1 | #include <stack>
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2 | #include <time.h>
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3 | #include <iomanip>
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4 |
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5 | #include "BvHierarchy.h"
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6 | #include "ViewCell.h"
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7 | #include "Plane3.h"
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8 | #include "Mesh.h"
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9 | #include "common.h"
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10 | #include "Environment.h"
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11 | #include "Polygon3.h"
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12 | #include "Ray.h"
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13 | #include "AxisAlignedBox3.h"
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14 | #include "Exporter.h"
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15 | #include "Plane3.h"
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16 | #include "ViewCellsManager.h"
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17 | #include "Beam.h"
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18 | #include "VspTree.h"
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19 | #include "HierarchyManager.h"
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20 |
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21 |
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22 | namespace GtpVisibilityPreprocessor {
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23 |
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24 |
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25 | #define PROBABILIY_IS_BV_VOLUME 1
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26 | #define USE_FIXEDPOINT_T 0
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27 | #define USE_VOLUMES_FOR_HEURISTICS 1
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28 |
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29 | //int BvhNode::sMailId = 10000; //2147483647;
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30 | //int BvhNode::sReservedMailboxes = 1;
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31 |
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32 | BvHierarchy *BvHierarchy::BvhSubdivisionCandidate::sBvHierarchy = NULL;
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33 |
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34 |
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35 | /// sorting operator
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36 | inline static bool ilt(Intersectable *obj1, Intersectable *obj2)
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37 | {
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38 | return obj1->mId < obj2->mId;
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39 | }
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40 |
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41 |
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42 | /// sorting operator
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43 | inline static bool smallerSize(Intersectable *obj1, Intersectable *obj2)
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44 | {
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45 | return obj1->GetBox().SurfaceArea() < obj2->GetBox().SurfaceArea();
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46 | }
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47 |
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48 |
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49 |
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50 | /***************************************************************/
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51 | /* class BvhNode implementation */
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52 | /***************************************************************/
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53 |
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54 | BvhNode::BvhNode():
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55 | mParent(NULL),
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56 | mTimeStamp(0),
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57 | mRenderCost(-1)
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58 |
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59 | {
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60 |
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61 | }
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62 |
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63 | BvhNode::BvhNode(const AxisAlignedBox3 &bbox):
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64 | mParent(NULL),
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65 | mBoundingBox(bbox),
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66 | mTimeStamp(0),
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67 | mRenderCost(-1)
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68 | {
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69 | }
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70 |
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71 |
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72 | BvhNode::BvhNode(const AxisAlignedBox3 &bbox, BvhInterior *parent):
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73 | mBoundingBox(bbox),
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74 | mParent(parent),
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75 | mTimeStamp(0),
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76 | mRenderCost(-1)
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77 | {
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78 | }
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79 |
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80 |
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81 | bool BvhNode::IsRoot() const
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82 | {
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83 | return mParent == NULL;
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84 | }
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85 |
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86 |
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87 | BvhInterior *BvhNode::GetParent()
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88 | {
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89 | return mParent;
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90 | }
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91 |
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92 |
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93 | void BvhNode::SetParent(BvhInterior *parent)
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94 | {
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95 | mParent = parent;
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96 | }
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97 |
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98 |
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99 | int BvhNode::GetRandomEdgePoint(Vector3 &point,
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100 | Vector3 &normal)
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101 | {
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102 | // get random edge
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103 | const int idx = Random(12);
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104 | Vector3 a, b;
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105 | mBoundingBox.GetEdge(idx, &a, &b);
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106 |
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107 | const float w = RandomValue(0.0f, 1.0f);
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108 |
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109 | point = a * w + b * (1.0f - w);
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110 |
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111 | // TODO
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112 | normal = Vector3(0);
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113 |
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114 | return idx;
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115 | }
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116 |
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117 |
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118 |
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119 | /******************************************************************/
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120 | /* class BvhInterior implementation */
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121 | /******************************************************************/
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122 |
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123 |
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124 | BvhLeaf::BvhLeaf(const AxisAlignedBox3 &bbox):
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125 | BvhNode(bbox),
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126 | mSubdivisionCandidate(NULL),
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127 | mGlList(0)
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128 | {
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129 | mActiveNode = this;
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130 | }
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131 |
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132 |
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133 | BvhLeaf::BvhLeaf(const AxisAlignedBox3 &bbox, BvhInterior *parent):
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134 | BvhNode(bbox, parent),
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135 | mGlList(0)
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136 |
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137 | {
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138 | mActiveNode = this;
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139 | }
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140 |
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141 |
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142 | BvhLeaf::BvhLeaf(const AxisAlignedBox3 &bbox,
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143 | BvhInterior *parent,
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144 | const int numObjects):
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145 | BvhNode(bbox, parent),
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146 | mGlList(0)
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147 |
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148 | {
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149 | mObjects.reserve(numObjects);
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150 | mActiveNode = this;
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151 | }
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152 |
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153 |
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154 | bool BvhLeaf::IsLeaf() const
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155 | {
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156 | return true;
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157 | }
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158 |
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159 |
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160 | BvhLeaf::~BvhLeaf()
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161 | {
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162 | }
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163 |
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164 |
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165 | void BvhLeaf::CollectObjects(ObjectContainer &objects)
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166 | {
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167 | ObjectContainer::const_iterator oit, oit_end = mObjects.end();
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168 | for (oit = mObjects.begin(); oit != oit_end; ++ oit)
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169 | {
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170 | objects.push_back(*oit);
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171 | }
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172 | }
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173 |
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174 | /******************************************************************/
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175 | /* class BvhInterior implementation */
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176 | /******************************************************************/
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177 |
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178 |
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179 | BvhInterior::BvhInterior(const AxisAlignedBox3 &bbox):
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180 | BvhNode(bbox), mFront(NULL), mBack(NULL)
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181 | {
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182 | }
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183 |
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184 |
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185 | BvhInterior::BvhInterior(const AxisAlignedBox3 &bbox, BvhInterior *parent):
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186 | BvhNode(bbox, parent), mFront(NULL), mBack(NULL)
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187 | {
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188 | }
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189 |
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190 |
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191 | void BvhInterior::ReplaceChildLink(BvhNode *oldChild, BvhNode *newChild)
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192 | {
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193 | if (mBack == oldChild)
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194 | mBack = newChild;
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195 | else
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196 | mFront = newChild;
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197 | }
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198 |
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199 |
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200 | bool BvhInterior::IsLeaf() const
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201 | {
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202 | return false;
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203 | }
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204 |
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205 |
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206 | BvhInterior::~BvhInterior()
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207 | {
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208 | DEL_PTR(mFront);
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209 | DEL_PTR(mBack);
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210 | }
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211 |
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212 |
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213 | void BvhInterior::SetupChildLinks(BvhNode *front, BvhNode *back)
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214 | {
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215 | mBack = back;
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216 | mFront = front;
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217 | }
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218 |
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219 |
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220 | void BvhInterior::CollectObjects(ObjectContainer &objects)
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221 | {
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222 | mFront->CollectObjects(objects);
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223 | mBack->CollectObjects(objects);
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224 | }
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225 |
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226 |
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227 | /*******************************************************************/
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228 | /* class BvHierarchy implementation */
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229 | /*******************************************************************/
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230 |
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231 |
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232 | BvHierarchy::BvHierarchy():
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233 | mRoot(NULL),
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234 | mTimeStamp(1),
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235 | mIsInitialSubdivision(false)
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236 | {
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237 | ReadEnvironment();
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238 | mSubdivisionCandidates = new SortableEntryContainer;
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239 | // for (int i = 0; i < 4; ++ i)
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240 | // mSortedObjects[i] = NULL;
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241 | }
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242 |
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243 |
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244 | BvHierarchy::~BvHierarchy()
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245 | {
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246 | // delete the local subdivision candidates
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247 | DEL_PTR(mSubdivisionCandidates);
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248 |
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249 | // delete the presorted objects
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250 | /*for (int i = 0; i < 4; ++ i)
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251 | {
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252 | DEL_PTR(mSortedObjects[i]);
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253 | }*/
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254 |
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255 | // delete the tree
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256 | DEL_PTR(mRoot);
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257 | }
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258 |
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259 |
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260 | void BvHierarchy::ReadEnvironment()
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261 | {
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262 | bool randomize = false;
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263 | Environment::GetSingleton()->GetBoolValue("BvHierarchy.Construction.randomize", randomize);
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264 |
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265 | // initialise random generator for heuristics
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266 | if (randomize)
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267 | Randomize();
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268 |
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269 | //////////////////////////////
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270 | //-- termination criteria for autopartition
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271 |
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272 | Environment::GetSingleton()->GetIntValue("BvHierarchy.Termination.maxDepth", mTermMaxDepth);
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273 | Environment::GetSingleton()->GetIntValue("BvHierarchy.Termination.maxLeaves", mTermMaxLeaves);
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274 | Environment::GetSingleton()->GetIntValue("BvHierarchy.Termination.minObjects", mTermMinObjects);
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275 | Environment::GetSingleton()->GetIntValue("BvHierarchy.Termination.minRays", mTermMinRays);
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276 | Environment::GetSingleton()->GetFloatValue("BvHierarchy.Termination.minProbability", mTermMinProbability);
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277 | Environment::GetSingleton()->GetIntValue("BvHierarchy.Termination.missTolerance", mTermMissTolerance);
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278 |
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279 |
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280 | //////////////////////////////
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281 | //-- max cost ratio for early tree termination
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282 |
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283 | Environment::GetSingleton()->GetFloatValue("BvHierarchy.Termination.maxCostRatio", mTermMaxCostRatio);
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284 | Environment::GetSingleton()->GetFloatValue("BvHierarchy.Termination.minGlobalCostRatio",
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285 | mTermMinGlobalCostRatio);
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286 | Environment::GetSingleton()->GetIntValue("BvHierarchy.Termination.globalCostMissTolerance",
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287 | mTermGlobalCostMissTolerance);
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288 |
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289 |
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290 | //////////////////////////////
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291 | //-- factors for subdivision heuristics
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292 |
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293 | // if only the driving axis is used for splits
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294 | Environment::GetSingleton()->GetBoolValue("BvHierarchy.splitUseOnlyDrivingAxis", mOnlyDrivingAxis);
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295 | Environment::GetSingleton()->GetFloatValue("BvHierarchy.maxStaticMemory", mMaxMemory);
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296 | Environment::GetSingleton()->GetBoolValue("BvHierarchy.useCostHeuristics", mUseCostHeuristics);
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297 | Environment::GetSingleton()->GetBoolValue("BvHierarchy.useSah", mUseSah);
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298 |
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299 | char subdivisionStatsLog[100];
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300 | Environment::GetSingleton()->GetStringValue("BvHierarchy.subdivisionStats", subdivisionStatsLog);
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301 | mSubdivisionStats.open(subdivisionStatsLog);
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302 |
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303 | Environment::GetSingleton()->GetFloatValue("BvHierarchy.Construction.renderCostDecreaseWeight", mRenderCostDecreaseWeight);
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304 | Environment::GetSingleton()->GetBoolValue("BvHierarchy.Construction.useGlobalSorting", mUseGlobalSorting);
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305 | Environment::GetSingleton()->GetIntValue("BvHierarchy.minRaysForVisibility", mMinRaysForVisibility);
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306 | Environment::GetSingleton()->GetIntValue("BvHierarchy.maxTests", mMaxTests);
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307 | Environment::GetSingleton()->GetBoolValue("BvHierarchy.Construction.useInitialSubdivision", mApplyInitialPartition);
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308 | Environment::GetSingleton()->GetIntValue("BvHierarchy.Construction.Initial.minObjects", mInitialMinObjects);
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309 | Environment::GetSingleton()->GetFloatValue("BvHierarchy.Construction.Initial.maxAreaRatio", mInitialMaxAreaRatio);
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310 | Environment::GetSingleton()->GetFloatValue("BvHierarchy.Construction.Initial.minArea", mInitialMinArea);
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311 |
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312 | //mMemoryConst = (float)(sizeof(VspLeaf) + sizeof(VspViewCell));
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313 | //mMemoryConst = (float)sizeof(BvhLeaf);
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314 | mMemoryConst = 16;//(float)sizeof(ObjectContainer);
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315 |
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316 | mUseBboxAreaForSah = true;
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317 |
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318 | /////////////
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319 | //-- debug output
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320 |
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321 | Debug << "******* Bvh hierarchy options ******** " << endl;
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322 | Debug << "max depth: " << mTermMaxDepth << endl;
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323 | Debug << "min probabiliy: " << mTermMinProbability<< endl;
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324 | Debug << "min objects: " << mTermMinObjects << endl;
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325 | Debug << "max cost ratio: " << mTermMaxCostRatio << endl;
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326 | Debug << "miss tolerance: " << mTermMissTolerance << endl;
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327 | Debug << "max leaves: " << mTermMaxLeaves << endl;
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328 | Debug << "randomize: " << randomize << endl;
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329 | Debug << "min global cost ratio: " << mTermMinGlobalCostRatio << endl;
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330 | Debug << "global cost miss tolerance: " << mTermGlobalCostMissTolerance << endl;
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331 | Debug << "only driving axis: " << mOnlyDrivingAxis << endl;
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332 | Debug << "max memory: " << mMaxMemory << endl;
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333 | Debug << "use cost heuristics: " << mUseCostHeuristics << endl;
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334 | Debug << "use surface area heuristics: " << mUseSah << endl;
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335 | Debug << "subdivision stats log: " << subdivisionStatsLog << endl;
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336 | Debug << "split borders: " << mSplitBorder << endl;
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337 | Debug << "render cost decrease weight: " << mRenderCostDecreaseWeight << endl;
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338 | Debug << "use global sort: " << mUseGlobalSorting << endl;
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339 | Debug << "minimal rays for visibility: " << mMinRaysForVisibility << endl;
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340 | Debug << "bvh mem const: " << mMemoryConst << endl;
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341 | Debug << "apply initial partition: " << mApplyInitialPartition << endl;
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342 | Debug << "min objects: " << mInitialMinObjects << endl;
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343 | Debug << "max area ratio: " << mInitialMaxAreaRatio << endl;
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344 | Debug << "min area: " << mInitialMinArea << endl;
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345 |
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346 | Debug << endl;
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347 | }
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348 |
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349 |
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350 | void BvHierarchy::AssociateObjectsWithLeaf(BvhLeaf *leaf)
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351 | {
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352 | ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
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353 |
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354 | for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
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355 | {
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356 | (*oit)->mBvhLeaf = leaf;
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357 | }
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358 | }
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359 |
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360 |
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361 | static int CountRays(const ObjectContainer &objects)
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362 | {
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363 | int nRays = 0;
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364 |
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365 | ObjectContainer::const_iterator oit, oit_end = objects.end();
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366 |
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367 | for (oit = objects.begin(); oit != oit_end; ++ oit)
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368 | {
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369 | nRays += (int)(*oit)->GetOrCreateRays()->size();
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370 | }
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371 |
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372 | return nRays;
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373 | }
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374 |
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375 | float BvHierarchy::GetViewSpaceVolume() const
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376 | {
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377 | return mViewCellsManager->GetViewSpaceBox().GetVolume();
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378 | }
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379 |
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380 |
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381 | BvhInterior *BvHierarchy::SubdivideNode(const BvhSubdivisionCandidate &sc,
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382 | BvhTraversalData &frontData,
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383 | BvhTraversalData &backData)
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384 | {
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385 | const BvhTraversalData &tData = sc.mParentData;
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386 | BvhLeaf *leaf = tData.mNode;
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387 |
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388 | AxisAlignedBox3 parentBox = leaf->GetBoundingBox();
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389 |
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390 | // update stats: we have two new leaves
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391 | mBvhStats.nodes += 2;
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392 |
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393 | if (tData.mDepth > mBvhStats.maxDepth)
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394 | {
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395 | mBvhStats.maxDepth = tData.mDepth;
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396 | }
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397 |
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398 | // add the new nodes to the tree
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399 | BvhInterior *node = new BvhInterior(parentBox, leaf->GetParent());
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400 |
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401 |
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402 | //////////////////
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403 | //-- create front and back leaf
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404 |
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405 | AxisAlignedBox3 fbox = EvalBoundingBox(sc.mFrontObjects, &parentBox);
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406 | AxisAlignedBox3 bbox = EvalBoundingBox(sc.mBackObjects, &parentBox);
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407 |
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408 | BvhLeaf *back = new BvhLeaf(bbox, node, (int)sc.mBackObjects.size());
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409 | BvhLeaf *front = new BvhLeaf(fbox, node, (int)sc.mFrontObjects.size());
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410 |
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411 | BvhInterior *parent = leaf->GetParent();
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412 |
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413 | // replace a link from node's parent
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414 | if (parent)
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415 | {
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416 | parent->ReplaceChildLink(leaf, node);
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417 | node->SetParent(parent);
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418 | }
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419 | else // no parent => this node is the root
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420 | {
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421 | mRoot = node;
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422 | }
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423 |
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424 | // and setup child links
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425 | node->SetupChildLinks(front, back);
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426 |
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427 | ++ mBvhStats.splits;
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428 |
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429 |
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430 | ////////////////////////////////////////
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431 | //-- fill front and back traversal data with the new values
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432 |
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433 | frontData.mDepth = backData.mDepth = tData.mDepth + 1;
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434 |
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435 | frontData.mNode = front;
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436 | backData.mNode = back;
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437 |
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438 | back->mObjects = sc.mBackObjects;
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439 | front->mObjects = sc.mFrontObjects;
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440 |
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441 | // if the number of rays is too low, no assumptions can be made
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442 | // (=> switch to surface area heuristics?)
