1 |
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2 | using System;
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3 | using System.Collections.Generic;
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4 | using System.Drawing;
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5 | using System.Linq;
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6 |
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7 | namespace HeuristicLab.Visualization {
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8 | public class ReingoldTilfordLayoutEngine<T> : ILayoutEngine<T> where T : class {
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9 | public int NodeWidth { get; set; }
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10 | public int NodeHeight { get; set; }
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11 | private int minHorizontalSpacing = 5;
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12 | public int HorizontalSpacing {
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13 | get { return minHorizontalSpacing; }
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14 | set { minHorizontalSpacing = value; }
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15 | }
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16 |
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17 | private int minVerticalSpacing = 5;
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18 | public int VerticalSpacing {
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19 | get { return minVerticalSpacing; }
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20 | set { minVerticalSpacing = value; }
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21 | }
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22 |
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23 | private readonly Func<T, IEnumerable<T>> GetChildren;
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24 |
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25 | public ReingoldTilfordLayoutEngine(Func<T, IEnumerable<T>> GetChildren) {
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26 | this.GetChildren = GetChildren;
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27 | }
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28 |
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29 | public IEnumerable<VisualTreeNode<T>> CalculateLayout(T root) {
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30 | return CalculateLayout(root, 0, 0);
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31 | }
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32 |
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33 | public IEnumerable<VisualTreeNode<T>> CalculateLayout(T root, float width, float height) {
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34 | Dictionary<T, LayoutNode<T>> layoutNodeMap = new Dictionary<T, LayoutNode<T>>();
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35 | var layoutRoot = new LayoutNode<T> { Content = root, Width = NodeWidth, Height = NodeHeight, };
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36 | layoutRoot.Ancestor = layoutRoot;
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37 | Expand(layoutRoot, layoutNodeMap);
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38 |
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39 | FirstWalk(layoutRoot);
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40 | SecondWalk(layoutRoot, -layoutRoot.Prelim);
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41 | NormalizeCoordinates(layoutNodeMap.Values);
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42 | if (height != 0 && width != 0) {
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43 | FitToBounds(width, height, layoutNodeMap.Values);
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44 | Center(width, height, layoutNodeMap.Values);
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45 | }
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46 |
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47 | return layoutNodeMap.Values.Select(x => new VisualTreeNode<T>(x.Content) {
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48 | Width = (int)Math.Round(x.Width),
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49 | Height = (int)Math.Round(x.Height),
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50 | X = (int)Math.Round(x.X),
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51 | Y = (int)Math.Round(x.Y)
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52 | });
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53 | }
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54 |
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55 | private void Expand(LayoutNode<T> lRoot, Dictionary<T, LayoutNode<T>> map) {
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56 | map.Add(lRoot.Content, lRoot);
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57 | var children = GetChildren(lRoot.Content).ToList();
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58 | if (!children.Any()) return;
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59 | lRoot.Children = new List<LayoutNode<T>>(children.Count);
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60 | for (int i = 0; i < children.Count; ++i) {
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61 | var node = new LayoutNode<T> {
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62 | Content = children[i],
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63 | Number = i,
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64 | Parent = lRoot,
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65 | Level = lRoot.Level + 1,
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66 | Width = NodeWidth,
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67 | Height = NodeHeight
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68 | };
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69 | node.Ancestor = node;
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70 | lRoot.Children.Add(node);
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71 | Expand(node, map);
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72 | }
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73 | }
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74 |
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75 |
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76 | /// <summary>
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77 | /// Transform LayoutNode coordinates so that all coordinates are positive and start from (0,0)
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78 | /// </summary>
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79 | private static void NormalizeCoordinates(IEnumerable<LayoutNode<T>> nodes) {
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80 | float xmin = 0, ymin = 0;
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81 | foreach (var node in nodes) {
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82 | if (xmin > node.X) xmin = node.X;
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83 | if (ymin > node.Y) ymin = node.Y;
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84 | }
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85 | foreach (var node in nodes) {
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86 | node.X -= xmin;
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87 | node.Y -= ymin;
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88 | }
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89 | }
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90 |
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91 | private void Center(float width, float height, IEnumerable<LayoutNode<T>> nodes) {
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92 | // center layout on screen
