE_PROBABILITY) - (1.0 - MAX_ALIVE_PROBABILITY); double prob = MIN_ALIVE_PROBABILITY + (prob_range * Math.random()); //print("Randomizing cubes! p = " + prob + "\n"); for (CubeState cube_state: this.cube_states) { cube_state.alive = (Math.random() <= prob); } } public List findCubeNeighbors(Cube cube, Integer index) { List neighbors = new LinkedList(); Integer i = 0; for (Cube c : model.cubes) { if(index != i) { if(abs(c.x - cube.x) < (Cube.EDGE_WIDTH * 2) && abs(c.y - cube.y) < (Cube.EDGE_HEIGHT * 2)) { //print("Cube " + i + " is a neighbor of " + index + "\n"); neighbors.add(i); } } i++; } return neighbors; } public boolean shouldLightCube(CubeState cube_state) { // Respect rate parameter. if(time_since_last_run < rateParameter.getValuef()) { any_changes_this_run = true; cube_state.just_changed = false; return cube_state.alive; } else { boolean new_life = cycleOfLife(cube_state); new_lives.add(new_life); return new_life; } } public void applyNewLives() { int index = 0; for(boolean liveliness: new_lives) { CubeState cube_state = this.cube_states.get(index); cube_state.alive = new_lives.get(index); index++; } } public boolean cycleOfLife(CubeState cube_state) { Integer index = cube_state.index; Integer alive_neighbor_count = countLiveNeighbors(cube_state); boolean before_alive = cube_state.alive; boolean after_alive = before_alive; double mutation = Math.random(); if(cube_state.alive) { if(alive_neighbor_count < 2 || alive_neighbor_count > 3) { after_alive = false; } else { after_alive = true; } } else { if(alive_neighbor_count == 2) { after_alive = true; } else { after_alive = false; } } if(mutation <= mutationParameter.getValuef()) { after_alive = !after_alive; } if(before_alive != after_alive) { cube_state.just_changed = true; any_changes_this_run = true; } return after_alive; } public Integer countLiveNeighbors(CubeState cube_state) { Integer count = 0; CubeState neighbor_cube_state; for(Integer neighbor_index: cube_state.neighbors) { neighbor_cube_state = this.cube_states.get(neighbor_index); if(neighbor_cube_state.alive) { count++; } } return count; } } class L8onAutomata extends SCPattern { // Controls the rate of life algorithm ticks, in milliseconds private BasicParameter rateParameter = new BasicParameter("DELAY", 75.0, 0.0, 1000.0); // Controls the probability of a mutation in the cycleOfStripperLife private BasicParameter mutationParameter = new BasicParameter("MUT", 0.000000011, 0.0, 0.1); // Controls the rate of life algorithm ticks, in milliseconds private BasicParameter saturationParameter = new BasicParameter("SAT", 90.0, 0.0, 100.0); private final SawLFO pointPos = new SawLFO(0, model.points.size(), 8000); public final double MIN_ALIVE_PROBABILITY = 0.2; public final double MAX_ALIVE_PROBABILITY = 0.9; public final float MAX_ALIVE_BRIGHTNESS = 90.0; class PointState { // Index of cube in glucose.model.cubes public Integer index; // Boolean which describes if cube is alive. public boolean alive; // Boolean which describes if strip was just changed; public boolean just_changed; // Current brightness public float current_brightness; public PointState(Integer index, boolean alive, float current_brightness) { this.index = index; this.alive = alive; this.current_brightness = current_brightness; this.just_changed = false; } } // Contains the state of all cubes by index. private List point_states; // Contains the amount of time since the last cycle of life. private int time_since_last_run; // Boolean describing if life changes were made during the current run. private boolean any_changes_this_run; // Hold the new lives private List new_states; public L8onAutomata(GLucose glucose) { super(glucose); //Print debug info about the cubes. //outputCubeInfo(); initPointStates(); randomizePointStates(); time_since_last_run = 0; any_changes_this_run = false; new_states = new ArrayList(); addParameter(mutationParameter); addParameter(rateParameter); addParameter(saturationParameter); addModulator(pointPos).trigger(); } private void initPointStates() { boolean alive = true; PointState point_state; this.point_states = new ArrayList(); Integer i = 0; float current_brightness = 0.0; for (LXPoint p : model.points) { point_state = new PointState(i, alive, current_brightness); this.point_states.add(point_state); ++i; } } public void run(double deltaMs) { Integer i = 0; PointState point_state; any_changes_this_run = false; new_states.clear(); time_since_last_run += deltaMs; for (LXPoint p : model.points) { point_state = this.point_states.get(i); if(shouldLightPoint(point_state)) { lightLivePoint(p, point_state, deltaMs); } else { lightDeadPoint(p, point_state, deltaMs); } i++; } if(!any_changes_this_run) { randomizePointStates(); } else { applyNewStates(); } if(time_since_last_run >= rateParameter.getValuef()) { time_since_last_run = 0; } } public void lightLivePoint(LXPoint p, PointState point_state, double deltaMs) { float point_dist = LXUtils.wrapdistf((float) point_state.index, pointPos.getValuef(), model.points.size()); float hv = (point_dist / model.points.size()) * 360; float bv = point_state.current_brightness; if(deltaMs >= rateParameter.getValuef() || !point_state.just_changed) { float bright_prop = min(((float) time_since_last_run / rateParameter.getValuef()), 1.0); bv = min(MAX_ALIVE_BRIGHTNESS, bright_prop * MAX_ALIVE_BRIGHTNESS); if(point_state.current_brightness < bv) { point_state.current_brightness = bv; } else { bv = point_state.current_brightness; } } colors[p.index] = lx.hsb( hv, saturationParameter.getValuef(), bv ); } public void lightDeadPoint(LXPoint p, PointState point_state, double deltaMs) { float point_dist = LXUtils.wrapdistf((float) point_state.index, pointPos.getValuef(), model.points.size()); float hv = (point_dist / model.points.size()) * 360; float bv = point_state.current_brightness; if(!point_state.just_changed || deltaMs >= rateParameter.getValuef()) { float bright_prop = 1.0 - min(((float) time_since_last_run / rateParameter.getValuef()), 1.0); bv = max(0.0, bright_prop * MAX_ALIVE_BRIGHTNESS); if(point_state.current_brightness > bv) { point_state.current_brightness = bv; } else { bv = point_state.current_brightness; } } colors[p.index] = lx.hsb( hv, saturationParameter.getValuef(), bv ); } public boolean shouldLightPoint(PointState point_state) { // Respect rate parameter. if(time_since_last_run < rateParameter.getValuef()) { any_changes_this_run = true; point_state.just_changed = false; return point_state.alive; } else { boolean new_state = cycleOfAutomata(point_state); new_states.add(new_state); return new_state; } } public boolean cycleOfAutomata(PointState point_state) { Integer index = point_state.index; Integer alive_neighbor_count = countLiveNeighbors(point_state); boolean before_alive = point_state.alive; boolean after_alive = before_alive; double mutation = Math.random(); if(point_state.alive) { if(alive_neighbor_count == 1) { after_alive = true; } else { after_alive = false; } } else { if(alive_neighbor_count == 1) { after_alive = true; } else { after_alive = false; } } if(mutation < mutationParameter.getValuef()) { after_alive = !after_alive; } if(before_alive != after_alive) { any_changes_this_run = true; point_state.just_changed = true; } return after_alive; } public int countLiveNeighbors(PointState point_state) { int count = 0; if (point_state.index > 0) { PointState before_neighbor = point_states.get(point_state.index - 1); if(before_neighbor.alive) { count++; } } if (point_state.index < (point_states.size() - 1)) { PointState after_neighbor = point_states.get(point_state.index + 1); if(after_neighbor.alive) { count++; } } return count; } private void applyNewStates() { int