X-Git-Url: http://git.megacz.com/?p=anneal.git;a=blobdiff_plain;f=src%2Fedu%2Fberkeley%2Fqfat%2FMesh.java;h=7083d7669ba43c46a34037597509eb87557070f8;hp=0e594614a70001e35662711562e07c97e1acb188;hb=85bf586c55813abe79fab0476e2196700a6d0ea1;hpb=9e6eb545b0735cf21d6804bc68bb16c58fc0da61 diff --git a/src/edu/berkeley/qfat/Mesh.java b/src/edu/berkeley/qfat/Mesh.java index 0e59461..7083d76 100644 --- a/src/edu/berkeley/qfat/Mesh.java +++ b/src/edu/berkeley/qfat/Mesh.java @@ -8,47 +8,28 @@ import javax.media.opengl.glu.*; import edu.berkeley.qfat.geom.*; import edu.wlu.cs.levy.CG.KDTree; import edu.berkeley.qfat.geom.Point; +import com.infomatiq.jsi.IntProcedure; public class Mesh implements Iterable { public static final float EPSILON = (float)0.0001; public static final Random random = new Random(); - private PointSet pointset = new PointSet(); - - public Iterable vertices() { return pointset; } - - public Iterable edges() { - return - new Iterable() { - public Iterator iterator() { - // HACK - HashSet hse = new HashSet(); - for(T t : Mesh.this) { - hse.add(t.e1()); - hse.add(t.e2()); - hse.add(t.e3()); - hse.add(t.e1().pair); - hse.add(t.e2().pair); - hse.add(t.e3().pair); - } - return hse.iterator(); - } }; - } + private RTree triangles = new RTree(); + private PointSet vertices = new PointSet(); - public Iterator iterator() { - for(Vert v : pointset) - if (v.e != null && v.e.t != null) - return new FaceIterator(v); - return new FaceIterator(); - } + public boolean immutableVertices; + public Mesh error_against = null; + public double error = 0; - public Mesh score_against = null; - public double score = 0; - public float score() { return (float)score; } + public Mesh(boolean immutableVertices) { this.immutableVertices = immutableVertices; } - public int numedges = 0; - public float avgedge = 0; + public void makeVerticesImmutable() { this.immutableVertices = true; } + public float error() { return (float)error; } + + public int size() { return vertices.size(); } + public Iterable vertices() { return vertices; } + public Iterator iterator() { return triangles.iterator(); } public void rebindPoints() { // unbind all points @@ -65,45 +46,18 @@ public class Mesh implements Iterable { } } - public void unApplyQuadricToNeighborAll() { - HashSet done = new HashSet(); - for(T t : this) - for(Vert p : new Vert[] { t.v1(), t.v2(), t.v3() }) { - if (done.contains(p)) continue; - done.add(p); - p.unApplyQuadricToNeighbor(); - } - } - public void recomputeAllFundamentalQuadrics() { - HashSet done = new HashSet(); - for(T t : this) - for(Vert p : new Vert[] { t.v1(), t.v2(), t.v3() }) { - if (done.contains(p)) continue; - done.add(p); - p.recomputeFundamentalQuadric(); - } - } - public float applyQuadricToNeighborAll() { - int num = 0; - double dist = 0; - HashSet done = new HashSet(); - for(T t : this) - for(Vert p : new Vert[] { t.v1(), t.v2(), t.v3() }) { - if (done.contains(p)) continue; - done.add(p); - p.applyQuadricToNeighbor(); - - } - return (float)(dist/num); - } - public void transform(Matrix m) { - ArrayList set = new ArrayList(); - for (Vert v : pointset) - set.add(v); - for(Vert v : set) v.transform(m); + ArrayList set = new ArrayList(); + for(Vertex v : vertices) set.add(v); + for(Vertex v : set) v.transform(m.times(v.p), true); } + public void rebuild() { /*vertices.rebuild();*/ } + public Vec diagonal() { return vertices.diagonal(); } + public Point centroid() { return