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443 | frontData.mNumRays = CountRays(sc.mFrontObjects);
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444 | backData.mNumRays = CountRays(sc.mBackObjects);
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445 |
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446 | AssociateObjectsWithLeaf(back);
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447 | AssociateObjectsWithLeaf(front);
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448 |
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449 | //-- compute pvs correction to cope with undersampling
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450 | frontData.mPvs = (float)CountViewCells(front->mObjects);
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451 | backData.mPvs = (float)CountViewCells(back->mObjects);
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452 |
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453 | frontData.mCorrectedPvs = sc.mCorrectedFrontPvs;
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454 | backData.mCorrectedPvs = sc.mCorrectedBackPvs;
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455 |
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456 | // compute probability of this node being visible,
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457 | // i.e., volume of the view cells that can see this node
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458 | frontData.mVolume = EvalViewCellsVolume(sc.mFrontObjects) / GetViewSpaceVolume();
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459 | backData.mVolume = EvalViewCellsVolume(sc.mBackObjects) / GetViewSpaceVolume();
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460 |
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461 | frontData.mCorrectedVolume = sc.mCorrectedFrontVolume;
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462 | backData.mCorrectedVolume = sc.mCorrectedBackVolume;
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463 |
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464 | // how often was max cost ratio missed in this branch?
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465 | frontData.mMaxCostMisses = sc.GetMaxCostMisses();
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466 | backData.mMaxCostMisses = sc.GetMaxCostMisses();
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467 |
|
---|
468 | // set the time stamp so the order of traversal can be reconstructed
|
---|
469 | node->SetTimeStamp(mHierarchyManager->mTimeStamp ++);
|
---|
470 |
|
---|
471 | // assign the objects in sorted order
|
---|
472 | if (mUseGlobalSorting)
|
---|
473 | {
|
---|
474 | AssignSortedObjects(sc, frontData, backData);
|
---|
475 | }
|
---|
476 |
|
---|
477 | // return the new interior node
|
---|
478 | return node;
|
---|
479 | }
|
---|
480 |
|
---|
481 |
|
---|
482 | BvhNode *BvHierarchy::Subdivide(SplitQueue &tQueue,
|
---|
483 | SubdivisionCandidate *splitCandidate,
|
---|
484 | const bool globalCriteriaMet)
|
---|
485 | {
|
---|
486 | BvhSubdivisionCandidate *sc =
|
---|
487 | dynamic_cast<BvhSubdivisionCandidate *>(splitCandidate);
|
---|
488 | BvhTraversalData &tData = sc->mParentData;
|
---|
489 |
|
---|
490 | BvhNode *currentNode = tData.mNode;
|
---|
491 |
|
---|
492 | if (!LocalTerminationCriteriaMet(tData) && !globalCriteriaMet)
|
---|
493 | {
|
---|
494 | //////////////
|
---|
495 | //-- continue subdivision
|
---|
496 |
|
---|
497 | BvhTraversalData tFrontData;
|
---|
498 | BvhTraversalData tBackData;
|
---|
499 |
|
---|
500 | // create new interior node and two leaf node
|
---|
501 | currentNode = SubdivideNode(*sc, tFrontData, tBackData);
|
---|
502 |
|
---|
503 | // decrease the weighted average cost of the subdivisoin
|
---|
504 | mTotalCost -= sc->GetRenderCostDecrease();
|
---|
505 | mPvsEntries += sc->GetPvsEntriesIncr();
|
---|
506 |
|
---|
507 | // subdivision statistics
|
---|
508 | if (1) PrintSubdivisionStats(*sc);
|
---|
509 |
|
---|
510 |
|
---|
511 | ///////////////////////////
|
---|
512 | //-- push the new split candidates on the queue
|
---|
513 |
|
---|
514 | BvhSubdivisionCandidate *frontCandidate =
|
---|
515 | new BvhSubdivisionCandidate(tFrontData);
|
---|
516 | BvhSubdivisionCandidate *backCandidate =
|
---|
517 | new BvhSubdivisionCandidate(tBackData);
|
---|
518 |
|
---|
519 | EvalSubdivisionCandidate(*frontCandidate);
|
---|
520 | EvalSubdivisionCandidate(*backCandidate);
|
---|
521 |
|
---|
522 | // cross reference
|
---|
523 | tFrontData.mNode->SetSubdivisionCandidate(frontCandidate);
|
---|
524 | tBackData.mNode->SetSubdivisionCandidate(backCandidate);
|
---|
525 |
|
---|
526 | //cout << "f: " << frontCandidate->GetPriority() << " b: " << backCandidate->GetPriority() << endl;
|
---|
527 | tQueue.Push(frontCandidate);
|
---|
528 | tQueue.Push(backCandidate);
|
---|
529 | }
|
---|
530 |
|
---|
531 | /////////////////////////////////
|
---|
532 | //-- node is a leaf => terminate traversal
|
---|
533 |
|
---|
534 | if (currentNode->IsLeaf())
|
---|
535 | {
|
---|
536 | /////////////////////
|
---|
537 | //-- store additional info
|
---|
538 | EvaluateLeafStats(tData);
|
---|
539 |
|
---|
540 | // this leaf is no candidate for splitting anymore
|
---|
541 | // => detach subdivision candidate
|
---|
542 | tData.mNode->SetSubdivisionCandidate(NULL);
|
---|
543 | // detach node so we don't delete it with the traversal data
|
---|
544 | tData.mNode = NULL;
|
---|
545 | }
|
---|
546 |
|
---|
547 | return currentNode;
|
---|
548 | }
|
---|
549 |
|
---|
550 |
|
---|
551 | float BvHierarchy::EvalPriority(const BvhSubdivisionCandidate &splitCandidate,
|
---|
552 | const float renderCostDecr,
|
---|
553 | const float oldRenderCost) const
|
---|
554 | {
|
---|
555 | float priority;
|
---|
556 |
|
---|
557 | if (mIsInitialSubdivision)
|
---|
558 | {
|
---|
559 | priority = (float)-splitCandidate.mParentData.mDepth;
|
---|
560 | return priority;
|
---|
561 | }
|
---|
562 |
|
---|
563 | BvhLeaf *leaf = splitCandidate.mParentData.mNode;
|
---|
564 |
|
---|
565 | // surface area heuristics is used when there is
|
---|
566 | // no view space subdivision available.
|
---|
567 | // In order to have some prioritized traversal,
|
---|
568 | // we use this formula instead
|
---|
569 | if (mHierarchyManager->GetViewSpaceSubdivisionType() ==
|
---|
570 | HierarchyManager::NO_VIEWSPACE_SUBDIV)
|
---|
571 | {
|
---|
572 | priority = EvalSahCost(leaf);
|
---|
573 | }
|
---|
574 | else
|
---|
575 | {
|
---|
576 | // take render cost of node into account
|
---|
577 | // otherwise danger of being stuck in a local minimum!
|
---|
578 | const float factor = mRenderCostDecreaseWeight;
|
---|
579 |
|
---|
580 | priority = factor * renderCostDecr + (1.0f - factor) * oldRenderCost;
|
---|
581 |
|
---|
582 | if (mHierarchyManager->mConsiderMemory)
|
---|
583 | {
|
---|
584 | priority /= ((float)splitCandidate.GetPvsEntriesIncr() + mMemoryConst);
|
---|
585 | }
|
---|
586 | }
|
---|
587 |
|
---|
588 | // hack: don't allow empty splits to be taken
|
---|
589 | if (splitCandidate.mFrontObjects.empty() || splitCandidate.mBackObjects.empty())
|
---|
590 | priority = 0;
|
---|
591 |
|
---|
592 | return priority;
|
---|
593 | }
|
---|
594 |
|
---|
595 |
|
---|
596 | static float AvgRayContribution(const int pvs, const int nRays)
|
---|
597 | {
|
---|
598 | return (float)pvs / ((float)nRays + Limits::Small);
|
---|
599 | }
|
---|
600 |
|
---|
601 |
|
---|
602 | void BvHierarchy::EvalSubdivisionCandidate(BvhSubdivisionCandidate &splitCandidate,
|
---|
603 | bool computeSplitPlane)
|
---|
604 | {
|
---|
605 | if (computeSplitPlane)
|
---|
606 | {
|
---|
607 | const bool sufficientSamples =
|
---|
608 | splitCandidate.mParentData.mNumRays > mMinRaysForVisibility;
|
---|
609 |
|
---|
610 | const bool useVisibiliyBasedHeuristics =
|
---|
611 | !mUseSah &&
|
---|
612 | (mHierarchyManager->GetViewSpaceSubdivisionType() ==
|
---|
613 | HierarchyManager::KD_BASED_VIEWSPACE_SUBDIV) &&
|
---|
614 | sufficientSamples;
|
---|
615 |
|
---|
616 | // compute best object partition
|
---|
617 | const float ratio = SelectObjectPartition(splitCandidate.mParentData,
|
---|
618 | splitCandidate.mFrontObjects,
|
---|
619 | splitCandidate.mBackObjects,
|
---|
620 | useVisibiliyBasedHeuristics);
|
---|
621 |
|
---|
622 | // cost ratio violated?
|
---|
623 | const bool maxCostRatioViolated = mTermMaxCostRatio < ratio;
|
---|
624 | const int previousMisses = splitCandidate.mParentData.mMaxCostMisses;
|
---|
625 |
|
---|
626 | splitCandidate.SetMaxCostMisses(maxCostRatioViolated ?
|
---|
627 | previousMisses + 1 : previousMisses);
|
---|
628 | }
|
---|
629 |
|
---|
630 | const BvhTraversalData &tData = splitCandidate.mParentData;
|
---|
631 | BvhLeaf *leaf = tData.mNode;
|
---|
632 |
|
---|
633 | // avg contribution of a ray to a pvs
|
---|
634 | const float pvs = (float)CountViewCells(leaf->mObjects);
|
---|
635 | const float avgRayContri = AvgRayContribution((int)pvs, tData.mNumRays);
|
---|
636 |
|
---|
637 | // high avg ray contri, the result is influenced by undersampling
|
---|
638 | splitCandidate.SetAvgRayContribution(avgRayContri);
|
---|
639 | const float viewSpaceVol = GetViewSpaceVolume();
|
---|
640 |
|
---|
641 | const float oldVolume = EvalViewCellsVolume(leaf->mObjects) / viewSpaceVol;
|
---|
642 | const float oldRatio = (tData.mVolume) > 0 ? oldVolume / tData.mVolume : 1;
|
---|
643 | const float parentVol = tData.mCorrectedVolume * oldRatio;
|
---|
644 |
|
---|
645 | // this leaf is a pvs entry in all the view cells
|
---|
646 | // that see one of the objects.
|
---|
647 | const float frontVol = EvalViewCellsVolume(splitCandidate.mFrontObjects) / viewSpaceVol;
|
---|
648 | const float backVol = EvalViewCellsVolume(splitCandidate.mBackObjects) / viewSpaceVol;
|
---|
649 |
|
---|
650 | splitCandidate.mCorrectedFrontVolume =
|
---|
651 | mHierarchyManager->EvalCorrectedPvs(frontVol, parentVol, avgRayContri);
|
---|
652 |
|
---|
653 | splitCandidate.mCorrectedBackVolume =
|
---|
654 | mHierarchyManager->EvalCorrectedPvs(backVol, parentVol, avgRayContri);
|
---|
655 |
|
---|
656 | const float relfrontCost = splitCandidate.mCorrectedFrontVolume *
|
---|
657 | EvalAbsCost(splitCandidate.mFrontObjects);
|
---|
658 | const float relBackCost = splitCandidate.mCorrectedBackVolume *
|
---|
659 | EvalAbsCost(splitCandidate.mBackObjects);
|
---|
660 | const float relParentCost = parentVol * EvalAbsCost(leaf->mObjects);
|
---|
661 |
|
---|
662 | // compute global decrease in render cost
|
---|
663 | const float newRenderCost = relfrontCost + relBackCost;
|
---|
664 | const float renderCostDecr = relParentCost - newRenderCost;
|
---|
665 |
|
---|
666 | splitCandidate.SetRenderCostDecrease(renderCostDecr);
|
---|
667 |
|
---|
668 | // increase in pvs entries
|
---|
669 | const int pvsEntriesIncr = EvalPvsEntriesIncr(splitCandidate, avgRayContri);
|
---|
670 | splitCandidate.SetPvsEntriesIncr(pvsEntriesIncr);
|
---|
671 |
|
---|
672 | if (0)
|
---|
673 | cout << "bvh volume cost"
|
---|
674 | << " avg ray contri: " << avgRayContri << " ratio: " << oldRatio
|
---|
675 | << " parent: " << parentVol << " old vol: " << oldVolume
|
---|
676 | << " frontvol: " << frontVol << " corr. " << splitCandidate.mCorrectedFrontVolume
|
---|
677 | << " backvol: " << backVol << " corr. " << splitCandidate.mCorrectedBackVolume << endl;
|
---|
678 |
|
---|
679 | #ifdef GTP_DEBUG
|
---|
680 | Debug << "old render cost: " << oldRenderCost << endl;
|
---|
681 | Debug << "new render cost: " << newRenderCost << endl;
|
---|
682 | Debug << "render cost decrease: " << renderCostDecr << endl;
|
---|
683 | #endif
|
---|
684 |
|
---|
685 | float priority = EvalPriority(splitCandidate,
|
---|
686 | renderCostDecr,
|
---|
687 | relParentCost);
|
---|
688 |
|
---|
689 | // compute global decrease in render cost
|
---|
690 | splitCandidate.SetPriority(priority);
|
---|
691 | }
|
---|
692 |
|
---|
693 |
|
---|
694 | int BvHierarchy::EvalPvsEntriesIncr(BvhSubdivisionCandidate &splitCandidate,
|
---|
695 | const float avgRayContri) const
|
---|
696 | {
|
---|
697 | const float oldPvsSize = (float)CountViewCells(splitCandidate.mParentData.mNode->mObjects);
|
---|
698 | const float oldPvsRatio = (splitCandidate.mParentData.mPvs > 0) ? oldPvsSize / splitCandidate.mParentData.mPvs : 1;
|
---|
699 |
|
---|
700 | const float parentPvs = splitCandidate.mParentData.mCorrectedPvs * oldPvsRatio;
|
---|
701 |
|
---|
702 | const int frontViewCells = CountViewCells(splitCandidate.mFrontObjects);
|
---|
703 | const int backViewCells = CountViewCells(splitCandidate.mBackObjects);
|
---|
704 |
|
---|
705 | splitCandidate.mCorrectedFrontPvs =
|
---|
706 | mHierarchyManager->EvalCorrectedPvs((float)frontViewCells, parentPvs, avgRayContri);
|
---|
707 | splitCandidate.mCorrectedBackPvs =
|
---|
708 | mHierarchyManager->EvalCorrectedPvs((float)backViewCells, parentPvs, avgRayContri);
|
---|
709 |
|
---|
710 | if (0)
|
---|
711 | cout << "bvh pvs"
|
---|
712 | << " avg ray contri: " << avgRayContri << " ratio: " << oldPvsRatio
|
---|
713 | << " parent: " << parentPvs << " " << " old vol: " << oldPvsSize
