//C++ TO C# CONVERTER WARNING: The original C++ declaration of the following method implementation was not found:
        public void Delaunay(Mesh mesh, int domainnr, MeshingParameters mp)
        {
            //C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
            //	static int timer = NgProfiler::CreateTimer("Meshing2::Delaunay - total");
            //C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
            //	static int timerstart = NgProfiler::CreateTimer("Meshing2::Delaunay - start");
            //C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
            //	static int timerfinish = NgProfiler::CreateTimer("Meshing2::Delaunay - finish");
            //C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
            //	static int timer1 = NgProfiler::CreateTimer("Meshing2::Delaunay - incremental");
            //C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
            //	static int timer1a = NgProfiler::CreateTimer("Meshing2::Delaunay - incremental a");
            //C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
            //	static int timer1b = NgProfiler::CreateTimer("Meshing2::Delaunay - incremental b");
            //C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
            //	static int timer1c = NgProfiler::CreateTimer("Meshing2::Delaunay - incremental c");
            //C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
            //	static int timer1d = NgProfiler::CreateTimer("Meshing2::Delaunay - incremental d");
            NgProfiler.RegionTimer reg = new NgProfiler.RegionTimer(Delaunay_timer);



            Console.Write("2D Delaunay meshing (in progress)");
            Console.Write("\n");


            BlockFillLocalH(mesh, mp);

            NgProfiler.StartTimer(Delaunay_timerstart);

            // do the delaunay


            // face bounding box:
            Box <3> bbox(Box <3> .EMPTY_BOX);

            for (int i = 0; i < adfront.GetNFL(); i++)
            {
                FrontLine line = adfront.GetLine(i);
                bbox.Add(Point <3> (adfront.GetPoint(line.L [0])));
                bbox.Add(Point <3> (adfront.GetPoint(line.L [1])));
            }

            for (int i = 0; i < mesh.LockedPoints().Size(); i++)
            {
                bbox.Add(new mesh.Point(mesh.LockedPoints [i]));
            }

            Console.Write("bbox = ");
            Console.Write(bbox);
            Console.Write("\n");

            // external point
            Vec <3> vdiag = bbox.PMax() - bbox.PMin();

            var          old_points = mesh.Points().Range();
            DelaunayTrig startel    = new DelaunayTrig();

            startel[0] = mesh.AddPoint(bbox.PMin() + Vec <3> (-8 * vdiag(0), -8 * vdiag(1), 0));
            startel[1] = mesh.AddPoint(bbox.PMin() + Vec <3> (+8 * vdiag(0), -8 * vdiag(1), 0));
            startel[2] = mesh.AddPoint(bbox.PMin() + Vec <3> (0, 8 * vdiag(1), 0));

            Box <3> hbox;

            hbox.Set(mesh[startel[0]]);
            hbox.Add(mesh[startel[1]]);
            hbox.Add(mesh[startel[2]]);
            Point <3> hp = mesh[startel[0]];

            hp(2) = 1;
            hbox.Add(hp);
            hp(2) = -1;
            hbox.Add(hp);
            BoxTree <3> searchtree(hbox);

            Array <DelaunayTrig> tempels = new Array <DelaunayTrig>();

            startel.CalcCenter(mesh);

            tempels.Append(startel);
            searchtree.Insert(startel.BoundingBox(), 0);

            Array <int>     closeels     = new Array <int>();
            Array <int>     intersecting = new Array <int>();
            Array <INDEX_2> edges        = new Array <INDEX_2>();



            // reorder points
            Array <PointIndex, PointIndex.BASE, PointIndex> mixed = new Array <PointIndex, PointIndex.BASE, PointIndex>(old_points.Size());

            int[] prims = { 11, 13, 17, 19, 23, 29, 31, 37 };
            int   prim;

            {
                int i = 0;
                while (old_points.Size() % prims[i] == 0)
                {
                    i++;
                }
                prim = prims[i];
            }

            foreach (PointIndex pi in old_points)
            {
                mixed[pi] = new PointIndex((prim * pi) % old_points.Size() + PointIndex.BASE);
            }

            NgProfiler.StopTimer(Delaunay_timerstart);
            NgProfiler.StartTimer(Delaunay_timer1);


            foreach (PointIndex i1 in old_points)
            {
                PointIndex i = mixed[i1];

                NgProfiler.StartTimer(Delaunay_timer1a);
                Point <3> newp = mesh[i];
                intersecting.SetSize(0);
                edges.SetSize(0);

                searchtree.GetIntersecting(newp, newp, closeels);
                // for (int jj = 0; jj < closeels.Size(); jj++)
                // for (int j = 0; j < tempels.Size(); j++)
                foreach (int j in closeels)
                {
                    if (tempels[j][0] < 0)
                    {
                        continue;
                    }
                    Point <3> c  = tempels[j].Center();
                    double    r2 = tempels[j].Radius2();

                    bool inside = Dist2(mesh[i], c) < r2;
                    if (inside)
                    {
                        intersecting.Append(j);
                    }
                }

