X-Git-Url: http://git.megacz.com/?p=anneal.git;a=blobdiff_plain;f=src%2Fedu%2Fberkeley%2Fqfat%2FMesh.java;h=fd73795255f4915d2c1eff3c8d4e2ac1b80ea99f;hp=02f589ed6f42a5b140a33dc7b3fe060d11754f19;hb=0e80eb500d944f8ad1f3a9e2d296d9a4cbcd7e25;hpb=4561a5ff23ca77f6deb217d3cff6253057735d30 diff --git a/src/edu/berkeley/qfat/Mesh.java b/src/edu/berkeley/qfat/Mesh.java index 02f589e..fd73795 100644 --- a/src/edu/berkeley/qfat/Mesh.java +++ b/src/edu/berkeley/qfat/Mesh.java @@ -6,6 +6,7 @@ import javax.swing.*; 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; @@ -44,12 +45,14 @@ public class Mesh implements Iterable { t.e2().dobind(); t.e3().dobind(); } + System.out.println("rebound!"); } public void transform(Matrix m) { ArrayList set = new ArrayList(); for(Vertex v : vertices) set.add(v); - for(Vertex v : set) v.transform(m.times(v.p), true); + for(Vertex v : set) v.transform(m.times(v.p), true, null); + for(Vertex v : set) v.goodp = v.p; } public void rebuild() { /*vertices.rebuild();*/ } @@ -75,19 +78,21 @@ public class Mesh implements Iterable { /** a vertex in the mesh */ public final class Vertex extends HasQuadric implements Visitor { - public Point p, oldp, goodp; + public Point p, goodp; + public Point oldp; E e; // some edge *leaving* this point - Matrix binding = Matrix.ONE; - Vertex bound_to = this; private boolean illegal = false; + public boolean visible = false; + public Point getPoint() { return p; } public float error() { return olderror; } private Vertex(Point p) { this.p = p; this.goodp = p; + this.oldp = p; if (vertices.get(p) != null) throw new Error(); vertices.add(this); } @@ -105,6 +110,22 @@ public class Mesh implements Iterable { error += olderror; } + /* + public Vertex hack(GL gl, Point mouse) { + double dist = Double.MAX_VALUE; + Vertex cur = null; + for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) { + Vertex v = e.getOther(this); + double dist2 = v.getPoint().glProject(gl).distance(mouse); + if ((cur==null || dist2 < dist) && v.visible) { + dist = dist2; + cur = v; + } + } + return cur; + } + */ + public float averageTriangleArea() { int count = 0; float ret = 0; @@ -131,6 +152,10 @@ public class Mesh implements Iterable { m = m.plus(e.t.norm().fundamentalQuadric(e.t.centroid())); count++; } + if (count > 0) { + m = m.plus(norm().fundamentalQuadric(this.p).times(count)); + count *= 2; + } return m.times(1/(float)count); } @@ -144,47 +169,124 @@ public class Mesh implements Iterable { if (quadric_count != 0) nerror = (nerror + quadric.preAndPostMultiply(p))/(quadric_count+1); + if (!immutableVertices && quadric_count == 0) { + //nerror = Math.max(nerror, 0.4f); + //nerror *= 2; + } + //System.out.println(nerror); for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) { - double ang = Math.abs(e.dihedralAngle()); + double ang = e.dihedralAngle(); if (ang > Math.PI) throw new Error(); + if (ang < -Math.PI) throw new Error(); float minangle = (float)(Math.PI * 0.8); + //nerror += ((ang / Math.PI)*(ang/Math.PI)) * e.length() * 0.05; + + nerror += (1-e.t.quality())*0.0001; if (ang > minangle) nerror += (ang - minangle); + + //System.out.println(((ang / Math.PI)*(ang/Math.PI)) * 0.000001); /* if (e.t.aspect() < 0.2) { nerror += (0.2-e.t.aspect()) * 10; } */ } + if (!immutableVertices) { + Vertex n = (Vertex)nearest(); + float d = norm().dot(n.norm()); + if (d > 1 || d < -1) throw new Error(); + if (d >= 0) { + nerror *= (2.0f - d); + } else { + nerror += 0.0003 * (2.0f + d); + nerror *= (2.0f + d); + } + } setError(nerror); } 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); + + // t1' = M * t1 + // t2' = t2.getMatrix(t1) * t1' + // t2' = t2.getMatrix(t1) * M * t1 + // t1 = t1.getMatrix(t2) * t2 + // M * t1 = M * t1.getMatrix(t2) * t2 + + if (bindingGroup!