index = 0; for(boolean new_state: new_states) { PointState point_state = this.point_states.get(index); point_state.alive = new_states.get(index); index++; } } private void randomizePointStates() { double prob_range = (1.0 - MIN_ALIVE_PROBABILITY) - (1.0 - MAX_ALIVE_PROBABILITY); double prob = MIN_ALIVE_PROBABILITY + (prob_range * Math.random()); //print("Randomizing points! p = " + prob + "\n"); for (PointState point_state: this.point_states) { point_state.alive = (Math.random() <= prob); point_state.just_changed = true; } } } class L8onStripLife extends SCPattern { // Controls the rate of life algorithm ticks, in milliseconds private BasicParameter rateParameter = new BasicParameter("DELAY", 112.5, 1.0, 1000.0); // Controls the probability of a mutation in the cycleOfStripperLife private BasicParameter mutationParameter = new BasicParameter("MUT", 0.000000011, 0.0, 0.1); // Controls the saturation. private BasicParameter saturationParameter = new BasicParameter("SAT", 90.0, 0.0, 100.0); public final double MIN_ALIVE_PROBABILITY = 0.4; public final double MAX_ALIVE_PROBABILITY = 0.9; public final float MAX_ALIVE_BRIGHTNESS = 90.0; private final SawLFO stripPos = new SawLFO(0, model.strips.size(), 8000); class StripState { // Index of strip in glucose.model.strips public Integer index; // Boolean which describes if strip is alive. public boolean alive; // Boolean which describes if strip was just changed; public boolean just_changed; // Current brightness public float current_brightness; // List of this cubes neighbors public List neighbors; public StripState(Integer index, boolean alive, float current_brightness, List neighbors) { this.index = index; this.alive = alive; this.current_brightness = current_brightness; this.neighbors = neighbors; this.just_changed = false; } } // Contains the state of all cubes by index. private List strip_states; // Contains the amount of time since the last cycle of life. private int time_since_last_run; // Boolean describing if life changes were made during the current run. private boolean any_changes_this_run; // Hold the new lives private List new_lives; public L8onStripLife(GLucose glucose) { super(glucose); //Print debug info about the strips. //outputStripInfo(); initStripStates(); randomizeStripStates(); time_since_last_run = 0; any_changes_this_run = false; new_lives = new ArrayList(); addParameter(rateParameter); addParameter(mutationParameter); addParameter(saturationParameter); addModulator(stripPos).trigger(); } public void run(double deltaMs) { Integer i = 0; StripState strip_state; any_changes_this_run = false; new_lives.clear(); time_since_last_run += deltaMs; for (Strip strip : model.strips) { strip_state = this.strip_states.get(i); if(shouldLightStrip(strip_state)) { lightLiveStrip(strip, strip_state, deltaMs); } else { lightDeadStrip(strip, strip_state, deltaMs); } i++; } if(!any_changes_this_run) { randomizeStripStates(); } else { applyNewLives(); } if(time_since_last_run >= rateParameter.getValuef()) { time_since_last_run = 0; } } public void lightLiveStrip(Strip strip, StripState strip_state, double deltaMs) { float strip_dist = LXUtils.wrapdistf((float) strip_state.index, stripPos.getValuef(), model.strips.size()); float hv = (strip_dist / model.strips.size()) * 360; float bv = strip_state.current_brightness; if(deltaMs >= rateParameter.getValuef() || !strip_state.just_changed) { float bright_prop = min(((float) time_since_last_run / rateParameter.getValuef()), 1.0); bv = min(MAX_ALIVE_BRIGHTNESS, bright_prop * MAX_ALIVE_BRIGHTNESS); if(strip_state.current_brightness < bv) { strip_state.current_brightness = bv; } else { bv = strip_state.current_brightness; } } for (LXPoint p : strip.points) { colors[p.index] = lx.hsb( hv, saturationParameter.getValuef(), bv ); } } public void lightDeadStrip(Strip