                NgProfiler.StopTimer(Delaunay_timer1a);
                NgProfiler.StartTimer(Delaunay_timer1b);

                // find outer edges
                foreach (var j in intersecting)
                {
                    DelaunayTrig trig = tempels[j];
                    for (int k = 0; k < 3; k++)
                    {
                        int     p1   = trig[k];
                        int     p2   = trig[(k + 1) % 3];
                        INDEX_2 edge = new INDEX_2(p1, p2);
                        edge.Sort();
                        bool found = false;
                        for (int l = 0; l < edges.Size(); l++)
                        {
                            if (edges[l] == edge)
                            {
                                edges.Delete(l);
                                found = true;
                                break;
                            }
                        }
                        if (!found)
                        {
                            edges.Append(edge);
                        }
                    }
                }

                NgProfiler.StopTimer(Delaunay_timer1b);
                NgProfiler.StartTimer(Delaunay_timer1c);

                /*
                 * for (int j = intersecting.Size()-1; j >= 0; j--)
                 * tempels.Delete (intersecting[j]);
                 */
                foreach (int j in intersecting)
                {
                    searchtree.DeleteElement(j);
                    tempels[j][0] = -1;
                    tempels[j][1] = -1;
                    tempels[j][2] = -1;
                }

                NgProfiler.StopTimer(Delaunay_timer1c);
                NgProfiler.StartTimer(Delaunay_timer1d);

                foreach (var edge in edges)
                {
                    DelaunayTrig trig = new DelaunayTrig(edge[0], edge[1], i);
                    trig.CalcCenter(mesh);
                    tempels.Append(trig);
                    searchtree.Insert(trig.BoundingBox(), tempels.Size() - 1);
                }

                NgProfiler.StopTimer(Delaunay_timer1d);
            }

            NgProfiler.StopTimer(Delaunay_timer1);
            NgProfiler.StartTimer(Delaunay_timerfinish);

            foreach (DelaunayTrig trig in tempels)
            {
                if (trig[0] < 0)
                {
                    continue;
                }

                Point <3> c = Center(mesh[trig[0]], mesh[trig[1]], mesh[trig[2]]);
                if (!adfront.Inside(Point <2> (c(0), c(1))))
                {
                    continue;
                }

                Vec <3> n = Cross(mesh[trig[1]] - mesh[trig[0]], mesh[trig[2]] - mesh[trig[0]]);
                if (n(2) < 0)
                {
                    Swap(ref trig[1], ref trig[2]);
                }

                Element2d el = new Element2d(trig[0], trig[1], trig[2]);
                el.SetIndex(domainnr);
                mesh.AddSurfaceElement(el);
            }

            foreach (PointIndex pi in mesh.Points().Range())
            {
                *testout << pi << ": " << mesh[pi].Type() << "\n";
            }

            NgProfiler.StopTimer(Delaunay_timerfinish);
        }
Beispiel #2
0
    public void EdgeSwapping(Mesh mesh, int usemetric)
    {
        if (!faceindex)
        {
            if (usemetric != 0)
            {
                PrintMessage(3, "Edgeswapping, metric");
            }
            else
            {
                PrintMessage(3, "Edgeswapping, topological");
            }

            for (faceindex = 1; faceindex <= mesh.GetNFD(); faceindex++)
            {
                EdgeSwapping(mesh, usemetric);

                if (multithread.terminate)
                {
                    throw new Exception("Meshing stopped");
                }
            }

            faceindex = 0;
            mesh.CalcSurfacesOfNode();
            return;
        }


//C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
//	static int timer = NgProfiler::CreateTimer("EdgeSwapping 2D");
        NgProfiler.RegionTimer reg1 = new NgProfiler.RegionTimer(EdgeSwapping_timer);

//C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
//	static int timerstart = NgProfiler::CreateTimer("EdgeSwapping 2D start");
        NgProfiler.StartTimer(EdgeSwapping_timerstart);


        Array <SurfaceElementIndex> seia = new Array <SurfaceElementIndex>();

        mesh.GetSurfaceElementsOfFace(faceindex, seia);

        for (int i = 0; i < seia.Size(); i++)
        {
            if (mesh[seia[i]].GetNP() != 3)
            {
                GenericImprove(mesh);
                return;
            }
        }

        int surfnr = mesh.GetFaceDescriptor(faceindex).SurfNr();

        Array <Neighbour>             neighbors = new Array <Neighbour>(mesh.GetNSE());
        INDEX_2_HASHTABLE <trionedge> other     = new INDEX_2_HASHTABLE <trionedge>(seia.Size() + 2);


        Array <char> swapped = new Array <char>(mesh.GetNSE());
        Array <int, PointIndex.BASE>    pdef   = new Array <int, PointIndex.BASE>(mesh.GetNP());
        Array <double, PointIndex.BASE> pangle = new Array <double, PointIndex.BASE>(mesh.GetNP());


        // int e;
        // double d;
        // Vec3d nv1, nv2;