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93 | var bounds = Bounds(nodes);
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94 | float dx = 0, dy = 0;
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95 | if (width > bounds.Width) { dx = (width - bounds.Width) / 2f; }
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96 | if (height > bounds.Height) { dy = (height - bounds.Height) / 2f; }
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97 | foreach (var node in nodes) { node.Translate(dx, dy); }
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98 | }
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99 |
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100 | private void FitToBounds(float width, float height, IEnumerable<LayoutNode<T>> nodes) {
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101 | var bounds = Bounds(nodes);
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102 | var myWidth = bounds.Width;
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103 | var myHeight = bounds.Height;
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104 |
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105 | if (myWidth <= width && myHeight <= height) return; // no need to fit since we are within bounds
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106 |
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107 | var layers = nodes.GroupBy(node => node.Level, node => node).ToList();
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108 |
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109 | if (myWidth > width) {
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110 | // need to scale horizontally
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111 | float x = width / myWidth;
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112 | foreach (var node in layers.SelectMany(g => g)) {
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113 | node.X *= x;
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114 | node.Width *= x;
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115 | }
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116 | float spacing = minHorizontalSpacing * x;
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117 | foreach (var layer in layers) {
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118 | var nodesLayer = layer.ToList();
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119 | float minWidth = float.MaxValue;
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120 | for (int i = 0; i < nodesLayer.Count - 1; ++i) { minWidth = Math.Min(minWidth, nodesLayer[i + 1].X - nodesLayer[i].X); }
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121 | float w = Math.Min(NodeWidth, minWidth - spacing);
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122 | foreach (var node in nodesLayer) {
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123 | node.X += (node.Width - w) / 2f;
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124 | node.Width = w;
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125 | //this is a simple solution to ensure that the leftmost and rightmost nodes are not drawn partially offscreen due to scaling and offset
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126 | //this should work well enough 99.9% of the time with no noticeable visual difference
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127 | if (node.X < 0) {
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128 | node.Width += node.X;
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129 | node.X = 0;
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130 | } else if (node.X + node.Width > width) {
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131 | node.Width = width - node.X;
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132 | }
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133 | }
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134 | }
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135 | }
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136 | if (myHeight > height) {
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137 | // need to scale vertically
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138 | float x = height / myHeight;
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139 | foreach (var node in layers.SelectMany(g => g)) {
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140 | node.Y *= x;
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141 | node.Height *= x;
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142 | }
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143 | }
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144 | }
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145 |
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146 |
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147 | /// <summary>
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148 | /// Returns the bounding box for this layout. When the layout is normalized, the rectangle should be [0,0,xmin,xmax].
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149 | /// </summary>
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150 | /// <returns></returns>
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151 | private RectangleF Bounds(IEnumerable<LayoutNode<T>> nodes) {
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152 | float xmin = 0, xmax = 0, ymin = 0, ymax = 0;
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153 | foreach (LayoutNode<T> node in nodes) {
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154 | float x = node.X, y = node.Y;
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155 | if (xmin > x) xmin = x;
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156 | if (xmax < x) xmax = x;
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157 | if (ymin > y) ymin = y;
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158 | if (ymax < y) ymax = y;
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159 | }
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160 | return new RectangleF(xmin, ymin, xmax + minHorizontalSpacing + NodeWidth, ymax + minVerticalSpacing + NodeHeight);
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161 | }
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162 |
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163 | #region methods specific to the reingold-tilford layout algorithm
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164 | private void FirstWalk(LayoutNode<T> v) {
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165 | LayoutNode<T> w;
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166 | if (v.IsLeaf) {
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167 | w = v.LeftSibling;
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168 | if (w != null) {
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169 | v.Prelim = w.Prelim + minHorizontalSpacing + NodeWidth;
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170 | }
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171 | } else {
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172 | var defaultAncestor = v.Children[0]; // leftmost child
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173 |
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174 | foreach (var child in v.Children) {
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175 | FirstWalk(child);
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176 | Apportion(child, ref defaultAncestor);
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177 | }
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178 | ExecuteShifts(v);
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179 | var leftmost = v.Children.First();
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180 | var rightmost = v.Children.Last();