vertices.centroid(); } + public Vertex nearest(Point p) { return vertices.nearest(p); } + + /** compute the volume of the mesh */ public float volume() { double total = 0; for(T t : this) { @@ -116,200 +70,205 @@ public class Mesh implements Iterable { return (float)total; } - public void rebuildPointSet() { pointset.rebuild(); } - public Vec diagonal() { return pointset.diagonal(); } - public Point centroid() { return pointset.centroid(); } - public Vert nearest(Point p) { return pointset.nearest(p); } - public final class Vert extends HasPoint { - public Point p; - E e; // some edge *leaving* this point + // Vertexices ////////////////////////////////////////////////////////////////////////////// - /** the nearest vertex in the "score_against" mesh */ - Vert nearest_in_other_mesh; - /** the number of vertices in the other mesh for which this is the nearest_in_other_mesh */ - int quadric_count; - /** the total error quadric (contributions from all vertices in other mesh for which this is nearest) */ - Matrix quadric = Matrix.ZERO; + /** a vertex in the mesh */ + public final class Vertex extends HasQuadric implements Visitor { + public Point p, oldp; + E e; // some edge *leaving* this point - Vert bound_to = this; - Matrix binding = new Matrix(); - float oldscore = 0; - boolean quadricStale = false; + Matrix binding = Matrix.ONE; + Vertex bound_to = this; + private boolean illegal = false; - public Matrix errorQuadric() { return quadric; } public Point getPoint() { return p; } - public float score() { return oldscore; } - - private Matrix fundamentalQuadric = null; - public Matrix fundamentalQuadric() { - if (fundamentalQuadric == null) recomputeFundamentalQuadric(); - return fundamentalQuadric; - } + public float error() { return olderror; } - private Vert(Point p) { + private Vertex(Point p) { this.p = p; - if (pointset.get(p) != null) throw new Error(); - pointset.add(this); + if (vertices.get(p) != null) throw new Error(); + vertices.add(this); } - public void recomputeFundamentalQuadric() { - if (!quadricStale && fundamentalQuadric != null) return; - quadricStale = false; - unApplyQuadricToNeighbor(); - Matrix m = Matrix.ZERO; - E e = this.e; - do { - T t = e.t; - m = m.plus(t.norm().fundamentalQuadric(t.centroid())); - e = e.pair.next; - } while(e != this.e); - fundamentalQuadric = m; - applyQuadricToNeighbor(); + public void reinsert() { + vertices.remove(this); + vertices.add(this); + for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) e.t.reinsert(); } - public void unApplyQuadricToNeighbor() { - if (nearest_in_other_mesh == null) return; - if (fundamentalQuadric == null) return; - nearest_in_other_mesh.unComputeError(); - nearest_in_other_mesh.quadric = nearest_in_other_mesh.quadric.minus(fundamentalQuadric); - nearest_in_other_mesh.quadric_count--; - if (nearest_in_other_mesh.quadric_count==0) - nearest_in_other_mesh.quadric = Matrix.ZERO; - nearest_in_other_mesh.computeError(); - nearest_in_other_mesh = null; + public float olderror = 0; + public void setError(float nerror) { + error -= olderror; + olderror = nerror; + error += olderror; } - public void applyQuadricToNeighbor() { - if (score_against == null) return; - - Vert new_nearest = score_against.nearest(p); - if (nearest_in_other_mesh != null && new_nearest == nearest_in_other_mesh) return; - - if (nearest_in_other_mesh != null) unApplyQuadricToNeighbor(); - if (nearest_in_other_mesh != null) throw