        // double loch(-1);
        double[] minangle = { 0, 1.481, 2.565, 3.627, 4.683, 5.736, 7, 9 };


        for (int i = 0; i < seia.Size(); i++)
        {
            Element2d sel = mesh[seia[i]];
            for (int j = 0; j < 3; j++)
            {
                pangle[sel[j]] = 0.0;
            }
        }
        // pangle = 0;

        for (int i = 0; i < seia.Size(); i++)
        {
            Element2d sel = mesh[seia[i]];
            for (int j = 0; j < 3; j++)
            {
                POINTTYPE typ = mesh[sel[j]].Type();
                if (typ == FIXEDPOINT || typ == EDGEPOINT)
                {
                    pangle[sel[j]] += Angle(mesh[sel[(j + 1) % 3]] - mesh[sel[j]], mesh[sel[(j + 2) % 3]] - mesh[sel[j]]);
                }
            }
        }

        // for (PointIndex pi = PointIndex::BASE;
        // pi < mesh.GetNP()+PointIndex::BASE; pi++)

        // pdef = 0;
        for (int i = 0; i < seia.Size(); i++)
        {
            Element2d sel = mesh[seia[i]];
            for (int j = 0; j < 3; j++)
            {
                PointIndex pi = sel[j];
                if (mesh[pi].Type() == INNERPOINT || mesh[pi].Type() == SURFACEPOINT)
                {
                    pdef[pi] = -6;
                }
                else
                {
                    for (int j = 0; j < 8; j++)
                    {
                        if (pangle[pi] >= minangle[j])
                        {
                            pdef[pi] = -1 - j;
                        }
                    }
                }
            }
        }

        for (int i = 0; i < seia.Size(); i++)
        {
            Element2d sel = mesh[seia[i]];
            for (int j = 0; j < 3; j++)
            {
                pdef[sel[j]]++;
            }
        }

        for (int i = 0; i < seia.Size(); i++)
        {
            for (int j = 0; j < 3; j++)
            {
                neighbors[seia[i]].SetNr(j, -1);
                neighbors[seia[i]].SetOrientation(j, 0);
            }
        }

        /*
         * Array<Vec3d> normals(mesh.GetNP());
         * for (i = 1; i <= mesh.GetNSE(); i++)
         * {
         * Element2d & hel = mesh.SurfaceElement(i);
         * if (hel.GetIndex() == faceindex)
         * for (k = 1; k <= 3; k++)
         * {
         * int pi = hel.PNum(k);
         * SelectSurfaceOfPoint (mesh.Point(pi), hel.GeomInfoPi(k));
         * int surfi = mesh.GetFaceDescriptor(faceindex).SurfNr();
         * GetNormalVector (surfi, mesh.Point(pi), normals.Elem(pi));
         * normals.Elem(pi) /= normals.Elem(pi).Length();
         * }
         * }
         */

        for (int i = 0; i < seia.Size(); i++)
        {
            Element2d sel = mesh[seia[i]];

            for (int j = 0; j < 3; j++)
            {
                PointIndex pi1 = sel.PNumMod(j + 2);
                PointIndex pi2 = sel.PNumMod(j + 3);

                //	    double loch = mesh.GetH(mesh[pi1]);

                INDEX_2 edge = new INDEX_2(pi1, pi2);
                edge.Sort();

                if (mesh.IsSegment(pi1, pi2))
                {
                    continue;
                }

                /*
                 * if (segments.Used (edge))
                 * continue;
                 */
                INDEX_2 ii2 = new INDEX_2(pi1, pi2);
                if (other.Used(ii2))
                {
                    // INDEX_2 i2s(ii2);
                    // i2s.Sort();

                    int i2 = other.Get(ii2).tnr;
                    int j2 = other.Get(ii2).sidenr;

                    neighbors[seia[i]].SetNr(j, i2);
                    neighbors[seia[i]].SetOrientation(j, j2);
                    neighbors[i2].SetNr(j2, seia[i]);
                    neighbors[i2].SetOrientation(j2, j);
                }
                else
                {
                    other.Set(new INDEX_2(pi2, pi1), new trionedge(seia[i], j));
                }
            }
        }

        for (int i = 0; i < seia.Size(); i++)
        {
            swapped[seia[i]] = 0;
        }

        NgProfiler.StopTimer(EdgeSwapping_timerstart);



        int t    = 4;
        int done = 0;

        while (done == 0 && t >= 2)
        {
            for (int i = 0; i < seia.Size(); i++)
            {
                SurfaceElementIndex t1 = seia[i];

                if (mesh[t1].IsDeleted())
                {
                    continue;
                }

                if (mesh[t1].GetIndex() != faceindex)
                {
                    continue;
                }

                if (multithread.terminate)
                {
                    throw new Exception("Meshing stopped");
                }

                for (int o1 = 0; o1 < 3; o1++)
                {
                    bool should;


                    SurfaceElementIndex t2 = neighbors[t1].GetNr(o1);
                    int o2 = neighbors[t1].GetOrientation(o1);

                    if (t2 == -1)
                    {
                        continue;
                    }
                    if (swapped[t1] || swapped[t2])
                    {
                        continue;
                    }


