1 | #ifndef _AxisAlignedBox3_H__
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2 | #define _AxisAlignedBox3_H__
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3 |
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4 | #include "Rectangle3.h"
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5 | #include "Matrix4x4.h"
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6 | #include "Vector3.h"
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7 | #include "Plane3.h"
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8 |
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9 | class Ray;
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10 | class Polygon3;
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11 |
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12 | // --------------------------------------------------------
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13 | // CAABox class.
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14 | // This is a box in 3-space, defined by min and max
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15 | // corner vectors. Many useful operations are defined
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16 | // on this
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17 | // --------------------------------------------------------
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18 | class AxisAlignedBox3
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19 | {
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20 | protected:
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21 | Vector3 mMin, mMax;
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22 | public:
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23 | // Constructors.
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24 | AxisAlignedBox3() { }
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25 | AxisAlignedBox3(const Vector3 &nMin, const Vector3 &nMax)
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26 | {
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27 | mMin = nMin; mMax = nMax;
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28 | }
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29 |
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30 | // AxisAlignedBox3(const Vector3 ¢er, const float radius):min(center - Vector3(radius)),
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31 | // max(center + Vector3(radius)) {}
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32 |
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33 | // initialization to the non existing bounding box
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34 | void Initialize() {
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35 | mMin = Vector3(MAXFLOAT);
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36 | mMax = Vector3(-MAXFLOAT);
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37 | }
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38 |
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39 | // The center of the box
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40 | Vector3 Center() const { return 0.5 * (mMin + mMax); }
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41 |
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42 | // The diagonal of the box
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43 | Vector3 Diagonal() const { return (mMax -mMin); }
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44 |
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45 | float Center(const int axis) const {
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46 | return 0.5f * (mMin[axis] + mMax[axis]);
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47 | }
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48 |
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49 | float Min(const int axis) const {
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50 | return mMin[axis];
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51 | }
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52 |
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53 | float Max(const int axis) const {
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54 | return mMax[axis];
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55 | }
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56 |
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57 | float Size(const int axis) const {
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58 | return Max(axis) - Min(axis);
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59 | }
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60 |
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61 | // Read-only const access tomMin and max vectors using references
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62 | const Vector3& Min() const { return mMin;}
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63 | const Vector3& Max() const { return mMax;}
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64 |
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65 | void Enlarge (const Vector3 &v) {
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66 | mMax += v;
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67 | mMin -= v;
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68 | }
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69 |
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70 | void SetMin(const Vector3 &v) {
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71 | mMin = v;
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72 | }
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73 |
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74 | void SetMax(const Vector3 &v) {
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75 | mMax = v;
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76 | }
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77 |
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78 | void SetMin(int axis, const float value) {
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79 | mMin[axis] = value;
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80 | }
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81 |
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82 | void SetMax(int axis, const float value) {
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83 | mMax[axis] = value;
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84 | }
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85 |
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86 | // Decrease box by given splitting plane
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87 | void Reduce(int axis, int right, float value) {
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88 | if ( (value >=mMin[axis]) && (value <= mMax[axis]) )
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89 | if (right)
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90 | mMin[axis] = value;
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91 | else
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92 | mMax[axis] = value;
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93 | }
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94 |
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95 | // the size of the box along all the axes
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96 | Vector3 Size() const { return mMax - mMin; }
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97 |
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98 | // Return whether the box is unbounded. Unbounded boxes appear
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99 | // when unbounded objects such as quadric surfaces are included.
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100 | bool Unbounded() const;
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101 |
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102 | // Expand the axis-aligned box to include the given object.