|
---|
714 | << " frontpvs: " << frontViewCells << " corr. " << splitCandidate.mCorrectedFrontPvs
|
---|
715 | << " backpvs: " << frontViewCells << " corr. " << splitCandidate.mCorrectedBackPvs << endl;
|
---|
716 |
|
---|
717 | return (int)(splitCandidate.mCorrectedFrontPvs + splitCandidate.mCorrectedBackPvs - parentPvs);
|
---|
718 | }
|
---|
719 |
|
---|
720 |
|
---|
721 | inline bool BvHierarchy::LocalTerminationCriteriaMet(const BvhTraversalData &tData) const
|
---|
722 | {
|
---|
723 | const bool terminationCriteriaMet =
|
---|
724 | (0
|
---|
725 | || ((int)tData.mNode->mObjects.size() <= 1)//mTermMinObjects)
|
---|
726 | //|| (data.mProbability <= mTermMinProbability)
|
---|
727 | //|| (data.mNumRays <= mTermMinRays)
|
---|
728 | );
|
---|
729 |
|
---|
730 | #ifdef _DEBUG
|
---|
731 | if (terminationCriteriaMet)
|
---|
732 | {
|
---|
733 | cout << "bvh local termination criteria met:" << endl;
|
---|
734 | cout << "objects: " << (int)tData.mNode->mObjects.size() << " " << mTermMinObjects << endl;
|
---|
735 | }
|
---|
736 | #endif
|
---|
737 | return terminationCriteriaMet;
|
---|
738 | }
|
---|
739 |
|
---|
740 |
|
---|
741 | inline bool BvHierarchy::GlobalTerminationCriteriaMet(const BvhTraversalData &data) const
|
---|
742 | {
|
---|
743 | // note: tracking for global cost termination
|
---|
744 | // does not make much sense for interleaved vsp / osp partition
|
---|
745 | // as it is the responsibility of the hierarchy manager
|
---|
746 |
|
---|
747 | const bool terminationCriteriaMet =
|
---|
748 | (0
|
---|
749 | || (mBvhStats.Leaves() >= mTermMaxLeaves)
|
---|
750 | //|| (mBvhStats.mGlobalCostMisses >= mTermGlobalCostMissTolerance)
|
---|
751 | //|| mOutOfMemory
|
---|
752 | );
|
---|
753 |
|
---|
754 | #ifdef GTP_DEBUG
|
---|
755 | if (terminationCriteriaMet)
|
---|
756 | {
|
---|
757 | Debug << "bvh global termination criteria met:" << endl;
|
---|
758 | Debug << "cost misses: " << mBvhStats.mGlobalCostMisses << " " << mTermGlobalCostMissTolerance << endl;
|
---|
759 | Debug << "leaves: " << mBvhStats.Leaves() << " " << mTermMaxLeaves << endl;
|
---|
760 | }
|
---|
761 | #endif
|
---|
762 | return terminationCriteriaMet;
|
---|
763 | }
|
---|
764 |
|
---|
765 |
|
---|
766 | void BvHierarchy::EvaluateLeafStats(const BvhTraversalData &data)
|
---|
767 | {
|
---|
768 | // the node became a leaf -> evaluate stats for leafs
|
---|
769 | BvhLeaf *leaf = data.mNode;
|
---|
770 |
|
---|
771 | ++ mCreatedLeaves;
|
---|
772 |
|
---|
773 |
|
---|
774 | /*if (data.mProbability <= mTermMinProbability)
|
---|
775 | {
|
---|
776 | ++ mBvhStats.minProbabilityNodes;
|
---|
777 | }*/
|
---|
778 |
|
---|
779 | ////////////////////////////////////////////
|
---|
780 | // depth related stuff
|
---|
781 |
|
---|
782 | if (data.mDepth < mBvhStats.minDepth)
|
---|
783 | {
|
---|
784 | mBvhStats.minDepth = data.mDepth;
|
---|
785 | }
|
---|
786 |
|
---|
787 | if (data.mDepth >= mTermMaxDepth)
|
---|
788 | {
|
---|
789 | ++ mBvhStats.maxDepthNodes;
|
---|
790 | }
|
---|
791 |
|
---|
792 | // accumulate depth to compute average depth
|
---|
793 | mBvhStats.accumDepth += data.mDepth;
|
---|
794 |
|
---|
795 |
|
---|
796 | ////////////////////////////////////////////
|
---|
797 | // objects related stuff
|
---|
798 |
|
---|
799 | // note: the sum should alwaysbe total number of objects for bvh
|
---|
800 | mBvhStats.objectRefs += (int)leaf->mObjects.size();
|
---|
801 |
|
---|
802 | if ((int)leaf->mObjects.size() <= mTermMinObjects)
|
---|
803 | {
|
---|
804 | ++ mBvhStats.minObjectsNodes;
|
---|
805 | }
|
---|
806 |
|
---|
807 | if (leaf->mObjects.empty())
|
---|
808 | {
|
---|
809 | ++ mBvhStats.emptyNodes;
|
---|
810 | }
|
---|
811 |
|
---|
812 | if ((int)leaf->mObjects.size() > mBvhStats.maxObjectRefs)
|
---|
813 | {
|
---|
814 | mBvhStats.maxObjectRefs = (int)leaf->mObjects.size();
|
---|
815 | }
|
---|
816 |
|
---|
817 | if ((int)leaf->mObjects.size() < mBvhStats.minObjectRefs)
|
---|
818 | {
|
---|
819 | mBvhStats.minObjectRefs = (int)leaf->mObjects.size();
|
---|
820 | }
|
---|
821 |
|
---|
822 | ////////////////////////////////////////////
|
---|
823 | // ray related stuff
|
---|
824 |
|
---|
825 | // note: this number should always accumulate to the total number of rays
|
---|
826 | mBvhStats.rayRefs += data.mNumRays;
|
---|
827 |
|
---|
828 | if (data.mNumRays <= mTermMinRays)
|
---|
829 | {
|
---|
830 | ++ mBvhStats.minRaysNodes;
|
---|
831 | }
|
---|
832 |
|
---|
833 | if (data.mNumRays > mBvhStats.maxRayRefs)
|
---|
834 | {
|
---|
835 | mBvhStats.maxRayRefs = data.mNumRays;
|
---|
836 | }
|
---|
837 |
|
---|
838 | if (data.mNumRays < mBvhStats.minRayRefs)
|
---|
839 | {
|
---|
840 | mBvhStats.minRayRefs = data.mNumRays;
|
---|
841 | }
|
---|
842 |
|
---|
843 | #ifdef _DEBUG
|
---|
844 | cout << "depth: " << data.mDepth << " objects: " << (int)leaf->mObjects.size()
|
---|
845 | << " rays: " << data.mNumRays << " rays / objects "
|
---|
846 | << (float)data.mNumRays / (float)leaf->mObjects.size() << endl;
|
---|
847 | #endif
|
---|
848 | }
|
---|
849 |
|
---|
850 |
|
---|
851 | #if 0
|
---|
852 |
|
---|
853 | /// compute object boundaries using spatial mid split
|
---|
854 | float BvHierarchy::EvalLocalObjectPartition(const BvhTraversalData &tData,
|
---|
855 | const int axis,
|
---|
856 | ObjectContainer &objectsFront,
|
---|
857 | ObjectContainer &objectsBack)
|
---|
858 | {
|
---|
859 | const float maxBox = tData.mBoundingBox.Max(axis);
|
---|
860 | const float minBox = tData.mBoundingBox.Min(axis);
|
---|
861 |
|
---|
862 | float midPoint = (maxBox + minBox) * 0.5f;
|
---|
863 |
|
---|
864 | ObjectContainer::const_iterator oit, oit_end = tData.mNode->mObjects.end();
|
---|
865 |
|
---|
866 | for (oit = tData.mNode->mObjects.begin(); oit != oit_end; ++ oit)
|
---|
867 | {
|
---|
868 | Intersectable *obj = *oit;
|
---|
869 | const AxisAlignedBox3 box = obj->GetBox();
|
---|
870 |
|
---|
871 | const float objMid = (box.Max(axis) + box.Min(axis)) * 0.5f;
|
---|
872 |
|
---|
873 | // object mailed => belongs to back objects
|
---|
874 | if (objMid < midPoint)
|
---|
875 | {
|
---|
876 | objectsBack.push_back(obj);
|
---|
877 | }
|
---|
878 | else
|
---|
879 | {
|
---|
880 | objectsFront.push_back(obj);
|
---|
881 | }
|
---|
882 | }
|
---|
883 |
|
---|
884 | const float oldRenderCost = EvalRenderCost(tData.mNode->mObjects);
|
---|
885 | const float newRenderCost = EvalRenderCost(objectsFront) * EvalRenderCost(objectsBack);
|
---|
886 |
|
---|
887 | const float ratio = newRenderCost / oldRenderCost;
|
---|
888 | return ratio;
|
---|
889 | }
|
---|
890 |
|
---|
891 | #else
|
---|
892 |
|
---|
893 | /// compute object partition by getting balanced objects on the left and right side
|
---|
894 | float BvHierarchy::EvalLocalObjectPartition(const BvhTraversalData &tData,
|
---|
895 | const int axis,
|
---|
896 | ObjectContainer &objectsFront,
|
---|
897 | ObjectContainer &objectsBack)
|
---|
898 | {
|
---|
899 | PrepareLocalSubdivisionCandidates(tData, axis);
|
---|
900 |
|
---|
901 | SortableEntryContainer::const_iterator cit, cit_end = mSubdivisionCandidates->end();
|
---|
902 |
|
---|
903 | int i = 0;
|
---|
904 | const int border = (int)tData.mNode->mObjects.size() / 2;
|
---|
905 |
|
---|
906 | for (cit = mSubdivisionCandidates->begin(); cit != cit_end; ++ cit, ++ i)
|
---|
907 | {
|
---|
908 | Intersectable *obj = (*cit).mObject;
|
---|
909 |
|
---|
910 | // object mailed => belongs to back objects
|
---|
911 | if (i < border)
|
---|
912 | {
|
---|
913 | objectsBack.push_back(obj);
|
---|
914 | }
|
---|
915 | else
|
---|
916 | {
|
---|
917 | objectsFront.push_back(obj);
|
---|
918 | }
|
---|
919 | }
|
---|
920 |
|
---|
921 | #if 1
|
---|
922 | const float cost = (tData.mNode->GetBoundingBox().Size().DrivingAxis() == axis) ? -1.0f : 0.0f;
|
---|
923 | #else
|
---|
924 | const float oldRenderCost = EvalRenderCost(tData.mNode->mObjects);
|
---|
925 | const float newRenderCost = EvalRenderCost(objectsFront) * EvalRenderCost(objectsBack);
|
---|
926 |
|
---|
927 | const float cost = newRenderCost / oldRenderCost;
|
---|
928 | #endif
|
---|
929 |
|
---|
930 | return cost;
|
---|
931 | }
|
---|
932 | #endif
|
---|
933 |
|
---|
934 | #if 1
|
---|
935 |
|
---|
936 | float BvHierarchy::EvalSah(const BvhTraversalData &tData,
|
---|
937 | const int axis,
|
---|
938 | ObjectContainer &objectsFront,
|
---|
939 | ObjectContainer &objectsBack)
|
---|
940 | {
|
---|
941 | // go through the lists, count the number of objects left and right
|
---|
942 | // and evaluate the following cost funcion:
|
---|
943 | // C = ct_div_ci + (ol + or) / queries
|
---|
944 | PrepareLocalSubdivisionCandidates(tData, axis);
|
---|
945 |
|
---|
946 | const float totalRenderCost = EvalAbsCost(tData.mNode->mObjects);
|
---|
947 | float objectsLeft = 0, objectsRight = totalRenderCost;
|
---|
948 |
|
---|
949 | const AxisAlignedBox3 nodeBbox = tData.mNode->GetBoundingBox();
|
---|
950 | const float boxArea = nodeBbox.SurfaceArea();
|
---|
951 |
|
---|
952 | float minSum = 1e20f;
|
---|
953 |
|
---|
954 | float minBorder = nodeBbox.Max(axis);
|
---|
955 | float maxBorder = nodeBbox.Min(axis);
|
---|
956 |
|
---|
957 | float areaLeft = 0, areaRight = 0;
|
---|
958 |
|
---|
959 | SortableEntryContainer::const_iterator currentPos =
|
---|
960 | mSubdivisionCandidates->begin();
|
---|
961 |
|
---|
962 | vector<float> bordersRight;
|
---|
963 |
|
---|
964 | // we keep track of both borders of the bounding boxes =>
|
---|
965 | // store the events in descending order
|
---|
966 |
|
---|
967 | bordersRight.resize(mSubdivisionCandidates->size());
|
---|
968 |
|
---|
969 | SortableEntryContainer::reverse_iterator rcit =
|
---|
970 | mSubdivisionCandidates->rbegin(), rcit_end =
|
---|
971 | mSubdivisionCandidates->rend();
|
---|
972 |
|
---|
973 | vector<float>::reverse_iterator rbit = bordersRight.rbegin();
|
---|
974 |
|
---|
975 | for (; rcit != rcit_end; ++ rcit, ++ rbit)
|
---|
976 | {
|
---|
977 | Intersectable *obj = (*rcit).mObject;
|
---|
978 | const AxisAlignedBox3 obox = obj->GetBox();
|
---|
979 |
|
---|
980 | if (obox.Min(axis) < minBorder)
|
---|
981 | {
|
---|
982 | minBorder = obox.Min(axis);
|
---|
983 | }
|
---|
984 |
|
---|
985 | (*rbit) = minBorder;
|
---|
986 | }
|
---|
987 |
|
---|
988 | // temporary surface areas
|
---|
989 | float al = 0;
|
---|
990 | float ar = boxArea;
|
---|
991 |
|
---|
992 | vector<float>::const_iterator bit = bordersRight.begin();
|
---|
993 | SortableEntryContainer::const_iterator cit, cit_end = mSubdivisionCandidates->end();
|
---|
994 |
|
---|
995 | for (cit = mSubdivisionCandidates->begin(); cit != cit_end; ++ cit, ++ bit)
|
---|
996 | {
|
---|
997 | Intersectable *obj = (*cit).mObject;
|
---|
998 |
|
---|
999 | const float renderCost = mViewCellsManager->EvalRenderCost(obj);
|
---|
1000 |
|
---|
1001 | objectsLeft += renderCost;
|
---|
1002 | objectsRight -= renderCost;
|
---|
1003 |
|
---|
1004 | const AxisAlignedBox3 obox = obj->GetBox();
|
---|
1005 |
|
---|
1006 | // the borders of the bounding boxes have changed
|
---|
1007 | if (obox.Max(axis) > maxBorder)
|
---|
1008 | {
|
---|
1009 | maxBorder = obox.Max(axis);
|
---|
1010 | }
|
---|
1011 |
|
---|
1012 | minBorder = (*bit);
|
---|
1013 |
|
---|
1014 | AxisAlignedBox3 lbox = nodeBbox;
|
---|
1015 | AxisAlignedBox3 rbox = nodeBbox;
|
---|
1016 |
|
---|
1017 | lbox.SetMax(axis, maxBorder);
|
---|
1018 | rbox.SetMin(axis, minBorder);
|
---|
1019 |
|
---|
1020 | al = lbox.SurfaceArea();
|
---|
1021 | ar = rbox.SurfaceArea();
|
---|
1022 |
|
---|
1023 | const bool noValidSplit = ((objectsLeft <= Limits::Small) || (objectsRight <= Limits::Small));
|
---|
1024 | const float sum = noValidSplit ? 1e25f : objectsLeft * al + objectsRight * ar;
|
---|
1025 |
|
---|
1026 | /*cout << "pos=" << (*cit).mPos << "\t q=(" << objectsLeft << "," << objectsRight <<")\t r=("
|
---|
1027 | << lbox.SurfaceArea() << "," << rbox.SurfaceArea() << ")" << endl;
|
---|
1028 | cout << "minborder: " << minBorder << " maxborder: " << maxBorder << endl;
|
---|
1029 | cout << "cost= " << sum << endl;*/
|
---|
1030 |
|
---|
1031 | if (sum < minSum)
|
---|
1032 | {
|
---|
1033 | minSum = sum;
|
---|
1034 | areaLeft = al;
|
---|
1035 | areaRight = ar;
|
---|
1036 |
|
---|
1037 | // objects belong to left side now
|
---|
1038 | for (; currentPos != (cit + 1); ++ currentPos);
|
---|
1039 | }
|
---|
1040 | }
|
---|
1041 |
|
---|
1042 | ////////////
|
---|
1043 | //-- assign object to front and back volume
|
---|
1044 |
|
---|
1045 | // belongs to back bv
|
---|
1046 | for (cit = mSubdivisionCandidates->begin(); cit != currentPos; ++ cit)
|
---|
1047 | objectsBack.push_back((*cit).mObject);
|
---|
1048 |
|
---|
1049 | // belongs to front bv
|
---|
1050 | for (cit = currentPos; cit != cit_end; ++ cit)
|
---|
1051 | objectsFront.push_back((*cit).mObject);
|
---|
1052 |
|
---|
1053 | float newCost = minSum / boxArea;
|
---|
1054 | float ratio = newCost / totalRenderCost;
|
---|
1055 |
|
---|
1056 | #ifdef GTP_DEBUG
|
---|
1057 | cout << "\n\nobjects=(" << (int)objectsBack.size() << "," << (int)objectsFront.size() << " of "
|
---|