strip, StripState strip_state, double deltaMs) { float strip_dist = LXUtils.wrapdistf((float) strip_state.index, stripPos.getValuef(), model.strips.size()); float hv = (strip_dist / model.strips.size()) * 360; float bv = strip_state.current_brightness; if(!strip_state.just_changed || deltaMs >= rateParameter.getValuef()) { float bright_prop = 1.0 - min(((float) time_since_last_run / rateParameter.getValuef()), 1.0); bv = max(0.0, bright_prop * MAX_ALIVE_BRIGHTNESS); if(strip_state.current_brightness > bv) { strip_state.current_brightness = bv; } else { bv = strip_state.current_brightness; } } for (LXPoint p : strip.points) { colors[p.index] = lx.hsb( hv, saturationParameter.getValuef(), bv ); } } public void outputStripInfo() { int i = 0; for (Strip strip : model.strips) { print("Strip " + i + ": " + strip.cx + "," + strip.cy + "," + strip.cz + "\n"); ++i; } } private void initStripStates() { List neighbors; boolean alive = false; float current_brightness = 0.0; StripState strip_state; this.strip_states = new ArrayList(); Integer i = 0; int total_neighbors = 0; for (Strip strip : model.strips) { neighbors = findStripNeighbors(strip, i); alive = true; strip_state = new StripState(i, alive, current_brightness, neighbors); this.strip_states.add(strip_state); total_neighbors += neighbors.size(); ++i; } float average_neighbor_count = (float) total_neighbors / (float) model.strips.size(); //print("Average neighbor count: " + average_neighbor_count + "\n"); } private void randomizeStripStates() { double prob_range = (1.0 - MIN_ALIVE_PROBABILITY) - (1.0 - MAX_ALIVE_PROBABILITY); double prob = MIN_ALIVE_PROBABILITY + (prob_range * Math.random()); //print("Randomizing strips! p = " + prob + "\n"); for (StripState strip_state : this.strip_states) { strip_state.alive = (Math.random() <= prob); strip_state.just_changed = true; } } public List findStripNeighbors(Strip strip, Integer index) { List neighbors = new LinkedList(); Integer i = 0; int neighbor_count = 0; double distance = 0.0; for (Strip s : model.strips) { if( (int)index != (int)i ) { distance = Math.sqrt( Math.pow((s.cx - strip.cx), 2) + Math.pow((s.cy - strip.cy), 2) + Math.pow((s.cz - strip.cz), 2) ); if(distance < ( (double) Cube.EDGE_WIDTH) ) { //print("Strip " + i + " is a neighbor of " + index + "\n"); neighbors.add(i); } } i++; } return neighbors; } public boolean shouldLightStrip(StripState strip_state) { // Respect rate parameter. if(time_since_last_run < rateParameter.getValuef()) { any_changes_this_run = true; strip_state.just_changed = false; return strip_state.alive; } else { boolean new_life = cycleOfStripperLife(strip_state); new_lives.add(new_life); return new_life; } } public void applyNewLives() { int index = 0; for(boolean liveliness: new_lives) { StripState strip_state = this.strip_states.get(index); strip_state.alive = new_lives.get(index); index++; } } public boolean cycleOfStripperLife(StripState strip_state) { Integer alive_neighbor_count = countLiveNeighbors(strip_state); boolean before_alive = strip_state.alive; boolean after_alive = before_alive; double mutation = Math.random(); if(strip_state.alive) { if(alive_neighbor_count < 2 || alive_neighbor_count > 6) { after_alive = false; } else { after_alive = true; } } else { if(alive_neighbor_count == 5) { after_alive = true; } else { after_alive = false; } } if(mutation < mutationParameter.getValuef()) { after_alive = !after_alive; } if(before_alive != after_alive) { any_changes_this_run = true; strip_state.just_changed = true; } return after_alive; } public Integer countLiveNeighbors(StripState strip_state) { Integer count = 0; StripState neighbor_strip_state; for(Integer neighbor_index: strip_state.neighbors) { neighbor_strip_state = this.strip_states.get(neighbor_index); if(neighbor_strip_state.alive) { count++; } } return count; } }