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103 | void Include(const Vector3 &newpt);
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104 | void Include(const Polygon3 &newpoly);
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105 | void Include(const AxisAlignedBox3 &bbox);
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106 | // Expand the axis-aligned box to include given values in particular axis
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107 | void Include(const int &axis, const float &newBound);
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108 |
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109 |
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110 | int
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111 | Side(const Plane3 &plane) const;
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112 |
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113 | // Overlap returns 1 if the two axis-aligned boxes overlap .. even weakly
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114 | friend inline bool Overlap(const AxisAlignedBox3 &, const AxisAlignedBox3 &);
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115 |
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116 | // Overlap returns 1 if the two axis-aligned boxes overlap .. only strongly
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117 | friend inline bool OverlapS(const AxisAlignedBox3 &,const AxisAlignedBox3 &);
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118 |
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119 | // Overlap returns 1 if the two axis-aligned boxes overlap for a given
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120 | // epsilon. If eps > 0.0, then the boxes has to have the real intersection
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121 | // box, if eps < 0.0, then the boxes need not intersect really, they
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122 | // can be at eps distance in the projection
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123 | friend inline bool Overlap(const AxisAlignedBox3 &,
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124 | const AxisAlignedBox3 &,
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125 | float eps);
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126 |
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127 | // Includes returns true if a includes b (completely
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128 | bool Includes(const AxisAlignedBox3 &b) const;
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129 |
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130 | virtual int IsInside(const Vector3 &v) const;
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131 |
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132 | // Test if the box is really sensefull
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133 | virtual bool IsCorrect();
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134 |
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135 | // To answer true requires the box of real volume of non-zero value
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136 | bool IsSingularOrIncorrect() const;
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137 |
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138 | // When the box is not of non-zero or negative surface area
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139 | bool IsCorrectAndNotPoint() const;
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140 |
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141 | // Returns true when the box degenerates to a point
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142 | bool IsPoint() const;
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143 |
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144 | void
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145 | GetSqrDistances(const Vector3 &point,
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146 | float &minDistance,
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147 | float &maxDistance
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148 | ) const;
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149 |
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150 | // returns true, when the sphere specified by the origin and radius
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151 | // fully contains the box
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152 | bool IsFullyContainedInSphere(const Vector3 ¢er, float radius) const;
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153 |
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154 | // returns true, when the volume of the sphere and volume of the
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155 | // axis aligned box has no intersection
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156 | bool HasNoIntersectionWithSphere(const Vector3 ¢er,
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157 | float radius) const;
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158 |
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159 |
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160 | // Given a sphere described by the center and radius,
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161 | // the fullowing function returns:
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162 | // -1 ... the sphere and the box are completely separate
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163 | // 0 ... the sphere and the box only partially overlap
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164 | // 1 ... the sphere contains fully the box
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165 | // Note: the case when box fully contains the sphere is not reported
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166 | // since it was not required.
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167 | int MutualPositionWithSphere(const Vector3 ¢er, float radius) const;
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168 |
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169 | // Given a cube described by the center and half-size (radius),
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170 | // the following function returns:
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171 | // -1 ... the cube and the box are completely separate
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172 | // 0 ... the cube and the box only partially overlap
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173 | // 1 ... the cube contains fully the box
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174 | int MutualPositionWithCube(const Vector3 ¢er, float halfSize) const;
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175 |
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176 |
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177 | Vector3 GetRandomPoint() {
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178 | Vector3 size = Size();
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179 | return mMin + Vector3(RandomValue(0, size.x),
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180 | RandomValue(0, size.y),
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181 | RandomValue(0, size.z));
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182 | }
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183 |
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184 | // Returns the smallest axis-aligned box that includes all points
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185 | // inside the two given boxes.
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186 | friend inline AxisAlignedBox3 Union(const AxisAlignedBox3 &x,
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187 | const AxisAlignedBox3 &y);
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188 |
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189 | // Returns the intersection of two axis-aligned boxes.
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190 | friend inline AxisAlignedBox3 Intersect(const AxisAlignedBox3 &x,
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191 | const AxisAlignedBox3 &y);
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192 |
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193 | // Given 4x4 matrix, transform the current box to new one.
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194 | friend inline AxisAlignedBox3 Transform(const AxisAlignedBox3 &box,
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195 | const Matrix4x4 &tform);
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196 |
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197 |
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198 | // returns true when two boxes are completely equal
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199 | friend inline int operator== (const AxisAlignedBox3 &A, const AxisAlignedBox3 &B);
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200 |
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201 | virtual float SurfaceArea() const;
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202 | virtual float GetVolume() const {
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203 | return (mMax.x - mMin.x) * (mMax.y - mMin.y) * (mMax.z - mMin.z);
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204 | }
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205 |
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206 | // Six faces are distuinguished by their name.