1058 | << (int)tData.mNode->mObjects.size() << ")\t area=("
|
---|
1059 | << areaLeft << ", " << areaRight << ", " << boxArea << ")" << endl
|
---|
1060 | << "cost= " << newCost << " oldCost=" << totalRenderCost / boxArea << endl;
|
---|
1061 | #endif
|
---|
1062 |
|
---|
1063 | return ratio;
|
---|
1064 | }
|
---|
1065 |
|
---|
1066 | #else
|
---|
1067 |
|
---|
1068 | float BvHierarchy::EvalSah(const BvhTraversalData &tData,
|
---|
1069 | const int axis,
|
---|
1070 | ObjectContainer &objectsFront,
|
---|
1071 | ObjectContainer &objectsBack)
|
---|
1072 | {
|
---|
1073 | // go through the lists, count the number of objects left and right
|
---|
1074 | // and evaluate the following cost funcion:
|
---|
1075 | // C = ct_div_ci + (ol + or) / queries
|
---|
1076 | PrepareLocalSubdivisionCandidates(tData, axis);
|
---|
1077 |
|
---|
1078 | const float totalRenderCost = EvalAbsCost(tData.mNode->mObjects);
|
---|
1079 | float objectsLeft = 0, objectsRight = totalRenderCost;
|
---|
1080 |
|
---|
1081 | const AxisAlignedBox3 nodeBbox = tData.mNode->GetBoundingBox();
|
---|
1082 |
|
---|
1083 | const float minBox = nodeBbox.Min(axis);
|
---|
1084 | const float maxBox = nodeBbox.Max(axis);
|
---|
1085 | const float boxArea = nodeBbox.SurfaceArea();
|
---|
1086 |
|
---|
1087 | float minSum = 1e20f;
|
---|
1088 |
|
---|
1089 | Vector3 minBorder = nodeBbox.Max();
|
---|
1090 | Vector3 maxBorder = nodeBbox.Min();
|
---|
1091 |
|
---|
1092 | float areaLeft = 0, areaRight = 0;
|
---|
1093 |
|
---|
1094 | SortableEntryContainer::const_iterator currentPos =
|
---|
1095 | mSubdivisionCandidates->begin();
|
---|
1096 |
|
---|
1097 | vector<Vector3> bordersRight;
|
---|
1098 |
|
---|
1099 | // we keep track of both borders of the bounding boxes =>
|
---|
1100 | // store the events in descending order
|
---|
1101 | bordersRight.resize(mSubdivisionCandidates->size());
|
---|
1102 |
|
---|
1103 | SortableEntryContainer::reverse_iterator rcit =
|
---|
1104 | mSubdivisionCandidates->rbegin(), rcit_end =
|
---|
1105 | mSubdivisionCandidates->rend();
|
---|
1106 |
|
---|
1107 | vector<Vector3>::reverse_iterator rbit = bordersRight.rbegin();
|
---|
1108 |
|
---|
1109 | for (; rcit != rcit_end; ++ rcit, ++ rbit)
|
---|
1110 | {
|
---|
1111 | Intersectable *obj = (*rcit).mObject;
|
---|
1112 | const AxisAlignedBox3 obox = obj->GetBox();
|
---|
1113 |
|
---|
1114 | for (int i = 0; i < 3; ++ i)
|
---|
1115 | {
|
---|
1116 | if (obox.Min(i) < minBorder[i])
|
---|
1117 | {
|
---|
1118 | minBorder[i] = obox.Min(i);
|
---|
1119 | }
|
---|
1120 | }
|
---|
1121 |
|
---|
1122 | (*rbit) = minBorder;
|
---|
1123 | }
|
---|
1124 |
|
---|
1125 | // temporary surface areas
|
---|
1126 | float al = 0;
|
---|
1127 | float ar = boxArea;
|
---|
1128 |
|
---|
1129 | vector<Vector3>::const_iterator bit = bordersRight.begin();
|
---|
1130 | SortableEntryContainer::const_iterator cit, cit_end =
|
---|
1131 | mSubdivisionCandidates->end();
|
---|
1132 |
|
---|
1133 | for (cit = mSubdivisionCandidates->begin(); cit != cit_end; ++ cit, ++ bit)
|
---|
1134 | {
|
---|
1135 | Intersectable *obj = (*cit).mObject;
|
---|
1136 |
|
---|
1137 | const float renderCost = mViewCellsManager->EvalRenderCost(obj);
|
---|
1138 |
|
---|
1139 | objectsLeft += renderCost;
|
---|
1140 | objectsRight -= renderCost;
|
---|
1141 |
|
---|
1142 | const AxisAlignedBox3 obox = obj->GetBox();
|
---|
1143 |
|
---|
1144 | AxisAlignedBox3 lbox = nodeBbox;
|
---|
1145 | AxisAlignedBox3 rbox = nodeBbox;
|
---|
1146 |
|
---|
1147 | // the borders of the left bounding box have changed
|
---|
1148 | for (int i = 0; i < 3; ++ i)
|
---|
1149 | {
|
---|
1150 | if (obox.Max(i) > maxBorder[i])
|
---|
1151 | {
|
---|
1152 | maxBorder[i] = obox.Max(i);
|
---|
1153 | }
|
---|
1154 | }
|
---|
1155 |
|
---|
1156 | minBorder = (*bit);
|
---|
1157 |
|
---|
1158 | lbox.SetMax(maxBorder);
|
---|
1159 | rbox.SetMin(minBorder);
|
---|
1160 |
|
---|
1161 | al = lbox.SurfaceArea();
|
---|
1162 | ar = rbox.SurfaceArea();
|
---|
1163 |
|
---|
1164 | const bool noValidSplit = ((objectsLeft <= Limits::Small) || (objectsRight <= Limits::Small));
|
---|
1165 | const float sum = noValidSplit ? 1e25 : objectsLeft * al + objectsRight * ar;
|
---|
1166 |
|
---|
1167 | /*cout << "pos=" << (*cit).mPos << "\t q=(" << objectsLeft << "," << objectsRight <<")\t r=("
|
---|
1168 | << lbox.SurfaceArea() << "," << rbox.SurfaceArea() << ")" << endl;
|
---|
1169 | cout << "minborder: " << minBorder << " maxborder: " << maxBorder << endl;
|
---|
1170 | cout << "cost= " << sum << endl;*/
|
---|
1171 |
|
---|
1172 | if (sum < minSum)
|
---|
1173 | {
|
---|
1174 | minSum = sum;
|
---|
1175 | areaLeft = al;
|
---|
1176 | areaRight = ar;
|
---|
1177 |
|
---|
1178 | // objects belong to left side now
|
---|
1179 | for (; currentPos != (cit + 1); ++ currentPos);
|
---|
1180 | }
|
---|
1181 | }
|
---|
1182 |
|
---|
1183 | /////////////
|
---|
1184 | //-- assign object to front and back volume
|
---|
1185 |
|
---|
1186 | // belongs to back bv
|
---|
1187 | for (cit = mSubdivisionCandidates->begin(); cit != currentPos; ++ cit)
|
---|
1188 | objectsBack.push_back((*cit).mObject);
|
---|
1189 |
|
---|
1190 | // belongs to front bv
|
---|
1191 | for (cit = currentPos; cit != cit_end; ++ cit)
|
---|
1192 | objectsFront.push_back((*cit).mObject);
|
---|
1193 |
|
---|
1194 | float newCost = minSum / boxArea;
|
---|
1195 | float ratio = newCost / totalRenderCost;
|
---|
1196 |
|
---|
1197 | #ifdef GTP_DEBUG
|
---|
1198 | cout << "\n\nobjects=(" << (int)objectsBack.size() << "," << (int)objectsFront.size() << " of "
|
---|
1199 | << (int)tData.mNode->mObjects.size() << ")\t area=("
|
---|
1200 | << areaLeft << ", " << areaRight << ", " << boxArea << ")" << endl
|
---|
1201 | << "cost= " << newCost << " oldCost=" << totalRenderCost / boxArea << endl;
|
---|
1202 | #endif
|
---|
1203 |
|
---|
1204 | return ratio;
|
---|
1205 | }
|
---|
1206 |
|
---|
1207 | #endif
|
---|
1208 |
|
---|
1209 | static bool PrepareOutput(const int axis,
|
---|
1210 | const int leaves,
|
---|
1211 | ofstream &sumStats,
|
---|
1212 | ofstream &vollStats,
|
---|
1213 | ofstream &volrStats)
|
---|
1214 | {
|
---|
1215 | if ((axis == 0) && (leaves > 0) && (leaves < 90))
|
---|
1216 | {
|
---|
1217 | char str[64];
|
---|
1218 | sprintf(str, "tmp/bvh_heur_sum-%04d.log", leaves);
|
---|
1219 | sumStats.open(str);
|
---|
1220 | sprintf(str, "tmp/bvh_heur_voll-%04d.log", leaves);
|
---|
1221 | vollStats.open(str);
|
---|
1222 | sprintf(str, "tmp/bvh_heur_volr-%04d.log", leaves);
|
---|
1223 | volrStats.open(str);
|
---|
1224 | }
|
---|
1225 |
|
---|
1226 | return sumStats.is_open() && vollStats.is_open() && volrStats.is_open();
|
---|
1227 | }
|
---|
1228 |
|
---|
1229 |
|
---|
1230 | static void PrintHeuristics(const float objectsRight,
|
---|
1231 | const float sum,
|
---|
1232 | const float volLeft,
|
---|
1233 | const float volRight,
|
---|
1234 | const float viewSpaceVol,
|
---|
1235 | ofstream &sumStats,
|
---|
1236 | ofstream &vollStats,
|
---|
1237 | ofstream &volrStats)
|
---|
1238 | {
|
---|
1239 | sumStats
|
---|
1240 | << "#Position\n" << objectsRight << endl
|
---|
1241 | << "#Sum\n" << sum / viewSpaceVol << endl
|
---|
1242 | << "#Vol\n" << (volLeft + volRight) / viewSpaceVol << endl;
|
---|
1243 |
|
---|
1244 | vollStats
|
---|
1245 | << "#Position\n" << objectsRight << endl
|
---|
1246 | << "#Vol\n" << volLeft / viewSpaceVol << endl;
|
---|
1247 |
|
---|
1248 | volrStats
|
---|
1249 | << "#Position\n" << objectsRight << endl
|
---|
1250 | << "#Vol\n" << volRight / viewSpaceVol << endl;
|
---|
1251 | }
|
---|
1252 |
|
---|
1253 |
|
---|
1254 | float BvHierarchy::EvalLocalCostHeuristics(const BvhTraversalData &tData,
|
---|
1255 | const int axis,
|
---|
1256 | ObjectContainer &objectsFront,
|
---|
1257 | ObjectContainer &objectsBack)
|
---|
1258 | {
|
---|
1259 | /////////////////////////////////////////////
|
---|
1260 | //-- go through the lists, count the number of objects
|
---|
1261 | //-- left and right and evaluate the cost funcion
|
---|
1262 |
|
---|
1263 | // prepare the heuristics by setting mailboxes and counters
|
---|
1264 | const float totalVol = PrepareHeuristics(tData, axis);
|
---|
1265 |
|
---|
1266 | // local helper variables
|
---|
1267 | float volLeft = 0;
|
---|
1268 | float volRight = totalVol;
|
---|
1269 |
|
---|
1270 | const float nTotalObjects = EvalAbsCost(tData.mNode->mObjects);
|
---|
1271 | float nObjectsLeft = 0;
|
---|
1272 | float nObjectsRight = nTotalObjects;
|
---|
1273 |
|
---|
1274 | const float viewSpaceVol =
|
---|
1275 | mViewCellsManager->GetViewSpaceBox().GetVolume();
|
---|
1276 |
|
---|
1277 | SortableEntryContainer::const_iterator backObjectsStart =
|
---|
1278 | mSubdivisionCandidates->begin();
|
---|
1279 |
|
---|
1280 | /////////////////////////////////
|
---|
1281 | //-- the parameters for the current optimum
|
---|
1282 |
|
---|
1283 | float volBack = volLeft;
|
---|
1284 | float volFront = volRight;
|
---|
1285 | float newRenderCost = nTotalObjects * totalVol;
|
---|
1286 |
|
---|
1287 | #ifdef GTP_DEBUG
|
---|
1288 | ofstream sumStats;
|
---|
1289 | ofstream vollStats;
|
---|
1290 | ofstream volrStats;
|
---|
1291 |
|
---|
1292 | const bool printStats = PrepareOutput(axis,
|
---|
1293 | mBvhStats.Leaves(),
|
---|
1294 | sumStats,
|
---|
1295 | vollStats,
|
---|
1296 | volrStats);
|
---|
1297 | #endif
|
---|
1298 |
|
---|
1299 | ///////////////////////
|
---|
1300 | //-- the sweep heuristics
|
---|
1301 | //-- traverse through events and find best split plane
|
---|
1302 |
|
---|
1303 | SortableEntryContainer::const_iterator cit,
|
---|
1304 | cit_end = cit_end = mSubdivisionCandidates->end();
|
---|
1305 |
|
---|
1306 | for (cit = mSubdivisionCandidates->begin(); cit != cit_end; ++ cit)
|
---|
1307 | {
|
---|
1308 | Intersectable *object = (*cit).mObject;
|
---|
1309 |
|
---|
1310 | // evaluate change in l and r volume
|
---|
1311 | // voll = view cells that see only left node (i.e., left pvs)
|
---|
1312 | // volr = view cells that see only right node (i.e., right pvs)
|
---|
1313 | EvalHeuristicsContribution(object, volLeft, volRight);
|
---|
1314 |
|
---|
1315 | const float rc = mViewCellsManager->EvalRenderCost(object);
|
---|
1316 |
|
---|
1317 | nObjectsLeft += rc;
|
---|
1318 | nObjectsRight -= rc;
|
---|
1319 |
|
---|
1320 | // split is only valid if #objects on left and right is not zero
|
---|
1321 | const bool noValidSplit = ((nObjectsLeft <= Limits::Small) ||
|
---|
1322 | (nObjectsRight <= Limits::Small));
|
---|
1323 |
|
---|
1324 | // the heuristics
|
---|
1325 | const float sum = noValidSplit ?
|
---|
1326 | 1e25f : volLeft * (float)nObjectsLeft + volRight * (float)nObjectsRight;
|
---|
1327 |
|
---|
1328 | #ifdef GTP_DEBUG
|
---|
1329 | if (printStats)
|
---|
1330 | {
|
---|
1331 | PrintHeuristics(nObjectsRight, sum, volLeft, volRight, viewSpaceVol,
|
---|
1332 | sumStats, vollStats, volrStats);
|
---|
1333 | }
|
---|
1334 | #endif
|
---|
1335 |
|
---|
1336 | if (sum < newRenderCost)
|
---|
1337 | {
|
---|
1338 | newRenderCost = sum;
|
---|
1339 |
|
---|
1340 | volBack = volLeft;
|
---|
1341 | volFront = volRight;
|
---|
1342 |
|
---|
1343 | // objects belongs to left side now
|
---|
1344 | for (; backObjectsStart != (cit + 1); ++ backObjectsStart);
|
---|
1345 | }
|
---|
1346 | }
|
---|
1347 |
|
---|
1348 | ////////////////////////////////////////
|
---|
1349 | //-- assign object to front and back volume
|
---|
1350 |
|
---|
1351 | // belongs to back bv
|
---|
1352 | for (cit = mSubdivisionCandidates->begin(); cit != backObjectsStart; ++ cit)
|
---|
1353 | {
|
---|
1354 | objectsBack.push_back((*cit).mObject);
|
---|
1355 | }
|
---|
1356 | // belongs to front bv
|
---|
1357 | for (cit = backObjectsStart; cit != cit_end; ++ cit)
|
---|
1358 | {
|
---|
1359 | objectsFront.push_back((*cit).mObject);
|
---|
1360 | }
|
---|
1361 |
|
---|
1362 | // render cost of the old parent
|
---|
1363 | const float oldRenderCost = (float)nTotalObjects * totalVol + Limits::Small;
|
---|
1364 | // the relative cost ratio
|
---|
1365 | const float ratio = newRenderCost / oldRenderCost;
|
---|
1366 |
|
---|
1367 | #ifdef GTP_DEBUG
|
---|
1368 | Debug << "\n§§§§ bvh eval const decrease §§§§" << endl
|
---|
1369 | << "back pvs: " << (int)objectsBack.size() << " front pvs: "
|
---|
1370 | << (int)objectsFront.size() << " total pvs: " << nTotalObjects << endl
|
---|
1371 | << "back p: " << volBack / viewSpaceVol << " front p "
|
---|
1372 | << volFront / viewSpaceVol << " p: " << totalVol / viewSpaceVol << endl
|
---|
1373 | << "old rc: " << oldRenderCost / viewSpaceVol << " new rc: "
|
---|
1374 | << newRenderCost / viewSpaceVol << endl
|
---|
1375 | << "render cost decrease: "
|
---|
1376 | << oldRenderCost / viewSpaceVol - newRenderCost / viewSpaceVol << endl;
|
---|
1377 | #endif
|
---|
1378 |
|
---|
1379 | return ratio;
|
---|
1380 | }
|
---|
1381 |
|
---|
1382 |
|
---|
1383 | void BvHierarchy::PrepareLocalSubdivisionCandidates(const BvhTraversalData &tData,
|
---|
1384 | const int axis)
|
---|
1385 | {
|
---|
1386 | //-- insert object queries
|
---|
1387 | ObjectContainer *objects = mUseGlobalSorting ?
