class SineSphere extends APat {
  float modelrad = sqrt((model.xMax)*(model.xMax) + (model.yMax)*(model.yMax) + (model.zMax)*(model.zMax));
  private BasicParameter yrotspeed = new BasicParameter("yspeed", 3000, 1, 10000);
  private BasicParameter yrot2speed = new BasicParameter("y2speed", 4000, 1, 15000);
  private BasicParameter yrot3speed = new BasicParameter("y3speed", 1400, 1, 15000);
  private BasicParameter vibrationrate = new BasicParameter("vib", 3000, 1, 10000);
  private SawLFO yrot = new SawLFO(0, TWO_PI, yrotspeed);
  private SawLFO yrot2 = new SawLFO(0, -TWO_PI, yrot2speed);
  private SawLFO yrot3 = new SawLFO(0, -TWO_PI, yrot3speed);
  public BasicParameter huespread = new BasicParameter("Hue", 0, 180);
  public BasicParameter widthparameter= new BasicParameter("Width", 20, 1, 60);
  public BasicParameter vibration_magnitude = new BasicParameter("Vmag", 20, 2, modelrad/2);
  public BasicParameter scale = new BasicParameter("Scale", 1, .1, 5);
  private int pitch = 0; 
  private int channel = 0; 
  private int velocity = 0; 
  private int cur = 0; 
  public final LXProjection sinespin; 
  public final LXProjection sinespin2;
  public final LXProjection sinespin3;
 
  Pick Galaxy, STime; 

  public BasicParameter rotationx = new BasicParameter("rotx", 0, 0, 1 );
  public BasicParameter rotationy = new BasicParameter("roty", 1, 0, 1);
  public BasicParameter rotationz = new BasicParameter("rotz", 0, 0, 1);
  
  public final PVector P = new PVector();

  class Sphery {
  float f1xcenter, f1ycenter, f1zcenter, f2xcenter , f2ycenter, f2zcenter; //second three are for an ellipse with two foci
  private  SinLFO vibration; 
  private  SinLFO surfacewave;

  private SinLFO xbounce;
  public SinLFO ybounce;
  private SinLFO zbounce;
  float vibration_magnitude, vperiod, radius, vibration_min, vibration_max;
  
  //public BasicParameter huespread;
  public BasicParameter bouncerate;
  public BasicParameter bounceamp;
  public BasicParameter vibrationrate;
  public final PVector circlecenter;
 
  public Sphery(float f1xcenter, float f1ycenter, float f1zcenter, float radius, float vibration_magnitude , float vperiod) 
  {
   this.f1xcenter = f1xcenter;
   this.f1ycenter = f1ycenter;
   this.f1zcenter = f1zcenter;
   this.radius = radius; 
   this.circlecenter= new PVector(f1xcenter,f1ycenter,f1zcenter);

   this.vibration_magnitude = vibration_magnitude;
   
   this.vperiod = vperiod;
   //addParameter(bounceamp = new BasicParameter("Amp", .5));
   //addParameter(bouncerate = new BasicParameter("Rate", .5));  //ybounce.modulateDurationBy(bouncerate);
   //addParameter(vibrationrate = new BasicParameter("vibration", 1000, 10000));
    //addParameter(widthparameter = new BasicParameter("Width", .2));
     //addModulator(xbounce = new SinLFO(model.xMax/3, 2*model.yMax/3, 2000)).trigger(); 
   addModulator(ybounce= new SinLFO(model.yMax/3, 2*model.yMax/3, 240000)).trigger(); //bounce.modulateDurationBy
    
   //addModulator(bounceamp); //ybounce.setMagnitude(bouncerate);
   addModulator( vibration = new SinLFO( this.radius - vibration_magnitude , this.radius + vibration_magnitude, vperiod)).trigger(); //vibration.setPeriod(240000/lx.tempo.bpm());