                    PointIndex pi1 = mesh[t1].PNumMod(o1 + 1 + 1);
                    PointIndex pi2 = mesh[t1].PNumMod(o1 + 1 + 2);
                    PointIndex pi3 = mesh[t1].PNumMod(o1 + 1);
                    PointIndex pi4 = mesh[t2].PNumMod(o2 + 1);

                    PointGeomInfo gi1 = mesh[t1].GeomInfoPiMod(o1 + 1 + 1);
                    PointGeomInfo gi2 = mesh[t1].GeomInfoPiMod(o1 + 1 + 2);
                    PointGeomInfo gi3 = mesh[t1].GeomInfoPiMod(o1 + 1);
                    PointGeomInfo gi4 = mesh[t2].GeomInfoPiMod(o2 + 1);

                    bool allowswap = true;

                    Vec <3> auxvec1 = mesh[pi3] - mesh[pi4];
                    Vec <3> auxvec2 = mesh[pi1] - mesh[pi4];

                    allowswap = allowswap && ngsimd.GlobalMembers.fabs(1.0 - (auxvec1 * auxvec2) / (auxvec1.Length() * auxvec2.Length())) > 1e-4;

                    if (!allowswap)
                    {
                        continue;
                    }

                    // normal of new
                    Vec <3> nv1 = netgen.GlobalMembers.Cross(auxvec1, auxvec2);

                    auxvec1   = new mesh.Point(pi4) - new mesh.Point(pi3);
                    auxvec2   = new mesh.Point(pi2) - new mesh.Point(pi3);
                    allowswap = allowswap && ngsimd.GlobalMembers.fabs(1.0 - (auxvec1 * auxvec2) / (auxvec1.Length() * auxvec2.Length())) > 1e-4;


                    if (!allowswap)
                    {
                        continue;
                    }

                    Vec <3> nv2 = netgen.GlobalMembers.Cross(auxvec1, auxvec2);


                    // normals of original
                    Vec <3> nv3 = netgen.GlobalMembers.Cross(mesh[pi1] - mesh[pi4], mesh[pi2] - mesh[pi4]);
                    Vec <3> nv4 = netgen.GlobalMembers.Cross(mesh[pi2] - mesh[pi3], mesh[pi1] - mesh[pi3]);

                    nv3 *= -1;
                    nv4 *= -1;
                    nv3.Normalize();
                    nv4.Normalize();

                    nv1.Normalize();
                    nv2.Normalize();

                    Vec <3> nvp3, nvp4;
                    SelectSurfaceOfPoint(new mesh.Point(pi3), gi3);
                    GetNormalVector(surfnr, new mesh.Point(pi3), gi3, nvp3);

                    nvp3.Normalize();

                    SelectSurfaceOfPoint(new mesh.Point(pi4), gi4);
                    GetNormalVector(surfnr, new mesh.Point(pi4), gi4, nvp4);

                    nvp4.Normalize();



                    double critval = ngsimd.GlobalMembers.cos(DefineConstants.M_PI / 6); // 30 degree
                    allowswap = allowswap && (nv1 * nvp3 > critval) && (nv1 * nvp4 > critval) && (nv2 * nvp3 > critval) && (nv2 * nvp4 > critval) && (nvp3 * nv3 > critval) && (nvp4 * nv4 > critval);


                    double horder = netgen.GlobalMembers.Dist(new mesh.Point(pi1), new mesh.Point(pi2));

                    if (nv1.Length() > 1e-3 * horder * horder && nv2.Length() > 1e-3 * horder * horder && allowswap)
                    {
                        if (usemetric == 0)
                        {
                            int    e = pdef[pi1] + pdef[pi2] - pdef[pi3] - pdef[pi4];
                            double d = netgen.GlobalMembers.Dist2(new mesh.Point(pi1), new mesh.Point(pi2)) - netgen.GlobalMembers.Dist2(new mesh.Point(pi3), new mesh.Point(pi4));

                            should = e >= t && (e > 2 || d > 0);
                        }
                        else
                        {
                            double loch = mesh.GetH(mesh[pi1]);
                            should = CalcTriangleBadness(new mesh.Point(pi4), new mesh.Point(pi3), new mesh.Point(pi1), metricweight, loch) + CalcTriangleBadness(new mesh.Point(pi3), new mesh.Point(pi4), new mesh.Point(pi2), metricweight, loch) < CalcTriangleBadness(new mesh.Point(pi1), new mesh.Point(pi2), new mesh.Point(pi3), metricweight, loch) + CalcTriangleBadness(new mesh.Point(pi2), new mesh.Point(pi1), new mesh.Point(pi4), metricweight, loch);
                        }

                        if (allowswap)
                        {
                            Element2d sw1 = new Element2d(pi4, pi3, pi1);
                            Element2d sw2 = new Element2d(pi3, pi4, pi2);

                            int legal1 = mesh.LegalTrig(mesh.SurfaceElement(t1)) + mesh.LegalTrig(mesh.SurfaceElement(t2));
                            int legal2 = mesh.LegalTrig(sw1) + mesh.LegalTrig(sw2);

                            if (legal1 < legal2)
                            {
                                should = true;
                            }
                            if (legal2 < legal1)
                            {
                                should = false;
                            }
                        }

                        if (should)
                        {
                            // do swapping !

