Exemplo n.º 1
0
        public static void MsaglStretchAccordingToZoomLevel(Tiling g, Dictionary <int, Node> idToNodes)
        {
            int[,] listNeighbors = new int[20, 3];
            double[] d = new double[10];
            int[]    a = new int[10];
            int[]    b = new int[10];
            Core.Geometry.Point[] p    = new Core.Geometry.Point[10];
            bool localRefinementsFound = true;
            int  iteration             = 8;
            int  offset = iteration * 2;

            a[1] = 1; b[1] = 1; a[2] = 0; b[2] = 1; a[3] = -1; b[3] = 1; a[4] = -1; b[4] = 0;
            a[5] = -1; b[5] = -1; a[6] = 0; b[6] = -1; a[7] = 1; b[7] = -1; a[8] = 1; b[8] = 0; a[9] = 0; b[9] = 0;

            while (localRefinementsFound && iteration > 0)
            {
                iteration--;
                localRefinementsFound = false;


                for (int index = g.N; index < g.NumOfnodesBeforeDetour; index++)
                {
                    Vertex w = g.VList[index];

                    int numNeighbors = 0;

                    for (int k = 0; k < g.DegList[w.Id]; k++)
                    {
                        if (g.EList[w.Id, k].Used == 0)
                        {
                            continue;
                        }
                        numNeighbors++;
                        listNeighbors[numNeighbors, 1] = g.EList[w.Id, k].NodeId;
                        listNeighbors[numNeighbors, 2] = k;
                    }

                    if (numNeighbors <= 1)
                    {
                        continue;
                    }

                    //compute the lowest zoom level among incident rails
                    var lowestZoomLevel = int.MaxValue;
                    for (int index2 = 1; index2 <= numNeighbors; index2++)
                    {
                        if (g.EList[index, listNeighbors[index2, 2]].Used < lowestZoomLevel)
                        {
                            lowestZoomLevel = g.EList[index, listNeighbors[index2, 2]].Used;
                        }
                    }

                    //for each possible move
                    for (int counter = 1; counter <= 9; counter++)
                    {
                        d[counter] = 0;
                        //find the ink cost of that move
                        for (int k = 1; k <= numNeighbors; k++)
                        {
                            //try to stretch the high priority rails
                            if (g.EList[index, listNeighbors[k, 2]].Used != lowestZoomLevel)
                            {
                                continue;
                            }
                            double length = Math.Sqrt((w.XLoc + a[counter] - g.VList[listNeighbors[k, 1]].XLoc) *
                                                      (w.XLoc + a[counter] - g.VList[listNeighbors[k, 1]].XLoc)
                                                      +
                                                      (w.YLoc + b[counter] - g.VList[listNeighbors[k, 1]].YLoc) *
                                                      (w.YLoc + b[counter] - g.VList[listNeighbors[k, 1]].YLoc)
                                                      );
                            if (length < .5)
                            {
                                length = 1000;
                            }

                            d[counter] += length;
                        }

                        p[counter] = new Core.Geometry.Point(a[counter], b[counter]);
                    }
                    Array.Sort(d, p);

                    for (int counter = 1; counter <= 9; counter++)
                    {
                        var mincostA = (int)p[counter].X;
                        var mincostB = (int)p[counter].Y;

                        if (!(mincostA == 0 && mincostB == 0))
                        {
                            w.XLoc += mincostA;
                            w.YLoc += mincostB;
                            if (g.GetNodeExceptTheGivenNode(w, w.XLoc, w.YLoc, offset) >= 0 ||
                                g.MsaglGoodResolution(w, listNeighbors, numNeighbors, offset) == false
                                //||g.noCrossings(w) == false
                                )
                            {
                                w.XLoc -= mincostA;
                                w.YLoc -= mincostB;
                            }
                            else
                            {
                                //Console.Write(".");
                                localRefinementsFound = true;
                                break;
                            }
                        }
                    }
                }
            }
            Console.WriteLine("Done");
        }
Exemplo n.º 2
0
        public static void MsaglMoveToMedian(Tiling g, Dictionary <int, Node> idToNodes, LgLayoutSettings _lgLayoutSettings)
        {
            //foreach point first produce the crossing candidates.
            g.buildCrossingCandidates();


