X-Git-Url: https://git.piment-noir.org/?p=SugarCubes.git;a=blobdiff_plain;f=ShaheenGandhi.pde;h=cda8fed4358c5b18302cdce3c6394179456a11c4;hp=c25badd6a262ed99000ba8a86882138d93d89e5f;hb=e0b9d8726c661f54f47340449037ac7f6b410de6;hpb=ee1f21c7b393e36fe80d72398206cd03df665052

diff --git a/ShaheenGandhi.pde b/ShaheenGandhi.pde
index c25badd..cda8fed 100644
--- a/ShaheenGandhi.pde
+++ b/ShaheenGandhi.pde
@@ -40,13 +40,17 @@ class HelixPattern extends SCPattern {
       return getPointAt(getTValue(pt));
     }
 
-    PVector rotatePoint(final PVector pt, final float rads) {
-      Vec3D axisVec3D = new Vec3D(vector.x, vector.y, vector.z);
-      Matrix4x4 mat = new Matrix4x4();
-      mat.rotateAroundAxis(axisVec3D, rads);
-      Vec3D ptVec3D = new Vec3D(pt.x, pt.y, pt.z);
-      Vec3D rotatedPt = mat.applyTo(ptVec3D);
-      return new PVector(rotatedPt.x, rotatedPt.y, rotatedPt.z);
+    PVector rotatePoint(final PVector p, final float t) {
+      final PVector o = origin;
+      final PVector v = vector;
+      
+      final float cost = cos(t);
+      final float sint = sin(t);
+
+      float x = (o.x*(v.y*v.y + v.z*v.z) - v.x*(o.y*v.y + o.z*v.z - v.x*p.x - v.y*p.y - v.z*p.z))*(1 - cost) + p.x*cost + (-o.z*v.y + o.y*v.z - v.z*p.y + v.y*p.z)*sint;
+      float y = (o.y*(v.x*v.x + v.z*v.z) - v.y*(o.x*v.x + o.z*v.z - v.x*p.x - v.y*p.y - v.z*p.z))*(1 - cost) + p.y*cost + (o.z*v.x - o.x*v.z + v.z*p.x - v.x*p.z)*sint;
+      float z = (o.z*(v.x*v.x + v.y*v.y) - v.z*(o.x*v.x + o.y*v.y - v.x*p.x - v.y*p.y - v.z*p.z))*(1 - cost) + p.z*cost + (-o.y*v.x + o.x*v.y - v.y*p.x + v.x*p.y)*sint;
+      return new PVector(x, y, z);
     }
   }
 
@@ -87,103 +91,188 @@ class HelixPattern extends SCPattern {
       phaseNormal.mult(radius);
     }
 
-    private void setPhase(float phase) {
-      this.phase = phase;
-      setPhaseNormalFromPhase();
-    }
-
     Line getAxis() {
       return axis;
     }
+    
+    PVector getPhaseNormal() {
+      return phaseNormal;
+    }
+    
+    float getPhase() {
+      return phase;
+    }
 
-    void step(int deltaMs) {
+    void step(double deltaMs) {
       // Rotate
       if (rotationPeriod != 0) {
-        setPhase(phase + (deltaMs / rotationPeriod) * TWO_PI);
+        this.phase = (phase + ((float)deltaMs / (float)rotationPeriod) * TWO_PI);
       }
     }
 