|
---|
1388 | tData.mSortedObjects[axis] : &tData.mNode->mObjects;
|
---|
1389 |
|
---|
1390 | CreateLocalSubdivisionCandidates(*objects, &mSubdivisionCandidates, !mUseGlobalSorting, axis);
|
---|
1391 | }
|
---|
1392 |
|
---|
1393 |
|
---|
1394 | void BvHierarchy::CreateLocalSubdivisionCandidates(const ObjectContainer &objects,
|
---|
1395 | SortableEntryContainer **subdivisionCandidates,
|
---|
1396 | const bool sort,
|
---|
1397 | const int axis)
|
---|
1398 | {
|
---|
1399 | (*subdivisionCandidates)->clear();
|
---|
1400 |
|
---|
1401 | // compute requested size and look if subdivision candidate has to be recomputed
|
---|
1402 | const int requestedSize = (int)objects.size() * 2;
|
---|
1403 |
|
---|
1404 | // creates a sorted split candidates array
|
---|
1405 | if ((*subdivisionCandidates)->capacity() > 500000 &&
|
---|
1406 | requestedSize < (int)((*subdivisionCandidates)->capacity() / 10) )
|
---|
1407 | {
|
---|
1408 | delete (*subdivisionCandidates);
|
---|
1409 | (*subdivisionCandidates) = new SortableEntryContainer;
|
---|
1410 | }
|
---|
1411 |
|
---|
1412 | (*subdivisionCandidates)->reserve(requestedSize);
|
---|
1413 |
|
---|
1414 | ObjectContainer::const_iterator oit, oit_end = objects.end();
|
---|
1415 |
|
---|
1416 | for (oit = objects.begin(); oit < oit_end; ++ oit)
|
---|
1417 | {
|
---|
1418 | Intersectable *object = *oit;
|
---|
1419 | const AxisAlignedBox3 &box = object->GetBox();
|
---|
1420 | const float midPt = (box.Min(axis) + box.Max(axis)) * 0.5f;
|
---|
1421 |
|
---|
1422 | (*subdivisionCandidates)->push_back(SortableEntry(object, midPt));
|
---|
1423 | }
|
---|
1424 |
|
---|
1425 | if (sort)
|
---|
1426 | { // no presorted candidate list
|
---|
1427 | stable_sort((*subdivisionCandidates)->begin(), (*subdivisionCandidates)->end());
|
---|
1428 | }
|
---|
1429 | }
|
---|
1430 |
|
---|
1431 |
|
---|
1432 | const BvhStatistics &BvHierarchy::GetStatistics() const
|
---|
1433 | {
|
---|
1434 | return mBvhStats;
|
---|
1435 | }
|
---|
1436 |
|
---|
1437 |
|
---|
1438 | float BvHierarchy::PrepareHeuristics(const BvhTraversalData &tData,
|
---|
1439 | const int axis)
|
---|
1440 | {
|
---|
1441 | BvhLeaf *leaf = tData.mNode;
|
---|
1442 | float vol = 0;
|
---|
1443 |
|
---|
1444 | // sort so we can use a sweep from right to left
|
---|
1445 | PrepareLocalSubdivisionCandidates(tData, axis);
|
---|
1446 |
|
---|
1447 | // collect and mark the view cells as belonging to front pvs
|
---|
1448 | ViewCellContainer viewCells;
|
---|
1449 |
|
---|
1450 | const int numRays = CollectViewCells(tData.mNode->mObjects, viewCells, true, true);
|
---|
1451 | //cout << "number of rays: " << numRays << endl;
|
---|
1452 |
|
---|
1453 | ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
|
---|
1454 | for (vit = viewCells.begin(); vit != vit_end; ++ vit)
|
---|
1455 | {
|
---|
1456 | #if USE_VOLUMES_FOR_HEURISTICS
|
---|
1457 | const float volIncr = (*vit)->GetVolume();
|
---|
1458 | #else
|
---|
1459 | const float volIncr = 1.0f;
|
---|
1460 | #endif
|
---|
1461 | vol += volIncr;
|
---|
1462 | }
|
---|
1463 |
|
---|
1464 | // we will mail view cells switching to the back side
|
---|
1465 | ViewCell::NewMail();
|
---|
1466 |
|
---|
1467 | return vol;
|
---|
1468 | }
|
---|
1469 |
|
---|
1470 | ///////////////////////////////////////////////////////////
|
---|
1471 |
|
---|
1472 |
|
---|
1473 | void BvHierarchy::EvalHeuristicsContribution(Intersectable *obj,
|
---|
1474 | float &volLeft,
|
---|
1475 | float &volRight)
|
---|
1476 | {
|
---|
1477 | // collect all view cells associated with this objects
|
---|
1478 | // (also multiple times, if they are pierced by several rays)
|
---|
1479 | ViewCellContainer viewCells;
|
---|
1480 | const bool useMailboxing = false;
|
---|
1481 |
|
---|
1482 | CollectViewCells(obj, viewCells, useMailboxing, false, true);
|
---|
1483 |
|
---|
1484 | // classify view cells and compute volume contri accordingly
|
---|
1485 | // possible view cell classifications:
|
---|
1486 | // view cell mailed => view cell can be seen from left child node
|
---|
1487 | // view cell counter > 0 view cell can be seen from right child node
|
---|
1488 | // combined: view cell volume belongs to both nodes
|
---|
1489 | ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
|
---|
1490 |
|
---|
1491 | for (vit = viewCells.begin(); vit != vit_end; ++ vit)
|
---|
1492 | {
|
---|
1493 | // view cells can also be seen from left child node
|
---|
1494 | ViewCell *viewCell = *vit;
|
---|
1495 | #if USE_VOLUMES_FOR_HEURISTICS
|
---|
1496 | const float vol = viewCell->GetVolume();
|
---|
1497 | #else
|
---|
1498 | const float vol = 1.0f;
|
---|
1499 | #endif
|
---|
1500 | if (!viewCell->Mailed())
|
---|
1501 | {
|
---|
1502 | viewCell->Mail();
|
---|
1503 | // we now see view cell from both nodes
|
---|
1504 | // => add volume to left node
|
---|
1505 | volLeft += vol;
|
---|
1506 | }
|
---|
1507 |
|
---|
1508 | // last reference into the right node
|
---|
1509 | if (-- viewCell->mCounter == 0)
|
---|
1510 | {
|
---|
1511 | // view cell was previously seen from both nodes =>
|
---|
1512 | // remove volume from right node
|
---|
1513 | volRight -= vol;
|
---|
1514 | }
|
---|
1515 | }
|
---|
1516 | }
|
---|
1517 |
|
---|
1518 |
|
---|
1519 | void BvHierarchy::SetViewCellsManager(ViewCellsManager *vcm)
|
---|
1520 | {
|
---|
1521 | mViewCellsManager = vcm;
|
---|
1522 | }
|
---|
1523 |
|
---|
1524 |
|
---|
1525 | AxisAlignedBox3 BvHierarchy::GetBoundingBox() const
|
---|
1526 | {
|
---|
1527 | return mBoundingBox;
|
---|
1528 | }
|
---|
1529 |
|
---|
1530 |
|
---|
1531 | float BvHierarchy::SelectObjectPartition(const BvhTraversalData &tData,
|
---|
1532 | ObjectContainer &frontObjects,
|
---|
1533 | ObjectContainer &backObjects,
|
---|
1534 | bool useVisibilityBasedHeuristics)
|
---|
1535 | {
|
---|
1536 | if (mIsInitialSubdivision)
|
---|
1537 | {
|
---|
1538 | ApplyInitialSplit(tData, frontObjects, backObjects);
|
---|
1539 | return 0;
|
---|
1540 | }
|
---|
1541 |
|
---|
1542 | ObjectContainer nFrontObjects[3];
|
---|
1543 | ObjectContainer nBackObjects[3];
|
---|
1544 | float nCostRatio[3];
|
---|
1545 |
|
---|
1546 | int sAxis = 0;
|
---|
1547 | int bestAxis = -1;
|
---|
1548 |
|
---|
1549 | if (mOnlyDrivingAxis)
|
---|
1550 | {
|
---|
1551 | const AxisAlignedBox3 box = tData.mNode->GetBoundingBox();
|
---|
1552 | sAxis = box.Size().DrivingAxis();
|
---|
1553 | }
|
---|
1554 |
|
---|
1555 | // if #rays high consider only use a subset of the rays for
|
---|
1556 | // visibility based heuristics
|
---|
1557 | VssRay::NewMail();
|
---|
1558 |
|
---|
1559 | if ((mMaxTests < tData.mNumRays) && mUseCostHeuristics && useVisibilityBasedHeuristics)
|
---|
1560 | {
|
---|
1561 | VssRayContainer rays;
|
---|
1562 |
|
---|
1563 | // maximal 2 objects share the same ray
|
---|
1564 | rays.reserve(tData.mNumRays * 2);
|
---|
1565 | CollectRays(tData.mNode->mObjects, rays);
|
---|
1566 |
|
---|
1567 | const float prop = (float)mMaxTests / (float)rays.size();
|
---|
1568 |
|
---|
1569 | VssRayContainer::const_iterator rit, rit_end = rays.end();
|
---|
1570 |
|
---|
1571 | // mail rays which will not be considered
|
---|
1572 | for (rit = rays.begin(); rit != rit_end; ++ rit)
|
---|
1573 | {
|
---|
1574 | if (Random(1.0f) > prop)
|
---|
1575 | {
|
---|
1576 | (*rit)->Mail();
|
---|
1577 | }
|
---|
1578 | }
|
---|
1579 | }
|
---|
1580 |
|
---|
1581 | ////////////////////////////////////
|
---|
1582 | //-- evaluate split cost for all three axis
|
---|
1583 |
|
---|
1584 | for (int axis = 0; axis < 3; ++ axis)
|
---|
1585 | {
|
---|
1586 | if (!mOnlyDrivingAxis || (axis == sAxis))
|
---|
1587 | {
|
---|
1588 | if (mUseCostHeuristics)
|
---|
1589 | {
|
---|
1590 | //////////////////////////////////
|
---|
1591 | //-- split objects using heuristics
|
---|
1592 |
|
---|
1593 | if (useVisibilityBasedHeuristics)
|
---|
1594 | {
|
---|
1595 | ///////////
|
---|
1596 | //-- heuristics using objects weighted by view cells volume
|
---|
1597 | nCostRatio[axis] =
|
---|
1598 | EvalLocalCostHeuristics(tData,
|
---|
1599 | axis,
|
---|
1600 | nFrontObjects[axis],
|
---|
1601 | nBackObjects[axis]);
|
---|
1602 | }
|
---|
1603 | else
|
---|
1604 | {
|
---|
1605 | //////////////////
|
---|
1606 | //-- view cells not constructed yet => use surface area heuristic
|
---|
1607 | nCostRatio[axis] = EvalSah(tData,
|
---|
1608 | axis,
|
---|
1609 | nFrontObjects[axis],
|
---|
1610 | nBackObjects[axis]);
|
---|
1611 | }
|
---|
1612 | }
|
---|
1613 | else
|
---|
1614 | {
|
---|
1615 | //-- split objects using some simple criteria
|
---|
1616 | nCostRatio[axis] =
|
---|
1617 | EvalLocalObjectPartition(tData, axis, nFrontObjects[axis], nBackObjects[axis]);
|
---|
1618 | }
|
---|
1619 |
|
---|
1620 | // no good results for degenerate axis split
|
---|
1621 | if (1 &&
|
---|
1622 | (tData.mNode->GetBoundingBox().Size(axis) < 0.0001))//Limits::Small))
|
---|
1623 | {
|
---|
1624 | nCostRatio[axis] += 9999;
|
---|
1625 | }
|
---|
1626 |
|
---|
1627 | if ((bestAxis == -1) || (nCostRatio[axis] < nCostRatio[bestAxis]))
|
---|
1628 | {
|
---|
1629 | bestAxis = axis;
|
---|
1630 | }
|
---|
1631 | }
|
---|
1632 | }
|
---|
1633 |
|
---|
1634 | ////////////////
|
---|
1635 | //-- assign values
|
---|
1636 |
|
---|
1637 | frontObjects = nFrontObjects[bestAxis];
|
---|
1638 | backObjects = nBackObjects[bestAxis];
|
---|
1639 |
|
---|
1640 | //cout << "val: " << nCostRatio[bestAxis] << " axis: " << bestAxis << endl;
|
---|
1641 | return nCostRatio[bestAxis];
|
---|
1642 | }
|
---|
1643 |
|
---|
1644 |
|
---|
1645 | int BvHierarchy::AssociateObjectsWithRays(const VssRayContainer &rays) const
|
---|
1646 | {
|
---|
1647 | int nRays = 0;
|
---|
1648 | VssRayContainer::const_iterator rit, rit_end = rays.end();
|
---|
1649 |
|
---|
1650 | VssRay::NewMail();
|
---|
1651 |
|
---|
1652 | for (rit = rays.begin(); rit != rays.end(); ++ rit)
|
---|
1653 | {
|
---|
1654 | VssRay *ray = (*rit);
|
---|
1655 |
|
---|
1656 | if (ray->mTerminationObject)
|
---|
1657 | {
|
---|
1658 | ray->mTerminationObject->GetOrCreateRays()->push_back(ray);
|
---|
1659 | if (!ray->Mailed())
|
---|
1660 | {
|
---|
1661 | ray->Mail();
|
---|
1662 | ++ nRays;
|
---|
1663 | }
|
---|
1664 | }
|
---|
1665 |
|
---|
1666 | #if COUNT_ORIGIN_OBJECTS
|
---|
1667 |
|
---|
1668 | if (ray->mOriginObject)
|
---|
1669 | {
|
---|
1670 | ray->mOriginObject->GetOrCreateRays()->push_back(ray);
|
---|
1671 |
|
---|
1672 | if (!ray->Mailed())
|
---|
1673 | {
|
---|
1674 | ray->Mail();
|
---|
1675 | ++ nRays;
|
---|
1676 | }
|
---|
1677 | }
|
---|
1678 | #endif
|
---|
1679 | }
|
---|
1680 |
|
---|
1681 | return nRays;
|
---|
1682 | }
|
---|
1683 |
|
---|
1684 |
|
---|
1685 | void BvHierarchy::PrintSubdivisionStats(const SubdivisionCandidate &sc)
|
---|
1686 | {
|
---|
1687 | const float costDecr = sc.GetRenderCostDecrease();
|
---|
1688 |
|
---|
1689 | mSubdivisionStats
|
---|
1690 | << "#Leaves\n" << mBvhStats.Leaves() << endl
|
---|
1691 | << "#RenderCostDecrease\n" << costDecr << endl
|
---|
1692 | << "#TotalRenderCost\n" << mTotalCost << endl
|
---|
1693 | << "#EntriesInPvs\n" << mPvsEntries << endl;
|
---|
1694 | }
|
---|
1695 |
|
---|
1696 |
|
---|
1697 | void BvHierarchy::CollectRays(const ObjectContainer &objects,
|
---|
1698 | VssRayContainer &rays) const
|
---|
1699 | {
|
---|
1700 | VssRay::NewMail();
|
---|
1701 | ObjectContainer::const_iterator oit, oit_end = objects.end();
|
---|
1702 |
|
---|
1703 | // evaluate reverse pvs and view cell volume on left and right cell
|
---|
1704 | // note: should I take all leaf objects or rather the objects hit by rays?
|
---|
1705 | for (oit = objects.begin(); oit != oit_end; ++ oit)
|
---|
1706 | {
|
---|
1707 | Intersectable *obj = *oit;
|
---|
1708 | VssRayContainer::const_iterator rit, rit_end = obj->GetOrCreateRays()->end();
|
---|
1709 |
|
---|
1710 | for (rit = obj->GetOrCreateRays()->begin(); rit < rit_end; ++ rit)
|
---|
1711 | {
|
---|
1712 | VssRay *ray = (*rit);
|
---|
1713 |
|
---|
1714 | if (!ray->Mailed())
|
---|
1715 | {
|
---|
1716 | ray->Mail();
|
---|
1717 | rays.push_back(ray);
|
---|
1718 | }
|
---|
1719 | }
|
---|
1720 | }
|
---|
1721 | }
|
---|
1722 |
|
---|
1723 |
|
---|
1724 | float BvHierarchy::EvalAbsCost(const ObjectContainer &objects)// const
|
---|
1725 | {
|
---|
1726 | #if USE_BETTER_RENDERCOST_EST
|
---|
1727 | ObjectContainer::const_iterator oit, oit_end = objects.end();
|
---|
1728 |
|
---|
1729 | for (oit = objects.begin(); oit != oit_end; ++ oit)
|
---|
1730 | {
|
---|
1731 | objRenderCost += ViewCellsManager::GetRendercost(*oit);
|
---|
1732 | }
|
---|
1733 | #else
|
---|
1734 | return (float)objects.size();
|
---|
1735 | #endif
|
---|
1736 | }
|
---|
1737 |
|
---|
1738 |
|
---|
1739 | float BvHierarchy::EvalSahCost(BvhLeaf *leaf) const
|
---|
1740 | {
|
---|
1741 | ////////////////
|
---|
1742 | //-- surface area heuristics
|
---|
1743 |
|
---|
1744 | if (leaf->mObjects.empty())
|
---|
1745 | return 0.0f;
|
---|
1746 |
|
---|
1747 | const AxisAlignedBox3 box = GetBoundingBox(leaf);
|
---|
1748 | const float area = box.SurfaceArea();
|
---|
1749 | const float viewSpaceArea = mViewCellsManager->GetViewSpaceBox().SurfaceArea();
|
---|
1750 |
|
---|
1751 | return EvalAbsCost(leaf->mObjects) * area / viewSpaceArea;
|
---|
1752 | }
|
---|
1753 |
|
---|
1754 |
|
---|
1755 | float BvHierarchy::EvalRenderCost(const ObjectContainer &objects) const
|
---|
1756 | {
|
---|
1757 | ///////////////
|
---|
1758 | //-- render cost heuristics
|
---|
1759 |
|
---|
1760 | const float viewSpaceVol = mViewCellsManager->GetViewSpaceBox().GetVolume();
|
---|
1761 |
|
---|
1762 | // probability that view point lies in a view cell which sees this node
|
---|
1763 | const float p = EvalViewCellsVolume(objects) / viewSpaceVol;
|
---|
1764 | const float objRenderCost = EvalAbsCost(objects);
|
---|
1765 |
|
---|
1766 | return objRenderCost * p;
|
---|
1767 | }
|
---|
1768 |
|
---|
1769 |
|
---|
1770 | float BvHierarchy::EvalProb(const ObjectContainer &objects) const
|
---|
1771 | {
|
---|
1772 | ///////////////
|
---|
1773 | //-- render cost heuristics
|
---|
1774 |
|
---|
1775 | const float viewSpaceVol = mViewCellsManager->GetViewSpaceBox().GetVolume();
|
---|
1776 |
|
---|
1777 | // probability that view point lies in a view cell which sees this node
|
---|
1778 | return EvalViewCellsVolume(objects) / viewSpaceVol;
|
---|
1779 | }
|
---|
1780 |
|
---|
1781 |
|
---|
1782 | AxisAlignedBox3 BvHierarchy::EvalBoundingBox(const ObjectContainer &objects,
|
---|
1783 | const AxisAlignedBox3 *parentBox) const
|
---|
1784 | {
|
---|
1785 | // if there are no objects in this box, box size is set to parent box size.