      
  }

  //  public Sphery(float f1xcenter, float f1ycenter, float f1zcenter, float vibration_magnitude, float vperiod) 
  // {
  //  this.f1xcenter = f1xcenter;
  //  this.f1ycenter = f1ycenter;
  //  this.f1zcenter = f1zcenter;
  //  this.vibration_magnitude = vibration_magnitude;
  // this.vperiod = vperiod;
  //  addModulator(ybounce= new SinLFO(model.yMax/3, 2*model.yMax/3, 240000)).trigger(); //bounce.modulateDurationBy
  //   addModulator( vibration = new SinLFO( modelrad/10 - vibration_magnitude , modelrad/10 + vibration_magnitude, vperiod)).trigger(); //vibration.setPeriod(240000/lx.tempo.bpm());
      
  // }

  //for an ellipse
//  public Sphery(float f1xcenter, float f1ycenter, float f1zcenter, float f2xcenter, float f2ycenter, float f2zcenter, 
//   float vibration_min, float vibration_max, float vperiod)  
 
//  {
//     this.f1xcenter = f1xcenter;
//    this.f1ycenter = f1ycenter;
//    this.f1zcenter = f1zcenter;
//    this.f2xcenter = f2xcenter;
//    this.f2ycenter = f2ycenter;
//    this.f2zcenter = f2zcenter;
//    this.vibration_min = vibration_min;
//    this.vibration_max = vibration_max;
//    this.vperiod = vperiod;
//    //addModulator(xbounce = new SinLFO(model.xMax/3, 2*model.yMax/3, 2000)).trigger(); 
//    addModulator(ybounce).trigger(); 
//    addModulator( vibration = new SinLFO(vibration_min , vibration_max, lx.tempo.rampf())).trigger(); //vibration.modulateDurationBy(vx);
//    addParameter(widthparameter = new BasicParameter("Width", .1));
//    //addParameter(huespread = new BasicParameter("bonk", .2));
  
// }
 
public int     c1c    (float a)              { return round(100*constrain(a,0,1));               }

void setVibrationPeriod(double period){
// to-do:  make this conditional upon time signature

this.vibration.setPeriod(period);
}

void setVibrationMagnitude(double mag){
//to-do: make this optionally conditional upon decibel volume, frequency spectrum)
this.vibration.setRange(-mag,mag);

}


float distfromcirclecenter(float px, float py, float pz, float f1x, float f1y, float f1z) 
{
   return dist(px, py, pz, f1x, f1y, f1z);
    }
 //void updatespherey(deltaMs, )

 float quadrant(PVector q) {
   float qtheta = atan2(  (q.x-f1xcenter) , (q.z - f1zcenter) ); 
   float qphi = acos( (q.z-f1zcenter)/(PVector.dist(q,circlecenter)) );  


    return map(qtheta, -PI/2, PI/2, 200-huespread.getValuef(), 240+huespread.getValuef());
  //if (q.x > f1xcenter ) {return 140 ;}
    //else  {return 250;}  
 }

 // float noisesat(PVector q) {
   

 //  return noise()

 // }
 color spheryvalue (PVector p) {
   circlecenter.set(this.f1xcenter, this.f1ycenter, this.f1zcenter); 

  
//switch(sShpape.cur() ) {}  

   float b = max(0, 100 - widthparameter.getValuef()*abs(p.dist(circlecenter)
      - vibration.getValuef()) );

   if (b <= 0) {
     return 0;
   }

   return lx.hsb(
     constrain(quadrant(p), 0, 360),
     // constrain(100*noise(quadrant(p)), 0, 100),
     100,
      b
   ); 
 }
 color ellipsevalue(float px, float py, float pz , float f1xc, float f1yc, float f1zc, float f2xc, float f2yc, float f2zc)
  {
//switch(sShpape.cur() ) {}  
   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  
      - 1.2*vibration.getValuef() ) ) ) ; 
  }

  
}  

boolean noteOn(Note note) {
    int row = note.getPitch(), col = note.getChannel();
  //  if (row == 57) {KeyPressed = col; return true; }
    return super.noteOn(note);
  }


