Пример #1
0
        private static void FlipEdgeEvent(DTSweepContext tcx, TriangulationPoint ep, TriangulationPoint eq, DelaunayTriangle t, TriangulationPoint p)
        {
            DelaunayTriangle   ot = t.NeighborAcrossFrom(p);
            TriangulationPoint op = ot.OppositePoint(t, p);

            if (ot == null)
            {
                // If we want to integrate the fillEdgeEvent do it here
                // With current implementation we should never get here
                throw new InvalidOperationException("[BUG:FIXME] FLIP failed due to missing triangle");
            }

            bool inScanArea = TriangulationUtil.InScanArea(p, t.PointCCWFrom(p), t.PointCWFrom(p), op);

            if (inScanArea)
            {
                // Lets rotate shared edge one vertex CW
                RotateTrianglePair(t, p, ot, op);
                tcx.MapTriangleToNodes(t);
                tcx.MapTriangleToNodes(ot);

                if (p == eq && op == ep)
                {
                    if (eq == tcx.EdgeEvent.ConstrainedEdge.Q && ep == tcx.EdgeEvent.ConstrainedEdge.P)
                    {
                        t.MarkConstrainedEdge(ep, eq);
                        ot.MarkConstrainedEdge(ep, eq);
                        Legalize(tcx, t);
                        Legalize(tcx, ot);
                    }
                    else
                    {
                        // XXX: I think one of the triangles should be legalized here?
                    }
                }
                else
                {
                    Orientation o = TriangulationUtil.Orient2d(eq, op, ep);
                    t = NextFlipTriangle(tcx, o, t, ot, p, op);
                    FlipEdgeEvent(tcx, ep, eq, t, p);
                }
            }
            else
            {
                TriangulationPoint newP = null;
                if (NextFlipPoint(ep, eq, ot, op, out newP))
                {
                    FlipScanEdgeEvent(tcx, ep, eq, t, ot, newP);
                    EdgeEvent(tcx, ep, eq, t, p);
                }
            }
        }
Пример #2
0
        /// <summary>
        /// Adds a triangle to the advancing front to fill a hole.
        /// </summary>
        /// <param name="tcx"></param>
        /// <param name="node">middle node, that is the bottom of the hole</param>
        private static void Fill(DTSweepContext tcx, AdvancingFrontNode node)
        {
            DelaunayTriangle triangle = new DelaunayTriangle(node.Prev.Point, node.Point, node.Next.Point);

            // TODO: should copy the cEdge value from neighbor triangles
            //       for now cEdge values are copied during the legalize
            triangle.MarkNeighbor(node.Prev.Triangle);
            triangle.MarkNeighbor(node.Triangle);
            tcx.Triangles.Add(triangle);

            // Update the advancing front
            node.Prev.Next = node.Next;
            node.Next.Prev = node.Prev;
//												tcx.RemoveNode (node);

            // If it was legalized the triangle has already been mapped
            if (!Legalize(tcx, triangle))
            {
                tcx.MapTriangleToNodes(triangle);
            }
        }
Пример #3
0
        /// <summary>
        /// Creates a new front triangle and legalize it
        /// </summary>
        private static AdvancingFrontNode NewFrontTriangle(DTSweepContext tcx, TriangulationPoint point, AdvancingFrontNode node)
        {
            AdvancingFrontNode newNode;
            DelaunayTriangle   triangle;

            triangle = new DelaunayTriangle(point, node.Point, node.Next.Point);
            triangle.MarkNeighbor(node.Triangle);
            tcx.Triangles.Add(triangle);

            newNode        = new AdvancingFrontNode(point);
            newNode.Next   = node.Next;
            newNode.Prev   = node;
            node.Next.Prev = newNode;
            node.Next      = newNode;

//												tcx.AddNode (newNode); // XXX: BST

            if (!Legalize(tcx, triangle))
            {
                tcx.MapTriangleToNodes(triangle);
            }

            return(newNode);
        }
Пример #4
0
        /// <summary>
        /// If this is a Delaunay Triangulation of a pointset we need to fill so the triangle mesh gets a ConvexHull
        /// </summary>
        private static void FinalizationConvexHull(DTSweepContext tcx)
        {
            AdvancingFrontNode n1, n2;
            DelaunayTriangle   t1, t2;
            TriangulationPoint first, p1;

            n1    = tcx.Front.Head.Next;
            n2    = n1.Next;
            first = n1.Point;

            TurnAdvancingFrontConvex(tcx, n1, n2);