=null && this != bindingGroup.getMaster()) { + Matrix v = getBindingMatrix(bindingGroup.getMaster()); + return ((Vertex)bindingGroup.getMaster()).move(v.inverse().times(m).times(v), ignoreProblems); + } + + if (bindingGroup != null) { + Matrix m2 = null; + for(int i=0; i<20 && !m.equals(m2); i++) { + m2 = m.times(getConstraint()); + //System.out.println(m.minus(m2)); + } + if (!m.equals(m2)) return true; + } + ok = false; + Point op = this.p; + Point pt = m.times(this.p); + for(Vertex v : (Iterable)getBoundPeers()) { + Point pt2 = v.getBindingMatrix(this).times(pt); + /* + if (Math.abs( v.p.minus(pt2).mag() / pt.minus(op).mag() ) > 5) + throw new Error(v.p+" "+pt2+"\n"+op+" "+pt+"\n"+v.getBindingMatrix(this)); + if (Math.abs( v.p.minus(pt2).mag() / pt.minus(op).mag() ) < 1/5) throw new Error(); + */ + good &= v.transform(pt2, ignoreProblems, v.getBindingMatrix(this)); + } + + if (!good && !ignoreProblems) { + for(Vertex v : (Iterable)getBoundPeers()) + v.transform(v.oldp, true, null); + } + + for(Vertex v : (Iterable)getBoundPeers()) + v.recomputeFundamentalQuadricIfNeighborChanged(); + for(Vertex v : (Iterable)getBoundPeers()) + v.reComputeErrorAround(); + ok = true; return good; } + public boolean ok = true; /** does NOT update bound pairs! */ - private boolean transform(Point newp, boolean ignoreProblems) { + private boolean transform(Point newp, boolean ignoreProblems, Matrix yes) { this.oldp = this.p; if (immutableVertices) throw new Error(); unApplyQuadricToNeighbor(); + + + boolean illegalbefore = illegal; + illegal = false; + /* + if (this.p.minus(newp).mag() > 0.1 && !ignoreProblems) { + try { + throw new Exception(""+this.p.minus(newp).mag()+" "+ignoreProblems+" "+yes); + } catch(Exception e) { + e.printStackTrace(); + } + illegal = true; + } + */ + this.p = newp; reinsert(); applyQuadricToNeighbor(); if (!ignoreProblems) { - illegal = false; checkLegality(); } - for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) e.p2.quadricStale = true; - return !illegal; + for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) + e.p2.quadricStale = true; + return !illegal || (illegalbefore && illegal); } public void checkLegality() { @@ -192,7 +294,7 @@ public class Mesh implements Iterable { for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) { 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 (e.t.aspect() < 0.2) illegal = true; } */ if (!illegal) triangles.range(oldp, this.p, (Visitor)this); @@ -222,6 +324,7 @@ public class Mesh implements Iterable { return !illegal; } + public E getEdge() { return e; } public E getFreeIncident() { E ret = getFreeIncident(e, e); if (ret != null) return ret; @@ -260,80 +363,55 @@ public class Mesh implements Iterable { 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 { - private HashSet set = new HashSet(); - public BindingGroup bind_others; - public BindingGroup other() { return bind_others; } - public BindingGroup(BindingGroup bind_others) { this.bind_others = bind_others; } - public BindingGroup() { this.bind_others = new BindingGroup(this); } - public BindingGroup(E e) { this(); set.add(e); } - public void add(E e) { - if (set.contains(e)) return; - set.add(e); - BindingGroup e_bind_peers = e.bind_peers; - BindingGroup e_bind_to = e.bind_to; - e.bind_peers = this; - e.bind_to = bind_others; - for (E epeer : e_bind_peers.set) add(epeer); - for (E eother : e_bind_to.set) bind_others.add(eother); - - for(E eother : bind_others.set) { - if (e.next.bind_to.set.contains(eother.prev)) { - e.next.next.bindEdge(eother.prev.prev); - } - if (e.prev.bind_to.set.contains(eother.next)) { - e.prev.prev.bindEdge(eother.next.next); - } - } - - } - public void dobind(E e) { - for(E ebound : set) { - e.p1.bind(ebound.p2); - e.p2.bind(ebound.p1); - } - } - public void shatter(BindingGroup bg1, BindingGroup bg2) { - for(E e : set) { - e.shatter(e.midpoint(), bg1, bg2); - } - } - } /** [UNIQUE] an edge */ - public final class E implements Comparable { + public final class E extends HasBindingGroup implements Comparable { public final Vertex p1, p2; T t; // triangle to our "left" E prev; // previous half-edge E next; // next half-edge E pair; // partner half-edge - public BindingGroup bind_peers = new BindingGroup(this); - public BindingGroup bind_to = bind_peers.other(); boolean shattered = false; public boolean intersects(T t) { return t.intersects(p1.p, p2.p); } + public Segment getSegment() { return new Segment(p1.getPoint(), p2.getPoint()); } + + public