// public boolean noteOn(Note note)  {
// pitch= note.getPitch();  
// velocity=note.getVelocity();
// channel=note.getChannel();
// return true;
// }

// public boolean gridPressed(int row, int col) {
//  pitch = row; channel = col; 
//  cur = NumApcCols*(pitch-53)+col; 
// //setState(row, col, 0 ? 1 : 0); 
// return true;
// }

//public grid
final Sphery[] spherys;
 
  SineSphere(GLucose glucose) 
  {
    super(glucose);
    println("modelrad  " + modelrad);   
    sinespin = new LXProjection(model);
    sinespin2 = new LXProjection(model);
    sinespin3= new LXProjection(model);
    addParameter(huespread);
    addParameter(vibrationrate);
    addParameter(widthparameter);
    addParameter(rotationx);
    addParameter(rotationy);
    addParameter(rotationz);
    addParameter(yrotspeed);
    addParameter(yrot2speed);
    addParameter(yrot3speed);
    addParameter(vibration_magnitude);
    addParameter(scale);
    addModulator(yrot).trigger();
    addModulator(yrot2).trigger(); 
    addModulator(yrot3).trigger();
    //Galaxy = addPick("Galaxy", 1, 3, new String[] {"home", "vertical","single","aquarium"});
    STime =addPick("Time", 1, 4, new String[]{"half", "triplet", "beat", "2x", "3x" });
    
    spherys = new Sphery[] {
    new Sphery(model.xMax/4, model.yMax/2, model.zMax/2, modelrad/12, modelrad/25, 3000),
    new Sphery(.75*model.xMax, model.yMax/2, model.zMax/2, modelrad/14, modelrad/28, 2000),
    new Sphery(model.cx, model.cy, model.cz,  modelrad/5, modelrad/15, 2300),
    new Sphery(.7*model.xMax, .65*model.yMax, .5*model.zMax, modelrad/11, modelrad/25, 3500),
    new Sphery(.75*model.xMax, .8*model.yMax, .7*model.zMax, modelrad/12, modelrad/30, 2000)
    
            



      // 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),
      // new Sphery(model.xMax/2, model.yMax/2, model.zMax/2,  modelrad/4, modelrad/8, 2300),

      // new Sphery(.7*model.xMax, .65*model.yMax, .5*model.zMax, modelrad/14, modelrad/7, 3500),
      // new Sphery(.75*model.xMax, .8*model.yMax, .7*model.zMax, modelrad/20, modelrad/10, 2000),
      // new Sphery(model.xMax/2, model.yMax/2, model.zMax/2,  modelrad/4, modelrad/8, 2300),
      
    };  
  }

// public void onParameterChanged(LXParameter parameter)
// {


//     for (Sphery s : spherys) {
//       if (s == null) continue;
//       double bampv = s.bounceamp.getValue();
//       double brv = s.bouncerate.getValue();
//       double tempobounce = lx.tempo.bpm();
//       if (parameter == s.bounceamp) 
//       {
//         s.ybounce.setRange(bampv*model.yMax/3 , bampv*2*model.yMax/3, brv);
//       }
//       else if ( parameter == s.bouncerate )   
//       {
//         s.ybounce.setDuration(120000./tempobounce);
//       }
//     }
//   }

    public void run( double deltaMs) {
     float  t = lx.tempo.rampf();
     float bpm = lx.tempo.bpmf();
     float scalevalue = scale.getValuef();
     int spherytime= STime.Cur();

     
     switch (spherytime) {

     case 0: t = map(.5*t ,0,.5, 0,1);   bpm = .5*bpm;  break;

     case 1: t = t;   bpm = bpm;   break;

     case 2: t = map(2*t,0,2,0,1);  bpm = 2*bpm; break;

     default: t= t;   bpm = bpm; 
     }

     //switch(sphery.colorscheme)
        
      for ( Sphery s: spherys){
      
      //s.vibration.setBasis(t);
      s.setVibrationPeriod(vibrationrate.getValuef());
    //  s.setVibrationMagnitude(vibration_magnitude.getValuef());
     