|
---|
1786 | // Question: Invalidate box instead?
|
---|
1787 | if (parentBox && objects.empty())
|
---|
1788 | return *parentBox;
|
---|
1789 |
|
---|
1790 | AxisAlignedBox3 box;
|
---|
1791 | box.Initialize();
|
---|
1792 |
|
---|
1793 | ObjectContainer::const_iterator oit, oit_end = objects.end();
|
---|
1794 |
|
---|
1795 | for (oit = objects.begin(); oit != oit_end; ++ oit)
|
---|
1796 | {
|
---|
1797 | Intersectable *obj = *oit;
|
---|
1798 | // grow bounding box to include all objects
|
---|
1799 | box.Include(obj->GetBox());
|
---|
1800 | }
|
---|
1801 |
|
---|
1802 | return box;
|
---|
1803 | }
|
---|
1804 |
|
---|
1805 |
|
---|
1806 | void BvHierarchy::CollectLeaves(BvhNode *root, vector<BvhLeaf *> &leaves) const
|
---|
1807 | {
|
---|
1808 | stack<BvhNode *> nodeStack;
|
---|
1809 | nodeStack.push(root);
|
---|
1810 |
|
---|
1811 | while (!nodeStack.empty())
|
---|
1812 | {
|
---|
1813 | BvhNode *node = nodeStack.top();
|
---|
1814 | nodeStack.pop();
|
---|
1815 |
|
---|
1816 | if (node->IsLeaf())
|
---|
1817 | {
|
---|
1818 | BvhLeaf *leaf = (BvhLeaf *)node;
|
---|
1819 | leaves.push_back(leaf);
|
---|
1820 | }
|
---|
1821 | else
|
---|
1822 | {
|
---|
1823 | BvhInterior *interior = (BvhInterior *)node;
|
---|
1824 |
|
---|
1825 | nodeStack.push(interior->GetBack());
|
---|
1826 | nodeStack.push(interior->GetFront());
|
---|
1827 | }
|
---|
1828 | }
|
---|
1829 | }
|
---|
1830 |
|
---|
1831 |
|
---|
1832 | AxisAlignedBox3 BvHierarchy::GetBoundingBox(BvhNode *node) const
|
---|
1833 | {
|
---|
1834 | return node->GetBoundingBox();
|
---|
1835 | }
|
---|
1836 |
|
---|
1837 |
|
---|
1838 | int BvHierarchy::CollectViewCells(const ObjectContainer &objects,
|
---|
1839 | ViewCellContainer &viewCells,
|
---|
1840 | const bool setCounter,
|
---|
1841 | const bool onlyUnmailedRays) const
|
---|
1842 | {
|
---|
1843 | ViewCell::NewMail();
|
---|
1844 | ObjectContainer::const_iterator oit, oit_end = objects.end();
|
---|
1845 |
|
---|
1846 | int numRays = 0;
|
---|
1847 | // loop through all object and collect view cell pvs of this node
|
---|
1848 | for (oit = objects.begin(); oit != oit_end; ++ oit)
|
---|
1849 | {
|
---|
1850 | // always use only mailed objects
|
---|
1851 | numRays += CollectViewCells(*oit, viewCells, true, setCounter, onlyUnmailedRays);
|
---|
1852 | }
|
---|
1853 |
|
---|
1854 | return numRays;
|
---|
1855 | }
|
---|
1856 |
|
---|
1857 |
|
---|
1858 | int BvHierarchy::CollectViewCells(Intersectable *obj,
|
---|
1859 | ViewCellContainer &viewCells,
|
---|
1860 | const bool useMailBoxing,
|
---|
1861 | const bool setCounter,
|
---|
1862 | const bool onlyUnmailedRays) const
|
---|
1863 | {
|
---|
1864 | VssRayContainer::const_iterator rit, rit_end = obj->GetOrCreateRays()->end();
|
---|
1865 |
|
---|
1866 | int numRays = 0;
|
---|
1867 |
|
---|
1868 | for (rit = obj->GetOrCreateRays()->begin(); rit < rit_end; ++ rit)
|
---|
1869 | {
|
---|
1870 | VssRay *ray = (*rit);
|
---|
1871 |
|
---|
1872 | if (onlyUnmailedRays && ray->Mailed())
|
---|
1873 | {
|
---|
1874 | continue;
|
---|
1875 | }
|
---|
1876 |
|
---|
1877 | ++ numRays;
|
---|
1878 |
|
---|
1879 | ViewCellContainer tmpViewCells;
|
---|
1880 | mHierarchyManager->mVspTree->GetViewCells(*ray, tmpViewCells);
|
---|
1881 |
|
---|
1882 | // matt: probably slow to allocate memory for view cells every time
|
---|
1883 | ViewCellContainer::const_iterator vit, vit_end = tmpViewCells.end();
|
---|
1884 |
|
---|
1885 | for (vit = tmpViewCells.begin(); vit != vit_end; ++ vit)
|
---|
1886 | {
|
---|
1887 | ViewCell *vc = *vit;
|
---|
1888 |
|
---|
1889 | // store view cells
|
---|
1890 | if (!useMailBoxing || !vc->Mailed())
|
---|
1891 | {
|
---|
1892 | if (useMailBoxing) // => view cell not mailed
|
---|
1893 | {
|
---|
1894 | vc->Mail();
|
---|
1895 | if (setCounter)
|
---|
1896 | {
|
---|
1897 | vc->mCounter = 0;
|
---|
1898 | }
|
---|
1899 | }
|
---|
1900 |
|
---|
1901 | viewCells.push_back(vc);
|
---|
1902 | }
|
---|
1903 |
|
---|
1904 | if (setCounter)
|
---|
1905 | {
|
---|
1906 | ++ vc->mCounter;
|
---|
1907 | }
|
---|
1908 | }
|
---|
1909 | }
|
---|
1910 |
|
---|
1911 | return numRays;
|
---|
1912 | }
|
---|
1913 |
|
---|
1914 |
|
---|
1915 | int BvHierarchy::CountViewCells(Intersectable *obj) const
|
---|
1916 | {
|
---|
1917 | int result = 0;
|
---|
1918 |
|
---|
1919 | VssRayContainer::const_iterator rit, rit_end = obj->GetOrCreateRays()->end();
|
---|
1920 |
|
---|
1921 | for (rit = obj->GetOrCreateRays()->begin(); rit < rit_end; ++ rit)
|
---|
1922 | {
|
---|
1923 | VssRay *ray = (*rit);
|
---|
1924 | ViewCellContainer tmpViewCells;
|
---|
1925 |
|
---|
1926 | mHierarchyManager->mVspTree->GetViewCells(*ray, tmpViewCells);
|
---|
1927 |
|
---|
1928 | ViewCellContainer::const_iterator vit, vit_end = tmpViewCells.end();
|
---|
1929 | for (vit = tmpViewCells.begin(); vit != vit_end; ++ vit)
|
---|
1930 | {
|
---|
1931 | ViewCell *vc = *vit;
|
---|
1932 |
|
---|
1933 | // store view cells
|
---|
1934 | if (!vc->Mailed())
|
---|
1935 | {
|
---|
1936 | vc->Mail();
|
---|
1937 | ++ result;
|
---|
1938 | }
|
---|
1939 | }
|
---|
1940 | }
|
---|
1941 |
|
---|
1942 | return result;
|
---|
1943 | }
|
---|
1944 |
|
---|
1945 |
|
---|
1946 | int BvHierarchy::CountViewCells(const ObjectContainer &objects) const
|
---|
1947 | {
|
---|
1948 | int nViewCells = 0;
|
---|
1949 | ViewCell::NewMail();
|
---|
1950 | ObjectContainer::const_iterator oit, oit_end = objects.end();
|
---|
1951 |
|
---|
1952 | // loop through all object and collect view cell pvs of this node
|
---|
1953 | for (oit = objects.begin(); oit != oit_end; ++ oit)
|
---|
1954 | {
|
---|
1955 | nViewCells += CountViewCells(*oit);
|
---|
1956 | }
|
---|
1957 |
|
---|
1958 | return nViewCells;
|
---|
1959 | }
|
---|
1960 |
|
---|
1961 |
|
---|
1962 | void BvHierarchy::CollectDirtyCandidates(BvhSubdivisionCandidate *sc,
|
---|
1963 | vector<SubdivisionCandidate *> &dirtyList,
|
---|
1964 | const bool onlyUnmailed)
|
---|
1965 | {
|
---|
1966 | BvhTraversalData &tData = sc->mParentData;
|
---|
1967 | BvhLeaf *node = tData.mNode;
|
---|
1968 |
|
---|
1969 | ViewCellContainer viewCells;
|
---|
1970 | //ViewCell::NewMail();
|
---|
1971 | int numRays = CollectViewCells(node->mObjects, viewCells, false, false);
|
---|
1972 |
|
---|
1973 | if (0) cout << "collected " << (int)viewCells.size() << " dirty candidates" << endl;
|
---|
1974 |
|
---|
1975 | // split candidates handling
|
---|
1976 | // these view cells are thrown into dirty list
|
---|
1977 | ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
|
---|
1978 |
|
---|
1979 | for (vit = viewCells.begin(); vit != vit_end; ++ vit)
|
---|
1980 | {
|
---|
1981 | VspViewCell *vc = dynamic_cast<VspViewCell *>(*vit);
|
---|
1982 | VspLeaf *leaf = vc->mLeaves[0];
|
---|
1983 |
|
---|
1984 | SubdivisionCandidate *candidate = leaf->GetSubdivisionCandidate();
|
---|
1985 |
|
---|
1986 | // is this leaf still a split candidate?
|
---|
1987 | if (candidate && (!onlyUnmailed || !candidate->Mailed()))
|
---|
1988 | {
|
---|
1989 | candidate->Mail();
|
---|
1990 | candidate->SetDirty(true);
|
---|
1991 | dirtyList.push_back(candidate);
|
---|
1992 | }
|
---|
1993 | }
|
---|
1994 | }
|
---|
1995 |
|
---|
1996 |
|
---|
1997 | BvhNode *BvHierarchy::GetRoot() const
|
---|
1998 | {
|
---|
1999 | return mRoot;
|
---|
2000 | }
|
---|
2001 |
|
---|
2002 |
|
---|
2003 | bool BvHierarchy::IsObjectInLeaf(BvhLeaf *leaf, Intersectable *object) const
|
---|
2004 | {
|
---|
2005 | ObjectContainer::const_iterator oit =
|
---|
2006 | lower_bound(leaf->mObjects.begin(), leaf->mObjects.end(), object, ilt);
|
---|
2007 |
|
---|
2008 | // objects sorted by id
|
---|
2009 | if ((oit != leaf->mObjects.end()) && ((*oit)->GetId() == object->GetId()))
|
---|
2010 | {
|
---|
2011 | return true;
|
---|
2012 | }
|
---|
2013 | else
|
---|
2014 | {
|
---|
2015 | return false;
|
---|
2016 | }
|
---|
2017 | }
|
---|
2018 |
|
---|
2019 |
|
---|
2020 | BvhLeaf *BvHierarchy::GetLeaf(Intersectable *object, BvhNode *node) const
|
---|
2021 | {
|
---|
2022 | // rather use the simple version
|
---|
2023 | if (!object)
|
---|
2024 | return NULL;
|
---|
2025 | return object->mBvhLeaf;
|
---|
2026 |
|
---|
2027 | ///////////////////////////////////////
|
---|
2028 | // start from root of tree
|
---|
2029 |
|
---|
2030 | if (node == NULL)
|
---|
2031 | node = mRoot;
|
---|
2032 |
|
---|
2033 | vector<BvhLeaf *> leaves;
|
---|
2034 |
|
---|
2035 | stack<BvhNode *> nodeStack;
|
---|
2036 | nodeStack.push(node);
|
---|
2037 |
|
---|
2038 | BvhLeaf *leaf = NULL;
|
---|
2039 |
|
---|
2040 | while (!nodeStack.empty())
|
---|
2041 | {
|
---|
2042 | BvhNode *node = nodeStack.top();
|
---|
2043 | nodeStack.pop();
|
---|
2044 |
|
---|
2045 | if (node->IsLeaf())
|
---|
2046 | {
|
---|
2047 | leaf = dynamic_cast<BvhLeaf *>(node);
|
---|
2048 |
|
---|
2049 | if (IsObjectInLeaf(leaf, object))
|
---|
2050 | {
|
---|
2051 | return leaf;
|
---|
2052 | }
|
---|
2053 | }
|
---|
2054 | else
|
---|
2055 | {
|
---|
2056 | // find point
|
---|
2057 | BvhInterior *interior = dynamic_cast<BvhInterior *>(node);
|
---|
2058 |
|
---|
2059 | if (interior->GetBack()->GetBoundingBox().Includes(object->GetBox()))
|
---|
2060 | {
|
---|
2061 | nodeStack.push(interior->GetBack());
|
---|
2062 | }
|
---|
2063 |
|
---|
2064 | // search both sides as we are using bounding volumes
|
---|
2065 | if (interior->GetFront()->GetBoundingBox().Includes(object->GetBox()))
|
---|
2066 | {
|
---|
2067 | nodeStack.push(interior->GetFront());
|
---|
2068 | }
|
---|
2069 | }
|
---|
2070 | }
|
---|
2071 |
|
---|
2072 | return leaf;
|
---|
2073 | }
|
---|
2074 |
|
---|
2075 |
|
---|
2076 | bool BvHierarchy::Export(OUT_STREAM &stream)
|
---|
2077 | {
|
---|
2078 | ExportNode(mRoot, stream);
|
---|
2079 |
|
---|
2080 | return true;
|
---|
2081 | }
|
---|
2082 |
|
---|
2083 |
|
---|
2084 | void BvHierarchy::ExportObjects(BvhLeaf *leaf, OUT_STREAM &stream)
|
---|
2085 | {
|
---|
2086 | ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
|
---|
2087 |
|
---|
2088 | for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
|
---|
2089 | {
|
---|
2090 | stream << (*oit)->GetId() << " ";
|
---|
2091 | }
|
---|
2092 | }
|
---|
2093 |
|
---|
2094 |
|
---|
2095 | void BvHierarchy::ExportNode(BvhNode *node, OUT_STREAM &stream)
|
---|
2096 | {
|
---|
2097 | if (node->IsLeaf())
|
---|
2098 | {
|
---|
2099 | BvhLeaf *leaf = dynamic_cast<BvhLeaf *>(node);
|
---|
2100 | const AxisAlignedBox3 box = leaf->GetBoundingBox();
|
---|
2101 | stream << "<Leaf"
|
---|
2102 | << " min=\"" << box.Min().x << " " << box.Min().y << " " << box.Min().z << "\""
|
---|
2103 | << " max=\"" << box.Max().x << " " << box.Max().y << " " << box.Max().z << "\""
|
---|
2104 | << " objects=\"";
|
---|
2105 |
|
---|
2106 | //-- export objects
|
---|
2107 | // tmp matt
|
---|
2108 | if (1) ExportObjects(leaf, stream);
|
---|
2109 |
|
---|
2110 | stream << "\" />" << endl;
|
---|
2111 | }
|
---|
2112 | else
|
---|
2113 | {
|
---|
2114 | BvhInterior *interior = dynamic_cast<BvhInterior *>(node);
|
---|
2115 | const AxisAlignedBox3 box = interior->GetBoundingBox();
|
---|
2116 |
|
---|
2117 | stream << "<Interior"
|
---|
2118 | << " min=\"" << box.Min().x << " " << box.Min().y << " " << box.Min().z << "\""
|
---|
2119 | << " max=\"" << box.Max().x << " " << box.Max().y << " " << box.Max().z
|
---|
2120 | << "\">" << endl;
|
---|
2121 |
|
---|
2122 | ExportNode(interior->GetBack(), stream);
|
---|
2123 | ExportNode(interior->GetFront(), stream);
|
---|
2124 |
|
---|
2125 | stream << "</Interior>" << endl;
|
---|
2126 | }
|
---|
2127 | }
|
---|
2128 |
|
---|
2129 |
|
---|
2130 | float BvHierarchy::EvalViewCellsVolume(const ObjectContainer &objects) const
|
---|
2131 | {
|
---|
2132 | float vol = 0;
|
---|
2133 |
|
---|
2134 | ViewCellContainer viewCells;
|
---|
2135 |
|
---|
2136 | // we have to account for all view cells that can
|
---|
2137 | // be seen from the objects
|
---|
2138 | int numRays = CollectViewCells(objects, viewCells, false, false);
|
---|
2139 |
|
---|
2140 | ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
|
---|
2141 |
|
---|
2142 | for (vit = viewCells.begin(); vit != vit_end; ++ vit)
|
---|
2143 | {
|
---|
2144 | vol += (*vit)->GetVolume();
|
---|
2145 | }
|
---|
2146 |
|
---|
2147 | return vol;
|
---|
2148 | }
|
---|
2149 |
|
---|
2150 |
|
---|
2151 | void BvHierarchy::Initialise(const ObjectContainer &objects)
|
---|
2152 | {
|
---|
2153 | AxisAlignedBox3 box = EvalBoundingBox(objects);
|
---|
2154 |
|
---|
2155 | ///////
|
---|
2156 | //-- create new root
|
---|
2157 |
|
---|
2158 | BvhLeaf *bvhleaf = new BvhLeaf(box, NULL, (int)objects.size());
|
---|
2159 | bvhleaf->mObjects = objects;
|
---|
2160 | mRoot = bvhleaf;
|
---|
2161 |
|
---|
2162 | // compute bounding box from objects
|
---|
2163 | mBoundingBox = mRoot->GetBoundingBox();
|
---|
2164 |
|
---|
2165 | // associate root with current objects
|
---|
2166 | AssociateObjectsWithLeaf(bvhleaf);
|
---|
2167 | }
|
---|
2168 |
|
---|
2169 |
|
---|
2170 | /*
|
---|
2171 | Mesh *BvHierarchy::MergeLeafToMesh()
|
---|
2172 | {
|
---|
2173 | vector<BvhLeaf *> leaves;
|
---|
2174 | CollectLeaves(leaves);
|
---|
2175 |
|
---|
2176 | vector<BvhLeaf *>::const_iterator lit, lit_end = leaves.end();
|
---|
2177 |
|
---|
2178 | for (lit = leaves.begin(); lit != lit_end; ++ lit)
|
---|
2179 | {
|
---|
2180 | Mesh *mesh = MergeLeafToMesh(*lit);
|
---|
2181 | }
|
---|
2182 | }*/
|
---|
2183 |
|
---|
2184 |
|
---|
2185 | void BvHierarchy::PrepareConstruction(SplitQueue &tQueue,
|
---|
2186 | const VssRayContainer &sampleRays,
|
---|
2187 | const ObjectContainer &objects)
|
---|
2188 | {
|
---|
2189 | ///////////////////////////////////////
|
---|
2190 | //-- we assume that we have objects sorted by their id =>
|
---|
2191 | //-- we don't have to sort them here and an binary search
|
---|
2192 | //-- for identifying if a object is in a leaf.