new Error(); - - nearest_in_other_mesh = new_nearest; - - // don't attract to vertices that face the other way - if (nearest_in_other_mesh.e == null || nearest_in_other_mesh.norm().dot(norm()) < 0) { - nearest_in_other_mesh = null; - } else { - nearest_in_other_mesh.unComputeError(); - nearest_in_other_mesh.quadric = nearest_in_other_mesh.quadric.plus(fundamentalQuadric()); - nearest_in_other_mesh.quadric_count++; - nearest_in_other_mesh.computeError(); + 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++; } - reComputeError(); + 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 void reComputeError() { - unComputeError(); - computeError(); - } - public void unComputeError() { - score -= oldscore; - oldscore = 0; + public Matrix _recomputeFundamentalQuadric() { + Matrix m = Matrix.ZERO; + int count = 0; + for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) { + m = m.plus(e.t.norm().fundamentalQuadric(e.t.centroid())); + count++; + } + return m.times(1/(float)count); } + + public HasQuadric nearest() { return error_against==null ? null : error_against.vertices.nearest(p, this); } public void computeError() { - oldscore = quadric_count == 0 ? 0 : (quadric.preAndPostMultiply(p) / quadric_count); - score += oldscore; + 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 + : nearest().fundamentalQuadric().preAndPostMultiply(p) * 100; + for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) { + double ang = Math.abs(e.crossAngle()); + 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()) * 300; + } + */ + } + setError(nerror); } /** does NOT update bound pairs! */ - public boolean transform(Matrix m) { + private boolean transform(Point newp, boolean ignoreProblems) { + this.oldp = this.p; + if (immutableVertices) throw new Error(); + unApplyQuadricToNeighbor(); - try { - if (pointset.get(this.p)==null) throw new Error(); - pointset.remove(this); - float newx = m.a*p.x + m.b*p.y + m.c*p.z + m.d; - float newy = m.e*p.x + m.f*p.y + m.g*p.z + m.h; - float newz = m.i*p.x + m.j*p.y + m.k*p.z + m.l; - this.p = new Point(newx, newy, newz); - pointset.add(this); - } catch (Exception e) { - throw new RuntimeException(e); - } + this.p = newp; + reinsert(); applyQuadricToNeighbor(); - // should recompute fundamental quadrics of all vertices sharing a face, but we defer... - E e = this.e; - do { - e.p2.quadricStale = true; - e = e.pair.next; - } while(e != this.e); - + 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; + } + + 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 (e.t.aspect() < 0.1) illegal = true; + } + */ + if (!illegal) triangles.range(oldp, this.p, (Visitor)this); + } - // FIXME: intersection test needed? - return true; + public void reComputeErrorAround() { + reComputeError(); + if (nearest_in_other_mesh != null) + nearest_in_other_mesh.reComputeError(); + for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) + e.p2.reComputeError(); + } + + public boolean visit(Object o) { + if (o instanceof Vertex) + return ((Vertex)o).e != null && ((Vertex)o).norm().dot(Vertex.this.norm()) >= 0; + T t = (T)o; + if (illegal) return false; + for(E e = Vertex.this.e; e!