            //now proceess the movement
            int[,] listNeighbors = new int[20, 3];
            double[] d = new double[10];
            int      a = 0, b = 0;

            Core.Geometry.Point[] p    = new Core.Geometry.Point[10];
            bool localRefinementsFound = true;
            int  iteration             = 10;
            //int offset = iteration * 2;
            int unit = (int)_lgLayoutSettings.NodeSeparation / 2;

            if (_lgLayoutSettings.hugeGraph)
            {
                iteration = 3;
                unit      = (int)_lgLayoutSettings.NodeSeparation;
            }

            while (localRefinementsFound && iteration > 0)
            {
                iteration--;
                localRefinementsFound = false;


                for (int index = g.N; index < g.NumOfnodesBeforeDetour; index++)
                {
                    Vertex w = g.VList[index];

                    int numNeighbors = 0;

                    for (int k = 0; k < g.DegList[w.Id]; k++)
                    {
                        numNeighbors++;
                        listNeighbors[numNeighbors, 1] = g.EList[w.Id, k].NodeId;
                        listNeighbors[numNeighbors, 2] = k;
                    }

                    if (numNeighbors <= 1)
                    {
                        continue;
                    }

                    for (int counter = 1; counter <= 9; counter++)
                    {
                        d[counter] = 0;

                        if (counter == 1)
                        {
                            a = unit; b = unit;
                        }
                        if (counter == 2)
                        {
                            a = 0; b = unit;
                        }
                        if (counter == 3)
                        {
                            a = -unit; b = unit;
                        }
                        if (counter == 4)
                        {
                            a = -unit; b = 0;
                        }
                        if (counter == 5)
                        {
                            a = -unit; b = -unit;
                        }
                        if (counter == 6)
                        {
                            a = 0; b = -unit;
                        }
                        if (counter == 7)
                        {
                            a = unit; b = -unit;
                        }
                        if (counter == 8)
                        {
                            a = unit; b = 0;
                        }
                        if (counter == 9)
                        {
                            a = 0; b = 0;
                        }


                        for (int k = 1; k <= numNeighbors; k++)
                        {
                            double length = Math.Sqrt((w.XLoc + a - g.VList[listNeighbors[k, 1]].XLoc) *
                                                      (w.XLoc + a - g.VList[listNeighbors[k, 1]].XLoc)
                                                      +
                                                      (w.YLoc + b - g.VList[listNeighbors[k, 1]].YLoc) *
                                                      (w.YLoc + b - g.VList[listNeighbors[k, 1]].YLoc)
                                                      );
                            if (length < 1)
                            {
                                length = 1000;
                            }

                            d[counter] += length;
                        }


                        p[counter] = new Core.Geometry.Point(a, b);
                    }
                    Array.Sort(d, p);

                    for (int counter = 1; counter <= 9; counter++)
                    {
                        var mincostA = (int)p[counter].X;
                        var mincostB = (int)p[counter].Y;

                        if (!(mincostA == 0 && mincostB == 0))
                        {
                            w.XLoc += mincostA;
                            w.YLoc += mincostB;
                            if (g.GetNodeExceptTheGivenNode(w, w.XLoc, w.YLoc, 5) >= 0 ||
                                g.MsaglGoodResolution(w, listNeighbors, numNeighbors, 5) == false ||
                                g.noCrossingsHeuristics(w, index) == false
                                )
                            {
                                w.XLoc -= mincostA;
                                w.YLoc -= mincostB;
                            }
                            else
                            {
                                //Console.Write(".");
                                localRefinementsFound = true;
                                break;
                            }
                        }
                    }
                }
            }
            Console.WriteLine("Done");
        }