                            done = 1;

                            mesh[t1].PNum(1) = pi1;
                            mesh[t1].PNum(2) = pi4;
                            mesh[t1].PNum(3) = pi3;

                            mesh[t2].PNum(1) = pi2;
                            mesh[t2].PNum(2) = pi3;
                            mesh[t2].PNum(3) = pi4;

                            mesh[t1].GeomInfoPi(1) = gi1;
                            mesh[t1].GeomInfoPi(2) = gi4;
                            mesh[t1].GeomInfoPi(3) = gi3;

                            mesh[t2].GeomInfoPi(1) = gi2;
                            mesh[t2].GeomInfoPi(2) = gi3;
                            mesh[t2].GeomInfoPi(3) = gi4;

                            pdef[pi1]--;
                            pdef[pi2]--;
                            pdef[pi3]++;
                            pdef[pi4]++;

                            swapped[t1] = 1;
                            swapped[t2] = 1;
                        }
                    }
                }
            }
            t--;
        }

        mesh.SetNextTimeStamp();
    }
Beispiel #3
0
//C++ TO C# CONVERTER WARNING: The original C++ declaration of the following method implementation was not found:
        public int GetLocals(int fstind, Array <Point3d, PointIndex.BASE> locpoints, Array <MiniElement2d> locfaces, Array <PointIndex, PointIndex.BASE> pindex, Array <int> findex, INDEX_2_HASHTABLE <int> getconnectedpairs, float xh, float relh, ref int facesplit)
        {
            // static int timer = NgProfiler::CreateTimer ("AdFront3::GetLocals");
            // NgProfiler::RegionTimer reg (timer);


            if (hashon && faces.Size() < 500)
            {
                hashon = 0;
            }
            if (hashon && !hashcreated)
            {
                hashtable.Create();
                hashcreated = 1;
            }

            int        i;
            int        j;
            PointIndex pstind = new PointIndex();
            Point3d    midp   = new Point3d();
            Point3d    p0     = new Point3d();

            //  static Array<int, PointIndex::BASE> invpindex;

            Array <MiniElement2d> locfaces2 = new Array <MiniElement2d>(); //all local faces in radius xh
            Array <int>           locfaces3 = new Array <int>();           // all faces in outer radius relh
            Array <int>           findex2   = new Array <int>();

            locfaces2.SetSize(0);
            locfaces3.SetSize(0);
            findex2.SetSize(0);

            int cluster = faces.Get(fstind).cluster;

            pstind = faces.Get(fstind).Face().PNum(1);
            p0     = points[pstind].P();

            locfaces2.Append(faces.Get(fstind).Face());
            findex2.Append(fstind);


            Box3d b1 = new Box3d(p0 - new Vec3d(xh, xh, xh), p0 + new Vec3d(xh, xh, xh));

            if (hashon)
            {
                hashtable.GetLocals(locfaces2, findex2, fstind, p0, xh);
            }
            else
            {
                for (i = 1; i <= faces.Size(); i++)
                {
                    MiniElement2d face = faces.Get(i).Face();
                    if (faces.Get(i).cluster == cluster && faces.Get(i).Valid() && i != fstind)
                    {
                        Box3d b2 = new Box3d();
                        b2.SetPoint(points[face[0]].P());
                        b2.AddPoint(points[face[1]].P());
                        b2.AddPoint(points[face[2]].P());

                        if (b1.Intersect(b2) != 0)
                        {
                            locfaces2.Append(faces.Get(i).Face());
                            findex2.Append(i);
                        }
                    }
                }
            }

            //local faces for inner radius:
            for (i = 1; i <= locfaces2.Size(); i++)
            {
                MiniElement2d face = locfaces2.Get(i);
                Point3d       p1   = points[face[0]].P();
                Point3d       p2   = points[face[1]].P();
                Point3d       p3   = points[face[2]].P();

                midp = Center(p1, p2, p3);

                if (Dist2(midp, p0) <= relh * relh || i == 1)
                {
                    locfaces.Append(locfaces2.Get(i));
                    findex.Append(findex2.Get(i));
                }
                else
                {
                    locfaces3.Append(i);
                }
            }

            facesplit = locfaces.Size();