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181 | float midPoint = (leftmost.Prelim + rightmost.Prelim) / 2;
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182 | w = v.LeftSibling;
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183 | if (w != null) {
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184 | v.Prelim = w.Prelim + minHorizontalSpacing + NodeWidth;
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185 | v.Mod = v.Prelim - midPoint;
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186 | } else {
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187 | v.Prelim = midPoint;
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188 | }
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189 | }
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190 | }
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191 |
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192 | private void SecondWalk(LayoutNode<T> v, float m) {
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193 | v.X = v.Prelim + m;
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194 | v.Y = v.Level * (minVerticalSpacing + NodeHeight);
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195 | if (v.IsLeaf) return;
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196 | foreach (var child in v.Children) {
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197 | SecondWalk(child, m + v.Mod);
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198 | }
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199 | }
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200 |
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201 | private void Apportion(LayoutNode<T> v, ref LayoutNode<T> defaultAncestor) {
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202 | var w = v.LeftSibling;
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203 | if (w == null) return;
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204 | LayoutNode<T> vip = v;
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205 | LayoutNode<T> vop = v;
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206 | LayoutNode<T> vim = w;
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207 | LayoutNode<T> vom = vip.LeftmostSibling;
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208 |
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209 | float sip = vip.Mod;
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210 | float sop = vop.Mod;
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211 | float sim = vim.Mod;
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212 | float som = vom.Mod;
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213 |
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214 | while (vim.NextRight != null && vip.NextLeft != null) {
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215 | vim = vim.NextRight;
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216 | vip = vip.NextLeft;
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217 | vom = vom.NextLeft;
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218 | vop = vop.NextRight;
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219 | vop.Ancestor = v;
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220 | float shift = (vim.Prelim + sim) - (vip.Prelim + sip) + minHorizontalSpacing + NodeWidth;
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221 | if (shift > 0) {
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222 | var ancestor = Ancestor(vim, v) ?? defaultAncestor;
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223 | MoveSubtree(ancestor, v, shift);
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224 | sip += shift;
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225 | sop += shift;
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226 | }
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227 | sim += vim.Mod;
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228 | sip += vip.Mod;
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229 | som += vom.Mod;
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230 | sop += vop.Mod;
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231 | }
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232 | if (vim.NextRight != null && vop.NextRight == null) {
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233 | vop.Thread = vim.NextRight;
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234 | vop.Mod += (sim - sop);
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235 | }
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236 | if (vip.NextLeft != null && vom.NextLeft == null) {
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237 | vom.Thread = vip.NextLeft;
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238 | vom.Mod += (sip - som);
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239 | defaultAncestor = v;
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240 | }
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241 | }
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242 |
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243 | private void MoveSubtree(LayoutNode<T> wm, LayoutNode<T> wp, float shift) {
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244 | int subtrees = wp.Number - wm.Number; // TODO: Investigate possible bug (if the value ever happens to be zero) - happens when the tree is actually a graph (but that's outside the use case of this algorithm which only works with trees)
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245 | if (subtrees == 0) throw new Exception("MoveSubtree failed: check if object is really a tree (no cycles)");
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246 | wp.Change -= shift / subtrees;
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247 | wp.Shift += shift;
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248 | wm.Change += shift / subtrees;
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249 | wp.Prelim += shift;
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250 | wp.Mod += shift;
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251 | }
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252 |
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253 | private void ExecuteShifts(LayoutNode<T> v) {
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254 | if (v.IsLeaf) return;
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255 | float shift = 0;
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256 | float change = 0;
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257 | for (int i = v.Children.Count - 1; i >= 0; --i) {
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258 | var w = v.Children[i];
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259 | w.Prelim += shift;
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260 | w.Mod += shift;
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261 | change += w.Change;
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262 | shift += (w.Shift + change);
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263 | }
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264 | }
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265 |
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266 | private LayoutNode<T> Ancestor(LayoutNode<T> u, LayoutNode<T> v) {
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267 | var ancestor = u.Ancestor;
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268 | if (ancestor == null) return null;
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269 | return ancestor.Parent == v.Parent ? ancestor : null;
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270 | }
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271 | #endregion
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272 | }
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273 | }
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