            // Lets remove triangles connected to the two "algorithm" points
            // XXX: When the first three nodes are points in a triangle we need to do a flip before
            // removing triangles or we will lose a valid triangle.
            // Same for last three nodes!
            // !!! If I implement ConvexHull for lower right and left boundary this fix should not be
            // needed and the removed triangles will be added again by default

            n1 = tcx.Front.Tail.Prev;
            if (n1.Triangle.Contains(n1.Next.Point) && n1.Triangle.Contains(n1.Prev.Point))
            {
                t1 = n1.Triangle.NeighborAcrossFrom(n1.Point);
                RotateTrianglePair(n1.Triangle, n1.Point, t1, t1.OppositePoint(n1.Triangle, n1.Point));
                tcx.MapTriangleToNodes(n1.Triangle);
                tcx.MapTriangleToNodes(t1);
            }
            n1 = tcx.Front.Head.Next;
            if (n1.Triangle.Contains(n1.Prev.Point) && n1.Triangle.Contains(n1.Next.Point))
            {
                t1 = n1.Triangle.NeighborAcrossFrom(n1.Point);
                RotateTrianglePair(n1.Triangle, n1.Point, t1, t1.OppositePoint(n1.Triangle, n1.Point));
                tcx.MapTriangleToNodes(n1.Triangle);
                tcx.MapTriangleToNodes(t1);
            }

            // Lower right boundary
            first       = tcx.Front.Head.Point;
            n2          = tcx.Front.Tail.Prev;
            t1          = n2.Triangle;
            p1          = n2.Point;
            n2.Triangle = null;
            do
            {
                tcx.RemoveFromList(t1);
                p1 = t1.PointCCWFrom(p1);
                if (p1 == first)
                {
                    break;
                }
                t2 = t1.NeighborCCWFrom(p1);
                t1.Clear();
                t1 = t2;
            } while (true);

            // Lower left boundary
            first = tcx.Front.Head.Next.Point;
            p1    = t1.PointCWFrom(tcx.Front.Head.Point);
            t2    = t1.NeighborCWFrom(tcx.Front.Head.Point);
            t1.Clear();
            t1 = t2;
            while (p1 != first)
            {
                tcx.RemoveFromList(t1);
                p1 = t1.PointCCWFrom(p1);
                t2 = t1.NeighborCCWFrom(p1);
                t1.Clear();
                t1 = t2;
            }

            // Remove current head and tail node now that we have removed all triangles attached
            // to them. Then set new head and tail node points
            tcx.Front.Head      = tcx.Front.Head.Next;
            tcx.Front.Head.Prev = null;
            tcx.Front.Tail      = tcx.Front.Tail.Prev;
            tcx.Front.Tail.Next = null;
        }
Пример #5
0
        /// <summary>
        /// Returns true if triangle was legalized
        /// </summary>
        private static bool Legalize(DTSweepContext tcx, DelaunayTriangle t)
        {
            // To legalize a triangle we start by finding if any of the three edges
            // violate the Delaunay condition
            for (int i = 0; i < 3; i++)
            {
                // TODO: fix so that cEdge is always valid when creating new triangles then we can check it here
                //       instead of below with ot
                if (t.EdgeIsDelaunay [i])
                {
                    continue;
                }

                DelaunayTriangle ot = t.Neighbors [i];
                if (ot == null)
                {
                    continue;
                }

                TriangulationPoint p  = t.Points [i];
                TriangulationPoint op = ot.OppositePoint(t, p);
                int oi = ot.IndexOf(op);
                // If this is a Constrained Edge or a Delaunay Edge(only during recursive legalization)
                // then we should not try to legalize
                if (ot.EdgeIsConstrained [oi] || ot.EdgeIsDelaunay [oi])
                {
                    t.SetConstrainedEdgeAcross(p, ot.EdgeIsConstrained [oi]);                      // XXX: have no good way of setting this property when creating new triangles so lets set it here
                    continue;
                }

                if (!TriangulationUtil.SmartIncircle(p, t.PointCCWFrom(p), t.PointCWFrom(p), op))
                {
                    continue;
                }

                // Lets mark this shared edge as Delaunay
                t.EdgeIsDelaunay [i]   = true;
                ot.EdgeIsDelaunay [oi] = true;

                // Lets rotate shared edge one vertex CW to legalize it
                RotateTrianglePair(t, p, ot, op);

                // We now got one valid Delaunay Edge shared by two triangles
                // This gives us 4 new edges to check for Delaunay

                // Make sure that triangle to node mapping is done only one time for a specific triangle
                if (!Legalize(tcx, t))
                {
                    tcx.MapTriangleToNodes(t);
                }
                if (!Legalize(tcx, ot))
                {
                    tcx.MapTriangleToNodes(ot);
                }

                // Reset the Delaunay edges, since they only are valid Delaunay edges
                // until we add a new triangle or point.
                // XXX: need to think about this. Can these edges be tried after we
                //      return to previous recursive level?
                t.EdgeIsDelaunay [i]   = false;
                ot.EdgeIsDelaunay [oi] = false;

                // If triangle have been legalized no need to check the other edges since
                // the recursive legalization will handles those so we can end here.
                return(true);
            }
            return(false);
        }