            //local faces for outer radius:
            for (i = 1; i <= locfaces3.Size(); i++)
            {
                locfaces.Append(locfaces2.Get(locfaces3.Get(i)));
                findex.Append(findex2.Get(locfaces3.Get(i)));
            }


            invpindex.SetSize(points.Size());
            for (i = 1; i <= locfaces.Size(); i++)
            {
                for (j = 1; j <= locfaces.Get(i).GetNP(); j++)
                {
                    PointIndex pi = locfaces.Get(i).PNum(j);
                    invpindex[pi] = -1;
                }
            }

            for (i = 1; i <= locfaces.Size(); i++)
            {
                for (j = 1; j <= locfaces.Get(i).GetNP(); j++)
                {
                    PointIndex pi = locfaces.Get(i).PNum(j);
                    if (invpindex[pi] == -1)
                    {
                        pindex.Append(pi);
                        locpoints.Append(points[pi].P());
                        invpindex[pi] = pindex.Size() - 1 + PointIndex.BASE;
                    }
                    // locfaces.Elem(i).PNum(j) = locpoints.Append (points[pi].P());
                    // }
                    // else
                    locfaces.Elem(i).PNum(j) = invpindex[pi];
                }
            }



            if (connectedpairs)
            {
                for (i = 1; i <= locpoints.Size(); i++)
                {
                    int pind = pindex.Get(i);
                    if (pind >= 1 && pind <= connectedpairs.Size())
                    {
                        for (j = 1; j <= connectedpairs.EntrySize(pind); j++)
                        {
                            int oi    = connectedpairs.Get(pind, j);
                            int other = invpindex.Get(oi);
                            if (other >= 1 && other <= pindex.Size() && pindex.Get(other) == oi)
                            {
                                // INDEX_2 coned(i, other);
                                // coned.Sort();
                                // (*testout) << "connected: " << locpoints.Get(i) << "-" << locpoints.Get(other) << endl;
                                getconnectedpairs.Set(INDEX_2.Sort(i, other), 1);
                            }
                        }
                    }
                }
            }


            /*
             * // add isolated points
             * for (i = 1; i <= points.Size(); i++)
             * if (points.Elem(i).Valid() && Dist (points.Elem(i).P(), p0) <= xh)
             *  {
             *    if (!invpindex.Get(i))
             *      {
             *            locpoints.Append (points.Get(i).P());
             *            pindex.Append (i);
             *            invpindex.Elem(i) = pindex.Size();
             *      }
             *  }
             */
            return(faces.Get(fstind).QualClass());
        }
Beispiel #4
0
    public void CombineImprove(Mesh mesh)
    {
        if (!faceindex)
        {
            PrintMessage(3, "Combine improve");

            for (faceindex = 1; faceindex <= mesh.GetNFD(); faceindex++)
            {
                CombineImprove(mesh);

                if (multithread.terminate)
                {
                    throw new Exception("Meshing stopped");
                }
            }
            faceindex = 0;
            return;
        }


//C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
//	static int timer = NgProfiler::CreateTimer("Combineimprove 2D");
        NgProfiler.RegionTimer reg = new NgProfiler.RegionTimer(CombineImprove_timer);

//C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
//	static int timerstart = NgProfiler::CreateTimer("Combineimprove 2D start");
        NgProfiler.StartTimer(CombineImprove_timerstart);


//C++ TO C# CONVERTER NOTE: This static local variable declaration (not allowed in C#) has been moved just prior to the method:
//	static int timerstart1 = NgProfiler::CreateTimer("Combineimprove 2D start1");
        NgProfiler.StartTimer(CombineImprove_timerstart1);



        // int i, j, k, l;
        // PointIndex pi;
        // SurfaceElementIndex sei;


        Array <SurfaceElementIndex> seia = new Array <SurfaceElementIndex>();

        mesh.GetSurfaceElementsOfFace(faceindex, seia);


        for (int i = 0; i < seia.Size(); i++)
        {
            if (mesh[seia[i]].GetNP() != 3)
            {
                return;
            }
        }



        int surfnr = 0;

        if (faceindex)
        {
            surfnr = mesh.GetFaceDescriptor(faceindex).SurfNr();
        }


        // PointIndex pi1, pi2;
        // MeshPoint p1, p2, pnew;
        double  bad1;
        double  bad2;
        Vec <3> nv;

        int np = mesh.GetNP();
        //int nse = mesh.GetNSE();

        TABLE <SurfaceElementIndex, PointIndex.BASE> elementsonnode = new TABLE <SurfaceElementIndex, PointIndex.BASE>(np);
        Array <SurfaceElementIndex> hasonepi  = new Array <SurfaceElementIndex>();
        Array <SurfaceElementIndex> hasbothpi = new Array <SurfaceElementIndex>();

        for (int i = 0; i < seia.Size(); i++)
        {
            Element2d el = mesh[seia[i]];
            for (int j = 0; j < el.GetNP(); j++)
            {
                elementsonnode.Add(el[j], seia[i]);
            }
        }

        Array <bool, PointIndex.BASE> @fixed = new Array <bool, PointIndex.BASE>(np);

        @fixed = false;

        NgProfiler.StopTimer(CombineImprove_timerstart1);