|
---|
2193 |
|
---|
2194 | mBvhStats.Reset();
|
---|
2195 | mBvhStats.Start();
|
---|
2196 | mBvhStats.nodes = 1;
|
---|
2197 |
|
---|
2198 | // store pointer to this tree
|
---|
2199 | BvhSubdivisionCandidate::sBvHierarchy = this;
|
---|
2200 |
|
---|
2201 | // root and bounding box was already constructed
|
---|
2202 | BvhLeaf *bvhLeaf = dynamic_cast<BvhLeaf *>(mRoot);
|
---|
2203 |
|
---|
2204 | // only rays intersecting objects in node are interesting
|
---|
2205 | const int nRays = AssociateObjectsWithRays(sampleRays);
|
---|
2206 | //cout << "using " << nRays << " of " << (int)sampleRays.size() << " rays" << endl;
|
---|
2207 |
|
---|
2208 | // probability that volume is "seen" from the view cells
|
---|
2209 | const float prop = EvalViewCellsVolume(objects) / GetViewSpaceVolume();
|
---|
2210 |
|
---|
2211 | // create bvh traversal data
|
---|
2212 | BvhTraversalData oData(bvhLeaf, 0, prop, nRays);
|
---|
2213 |
|
---|
2214 | // create sorted object lists for the first data
|
---|
2215 | if (mUseGlobalSorting)
|
---|
2216 | {
|
---|
2217 | AssignInitialSortedObjectList(oData, objects);
|
---|
2218 | }
|
---|
2219 |
|
---|
2220 |
|
---|
2221 | ///////////////////
|
---|
2222 | //-- add first candidate for object space partition
|
---|
2223 |
|
---|
2224 | mTotalCost = EvalRenderCost(objects);
|
---|
2225 | mPvsEntries = CountViewCells(objects);
|
---|
2226 |
|
---|
2227 | oData.mCorrectedPvs = oData.mPvs = (float)mPvsEntries;
|
---|
2228 | oData.mCorrectedVolume = oData.mVolume = prop;
|
---|
2229 |
|
---|
2230 | BvhSubdivisionCandidate *oSubdivisionCandidate =
|
---|
2231 | new BvhSubdivisionCandidate(oData);
|
---|
2232 |
|
---|
2233 | bvhLeaf->SetSubdivisionCandidate(oSubdivisionCandidate);
|
---|
2234 |
|
---|
2235 | if (mApplyInitialPartition)
|
---|
2236 | {
|
---|
2237 | vector<SubdivisionCandidate *> candidateContainer;
|
---|
2238 |
|
---|
2239 | mIsInitialSubdivision = true;
|
---|
2240 |
|
---|
2241 | // evaluate priority
|
---|
2242 | EvalSubdivisionCandidate(*oSubdivisionCandidate);
|
---|
2243 | PrintSubdivisionStats(*oSubdivisionCandidate);
|
---|
2244 |
|
---|
2245 | ApplyInitialSubdivision(oSubdivisionCandidate, candidateContainer);
|
---|
2246 |
|
---|
2247 | mIsInitialSubdivision = false;
|
---|
2248 |
|
---|
2249 | vector<SubdivisionCandidate *>::const_iterator cit, cit_end = candidateContainer.end();
|
---|
2250 |
|
---|
2251 | for (cit = candidateContainer.begin(); cit != cit_end; ++ cit)
|
---|
2252 | {
|
---|
2253 | BvhSubdivisionCandidate *sCandidate = dynamic_cast<BvhSubdivisionCandidate *>(*cit);
|
---|
2254 |
|
---|
2255 | // reevaluate priority
|
---|
2256 | EvalSubdivisionCandidate(*sCandidate);
|
---|
2257 | tQueue.Push(sCandidate);
|
---|
2258 | }
|
---|
2259 | }
|
---|
2260 | else
|
---|
2261 | {
|
---|
2262 | // evaluate priority
|
---|
2263 | EvalSubdivisionCandidate(*oSubdivisionCandidate);
|
---|
2264 | PrintSubdivisionStats(*oSubdivisionCandidate);
|
---|
2265 |
|
---|
2266 | tQueue.Push(oSubdivisionCandidate);
|
---|
2267 | }
|
---|
2268 |
|
---|
2269 | cout << "size of initial bv subdivision: " << GetStatistics().Leaves() << endl;
|
---|
2270 | }
|
---|
2271 |
|
---|
2272 |
|
---|
2273 | void BvHierarchy::AssignInitialSortedObjectList(BvhTraversalData &tData,
|
---|
2274 | const ObjectContainer &objects)
|
---|
2275 | {
|
---|
2276 | // we sort the objects as a preprocess so they don't have
|
---|
2277 | // to be sorted for each split
|
---|
2278 | for (int i = 0; i < 3; ++ i)
|
---|
2279 | {
|
---|
2280 | SortableEntryContainer *sortedObjects = new SortableEntryContainer();
|
---|
2281 |
|
---|
2282 | CreateLocalSubdivisionCandidates(objects,
|
---|
2283 | &sortedObjects,
|
---|
2284 | true,
|
---|
2285 | i);
|
---|
2286 |
|
---|
2287 | // copy list into traversal data list
|
---|
2288 | tData.mSortedObjects[i] = new ObjectContainer();
|
---|
2289 | tData.mSortedObjects[i]->reserve((int)objects.size());
|
---|
2290 |
|
---|
2291 | SortableEntryContainer::const_iterator oit, oit_end = sortedObjects->end();
|
---|
2292 |
|
---|
2293 | for (oit = sortedObjects->begin(); oit != oit_end; ++ oit)
|
---|
2294 | {
|
---|
2295 | tData.mSortedObjects[i]->push_back((*oit).mObject);
|
---|
2296 | }
|
---|
2297 |
|
---|
2298 | delete sortedObjects;
|
---|
2299 | }
|
---|
2300 |
|
---|
2301 | // last sorted list: by size
|
---|
2302 | tData.mSortedObjects[3] = new ObjectContainer();
|
---|
2303 | tData.mSortedObjects[3]->reserve((int)objects.size());
|
---|
2304 |
|
---|
2305 | *(tData.mSortedObjects[3]) = objects;
|
---|
2306 | stable_sort(tData.mSortedObjects[3]->begin(), tData.mSortedObjects[3]->end(), smallerSize);
|
---|
2307 | }
|
---|
2308 |
|
---|
2309 |
|
---|
2310 | void BvHierarchy::AssignSortedObjects(const BvhSubdivisionCandidate &sc,
|
---|
2311 | BvhTraversalData &frontData,
|
---|
2312 | BvhTraversalData &backData)
|
---|
2313 | {
|
---|
2314 | Intersectable::NewMail();
|
---|
2315 |
|
---|
2316 | // we sorted the objects as a preprocess so they don't have
|
---|
2317 | // to be sorted for each split
|
---|
2318 | ObjectContainer::const_iterator fit, fit_end = sc.mFrontObjects.end();
|
---|
2319 |
|
---|
2320 | for (fit = sc.mFrontObjects.begin(); fit != fit_end; ++ fit)
|
---|
2321 | {
|
---|
2322 | (*fit)->Mail();
|
---|
2323 | }
|
---|
2324 |
|
---|
2325 | for (int i = 0; i < 4; ++ i)
|
---|
2326 | {
|
---|
2327 | frontData.mSortedObjects[i] = new ObjectContainer();
|
---|
2328 | backData.mSortedObjects[i] = new ObjectContainer();
|
---|
2329 |
|
---|
2330 | frontData.mSortedObjects[i]->reserve((int)sc.mFrontObjects.size());
|
---|
2331 | backData.mSortedObjects[i]->reserve((int)sc.mFrontObjects.size());
|
---|
2332 |
|
---|
2333 | ObjectContainer::const_iterator oit, oit_end = sc.mParentData.mSortedObjects[i]->end();
|
---|
2334 |
|
---|
2335 | for (oit = sc.mParentData.mSortedObjects[i]->begin(); oit != oit_end; ++ oit)
|
---|
2336 | {
|
---|
2337 | if ((*oit)->Mailed())
|
---|
2338 | {
|
---|
2339 | frontData.mSortedObjects[i]->push_back(*oit);
|
---|
2340 | }
|
---|
2341 | else
|
---|
2342 | {
|
---|
2343 | backData.mSortedObjects[i]->push_back(*oit);
|
---|
2344 | }
|
---|
2345 | }
|
---|
2346 | }
|
---|
2347 | }
|
---|
2348 |
|
---|
2349 |
|
---|
2350 | void BvHierarchy::Reset(SplitQueue &tQueue,
|
---|
2351 | const VssRayContainer &sampleRays,
|
---|
2352 | const ObjectContainer &objects)
|
---|
2353 | {
|
---|
2354 | // reset stats
|
---|
2355 | mBvhStats.Reset();
|
---|
2356 | mBvhStats.Start();
|
---|
2357 | mBvhStats.nodes = 1;
|
---|
2358 |
|
---|
2359 | // reset root
|
---|
2360 | DEL_PTR(mRoot);
|
---|
2361 |
|
---|
2362 | BvhLeaf *bvhleaf = new BvhLeaf(mBoundingBox, NULL, (int)objects.size());
|
---|
2363 | bvhleaf->mObjects = objects;
|
---|
2364 | mRoot = bvhleaf;
|
---|
2365 |
|
---|
2366 | //mTermMinProbability *= mVspTree->GetBoundingBox().GetVolume();
|
---|
2367 | // probability that volume is "seen" from the view cells
|
---|
2368 | const float viewSpaceVol = mViewCellsManager->GetViewSpaceBox().GetVolume();
|
---|
2369 | const float prop = EvalViewCellsVolume(objects);
|
---|
2370 |
|
---|
2371 | const int nRays = CountRays(objects);
|
---|
2372 | BvhLeaf *bvhLeaf = dynamic_cast<BvhLeaf *>(mRoot);
|
---|
2373 |
|
---|
2374 | // create bvh traversal data
|
---|
2375 | BvhTraversalData oData(bvhLeaf, 0, prop, nRays);
|
---|
2376 |
|
---|
2377 | AssignInitialSortedObjectList(oData, objects);
|
---|
2378 |
|
---|
2379 |
|
---|
2380 | ///////////////////
|
---|
2381 | //-- add first candidate for object space partition
|
---|
2382 |
|
---|
2383 | BvhSubdivisionCandidate *oSubdivisionCandidate =
|
---|
2384 | new BvhSubdivisionCandidate(oData);
|
---|
2385 |
|
---|
2386 | EvalSubdivisionCandidate(*oSubdivisionCandidate);
|
---|
2387 | bvhLeaf->SetSubdivisionCandidate(oSubdivisionCandidate);
|
---|
2388 |
|
---|
2389 | mTotalCost = (float)objects.size() * prop;
|
---|
2390 |
|
---|
2391 | PrintSubdivisionStats(*oSubdivisionCandidate);
|
---|
2392 |
|
---|
2393 | tQueue.Push(oSubdivisionCandidate);
|
---|
2394 | }
|
---|
2395 |
|
---|
2396 |
|
---|
2397 | void BvhStatistics::Print(ostream &app) const
|
---|
2398 | {
|
---|
2399 | app << "=========== BvHierarchy statistics ===============\n";
|
---|
2400 |
|
---|
2401 | app << setprecision(4);
|
---|
2402 |
|
---|
2403 | app << "#N_CTIME ( Construction time [s] )\n" << Time() << " \n";
|
---|
2404 |
|
---|
2405 | app << "#N_NODES ( Number of nodes )\n" << nodes << "\n";
|
---|
2406 |
|
---|
2407 | app << "#N_INTERIORS ( Number of interior nodes )\n" << Interior() << "\n";
|
---|
2408 |
|
---|
2409 | app << "#N_LEAVES ( Number of leaves )\n" << Leaves() << "\n";
|
---|
2410 |
|
---|
2411 | app << "#AXIS_ALIGNED_SPLITS (number of axis aligned splits)\n" << splits << endl;
|
---|
2412 |
|
---|
2413 | app << "#N_MAXCOSTNODES ( Percentage of leaves with terminated because of max cost ratio )\n"
|
---|
2414 | << maxCostNodes * 100 / (double)Leaves() << endl;
|
---|
2415 |
|
---|
2416 | app << "#N_PMINPROBABILITYLEAVES ( Percentage of leaves with mininum probability )\n"
|
---|
2417 | << minProbabilityNodes * 100 / (double)Leaves() << endl;
|
---|
2418 |
|
---|
2419 |
|
---|
2420 | //////////////////////////////////////////////////
|
---|
2421 |
|
---|
2422 | app << "#N_PMAXDEPTHLEAVES ( Percentage of leaves at maximum depth )\n"
|
---|
2423 | << maxDepthNodes * 100 / (double)Leaves() << endl;
|
---|
2424 |
|
---|
2425 | app << "#N_PMAXDEPTH ( Maximal reached depth )\n" << maxDepth << endl;
|
---|
2426 |
|
---|
2427 | app << "#N_PMINDEPTH ( Minimal reached depth )\n" << minDepth << endl;
|
---|
2428 |
|
---|
2429 | app << "#AVGDEPTH ( average depth )\n" << AvgDepth() << endl;
|
---|
2430 |
|
---|
2431 |
|
---|
2432 | ////////////////////////////////////////////////////////
|
---|
2433 |
|
---|
2434 | app << "#N_PMINOBJECTSLEAVES ( Percentage of leaves with mininum objects )\n"
|
---|
2435 | << minObjectsNodes * 100 / (double)Leaves() << endl;
|
---|
2436 |
|
---|
2437 | app << "#N_MAXOBJECTREFS ( Max number of object refs / leaf )\n" << maxObjectRefs << "\n";
|
---|
2438 |
|
---|
2439 | app << "#N_MINOBJECTREFS ( Min number of object refs / leaf )\n" << minObjectRefs << "\n";
|
---|
2440 |
|
---|
2441 | app << "#N_EMPTYLEAFS ( Empty leafs )\n" << emptyNodes << "\n";
|
---|
2442 |
|
---|
2443 | app << "#N_PAVGOBJECTSLEAVES ( average object refs / leaf)\n" << AvgObjectRefs() << endl;
|
---|
2444 |
|
---|
2445 |
|
---|
2446 | ////////////////////////////////////////////////////////
|
---|
2447 |
|
---|
2448 | app << "#N_PMINRAYSLEAVES ( Percentage of leaves with mininum rays )\n"
|
---|
2449 | << minRaysNodes * 100 / (double)Leaves() << endl;
|
---|
2450 |
|
---|
2451 | app << "#N_MAXRAYREFS ( Max number of ray refs / leaf )\n" << maxRayRefs << "\n";
|
---|
2452 |
|
---|
2453 | app << "#N_MINRAYREFS ( Min number of ray refs / leaf )\n" << minRayRefs << "\n";
|
---|
2454 |
|
---|
2455 | app << "#N_PAVGRAYLEAVES ( average ray refs / leaf )\n" << AvgRayRefs() << endl;
|
---|
2456 |
|
---|
2457 | app << "#N_PAVGRAYCONTRIBLEAVES ( Average ray contribution)\n" <<
|
---|
2458 | rayRefs / (double)objectRefs << endl;
|
---|
2459 |
|
---|
2460 | app << "#N_PMAXRAYCONTRIBLEAVES ( Percentage of leaves with maximal ray contribution )\n"<<
|
---|
2461 | maxRayContriNodes * 100 / (double)Leaves() << endl;
|
---|
2462 |
|
---|
2463 | app << "#N_PGLOBALCOSTMISSES ( Global cost misses )\n" << mGlobalCostMisses << endl;
|
---|
2464 |
|
---|
2465 | app << "========== END OF BvHierarchy statistics ==========\n";
|
---|
2466 | }
|
---|