       }
      

      sinespin.reset()
      // Translate so the center of the car is the origin, offset 
      .center()
       .scale(scalevalue, scalevalue, scalevalue)
      // Rotate around the origin (now the center of the car) about an y-vector
      .rotate(yrot.getValuef(), rotationx.getValuef(), rotationy.getValuef() , rotationz.getValuef())
      .translate(model.cx, model.cy, model.cz);
      

   
   

     for (LXVector p: sinespin)
     // for (Point p: model.points)
     {
       P.set(p.x, p.y, p.z);
      // PVector P = new PVector(p.x, p.y, p.z);
    color c = #000000;
    c = blendIfColor(c, spherys[1].spheryvalue(P), ADD);
    c = blendIfColor(c, spherys[0].spheryvalue(P), ADD);
    c = blendIfColor(c, spherys[2].spheryvalue(P),ADD);
    

    colors[p.index] = c;
    
      
               }
   sinespin2.reset()
   .center()
   .scale(scalevalue,scalevalue,scalevalue)
   .rotate(yrot2.getValuef(), rotationx.getValuef(), rotationy.getValuef() , rotationz.getValuef())
   .translate(model.cx,model.cy,model.cz);

    for (LXVector p: sinespin2)
    {   color c = 0;
      // PVector P = new PVector(p.x, p.y, p.z);
        P.set(p.x, p.y, p.z);
        c = blendIfColor(c, spherys[3].spheryvalue(P),ADD);
         
        colors[p.index] = blendIfColor(colors[p.index], c , ADD);

    }  
    sinespin3.reset()
    .center()
    .scale(scalevalue,scalevalue,scalevalue)
    .rotate(yrot3.getValuef(),-1 + rotationx.getValuef(), rotationy.getValuef(), rotationz.getValuef())
    .translate(model.cx, model.cy, model.cz);
   for (LXVector p: sinespin3)
    {   color c = 0;
      // PVector P = new PVector(p.x, p.y, p.z);
        P.set(p.x, p.y, p.z);
        c = blendIfColor(c, spherys[4].spheryvalue(P),ADD);
         
        colors[p.index] = blendIfColor(colors[p.index], c , ADD);

    }



  



  }
  
  color blendIfColor(color c1, color c2, int mode) {
    if (c2 != 0) {
      return blendColor(c1, c2, mode);
    }
    return c1;
  }
  

      //   color c = 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 lx.hsb(0,0,0);
      //  // else if(spheremode ==2)
       // { color c = 0;
       //   return lx.hsb(CalcCone( (xyz by = new xyz(0,spherys[2].ybounce.getValuef(),0) ), Px, mid) );

       // }

  
       //   } 
        
  }
/*This just takes all of Dan Horwitz's code that I want to inherit and leaves the rest behind.
 A work in progress. */

public class APat extends SCPattern


{
  ArrayList<Pick>   picks  = new ArrayList<Pick>  ();
  ArrayList<DBool>  bools  = new ArrayList<DBool> ();

  PVector   mMax, mCtr, mHalf;

  MidiOutput  APCOut;
  int     nMaxRow   = 53;
  float   LastJog = -1;
  float[]   xWaveNz, yWaveNz;
  int     nPoint  , nPoints;
  PVector   xyzJog = new PVector(), modmin;

  float     NoiseMove = random(10000);
  BasicParameter  pSpark, pWave, pRotX, pRotY, pRotZ, pSpin, pTransX, pTransY;
  DBool     pXsym, pYsym, pRsym, pXdup, pXtrip, pJog, pGrey;