     PVector pointOnToroidalAxis(float t) {
       PVector p = axis.getPointAt(t);
       PVector middle = PVector.add(p, phaseNormal);
-      return axis.rotatePoint(middle, (t / period) * TWO_PI);
+      return axis.rotatePoint(middle, (t / period) * TWO_PI + phase);
+    }
+    
+    private float myDist(PVector p1, PVector p2) {
+      final float x = p2.x-p1.x;
+      final float y = p2.y-p1.y;
+      final float z = p2.z-p1.z;
+      return sqrt(x*x + y*y + z*z);
     }
 
     color colorOfPoint(final PVector p) {
+      final float t = axis.getTValue(p);
+      final PVector axisPoint = axis.getPointAt(t);
+
+      // For performance reasons, cut out points that are outside of
+      // the tube where the toroidal coil lives.
+      if (abs(myDist(p, axisPoint) - radius) > girth*.5f) {
+        return lx.hsb(0,0,0);
+      }
+
       // Find the appropriate point for the current rotation
       // of the helix.
-      float t = axis.getTValue(projectedPoint);
-      PVector toroidPoint = pointOnToroidalAxis(t);
+      PVector toroidPoint = axisPoint;
+      toroidPoint.add(phaseNormal);
+      toroidPoint = axis.rotatePoint(toroidPoint, (t / period) * TWO_PI + phase);
 
       // The rotated point represents the middle of the girth of
       // the helix.  Figure out if the current point is inside that
       // region.
-      float d = PVector.dist(p, toroidPoint);
-      boolean inToroid = d < girth;
+      float d = myDist(p, toroidPoint);
 
-      // Soften edges by fading brightness
+      // Soften edges by fading brightness.
       float b = constrain(100*(1 - ((d-.5*girth)/(girth*.5))), 0, 100);
-      return color((lx.getBaseHuef() + (360*(phase / TWO_PI)))%360, (inToroid ? 80 : 0), b);
+      return lx.hsb((lx.getBaseHuef() + (360*(phase / TWO_PI)))%360, 80, b);
+    }
+  }
+  
+  private class BasePairInfo {
+    Line line;
+    float colorPhase1;
+    float colorPhase2;
+    
+    BasePairInfo(Line line, float colorPhase1, float colorPhase2) {
+      this.line = line;
+      this.colorPhase1 = colorPhase1;
+      this.colorPhase2 = colorPhase2;
     }
   }
 
   private final Helix h1;
   private final Helix h2;
+  private final BasePairInfo[] basePairs;
 
   private final BasicParameter helix1On = new BasicParameter("H1ON", 1);
   private final BasicParameter helix2On = new BasicParameter("H2ON", 1);
+  private final BasicParameter basePairsOn = new BasicParameter("BPON", 1);
 
-  public HelixPattern(GLucose glucose) {
-    super(glucose);
+  private static final float helixCoilPeriod = 100;
+  private static final float helixCoilRadius = 50;
+  private static final float helixCoilGirth = 30;
+  private static final float helixCoilRotationPeriod = 5000;
+
+  private static final float spokePeriod = 40;
+  private static final float spokeGirth = 20;
+  private static final float spokePhase = 10;
+  private static final float spokeRadius = helixCoilRadius - helixCoilGirth*.5f;
+  
+  private static final float tMin = -200;
+  private static final float tMax = 200;
+
+  public HelixPattern(LX lx) {
+    super(lx);
 
     addParameter(helix1On);
     addParameter(helix2On);
+    addParameter(basePairsOn);
+
+    PVector origin = new PVector(100, 50, 55);
+    PVector axis = new PVector(1,0,0);
 
     h1 = new Helix(
-      new Line(new PVector(100, 50, 70), new PVector(1,0,0)),
-      700, // period
-      50, // radius
-      30, // girth
-      0,  // phase
-      10000); // rotation period (ms)
+      new Line(origin, axis),
+      helixCoilPeriod,
+      helixCoilRadius,
+      helixCoilGirth,
+      0,
+      helixCoilRotationPeriod);
     h2 = new Helix(
-      new Line(new PVector(100, 50, 70), new PVector(1,0,0)),
-      700,
-      50,
-      30,
+      new Line(origin, axis),
+      helixCoilPeriod,
+      helixCoilRadius,
+      helixCoilGirth,
       PI,
-      10000);
-
-    // TODO(shaheen) calculate line segments between
-    // toroidal points selected by stepping the
-    // parameterized t value.  select base pairs and
-    // associated colors.  lerp between colors for each
-    // base pair to produce a DNA effect.
+      helixCoilRotationPeriod);
+      
+    basePairs = new BasePairInfo[(int)floor((tMax - tMin)/spokePeriod)];
+  }
 