2467 |
|
---|
2468 |
|
---|
2469 | // TODO: return memory usage in MB
|
---|
2470 | float BvHierarchy::GetMemUsage() const
|
---|
2471 | {
|
---|
2472 | return (float)(sizeof(BvHierarchy)
|
---|
2473 | + mBvhStats.Leaves() * sizeof(BvhLeaf)
|
---|
2474 | + mBvhStats.Interior() * sizeof(BvhInterior)
|
---|
2475 | ) / float(1024 * 1024);
|
---|
2476 | }
|
---|
2477 |
|
---|
2478 |
|
---|
2479 | void BvHierarchy::SetActive(BvhNode *node) const
|
---|
2480 | {
|
---|
2481 | vector<BvhLeaf *> leaves;
|
---|
2482 |
|
---|
2483 | // sets the pointers to the currently active view cells
|
---|
2484 | CollectLeaves(node, leaves);
|
---|
2485 | vector<BvhLeaf *>::const_iterator lit, lit_end = leaves.end();
|
---|
2486 |
|
---|
2487 | for (lit = leaves.begin(); lit != lit_end; ++ lit)
|
---|
2488 | {
|
---|
2489 | (*lit)->SetActiveNode(node);
|
---|
2490 | }
|
---|
2491 | }
|
---|
2492 |
|
---|
2493 |
|
---|
2494 | BvhNode *BvHierarchy::SubdivideAndCopy(SplitQueue &tQueue,
|
---|
2495 | SubdivisionCandidate *splitCandidate)
|
---|
2496 | {
|
---|
2497 | BvhSubdivisionCandidate *sc =
|
---|
2498 | dynamic_cast<BvhSubdivisionCandidate *>(splitCandidate);
|
---|
2499 | BvhTraversalData &tData = sc->mParentData;
|
---|
2500 |
|
---|
2501 | BvhNode *currentNode = tData.mNode;
|
---|
2502 | BvhNode *oldNode = (BvhNode *)splitCandidate->mEvaluationHack;
|
---|
2503 |
|
---|
2504 | if (!oldNode->IsLeaf())
|
---|
2505 | {
|
---|
2506 | //////////////
|
---|
2507 | //-- continue subdivision
|
---|
2508 |
|
---|
2509 | BvhTraversalData tFrontData;
|
---|
2510 | BvhTraversalData tBackData;
|
---|
2511 |
|
---|
2512 | BvhInterior *oldInterior = dynamic_cast<BvhInterior *>(oldNode);
|
---|
2513 |
|
---|
2514 | sc->mFrontObjects.clear();
|
---|
2515 | sc->mBackObjects.clear();
|
---|
2516 |
|
---|
2517 | oldInterior->GetFront()->CollectObjects(sc->mFrontObjects);
|
---|
2518 | oldInterior->GetBack()->CollectObjects(sc->mBackObjects);
|
---|
2519 |
|
---|
2520 | // evaluate the changes in render cost and pvs entries
|
---|
2521 | EvalSubdivisionCandidate(*sc, false);
|
---|
2522 |
|
---|
2523 | // create new interior node and two leaf node
|
---|
2524 | currentNode = SubdivideNode(*sc, tFrontData, tBackData);
|
---|
2525 |
|
---|
2526 | //oldNode->mRenderCostDecr += sc->GetRenderCostDecrease();
|
---|
2527 | //oldNode->mPvsEntriesIncr += sc->GetPvsEntriesIncr();
|
---|
2528 |
|
---|
2529 | //oldNode->mRenderCostDecr = sc->GetRenderCostDecrease();
|
---|
2530 | //oldNode->mPvsEntriesIncr = sc->GetPvsEntriesIncr();
|
---|
2531 |
|
---|
2532 | ///////////////////////////
|
---|
2533 | //-- push the new split candidates on the queue
|
---|
2534 |
|
---|
2535 | BvhSubdivisionCandidate *frontCandidate = new BvhSubdivisionCandidate(tFrontData);
|
---|
2536 | BvhSubdivisionCandidate *backCandidate = new BvhSubdivisionCandidate(tBackData);
|
---|
2537 |
|
---|
2538 | frontCandidate->SetPriority((float)-oldInterior->GetFront()->GetTimeStamp());
|
---|
2539 | backCandidate->SetPriority((float)-oldInterior->GetBack()->GetTimeStamp());
|
---|
2540 |
|
---|
2541 | frontCandidate->mEvaluationHack = oldInterior->GetFront();
|
---|
2542 | backCandidate->mEvaluationHack = oldInterior->GetBack();
|
---|
2543 |
|
---|
2544 | // cross reference
|
---|
2545 | tFrontData.mNode->SetSubdivisionCandidate(frontCandidate);
|
---|
2546 | tBackData.mNode->SetSubdivisionCandidate(backCandidate);
|
---|
2547 |
|
---|
2548 | //cout << "f: " << frontCandidate->GetPriority() << " b: " << backCandidate->GetPriority() << endl;
|
---|
2549 | tQueue.Push(frontCandidate);
|
---|
2550 | tQueue.Push(backCandidate);
|
---|
2551 | }
|
---|
2552 |
|
---|
2553 | /////////////////////////////////
|
---|
2554 | //-- node is a leaf => terminate traversal
|
---|
2555 |
|
---|
2556 | if (currentNode->IsLeaf())
|
---|
2557 | {
|
---|
2558 | // this leaf is no candidate for splitting anymore
|
---|
2559 | // => detach subdivision candidate
|
---|
2560 | tData.mNode->SetSubdivisionCandidate(NULL);
|
---|
2561 | // detach node so we don't delete it with the traversal data
|
---|
2562 | tData.mNode = NULL;
|
---|
2563 | }
|
---|
2564 |
|
---|
2565 | return currentNode;
|
---|
2566 | }
|
---|
2567 |
|
---|
2568 |
|
---|
2569 | void BvHierarchy::CollectObjects(const AxisAlignedBox3 &box,
|
---|
2570 | ObjectContainer &objects)
|
---|
2571 | {
|
---|
2572 | stack<BvhNode *> nodeStack;
|
---|
2573 |
|
---|
2574 | nodeStack.push(mRoot);
|
---|
2575 |
|
---|
2576 | while (!nodeStack.empty()) {
|
---|
2577 | BvhNode *node = nodeStack.top();
|
---|
2578 |
|
---|
2579 | nodeStack.pop();
|
---|
2580 | if (node->IsLeaf()) {
|
---|
2581 | BvhLeaf *leaf = (BvhLeaf *)node;
|
---|
2582 | if (Overlap(box, leaf->GetBoundingBox())) {
|
---|
2583 | Intersectable *object = leaf;
|
---|
2584 | if (!object->Mailed()) {
|
---|
2585 | object->Mail();
|
---|
2586 | objects.push_back(object);
|
---|
2587 | }
|
---|
2588 | }
|
---|
2589 | }
|
---|
2590 | else
|
---|
2591 | {
|
---|
2592 | BvhInterior *interior = (BvhInterior *)node;
|
---|
2593 | if (Overlap(box, interior->GetBoundingBox())) {
|
---|
2594 | bool pushed = false;
|
---|
2595 | if (!interior->GetFront()->Mailed()) {
|
---|
2596 | nodeStack.push(interior->GetFront());
|
---|
2597 | pushed = true;
|
---|
2598 | }
|
---|
2599 | if (!interior->GetBack()->Mailed()) {
|
---|
2600 | nodeStack.push(interior->GetBack());
|
---|
2601 | pushed = true;
|
---|
2602 | }
|
---|
2603 | // avoid traversal of this node in the next query
|
---|
2604 | if (!pushed)
|
---|
2605 | interior->Mail();
|
---|
2606 | }
|
---|
2607 | }
|
---|
2608 | }
|
---|
2609 | }
|
---|
2610 |
|
---|
2611 |
|
---|
2612 | void BvHierarchy::CreateUniqueObjectIds()
|
---|
2613 | {
|
---|
2614 | stack<BvhNode *> nodeStack;
|
---|
2615 | nodeStack.push(mRoot);
|
---|
2616 |
|
---|
2617 | int currentId = 0;
|
---|
2618 | while (!nodeStack.empty())
|
---|
2619 | {
|
---|
2620 | BvhNode *node = nodeStack.top();
|
---|
2621 | nodeStack.pop();
|
---|
2622 |
|
---|
2623 | node->SetId(currentId ++);
|
---|
2624 |
|
---|
2625 | if (!node->IsLeaf())
|
---|
2626 | {
|
---|
2627 | BvhInterior *interior = (BvhInterior *)node;
|
---|
2628 |
|
---|
2629 | nodeStack.push(interior->GetFront());
|
---|
2630 | nodeStack.push(interior->GetBack());
|
---|
2631 | }
|
---|
2632 | }
|
---|
2633 | }
|
---|
2634 |
|
---|
2635 |
|
---|
2636 | void BvHierarchy::ApplyInitialSubdivision(SubdivisionCandidate *firstCandidate,
|
---|
2637 | vector<SubdivisionCandidate *> &candidateContainer)
|
---|
2638 | {
|
---|
2639 | SplitQueue tempQueue;
|
---|
2640 | tempQueue.Push(firstCandidate);
|
---|
2641 |
|
---|
2642 | while (!tempQueue.Empty())
|
---|
2643 | {
|
---|
2644 | SubdivisionCandidate *candidate = tempQueue.Top();
|
---|
2645 | tempQueue.Pop();
|
---|
2646 |
|
---|
2647 | BvhSubdivisionCandidate *bsc =
|
---|
2648 | dynamic_cast<BvhSubdivisionCandidate *>(candidate);
|
---|
2649 |
|
---|
2650 | if (!InitialTerminationCriteriaMet(bsc->mParentData))
|
---|
2651 | {
|
---|
2652 | const bool globalCriteriaMet = GlobalTerminationCriteriaMet(bsc->mParentData);
|
---|
2653 |
|
---|
2654 | BvhNode *node = Subdivide(tempQueue, bsc, globalCriteriaMet);
|
---|
2655 |
|
---|
2656 | // not needed anymore
|
---|
2657 | delete bsc;
|
---|
2658 | }
|
---|
2659 | else // initial preprocessing finished for this candidate
|
---|
2660 | {
|
---|
2661 | // add to candidate container
|
---|
2662 | candidateContainer.push_back(bsc);
|
---|
2663 | }
|
---|
2664 | }
|
---|
2665 | }
|
---|
2666 |
|
---|
2667 |
|
---|
2668 | void BvHierarchy::ApplyInitialSplit(const BvhTraversalData &tData,
|
---|
2669 | ObjectContainer &frontObjects,
|
---|
2670 | ObjectContainer &backObjects)
|
---|
2671 | {
|
---|
2672 | ObjectContainer *objects = tData.mSortedObjects[3];
|
---|
2673 |
|
---|
2674 | ObjectContainer::const_iterator oit, oit_end = objects->end();
|
---|
2675 |
|
---|
2676 | float maxAreaDiff = -1.0f;
|
---|
2677 |
|
---|
2678 | ObjectContainer::const_iterator backObjectsStart = objects->begin();
|
---|
2679 |
|
---|
2680 | for (oit = objects->begin(); oit != (objects->end() - 1); ++ oit)
|
---|
2681 | {
|
---|
2682 | Intersectable *objS = *oit;
|
---|
2683 | Intersectable *objL = *(oit + 1);
|
---|
2684 |
|
---|
2685 | const float areaDiff =
|
---|
2686 | objL->GetBox().SurfaceArea() - objS->GetBox().SurfaceArea();
|
---|
2687 |
|
---|
2688 | if (areaDiff > maxAreaDiff)
|
---|
2689 | {
|
---|
2690 | maxAreaDiff = areaDiff;
|
---|
2691 | backObjectsStart = oit + 1;
|
---|
2692 | }
|
---|
2693 | }
|
---|
2694 |
|
---|
2695 | // belongs to back bv
|
---|
2696 | for (oit = objects->begin(); oit != backObjectsStart; ++ oit)
|
---|
2697 | {
|
---|
2698 | frontObjects.push_back(*oit);
|
---|
2699 | }
|
---|
2700 |
|
---|
2701 | // belongs to front bv
|
---|
2702 | for (oit = backObjectsStart; oit != oit_end; ++ oit)
|
---|
2703 | {
|
---|
2704 | backObjects.push_back(*oit);
|
---|
2705 | }
|
---|
2706 |
|
---|
2707 | cout << "front: " << (int)frontObjects.size() << " back: " << (int)backObjects.size() << " "
|
---|
2708 | << backObjects.front()->GetBox().SurfaceArea() - frontObjects.back()->GetBox().SurfaceArea() << endl;
|
---|
2709 | }
|
---|
2710 |
|
---|
2711 |
|
---|
2712 | inline static float AreaRatio(Intersectable *smallObj, Intersectable *largeObj)
|
---|
2713 | {
|
---|
2714 | const float areaSmall = smallObj->GetBox().SurfaceArea();
|
---|
2715 | const float areaLarge = largeObj->GetBox().SurfaceArea();
|
---|
2716 |
|
---|
2717 | return areaSmall / (areaLarge - areaSmall + Limits::Small);
|
---|
2718 | }
|
---|
2719 |
|
---|
2720 |
|
---|
2721 | bool BvHierarchy::InitialTerminationCriteriaMet(const BvhTraversalData &tData) const
|
---|
2722 | {
|
---|
2723 | const bool terminationCriteriaMet =
|
---|
2724 | (0
|
---|
2725 | || ((int)tData.mNode->mObjects.size() < mInitialMinObjects)
|
---|
2726 | || (tData.mNode->mObjects.back()->GetBox().SurfaceArea() < mInitialMinArea)
|
---|
2727 | || (AreaRatio(tData.mNode->mObjects.front(), tData.mNode->mObjects.back()) > mInitialMaxAreaRatio)
|
---|
2728 | );
|
---|
2729 |
|
---|
2730 | cout << "criteria met: "<< terminationCriteriaMet << "\n"
|
---|
2731 | << "size: " << (int)tData.mNode->mObjects.size() << " max: " << mInitialMinObjects << endl
|
---|
2732 | << "ratio: " << AreaRatio(tData.mNode->mObjects.front(), tData.mNode->mObjects.back()) << " max: " << mInitialMaxAreaRatio << endl
|
---|
2733 | << "area: " << tData.mNode->mObjects.back()->GetBox().SurfaceArea() << " max: " << mInitialMinArea << endl << endl;
|
---|
2734 |
|
---|
2735 | return terminationCriteriaMet;
|
---|
2736 | }
|
---|
2737 |
|
---|
2738 |
|
---|
2739 | // HACK
|
---|
2740 | float BvHierarchy::GetRenderCostIncrementially(BvhNode *node) const
|
---|
2741 | {
|
---|
2742 | if (node->mRenderCost < 0)
|
---|
2743 | {
|
---|
2744 | //cout <<"p";
|
---|
2745 | if (node->IsLeaf())
|
---|
2746 | {
|
---|
2747 | BvhLeaf *leaf = dynamic_cast<BvhLeaf *>(node);
|
---|
2748 | node->mRenderCost = EvalAbsCost(leaf->mObjects);
|
---|
2749 | }
|
---|
2750 | else
|
---|
2751 | {
|
---|
2752 | BvhInterior *interior = dynamic_cast<BvhInterior *>(node);
|
---|
2753 |
|
---|
2754 | node->mRenderCost = GetRenderCostIncrementially(interior->GetFront()) +
|
---|
2755 | GetRenderCostIncrementially(interior->GetBack());
|
---|
2756 | }
|
---|
2757 | }
|
---|
2758 |
|
---|
2759 | return node->mRenderCost;
|
---|
2760 | }
|
---|
2761 |
|
---|
2762 |
|
---|
2763 | void BvHierarchy::Compress()
|
---|
2764 | {
|
---|
2765 | }
|
---|
2766 |
|
---|
2767 |
|
---|
2768 | }
|
---|