  float   lxh   ()                  { return lx.getBaseHuef();                      }
  int     c1c    (float a)              { return round(100*constrain(a,0,1));               }
  float     interpWv(float i, float[] vals)       { return interp(i-floor(i), vals[floor(i)], vals[ceil(i)]);     }
  void    setNorm (PVector vec)           { vec.set(vec.x/mMax.x, vec.y/mMax.y, vec.z/mMax.z);        }
  void    setRand (PVector vec)           { vec.set(random(mMax.x), random(mMax.y), random(mMax.z));      }
  void    setVec  (PVector vec, LXPoint p)        { vec.set(p.x, p.y, p.z);                       }
  void    interpolate(float i, PVector a, PVector b)  { a.set(interp(i,a.x,b.x), interp(i,a.y,b.y), interp(i,a.z,b.z));   }
  //void      StartRun(double deltaMs)          { }
  float     val   (BasicParameter p)          { return p.getValuef();                       }
  //color   CalcPoint(PVector p)            { return lx.hsb(0,0,0);                       }
  color   blend3(color c1, color c2, color c3)    { return blendColor(c1,blendColor(c2,c3,ADD),ADD);          }

  void  rotateZ (PVector p, PVector o, float nSin, float nCos) { p.set(    nCos*(p.x-o.x) - nSin*(p.y-o.y) + o.x    , nSin*(p.x-o.x) + nCos*(p.y-o.y) + o.y,p.z); }
  void  rotateX (PVector p, PVector o, float nSin, float nCos) { p.set(p.x,nCos*(p.y-o.y) - nSin*(p.z-o.z) + o.y    , nSin*(p.y-o.y) + nCos*(p.z-o.z) + o.z    ); }
  void  rotateY (PVector p, PVector o, float nSin, float nCos) { p.set(    nSin*(p.z-o.z) + nCos*(p.x-o.x) + o.x,p.y, nCos*(p.z-o.z) - nSin*(p.x-o.x) + o.z    ); }

  BasicParameter  addParam(String label, double value)  { BasicParameter p = new BasicParameter(label, value); addParameter(p); return p; }

  PVector   vT1 = new PVector(), vT2 = new PVector();
  float     calcCone (PVector v1, PVector v2, PVector c)  { vT1.set(v1); vT2.set(v2); vT1.sub(c); vT2.sub(c);
                                  return degrees(PVector.angleBetween(vT1,vT2)); }

  Pick    addPick(String name, int def, int _max, String[] desc) {
    Pick P    = new Pick(name, def, _max+1, nMaxRow, desc); 
    nMaxRow   = P.EndRow + 1;
    picks.add(P);
    return P;
  }

    boolean   noteOff(Note note) {
    int row = note.getPitch(), col = note.getChannel();
    for (int i=0; i<bools.size(); i++) if (bools.get(i).set(row, col, false)) { presetManager.dirty(this); return true; }
    updateLights(); return false;
  }

    boolean   noteOn(Note note) {
    int row = note.getPitch(), col = note.getChannel();
    for (int i=0; i<picks.size(); i++) if (picks.get(i).set(row, col))        { presetManager.dirty(this); return true; }
    for (int i=0; i<bools.size(); i++) if (bools.get(i).set(row, col, true))  { presetManager.dirty(this); return true; }
    println("row: " + row + "  col:   " + col); return false;
  }

  void    onInactive()      { uiDebugText.setText(""); }
  void    onReset()         {
    for (int i=0; i<bools .size(); i++) bools.get(i).reset();
    for (int i=0; i<picks .size(); i++) picks.get(i).reset();
    presetManager.dirty(this); 
    updateLights(); 
  }

  APat(GLucose glucose) {
    super(glucose);

    

    nPoints   = model.points.size();
    pXsym     = new DBool("X-SYM", false, 48, 0); bools.add(pXsym );
    pYsym     = new DBool("Y-SYM", false, 48, 1); bools.add(pYsym );
    pRsym     = new DBool("R-SYM", false, 48, 2); bools.add(pRsym );
    pXdup   = new DBool("X-DUP", false, 48, 3); bools.add(pXdup );
    pJog    = new DBool("JOG"  , false, 48, 4); bools.add(pJog  );
    pGrey   = new DBool("GREY" , false, 48, 5); bools.add(pGrey );

    modmin    = new PVector(model.xMin, model.yMin, model.zMin);
    mMax    =   new PVector(model.xMax, model.yMax, model.zMax); mMax.sub(modmin);
    mCtr    =   new PVector(); mCtr.set(mMax); mCtr.mult(.5);
    mHalf   =   new PVector(.5,.5,.5);
    xWaveNz   = new float[ceil(mMax.y)+1];
    yWaveNz   = new float[ceil(mMax.x)+1];