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207 | enum EFaces { ID_Back = 0, ID_Left = 1, ID_Bottom = 2, ID_Front = 3,
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208 | ID_Right = 4, ID_Top = 5};
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209 |
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210 | // Compute tmin and tmax for a ray, whenever required .. need not pierce box
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211 | int ComputeMinMaxT(const Ray &ray, float *tmin, float *tmax) const;
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212 |
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213 | // Compute tmin and tmax for a ray, whenever required .. need not pierce box
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214 | int ComputeMinMaxT(const Ray &ray, float *tmin, float *tmax,
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215 | EFaces &entryFace, EFaces &exitFace) const;
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216 |
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217 | // If a ray pierces the box .. returns 1, otherwise 0.
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218 | // Computes the signed distances for case: tmin < tmax and tmax > 0
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219 | int GetMinMaxT(const Ray &ray, float *tmin, float *tmax) const;
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220 | // computes the signed distances for case: tmin < tmax and tmax > 0
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221 | int GetMinMaxT(const Ray &ray, float *tmin, float *tmax,
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222 | EFaces &entryFace, EFaces &exitFace) const;
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223 |
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224 | // Writes a brief description of the object, indenting by the given
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225 | // number of spaces first.
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226 | virtual void Describe(ostream& app, int ind) const;
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227 |
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228 | // For edge .. number <0..11> returns two incident vertices
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229 | void GetEdge(const int edge, Vector3 *a, Vector3 *b) const;
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230 |
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231 | // Compute the coordinates of one vertex of the box for 0/1 in each axis
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232 | // 0 .. smaller coordinates, 1 .. large coordinates
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233 | Vector3 GetVertex(int xAxis, int yAxis, int zAxis) const;
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234 |
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235 | // Compute the vertex for number N=<0..7>, N = 4*x + 2*y + z, where
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236 | // x,y,z are either 0 or 1; (0 .. lower coordinate, 1 .. large coordinate)
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237 | // (xmin,ymin, zmin) .. N = 0, (xmax, ymax, zmax) .. N= 7
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238 | void GetVertex(const int N, Vector3 &vertex) const;
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239 |
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240 | Vector3 GetVertex(const int N) const {
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241 | Vector3 v;
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242 | GetVertex(N, v);
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243 | return v;
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244 | }
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245 |
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246 | // Returns 1, if the box includes on arbitrary face a given box
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247 | int IsPiercedByBox(const AxisAlignedBox3 &box, int &axis) const;
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248 |
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249 |
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250 | int GetFaceVisibilityMask(const Vector3 &position) const;
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251 | int GetFaceVisibilityMask(const Rectangle3 &rectangle) const;
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252 |
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253 | Rectangle3 GetFace(const int face) const;
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254 |
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255 | // For a given point returns the region, where the point is located
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256 | // there are 27 regions (0..26) .. determined by the planes embedding in the
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257 | // sides of the bounding box (0 .. lower the position of the box,
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258 | // 1 .. inside the box, 2 .. greater than box). The region number is given as
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259 | // R = 9*x + 3*y + z ; e.g. region .. inside the box is 13.
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260 | int GetRegionID(const Vector3 &point) const;
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261 |
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262 | // Set the corner point of rectangle on the face of bounding box
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263 | // given by the index number and the rectangle lying on this face
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264 | // void GetFaceRectCorner(const CRectLeaf2D *rect, EFaces faceIndx,
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265 | // const int &cornerIndx, Vector3 &cornerPoint);
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266 |
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267 | // Project the box to a plane given a normal vector of this plane. Computes
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268 | // the surface area of projected silhouettes for parallel projection.
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269 | float ProjectToPlaneSA(const Vector3 &normal) const;
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270 |
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271 | // Computes projected surface area of the box to a given viewing plane
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272 | // given a viewpoint. This corresponds the probability, the box will
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273 | // be hit by the ray .. moreover returns .. the region number (0-26).
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274 | // the function supposes all the points lie of the box lies in the viewing
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275 | // frustrum !!! The positive halfspace of viewplane has to contain
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276 | // viewpoint. "projectionType" == 0 .. perspective projection,
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277 | // == 1 .. parallel projection.
