import javax.media.opengl.*;
import javax.media.opengl.glu.*;
import edu.berkeley.qfat.geom.*;
+import edu.berkeley.qfat.geom.HasBindingGroup;
import edu.wlu.cs.levy.CG.KDTree;
import edu.berkeley.qfat.geom.Point;
import com.infomatiq.jsi.IntProcedure;
/** a vertex in the mesh */
public final class Vertex extends HasQuadric implements Visitor {
- public Point p, oldp;
+ public Point p, oldp, goodp;
E e; // some edge *leaving* this point
- Matrix binding = Matrix.ONE;
- Vertex bound_to = this;
private boolean illegal = false;
public Point getPoint() { return p; }
private Vertex(Point p) {
this.p = p;
+ this.goodp = p;
if (vertices.get(p) != null) throw new Error();
vertices.add(this);
}
error += olderror;
}
+ public float averageTriangleArea() {
+ int count = 0;
+ float ret = 0;
+ for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) {
+ ret += e.t.area();
+ count++;
+ }
+ return ret/count;
+ }
+ public float averageEdgeLength() {
+ int count = 0;
+ float ret = 0;
+ for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) {
+ ret += e.length();
+ count++;
+ }
+ return ret/count;
+ }
+
public Matrix _recomputeFundamentalQuadric() {
Matrix m = Matrix.ZERO;
int count = 0;
public HasQuadric nearest() { return error_against==null ? null : error_against.vertices.nearest(p, this); }
public void computeError() {
+ if (error_against==null) return;
float nerror =
- quadric_count != 0
- ? (quadric.preAndPostMultiply(p) * 100) / quadric_count
- : nearest_in_other_mesh != null
- ? nearest_in_other_mesh.fundamentalQuadric().preAndPostMultiply(p) * 100 * 10
- : error_against != null
- ? nearest().fundamentalQuadric().preAndPostMultiply(p) * 100 * 10
- : 0;
+ nearest_in_other_mesh != null
+ ? nearest_in_other_mesh.fundamentalQuadric().preAndPostMultiply(p)
+ : nearest().fundamentalQuadric().preAndPostMultiply(p);
+ if (quadric_count != 0)
+ nerror = (nerror + quadric.preAndPostMultiply(p))/(quadric_count+1);
+
for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) {
- double ang = Math.abs(e.crossAngle());
+ double ang = Math.abs(e.dihedralAngle());
if (ang > Math.PI) throw new Error();
float minangle = (float)(Math.PI * 0.8);
if (ang > minangle) nerror += (ang - minangle);
+ /*
+ if (e.t.aspect() < 0.2) {
+ nerror += (0.2-e.t.aspect()) * 10;
+ }
+ */
}
+
setError(nerror);
}
+ public boolean move(Matrix m, boolean ignoreProblems) {
+ boolean good = true;
+
+ for(Vertex p : (Iterable<Vertex>)getBoundPeers())
+ good &= p.transform(m.times(p.p), ignoreProblems);
+
+ for(Vertex p : (Iterable<Vertex>)getBoundPeers())
+ if (good || ignoreProblems) p.reComputeErrorAround();
+ else p.transform(p.oldp, true);
+
+ return good;
+ }
+
/** does NOT update bound pairs! */
private boolean transform(Point newp, boolean ignoreProblems) {
this.oldp = this.p;
}
public void checkLegality() {
+ /*
for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) {
- if (Math.abs(e.crossAngle()) > (Math.PI * 0.9) || Math.abs(e.next.crossAngle()) > (Math.PI * 0.9)) illegal = true;
+ if (Math.abs(e.dihedralAngle()) > (Math.PI * 0.9) ||
+ Math.abs(e.next.dihedralAngle()) > (Math.PI * 0.9)) illegal = true;
if (e.t.aspect() < 0.1) illegal = true;
}
- if (illegal) triangles.range(oldp, this.p, (Visitor<T>)this);
+ */
+ if (!illegal) triangles.range(oldp, this.p, (Visitor<T>)this);
}
public void reComputeErrorAround() {
return !illegal;
}
- public boolean move(Matrix m, boolean ignoreProblems) {
- boolean good = true;
- for(Vertex p = this; p != null; p = (p.bound_to==this)?null:p.bound_to)
- good &= p.transform(m.times(p.p), ignoreProblems);
- for(Vertex p = this; p != null; p = (p.bound_to==this)?null:p.bound_to)
- if (good || ignoreProblems) p.reComputeErrorAround();
- else p.transform(p.oldp, true);
- return good;
- }
-
public E getFreeIncident() {
E ret = getFreeIncident(e, e);
if (ret != null) return ret;
return norm.norm();
}
- public boolean isBoundTo(Vertex p) {
- for(Vertex px = p; px!=null; px=(px.bound_to==p?null:px.bound_to))
- if (px==this)
- return true;
- return false;
- }
-
- public void unbind() { bound_to = this; binding = Matrix.ONE; }
- public void bind(Vertex p) { bind(p, Matrix.ONE); }
- public void bind(Vertex p, Matrix binding) {
- if (isBoundTo(p)) return;
- Vertex temp_bound_to = p.bound_to;
- Matrix temp_binding = p.binding;
- p.bound_to = this.bound_to;
- p.binding = binding.times(this.binding); // FIXME: may have order wrong here