    //println (model.xMin + " " + model.yMin + " " +  model.zMin);
    //println (model.xMax + " " + model.yMax + " " +  model.zMax);
    //for (MidiOutputDevice o: RWMidi.getOutputDevices()) { if (o.toString().contains("APC")) { APCOut = o.createOutput(); break;}}
  }

  float spin() {
    float raw = val(pSpin);
    if (raw <= 0.45) {
      return raw + 0.05;
    } else if (raw >= 0.55) {
      return raw - 0.05;
    }
    return 0.5;
  }
  
  void setAPCOutput(MidiOutput output) {
    APCOut = output;
  }

  void updateLights() { if (APCOut == null) return;
      for (int i = 0; i < NumApcRows; ++i) 
        for (int j = 0; j < 8; ++j)     APCOut.sendNoteOn(j, 53+i,  0);
    for (int i=0; i<picks .size(); i++)   APCOut.sendNoteOn(picks.get(i).CurCol, picks.get(i).CurRow, 3);
    for (int i=0; i<bools .size(); i++)   if (bools.get(i).b)   APCOut.sendNoteOn (bools.get(i).col, bools.get(i).row, 1);
                        else          APCOut.sendNoteOff  (bools.get(i).col, bools.get(i).row, 0);
  }

  void run(double deltaMs)
  {
    if (deltaMs > 100) return;

    if (this == midiEngine.getFocusedDeck().getActivePattern()) {
      String Text1="", Text2="";
      for (int i=0; i<bools.size(); i++) if (bools.get(i).b) Text1 += " " + bools.get(i).tag       + "   ";
      for (int i=0; i<picks.size(); i++) Text1 += picks.get(i).tag + ": " + picks.get(i).CurDesc() + "   ";
      uiDebugText.setText(Text1, Text2);
    }

    
  }
}

class CubeCurl extends SCPattern{
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);

CubeCurl(GLucose glucose){
super(glucose);
addModulator(curl).trigger();
addModulator(bg).trigger();
 this.CH = Cube.EDGE_HEIGHT;
 this.CW = Cube.EDGE_WIDTH;
 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(new PVector(a.cx, a.cy, a.cz) );
  
} 

}
//there is definitely a better way of doing this!
PVector centerofcube(int i) { 
Cube c = model.cubes.get(i);
PVector cubecenter = new PVector(c.cx, c.cy, c.cz);

return cubecenter;
}


void run(double deltaMs){
for (int i =0; i < model.cubes.size(); i++)  {
Cube c = model.cubes.get(i);
float cfloor = c.y;

// if (i%3 == 0){

// for (LXPoint 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) {
  
//  for (LXPoint 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 (LXPoint 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),  );


    }


  //}

   }
  }
 }

 class HueTestHSB extends SCPattern{
  BasicParameter HueT = new BasicParameter("Hue", .5);
  BasicParameter SatT = new BasicParameter("Sat", .5);
  BasicParameter BriT = new BasicParameter("Bright", .5);

HueTestHSB(GLucose glucose) {
  super(glucose);
  addParameter(HueT);
  addParameter(SatT);
  addParameter(BriT);
}
  void run(double deltaMs){

  for (LXPoint p : model.points) {
    color c = 0;
    c = blendColor(c, lx.hsb(360*HueT.getValuef(), 100*SatT.getValuef(), 100*BriT.getValuef()), ADD);
    colors[p.index]= c;
  }
   int now= millis();
   if (now % 1000 <= 20)
   {
   println("Hue: " + 360*HueT.getValuef() + "Sat: " + 100*SatT.getValuef() + "Bright:  " + 100*BriT.getValuef());
   }
  }

 }