        /*
         * for (SegmentIndex si = 0; si < mesh.GetNSeg(); si++)
         * {
         * INDEX_2 i2(mesh[si][0], mesh[si][1]);
         * fixed[i2.I1()] = true;
         * fixed[i2.I2()] = true;
         * }
         */

        for (int i = 0; i < seia.Size(); i++)
        {
            Element2d sel = mesh[seia[i]];
            for (int j = 0; j < sel.GetNP(); j++)
            {
                PointIndex pi1 = sel.PNumMod(j + 2);
                PointIndex pi2 = sel.PNumMod(j + 3);
                if (mesh.IsSegment(pi1, pi2))
                {
                    @fixed[pi1] = true;
                    @fixed[pi2] = true;
                }
            }
        }



        for (int i = 0; i < mesh.LockedPoints().Size(); i++)
        {
            @fixed[mesh.LockedPoints()[i]] = true;
        }



        Array <Vec <3>, PointIndex.BASE> normals = new Array <Vec <3>, PointIndex.BASE>(np);

        for (PointIndex pi = mesh.Points().Begin(); pi < mesh.Points().End(); pi++)
        {
            if (elementsonnode[pi].Size())
            {
                Element2d hel = mesh[elementsonnode[pi][0]];
                for (int k = 0; k < 3; k++)
                {
                    if (hel[k] == pi)
                    {
                        SelectSurfaceOfPoint(mesh[pi], hel.GeomInfoPi(k + 1));
                        GetNormalVector(surfnr, mesh[pi], hel.GeomInfoPi(k + 1), normals[pi]);
                        break;
                    }
                }
            }
        }

        NgProfiler.StopTimer(CombineImprove_timerstart);

        for (int i = 0; i < seia.Size(); i++)
        {
            SurfaceElementIndex sei  = seia[i];
            Element2d           elem = mesh[sei];
            if (elem.IsDeleted())
            {
                continue;
            }

            for (int j = 0; j < 3; j++)
            {
                PointIndex pi1 = elem[j];
                PointIndex pi2 = elem[(j + 1) % 3];

                if (pi1 < PointIndex.BASE || pi2 < PointIndex.BASE)
                {
                    continue;
                }

                /*
                 * INDEX_2 i2(pi1, pi2);
                 * i2.Sort();
                 * if (segmentht.Used(i2))
                 * continue;
                 */

                bool debugflag = false;

                if (debugflag)
                {
                    (*testout) << "Combineimprove, face = " << faceindex << "pi1 = " << pi1 << " pi2 = " << pi2 << "\n";
                }

                /*
                 * // save version:
                 * if (fixed.Get(pi1) || fixed.Get(pi2))
                 * continue;
                 * if (pi2 < pi1) swap (pi1, pi2);
                 */

                // more general
                if (@fixed[pi2])
                {
                    netgen.GlobalMembers.Swap(ref pi1, ref pi2);
                }

                if (@fixed[pi2])
                {
                    continue;
                }

                double loch = mesh.GetH(mesh[pi1]);

                INDEX_2 si2 = new INDEX_2(pi1, pi2);
                si2.Sort();

                /*
                 * if (edgetested.Used (si2))
                 * continue;
                 * edgetested.Set (si2, 1);
                 */

                hasonepi.SetSize(0);
                hasbothpi.SetSize(0);

                for (int k = 0; k < elementsonnode[pi1].Size(); k++)
                {
                    Element2d el2 = mesh[elementsonnode[pi1][k]];

                    if (el2.IsDeleted())
                    {
                        continue;
                    }

                    if (el2[0] == pi2 || el2[1] == pi2 || el2[2] == pi2)
                    {
                        hasbothpi.Append(elementsonnode[pi1][k]);
                        nv = netgen.GlobalMembers.Cross(new Vec3d(mesh[el2[0]], mesh[el2[1]]), new Vec3d(mesh[el2[0]], mesh[el2[2]]));
                    }
                    else
                    {
                        hasonepi.Append(elementsonnode[pi1][k]);
                    }
                }


                Element2d hel = mesh[hasbothpi[0]];
                for (int k = 0; k < 3; k++)
                {
                    if (hel[k] == pi1)
                    {
                        SelectSurfaceOfPoint(mesh[pi1], hel.GeomInfoPi(k + 1));
                        GetNormalVector(surfnr, mesh[pi1], hel.GeomInfoPi(k + 1), nv);
                        break;
                    }
                }

                //	  nv = normals.Get(pi1);



                for (int k = 0; k < elementsonnode[pi2].Size(); k++)
                {
                    Element2d el2 = mesh[elementsonnode[pi2][k]];
                    if (el2.IsDeleted())
                    {
                        continue;
                    }

                    if (el2[0] == pi1 || el2[1] == pi1 || el2[2] == pi1)
                    {
                        ;
                    }
                    else
                    {
                        hasonepi.Append(elementsonnode[pi2][k]);
                    }
                }

                bad1 = 0;
                int illegal1 = 0;
                int illegal2 = 0;
                for (int k = 0; k < hasonepi.Size(); k++)
                {
                    Element2d el = mesh[hasonepi[k]];
                    bad1     += CalcTriangleBadness(mesh[el[0]], mesh[el[1]], mesh[el[2]], nv, -1, loch);
                    illegal1 += 1 - mesh.LegalTrig(el);
                }

                for (int k = 0; k < hasbothpi.Size(); k++)
                {
                    Element2d el = mesh[hasbothpi[k]];
                    bad1     += CalcTriangleBadness(mesh[el[0]], mesh[el[1]], mesh[el[2]], nv, -1, loch);
                    illegal1 += 1 - mesh.LegalTrig(el);
                }
                bad1 /= (hasonepi.Size() + hasbothpi.Size());