void bindingGroupChanged(edu.berkeley.qfat.geom.BindingGroup newBindingGroup_) { + + edu.berkeley.qfat.geom.BindingGroup newBindingGroup = + (edu.berkeley.qfat.geom.BindingGroup)newBindingGroup_; + if (newBindingGroup==null) return; + if (this==newBindingGroup.getMaster()) return; + HashSet nbg = new HashSet(); + for(E eother : (Iterable)newBindingGroup) nbg.add(eother); + for(E eother : nbg) { + if (next==null || prev==null) continue; + if (eother.next==null || eother.prev==null) continue; + + if (next.isBoundTo(eother.pair.prev.pair) && !prev.isBoundTo(eother.pair.next.pair)) + prev.bindTo(next.getBindingMatrix(eother.pair.prev.pair), eother.pair.next.pair); + if (!next.isBoundTo(eother.pair.prev.pair) && prev.isBoundTo(eother.pair.next.pair)) + next.bindTo(prev.getBindingMatrix(eother.pair.next.pair), eother.pair.prev.pair); + + /* + if (next.isBoundTo(eother.prev) && !prev.isBoundTo(eother.next)) + prev.bindTo(next.getBindingMatrix(eother.prev), eother.next); + if (!next.isBoundTo(eother.prev) && prev.isBoundTo(eother.next)) + next.bindTo(prev.getBindingMatrix(eother.next), eother.prev); + */ + if (next.isBoundTo(eother.next) && !prev.isBoundTo(eother.prev)) + prev.bindTo(next.getBindingMatrix(eother.next), eother.prev); + if (!next.isBoundTo(eother.next) && prev.isBoundTo(eother.prev)) + next.bindTo(prev.getBindingMatrix(eother.prev), eother.next); + } + + } + public float stretchRatio() { Vertex nearest = error_against.nearest(midpoint()); float nearest_distance = midpoint().distance(nearest.p); @@ -343,40 +421,95 @@ public class Mesh implements Iterable { 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 void bindEdge(E e, Matrix m) { + _bindEdge(e, m); + pair._bindEdge(e.pair, m); + } + public void _bindEdge(E e, Matrix m) { + e = e.pair; + /* + //assumes edges are identical length at binding time + Vec reflectionPlaneNormal = e.p2.p.minus(e.p1.p).norm(); + float a = reflectionPlaneNormal.x; + float b = reflectionPlaneNormal.y; + float c = reflectionPlaneNormal.z; + Matrix reflectionMatrix = + new Matrix( 1-2*a*a, -2*a*b, -2*a*c, 0, + -2*a*b, 1-2*b*b, -2*b*c, 0, + -2*a*c, -2*b*c, 1-2*c*c, 0, + 0, 0, 0, 1); + m = m.times(Matrix.translate(e.midpoint().minus(Point.ORIGIN)) + .times(reflectionMatrix) + .times(Matrix.translate(Point.ORIGIN.minus(e.midpoint())))); + System.out.println(reflectionPlaneNormal); + System.out.println(" " + p1.p + " " + m.times(e.p1.p)); + System.out.println(" " + p2.p + " " + m.times(e.p2.p)); + */ + /* + if (m.times(e.p1.p).minus(p1.p).mag() > EPSILON) throw new Error(); + if (m.times(e.p2.p).minus(p2.p).mag() > EPSILON) throw new Error(); + */ + this.bindTo(m, e); + } + + public void dobind() { + for(E e : (Iterable)getBoundPeers()) { + if (e==this) continue; + p1.bindTo(getBindingMatrix(e), e.p1); + p2.bindTo(getBindingMatrix(e), e.p2); + e.p1.setConstraint(getConstraint()); + e.p2.setConstraint(getConstraint()); + } + } - public Point shatter() { return shatter(midpoint(), null, null); } - public Point shatter(Point mid, BindingGroup bg1, BindingGroup bg2) { - if (shattered || destroyed) return mid; + public Point shatter() { + if (shattered || destroyed) return null; shattered = true; - - Vertex r = next.p2; - E next = this.next; - E prev = this.prev; - - int old_colorclass = t==null ? 0 : t.colorclass; - 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()); - 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); - return mid; + E first = null; + E firste = null; + E firstx = null; + E firstq = null; + for(E e : (Iterable)getBoundPeers()) { + E enext = e.next; + E eprev = e.prev; + E pnext = e.pair.next; + E pprev = e.pair.prev; + Point mid = e.midpoint(); + Vertex r = e.next.p2; + Vertex l = e.pair.next.p2; + if (!e.destroyed) { + e.destroy(); + e.pair.destroy(); + newT(r.p, e.p1.p, mid, null, 0); + newT(r.p, mid, e.p2.p, null, 0); + newT(l.p, mid, e.p1.p, null, 0); + newT(l.p, e.p2.p, mid, null, 0); + } + } + for(E e : (Iterable)getBoundPeers()) { + Point mid = e.midpoint(); + if (first==null) { + first = e.p1.getE(mid); + firste = e; + firstx = e.pair; + firstq = e.p2.getE(mid).pair; + continue; + } + e.p1.getE(mid). bindTo(e.getBindingMatrix(firste), first); + e.p1.getE(mid).pair. bindTo(e.getBindingMatrix(firste), first.pair); + e.p2.getE(mid).pair. bindTo(e.getBindingMatrix(firste), firstq); + e.p2.getE(mid).pair.pair.bindTo(e.getBindingMatrix(firste), firstq.pair); + } + /* + first.setConstraint(firste.getConstraint()); + firstq.setConstraint(firste.getConstraint()); + */ + return null; } public boolean destroyed = false; @@ -401,10 +534,6 @@ public class Mesh implements Iterable { pair.next.t = null; pair.prev.t = null; - this.bind_to = null; - pair.bind_to = null; - this.bind_peers = null; - pair.bind_peers = null; pair.prev.next = next; next.prev = pair.prev; prev.next = pair.next; @@ -417,7 +546,6 @@ public class Mesh implements Iterable { this.prev.next = this; this.next.prev = this; this.pair.pair = this; - bind_peers.add(this); if (this.next.p1 != p2) throw new Error(); if (this.prev.p2 != p1) throw new Error(); if (this.p1.e == null) this.p1.e = this; @@ -430,7 +558,12 @@ public class Mesh implements Iterable { public double dihedralAngle() { Vec v1 = t.norm().times(-1); Vec v2 = pair.t.norm().times(-1); - return Math.acos(v1.norm().dot(v2.norm())); + double prod = v1.norm().dot(v2.norm()); + prod = Math.min(1,prod); + prod = Math.max(-1,prod); + double ret = Math.acos(prod); + if (Double.isNaN(ret)) throw new Error("nan! " + prod); + return ret; } /** angle between this half-edge and the next */ @@ -440,10 +573,16 @@ public class Mesh implements Iterable { return Math.acos(v1.norm().dot(v2.norm())); } + public Vertex getOther(Vertex v) { + if (this.p1 == v) return p2; + if (this.p2 == v) return p1; + throw new Error(); + } + public void makeAdjacent(E e) { if (this.next == e) return; if (p2 != e.p1) throw new Error("cannot make adjacent -- no shared vertex"); - if (t != null || e.t != null) throw new Error("cannot make adjacent -- edges not both free"); + if (t != null || e.t != null) throw new Error("cannot make adjacent -- edges not both free "); E freeIncident = p2.getFreeIncident(e, this); @@ -524,7 +663,22 @@ public class Mesh implements Iterable { if (v2 != null) return new E(v2.getFreeIncident(), p1).pair; return new E(p1, p2); } + public boolean coalesce = false; + private static float round(float f) { + return Math.round(f*1000)/1000f; + } public T newT(Point p1, Point p2, Point p3, Vec norm, int colorclass) { + if (coalesce) { + + for(Vertex v : vertices) { if (p1.distance(v.p) < EPSILON) { p1 = v.p; break; } } + for(Vertex v : vertices) { if (p2.distance(v.p) < EPSILON) { p2 = v.p; break; } } + for(Vertex v : vertices) { if (p3.distance(v.p) < EPSILON) { p3 = v.p; break; } } + /* + p1 = new Point(round(p1.x), round(p1.y), round(p1.z)); + p2 = new Point(round(p2.x), round(p2.y), round(p2.z)); + p3 = new Point(round(p3.x), round(p3.y), round(p3.z)); + */ + } if (norm != null) { Vec norm2 = p3.minus(p1).cross(p2.minus(p1)); float dot = norm.dot(norm2); @@ -546,12 +700,16 @@ public class Mesh implements Iterable { return ret; } + private int max_serial = 0; /** [UNIQUE] a triangle (face) */ public final class T extends Triangle { public final E e1; public final int color; public final int colorclass; + public final int serial = max_serial++; + public boolean occluded; + T(E e1, int colorclass) { this.e1 = e1; E e2 = e1.next; @@ -595,23 +753,26 @@ public class Mesh implements Iterable { public void reinsert() { triangles.remove(this); triangles.add(this); } public boolean shouldBeDrawn() { - 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; + + if (e1().bindingGroupSize() <= 1) return false; + if (e2().bindingGroupSize() <= 1) return false; + if (e3().bindingGroupSize() <= 1) return false; + return true; } + public void glTriangle(GL gl, Matrix m) { + gl.glPushName(serial); + gl.glBegin(GL.GL_TRIANGLES); + glVertices(gl, m); + gl.glEnd(); + gl.glPopName(); + } + /** issue gl.glVertex() for each of the triangle's points */ - public void glVertices(GL gl) { + public void glVertices(GL gl, Matrix m) { 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); + super.glVertices(gl, m); } - } }