=null; e=e.pair.next==Vertex.this.e?null:e.pair.next) { + if (!t.has(e.p1) && !t.has(e.p2) && e.intersects(t)) { illegal = true; } + if (e.t != null) { + if (!e.t.has(t.e1().p1) && !e.t.has(t.e1().p2) && t.e1().intersects(e.t)) { illegal = true; } + if (!e.t.has(t.e2().p1) && !e.t.has(t.e2().p2) && t.e2().intersects(e.t)) { illegal = true; } + if (!e.t.has(t.e3().p1) && !e.t.has(t.e3().p2) && t.e3().intersects(e.t)) { illegal = true; } + } + } + return !illegal; } - public boolean move(Vec v) { - Matrix m = new Matrix(v); - Vert p = this; + public boolean move(Matrix m, boolean ignoreProblems) { boolean good = true; - do { - good &= p.transform(m); - p = p.bound_to; - } while (p != this); + 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; - ret = getFreeIncident(e.pair.next, e.pair.next); - if (ret == null) throw new Error("unable to find free incident to " + this); - return ret; + for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) + System.out.println(e + " " + e.t); + throw new Error("unable to find free incident to " + this); } public E getFreeIncident(E start, E before) { - E e = start; - do { - if (e.pair.p2 == this && e.pair.t == null && e.pair.next.t == null) return e.pair; - e = e.pair.next; - } while(e != before); + for(E e = start; e!=null; e=e.pair.next==before?null:e.pair.next) + if (e.pair.p2 == this && e.pair.t == null && e.pair.next.t == null) + return e.pair; return null; } public E getE(Point p2) { - Vert v = pointset.get(p2); + Vertex v = vertices.get(p2); if (v==null) return null; return getE(v); } - public E getE(Vert p2) { - E e = this.e; - do { - if (e==null) return null; + public E getE(Vertex p2) { + for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) if (e.p1 == this && e.p2 == p2) return e; - e = e.pair.next; - } while (e!=this.e); return null; } + private void glNormal(GL gl) { + Vec norm = norm(); + gl.glNormal3f(norm.x, norm.y, norm.z); + } public Vec norm() { Vec norm = new Vec(0, 0, 0); - E e = this.e; - do { - if (e.t != null) norm = norm.plus(e.t.norm().times((float)e.prev.angle())); - e = e.pair.next; - } while(e != this.e); + for(E e = this.e; e!=null; e=e.pair.next==this.e?null:e.pair.next) + if (e.t != null) + norm = norm.plus(e.t.norm().times((float)e.prev.angle())); return norm.norm(); } - public boolean isBoundTo(Vert p) { - Vert px = p; - do { - if (px==this) return true; - px = px.bound_to; - } while(px != p); + 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 = new Matrix(); } - public void bind(Vert p) { bind(p, new Matrix()); } - public void bind(Vert p, Matrix binding) { + + 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; - Vert temp_bound_to = p.bound_to; + 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 @@ -319,66 +278,41 @@ public class Mesh implements Iterable { } public class BindingGroup { - private HashSet left = new HashSet(); - private HashSet right = new HashSet(); - public BindingGroup() { } - public BindingGroup(E e) { add(null, e, false); } - public void add(E ethis, E e, boolean swap) { - if (ethis==null) { } - else if (right.contains(ethis)) swap = !swap; - else if (!left.contains(ethis)) throw new Error(); - - if (e.bg != null) { - if (e.bg == this) { - if ((!swap ? right : left).contains(e)) throw new Error("double bind!"); - return; - } - for(E ex : (!swap ? e.bg.left : e.bg.right)) { - ex.bg = this; - left.add(ex); + 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); } - for(E ex : (!swap ? e.bg.right : e.bg.left)) { - ex.bg = this; - right.add(ex); - } - - } else { - (!swap ? left : right).add(e); - e.bg = this; - } - for(E ex : (!swap ? right : left)) { - if (e.prev.isBoundTo(ex.prev)) { - System.out.println("hit!"); + if (e.prev.bind_to.set.contains(eother.next)) { + e.prev.prev.bindEdge(eother.next.next); } } - } - public boolean isBoundTo(E e1, E e2) { - if (left.contains(e1) && right.contains(e2)) return true; - if (left.contains(e2) && right.contains(e1)) return true; - return false; + } public void dobind(E e) { - Vert v1 = null; - Vert v2 = null; - if (left.contains(e)) { v1 = e.p1; v2 = e.p2; } - if (right.contains(e)) { v1 = e.p2; v2 = e.p1; } - for(E ex : left) { - if (ex==e) continue; - v1.bind(ex.p1); - v2.bind(ex.p2); - } - for(E ex : right) { - if (ex==e) continue; - v1.bind(ex.p2); - v2.bind(ex.p1); + for(E ebound : set) { + e.p1.bind(ebound.p2); + e.p2.bind(ebound.p1); } } public void shatter(BindingGroup bg1, BindingGroup bg2) { - for(E e : left) { - e.shatter(e.midpoint(), bg1, bg2, false); - } - for(E e : right) { - e.shatter(e.midpoint(), bg1, bg2, true); // swap correct? + for(E e : set) { + e.shatter(e.midpoint(), bg1, bg2); } } } @@ -386,40 +320,58 @@ public class Mesh implements Iterable { /** [UNIQUE] an edge */ public final class E implements Comparable { - public final Vert p1, p2; + 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 bg = new BindingGroup(this); + public BindingGroup bind_peers = new BindingGroup(this); + public BindingGroup bind_to = bind_peers.other(); boolean shattered = false; - public boolean isBoundTo(E e) { return bg.isBoundTo(this, e); } - - - public int compareTo(E e) { return e.length() > length() ? 1 : -1; } - public void bindEdge(E e) { bg.add(this, e, true); } - public void dobind() { if (bg != null) bg.dobind(this); } - - public Point shatter() { return shatter(midpoint(), null, null, false); } - public Point shatter(Point mid, BindingGroup bg1, BindingGroup bg2, boolean swap) { - if (shattered) return mid; + public boolean intersects(T t) { return t.intersects(p1.p, p2.p); } + public float comparator() { + /* + Vertex nearest = error_against.nearest(midpoint()); + //return (float)Math.max(length(), midpoint().distance(nearest.p)); + //return length(); + 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; + */ + 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) { + if (shattered || destroyed) return mid; shattered = true; - Vert r = next.p2; + 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(); - bg.shatter(bg1, bg2); + 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); - newT(r.p, mid, p2.p, null); - (swap ? bg1 : bg2).add(null, p1.getE(mid), swap); - (swap ? bg2 : bg1).add(null, p2.getE(mid).pair, swap); + 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; } @@ -428,42 +380,54 @@ public class Mesh implements Iterable { if (destroyed) return; destroyed = true; pair.destroyed = true; + + if (t != null) t.destroy(); + t = null; + + if (pair.t != null) pair.t.destroy(); + pair.t = null; + if (next.t != null) next.t.destroy(); if (prev.t != null) prev.t.destroy(); next.t = null; prev.t = null; + + if (pair.next.t != null) pair.next.t.destroy(); + if (pair.prev.t != null) pair.next.t.destroy(); pair.next.t = null; pair.prev.t = null; - this.bg = null; - pair.bg = 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; pair.next = prev; if (p1.e == this) p1.e = prev.next; if (pair.p1.e == pair) pair.p1.e = pair.prev.next; - avgedge -= this.length(); - avgedge -= pair.length(); - numedges--; - numedges--; } private void sync() { 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; - if (!added) { - added = true; - numedges++; - avgedge += length(); - } + if (!added) added = true; } private boolean added = false; - public T makeT() { return t==null ? (t = new T(this)) : t; } + public T makeT(int colorclass) { return t==null ? (t = new T(this, colorclass)) : t; } + + public double crossAngle() { + Vec v1 = t.norm().times(-1); + Vec v2 = pair.t.norm().times(-1); + return Math.acos(v1.norm().dot(v2.norm())); + } /** angle between this half-edge and the next */ public double angle() { @@ -494,10 +458,10 @@ public class Mesh implements Iterable { /** creates an isolated edge out in the middle of space */ public E(Point p1, Point p2) { - if (pointset.get(p1) != null) throw new Error(); - if (pointset.get(p2) != null) throw new Error(); - this.p1 = new Vert(p1); - this.p2 = new Vert(p2); + if (vertices.get(p1) != null) throw new Error(); + if (vertices.get(p2) != null) throw new Error(); + this.p1 = new Vertex(p1); + this.p2 = new Vertex(p2); this.prev = this.next = this.pair = new E(this, this, this); this.p1.e = this; this.p2.e = this.pair; @@ -506,9 +470,9 @@ public class Mesh implements Iterable { /** adds a new half-edge from prev.p2 to p2 */ public E(E prev, Point p) { - Vert p2; - p2 = pointset.get(p); - if (p2 == null) p2 = new Vert(p); + Vertex p2; + p2 = vertices.get(p); + if (p2 == null) p2 = new Vertex(p); this.p1 = prev.p2; this.p2 = p2; this.prev = prev; @@ -537,84 +501,15 @@ public class Mesh implements Iterable { sync(); } public Point midpoint() { return new Point((p1.p.x+p2.p.x)/2, (p1.p.y+p2.p.y)/2, (p1.p.z+p2.p.z)/2); } - public boolean has(Vert v) { return v==p1 || v==p2; } + public boolean has(Vertex v) { return v==p1 || v==p2; } public float length() { return p1.p.minus(p2.p).mag(); } public String toString() { return p1+"->"+p2; } - public boolean intersects(T t) { - double A0=t.v1().p.x, A1=t.v1().p.y, A2=t.v1().p.z; - double B0=t.v2().p.x, B1=t.v2().p.y, B2=t.v2().p.z; - double C0=t.v3().p.x, C1=t.v3().p.y, C2=t.v3().p.z; - double j0=p1.p.x, j1=p1.p.y, j2=p1.p.z; - double k0=p2.p.x, k1=p2.p.y, k2=p2.p.z; - double J0, J1, J2; - double K0, K1, K2; - double i0, i1, i2; - double a0, a1, a2; - double b0, b1, b2; - double c0, c1, c2; - double in_det; - double R00, R01, R02, R03, - R10, R11, R12, R13, - R20, R21, R22, R23, - R30, R31, R32, R33; - - - /* a = B - A */ - a0 = B0 - A0; - a1 = B1 - A1; - a2 = B2 - A2; - /* b = C - B */ - b0 = C0 - A0; - b1 = C1 - A1; - b2 = C2 - A2; - /* c = a × b */ - c0 = a1 * b2 - a2 * b1; - c1 = a2 * b0 - a0 * b2; - c2 = a0 * b1 - a1 * b0; - - /* M^(-1) = (1/det(M)) * adj(M) */ - in_det = 1 / (c0 * c0 + c1 * c1 + c2 * c2); - R00 = (b1 * c2 - b2 * c1) * in_det; - R01 = (b2 * c0 - b0 * c2) * in_det; - R02 = (b0 * c1 - b1 * c0) * in_det; - R10 = (c1 * a2 - c2 * a1) * in_det; - R11 = (c2 * a0 - c0 * a2) * in_det; - R12 = (c0 * a1 - c1 * a0) * in_det; - R20 = (c0) * in_det; - R21 = (c1) * in_det; - R22 = (c2) * in_det; - - /* O = M^(-1) * A */ - R03 = -(R00 * A0 + R01 * A1 + R02 * A2); - R13 = -(R10 * A0 + R11 * A1 + R12 * A2); - R23 = -(R20 * A0 + R21 * A1 + R22 * A2); - - /* fill in last row of 4x4 matrix */ - R30 = R31 = R32 = 0; - R33 = 1; - - J2 = R20 * j0 + R21 * j1 + R22 * j2 + R23; - K2 = R20 * k0 + R21 * k1 + R22 * k2 + R23; - if (J2 * K2 >= 0) return false; - - J0 = R00 * j0 + R01 * j1 + R02 * j2 + R03; - K0 = R00 * k0 + R01 * k1 + R02 * k2 + R03; - i0 = J0 + J2 * ((K0 - J0) / (J2 - K2)); - if (i0 < 0 || i0 > 1) return false; - - J1 = R10 * j0 + R11 * j1 + R12 * j2 + R13; - K1 = R10 * k0 + R11 * k1 + R12 * k2 + R13; - i1 = J1 + J2 * ((K1 - J1) / (J2 - K2)); - if (i1 < 0 || i1 > 1 || i0 + i1 > 1) return false; - - return true; - } } public E makeE(Point p1, Point p2) { - Vert v1 = pointset.get(p1); - Vert v2 = pointset.get(p2); + Vertex v1 = vertices.get(p1); + Vertex v2 = vertices.get(p2); if (v1 != null && v2 != null) { E e = v1.getE(v2); if (e != null) return e; @@ -625,7 +520,7 @@ public class Mesh implements Iterable { if (v2 != null) return new E(v2.getFreeIncident(), p1).pair; return new E(p1, p2); } - public T newT(Point p1, Point p2, Point p3, Vec norm) { + public T newT(Point p1, Point p2, Point p3, Vec norm, int colorclass) { if (norm != null) { Vec norm2 = p3.minus(p1).cross(p2.minus(p1)); float dot = norm.dot(norm2); @@ -640,44 +535,20 @@ public class Mesh implements Iterable { e23.makeAdjacent(e31); e31.makeAdjacent(e12); } - T ret = e12.makeT(); + T ret = e12.makeT(colorclass); if (e12.t == null) throw new Error(); if (e23.t == null) throw new Error(); if (e31.t == null) throw new Error(); return ret; } - - public class FaceIterator implements Iterator { - private HashSet visited = new HashSet(); - private LinkedList next = new LinkedList(); - public FaceIterator() { } - public FaceIterator(Vert v) { next.addFirst(v.e.t); } - public boolean hasNext() { return next.peek()!=null; } - public void remove() { throw new Error(); } - public T next() { - T ret = next.removeFirst(); - if (ret == null) return null; - visited.add(ret); - T t1 = ret.e1().pair.t; - T t2 = ret.e2().pair.t; - T t3 = ret.e3().pair.t; - if (t1 != null && !visited.contains(t1)) next.addFirst(t1); - if (t2 != null && !visited.contains(t2)) next.addFirst(t2); - if (t3 != null && !visited.contains(t3)) next.addFirst(t3); - return ret; - } - } - /** [UNIQUE] a triangle (face) */ public final class T extends Triangle { public final E e1; public final int color; + public final int colorclass; - public void destroy() { - } - - T(E e1) { + T(E e1, int colorclass) { this.e1 = e1; E e2 = e1.next; E e3 = e2.next; @@ -699,18 +570,44 @@ public class Mesh implements Iterable { break; } this.color = color; + this.colorclass = colorclass; + triangles.add(this); } public E e1() { return e1; } public E e2() { return e1.next; } public E e3() { return e1.prev; } - public Vert v1() { return e1.p1; } - public Vert v2() { return e1.p2; } - public Vert v3() { return e1.next.p2; } + public Vertex v1() { return e1.p1; } + public Vertex v2() { return e1.p2; } + public Vertex v3() { return e1.next.p2; } public Point p1() { return e1.p1.p; } public Point p2() { return e1.p2.p; } public Point p3() { return e1.next.p2.p; } public boolean hasE(E e) { return e1==e || e1.next==e || e1.prev==e; } - public boolean has(Vert v) { return v1()==v || v2()==v || v3()==v; } - } + public boolean has(Vertex v) { return v1()==v || v2()==v || v3()==v; } + + public void removeFromRTree() { triangles.remove(this); } + public void addToRTree() { triangles.insert(this); } + public void destroy() { triangles.remove(this); } + 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; + return true; + } + /** issue gl.glVertex() for each of the triangle's points */ + public void glVertices(GL gl) { + norm().glNormal(gl); + Point p1 = v1().oldp; + Point p2 = v2().oldp; + Point p3 = v3().oldp; + if (p1==null || p2==null || p3==null) return; + p1.glVertex(gl); + p2.glVertex(gl); + p3.glVertex(gl); + } + + } }