                MeshPoint p1 = mesh[pi1];
                MeshPoint p2 = mesh[pi2];

                MeshPoint pnew = new MeshPoint(p1);
                mesh[pi1] = pnew;
                mesh[pi2] = pnew;

                bad2 = 0;
                for (int k = 0; k < hasonepi.Size(); k++)
                {
                    Element2d el  = mesh[hasonepi[k]];
                    double    err = CalcTriangleBadness(mesh[el[0]], mesh[el[1]], mesh[el[2]], nv, -1, loch);
                    bad2 += err;

                    Vec <3> hnv = netgen.GlobalMembers.Cross(new Vec3d(mesh[el[0]], mesh[el[1]]), new Vec3d(mesh[el[0]], mesh[el[2]]));
                    if (hnv * nv < 0)
                    {
                        bad2 += 1e10;
                    }

                    for (int l = 0; l < 3; l++)
                    {
                        if ((normals[el[l]] * nv) < 0.5)
                        {
                            bad2 += 1e10;
                        }
                    }

                    illegal2 += 1 - mesh.LegalTrig(el);
                }
                bad2 /= hasonepi.Size();

                mesh[pi1] = p1;
                mesh[pi2] = p2;


                if (debugflag)
                {
                    (*testout) << "bad1 = " << bad1 << ", bad2 = " << bad2 << "\n";
                }


                bool should = (bad2 < bad1 && bad2 < 1e4);
                if (bad2 < 1e4)
                {
                    if (illegal1 > illegal2)
                    {
                        should = true;
                    }
                    if (illegal2 > illegal1)
                    {
                        should = false;
                    }
                }


                if (should)
                {
                    /*
                     * (*testout) << "combine !" << endl;
                     * (*testout) << "bad1 = " << bad1 << ", bad2 = " << bad2 << endl;
                     * (*testout) << "illegal1 = " << illegal1 << ", illegal2 = " << illegal2 << endl;
                     * (*testout) << "loch = " << loch << endl;
                     */

                    mesh[pi1] = pnew;
                    PointGeomInfo gi = new PointGeomInfo();
                    // bool gi_set(false);


                    Element2d el1p = new Element2d(null);
                    int       l    = 0;
                    while (mesh[elementsonnode[pi1][l]].IsDeleted() && l < elementsonnode.EntrySize(pi1))
                    {
                        l++;
                    }
                    if (l < elementsonnode.EntrySize(pi1))
                    {
                        el1p = mesh[elementsonnode[pi1][l]];
                    }
                    else
                    {
                        cerr << "OOPS!" << "\n";
                    }

                    for (l = 0; l < el1p.GetNP(); l++)
                    {
                        if (el1p[l] == pi1)
                        {
                            gi = el1p.GeomInfoPi(l + 1);
                            // gi_set = true;
                        }
                    }

                    // (*testout) << "Connect point " << pi2 << " to " << pi1 << "\n";
                    for (int k = 0; k < elementsonnode[pi2].Size(); k++)
                    {
                        Element2d el = mesh[elementsonnode[pi2][k]];
                        if (el.IsDeleted())
                        {
                            continue;
                        }
                        elementsonnode.Add(pi1, elementsonnode[pi2][k]);

                        bool haspi1 = false;
                        for (l = 0; l < el.GetNP(); l++)
                        {
                            if (el[l] == pi1)
                            {
                                haspi1 = true;
                            }
                        }
                        if (haspi1)
                        {
                            continue;
                        }

                        for (int l = 0; l < el.GetNP(); l++)
                        {
                            if (el[l] == pi2)
                            {
                                el[l] = pi1;
                                el.GeomInfoPi(l + 1) = gi;
                            }

                            @fixed[el[l]] = true;
                        }
                    }

                    /*
                     * for (k = 0; k < hasbothpi.Size(); k++)
                     * {
                     * cout << mesh[hasbothpi[k]] << endl;
                     * for (l = 0; l < 3; l++)
                     * cout << mesh[mesh[hasbothpi[k]][l]] << " ";
                     * cout << endl;
                     * }
                     */

                    for (int k = 0; k < hasbothpi.Size(); k++)
                    {
                        mesh[hasbothpi[k]].Delete();

                        /*
                         * for (l = 0; l < 4; l++)
                         * mesh[hasbothpi[k]][l] = PointIndex::BASE-1;
                         */
                    }
                }
            }
        }

        //  mesh.Compress();
        mesh.SetNextTimeStamp();
    }