- this.bound_to = temp_bound_to;
- this.binding = temp_binding.times(temp_binding); // FIXME: may have order wrong here
- }
+ public void bindTo(Vertex p) { bindTo(Matrix.ONE, p); }
}
public class BindingGroup {
}
public void dobind(E e) {
for(E ebound : set) {
- e.p1.bind(ebound.p2);
- e.p2.bind(ebound.p1);
+ e.p1.bindTo(Matrix.ONE, ebound.p2);
+ e.p2.bindTo(Matrix.ONE, ebound.p1);
}
}
- public void shatter(BindingGroup bg1, BindingGroup bg2) {
+ public void shatter(BindingGroup bg1, BindingGroup bg2, boolean triangles) {
for(E e : set) {
- e.shatter(e.midpoint(), bg1, bg2);
+ e.shatter(e.midpoint(), bg1, bg2, triangles);
}
}
}
/** [UNIQUE] an edge */
- public final class E implements Comparable<E> {
+ public final class E extends HasBindingGroup implements Comparable<E> {
public final Vertex p1, p2;
T t; // triangle to our "left"
boolean shattered = false;
public boolean intersects(T t) { return t.intersects(p1.p, p2.p); }
- public float comparator() {
+
+ public void bindingGroupChanged(edu.berkeley.qfat.geom.BindingGroup newBindingGroup_) {
+ edu.berkeley.qfat.geom.BindingGroup<E> newBindingGroup = (edu.berkeley.qfat.geom.BindingGroup<E>)newBindingGroup_;
+ if (newBindingGroup==null) return;
+ if (this==newBindingGroup.getMaster()) return;
+ for(E eother : (Iterable<E>)newBindingGroup) {
+ this.next.bindTo(newBindingGroup.getMatrix(eother), eother.next);
+ this.prev.bindTo(newBindingGroup.getMatrix(eother), eother.prev);
+ }
+ }
+
+ public float stretchRatio() {
Vertex nearest = error_against.nearest(midpoint());
- return (float)Math.max(length(), midpoint().distance(nearest.p));
+ float nearest_distance = midpoint().distance(nearest.p);
+ float other_distance =
+ (p1.p.distance(error_against.nearest(p1.p).p)+
+ p2.p.distance(error_against.nearest(p2.p).p))/2;
+ return nearest_distance/other_distance;
+ }
+ public float comparator() {
+ return length();
+ //return t==null?0:(1/t.aspect());
}
public int compareTo(E e) {
return e.comparator() > comparator() ? 1 : -1;
public void bindEdge(E e) { bind_to.add(e); }
public void dobind() { bind_to.dobind(this); }
- public Point shatter() { return shatter(midpoint(), null, null); }
- public Point shatter(Point mid, BindingGroup bg1, BindingGroup bg2) {
+ public Point shatter() { return shatter(true); }
+ public Point shatter(boolean triangles) { return shatter(midpoint(), null, null, triangles); }
+ public Point shatter(Point mid, BindingGroup bg1, BindingGroup bg2, boolean triangles) {
+ return shatter(mid, bg1, bg2, triangles, false);
+ }
+ public Point shatter(Point mid, BindingGroup bg1, BindingGroup bg2, boolean triangles, boolean leader) {
if (shattered || destroyed) return mid;
shattered = true;
if (bg1==null) bg1 = new BindingGroup();
if (bg2==null) bg2 = new BindingGroup();
BindingGroup old_bind_to = bind_to;
- bind_peers.shatter(bg1, bg2);
- old_bind_to.shatter(bg2.other(), bg1.other());
+ bind_peers.shatter(bg1, bg2, triangles);
+ old_bind_to.shatter(bg2.other(), bg1.other(), triangles);
+ if (!triangles) {
+ next.shatter(false);
+ prev.shatter(false);
+ }
pair.shatter();
destroy();
- newT(r.p, p1.p, mid, null, old_colorclass);
- newT(r.p, mid, p2.p, null, old_colorclass);
- bg1.add(p1.getE(mid));
- bg2.add(p2.getE(mid).pair);
+ if (triangles) {
+ newT(r.p, p1.p, mid, null, old_colorclass);
+ newT(r.p, mid, p2.p, null, old_colorclass);
+ bg1.add(p1.getE(mid));
+ bg2.add(p2.getE(mid).pair);
+ if (leader) p1.getE(mid).shatter();
+ }
return mid;
}
public T makeT(int colorclass) { return t==null ? (t = new T(this, colorclass)) : t; }
- public double crossAngle() {
+ public double dihedralAngle() {
Vec v1 = t.norm().times(-1);
Vec v2 = pair.t.norm().times(-1);
return Math.acos(v1.norm().dot(v2.norm()));
public void reinsert() { triangles.remove(this); triangles.add(this); }
public boolean shouldBeDrawn() {
+ if (e1().bind_to==null) return false;
+ if (e2().bind_to==null) return false;
+ if (e3().bind_to==null) return false;
if (e1().bind_to.set.size() == 0) return false;
if (e2().bind_to.set.size() == 0) return false;
if (e3().bind_to.set.size() == 0) return false;
return true;
}
+ /** issue gl.glVertex() for each of the triangle's points */
+ public void glVertices(GL gl) {
+ if (!shouldBeDrawn()) return;
+ norm().glNormal(gl);
+ Point p1 = v1().goodp;
+ Point p2 = v2().goodp;
+ Point p3 = v3().goodp;
+ p1.glVertex(gl);
+ p2.glVertex(gl);
+ p3.glVertex(gl);
+ }
+
}
}