+  private void calculateSpokes() {
+    float colorPhase = PI/6;
+    for (float t = tMin + spokePhase; t < tMax; t += spokePeriod) {
+      int spokeIndex = (int)floor((t - tMin)/spokePeriod);
+      PVector h1point = h1.pointOnToroidalAxis(t);
+      PVector spokeCenter = h1.getAxis().getPointAt(t);
+      PVector spokeVector = PVector.sub(h1point, spokeCenter);
+      Line spokeLine = new Line(spokeCenter, spokeVector);
+      basePairs[spokeIndex] = new BasePairInfo(spokeLine, colorPhase * spokeIndex, colorPhase * (spokeIndex + 1));
+    }
+  }
+  
+  private color calculateSpokeColor(final PVector pt) {
+    // Find the closest spoke's t-value and calculate its
+    // axis.  Until everything animates in the model reference
+    // frame, this has to be calculated at every step because
+    // the helices rotate.
+    Line axis = h1.getAxis();
+    float t = axis.getTValue(pt) + spokePhase;
+    int spokeIndex = (int)floor((t - tMin + spokePeriod/2) / spokePeriod);
+    if (spokeIndex < 0 || spokeIndex >= basePairs.length) {
+      return lx.hsb(0,0,0);
+    }
+    BasePairInfo basePair = basePairs[spokeIndex];
+    Line spokeLine = basePair.line;
+    PVector pointOnSpoke = spokeLine.projectPoint(pt);
+    float d = PVector.dist(pt, pointOnSpoke);
+    float b = (PVector.dist(pointOnSpoke, spokeLine.getPoint()) < spokeRadius) ? constrain(100*(1 - ((d-.5*spokeGirth)/(spokeGirth*.5))), 0, 100) : 0.f;
+    float phase = spokeLine.getTValue(pointOnSpoke) < 0 ? basePair.colorPhase1 : basePair.colorPhase2;
+    return lx.hsb((lx.getBaseHuef() + (360*(phase / TWO_PI)))%360, 80.f, b);
   }
 
-  void run(int deltaMs) {
+  void run(double deltaMs) {
     boolean h1on = helix1On.getValue() > 0.5;
     boolean h2on = helix2On.getValue() > 0.5;
+    boolean spokesOn = (float)basePairsOn.getValue() > 0.5;
 
     h1.step(deltaMs);
     h2.step(deltaMs);
+    calculateSpokes();
 
-    for (Point p : model.points) {
-      color h1c = color(0,0,0);
-      color h2c = color(0,0,0);
+    for (LXPoint p : model.points) {
+      PVector pt = new PVector(p.x,p.y,p.z);
+      color h1c = h1.colorOfPoint(pt);
+      color h2c = h2.colorOfPoint(pt);
+      color spokeColor = calculateSpokeColor(pt);
+
+      if (!h1on) {
+        h1c = lx.hsb(0,0,0);
+      }
 
-      if (h1on) {
-        h1c = h1.colorOfPoint(new PVector(p.x,p.y,p.z));
+      if (!h2on) {
+        h2c = lx.hsb(0,0,0);
       }
 
-      if (h2on) {
-        h2c = h2.colorOfPoint(new PVector(p.x,p.y,p.z));
+      if (!spokesOn) {
+        spokeColor = lx.hsb(0,0,0);
       }
 
       // The helices are positioned to not overlap.  If that changes,
       // a better blending formula is probably needed.
-      colors[p.index] = blendColor(h1c, h2c, ADD);
+      colors[p.index] = blendColor(blendColor(h1c, h2c, ADD), spokeColor, ADD);
     }
   }
 }