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278 | float ProjectToPlaneSA(const Plane3 &viewplane,
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279 | const Vector3 &viewpoint,
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280 | int *tcase,
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281 | const float &maxSA,
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282 | int projectionType) const;
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283 |
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284 | // Computes projected surface area of the box to a given viewing plane
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285 | // and viewpoint. It clipps the area by all the planes given .. they should
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286 | // define the viewing frustrum. Variable tclip defines, which planes are
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287 | // used for clipping, parameter 31 is the most general, clip all the plane.
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288 | // 1 .. clip left, 2 .. clip top, 4 .. clip right, 8 .. clip bottom,
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289 | // 16 .. clip supporting plane(its normal towards the viewing frustrum).
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290 | // "typeProjection" == 0 .. perspective projection,
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291 | // == 1 .. parallel projection
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292 | float ProjectToPlaneSA(const Plane3 &viewplane,
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293 | const Vector3 &viewpoint,
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294 | int *tcase, int &tclip,
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295 | const Plane3 &leftPlane,
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296 | const Plane3 &topPlane,
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297 | const Plane3 &rightPlane,
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298 | const Plane3 &bottomPlane,
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299 | const Plane3 &suppPlane,
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300 | const float &maxSA,
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301 | int typeProjection) const;
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302 |
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303 | // Projects the box to a unit sphere enclosing a given viewpoint and
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304 | // returns the solid angle of the box projected to a unit sphere
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305 | float ProjectToSphereSA(const Vector3 &viewpoint, int *tcase) const;
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306 |
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307 | /** Returns vertex indices of edge.
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308 | */
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309 | void GetEdge(const int edge, int &aIdx, int &bIdx) const;
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310 |
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311 | /** Computes cross section of plane with box (i.e., bounds box).
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312 | @returns the cross section
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313 | */
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314 | Polygon3 *CrossSection(const Plane3 &plane);
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315 |
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316 | #define __EXTENT_HACK
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317 | // get the extent of face
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318 | float GetExtent(const int &face) const {
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319 | #if defined(__EXTENT_HACK) && defined(__VECTOR_HACK)
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320 | return mMin[face];
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321 | #else
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322 | if (face < 3)
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323 | return mMin[face];
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324 | else
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325 | return mMax[face-3];
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326 | #endif
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327 | }
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328 |
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329 | // The vertices that form boundaries of the projected bounding box
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330 | // for all the regions possible, number of regions is 3^3 = 27,
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331 | // since two parallel sides of bbox forms three disjoint spaces
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332 | // the vertices are given in anti-clockwise order .. stopped by -1 elem.
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333 | static const int bvertices[27][9];
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334 |
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335 | // The list of all faces visible from a given region (except region 13)
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336 | // the faces are identified by triple: (axis, min-vertex, max-vertex),
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337 | // that is maximaly three triples are defined. axis = 0 (x-axis),
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338 | // axis = 1 (y-axis), axis = 2 (z-axis), -1 .. terminator. Is is always
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339 | // true that: min-vertex < max-vertex for all coordinates excluding axis
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340 | static const int bfaces[27][10];
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341 |
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342 | // The correct corners indexed starting from entry face to exit face
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343 | // first index determines entry face, second index exit face, and
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344 | // the two numbers (indx, inc) determines: ind = the index on the exit
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345 | // face, when starting from the vertex 0 on entry face, 'inc' is
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346 | // the increment when we go on entry face in order 0,1,2,3 to create
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347 | // convex shaft with the rectangle on exit face. That is, inc = -1 or 1.
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348 | static const int pairFaceRects[6][6][2];
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349 |
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350 | // The vertices that form CLOSEST points with respect to the region
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351 | // for all the regions possible, number of regions is 3^3 = 27,
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352 | // since two parallel sides of bbox forms three disjoint spaces.
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353 | // The vertices are given in anti-clockwise order, stopped by -1 elem,
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354 | // at most 8 points, at least 1 point.
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355 | static const int cvertices[27][9];
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356 | static const int csvertices[27][6];
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357 |
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358 | // The vertices that form FARTHEST points with respect to the region
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359 | // for all the regions possible, number of regions is 3^3 = 27,
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360 | // since two parallel sides of bbox forms three disjoint spaces.
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361 | // The vertices are given in anti-clockwise order, stopped by -1 elem,
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362 | // at most 8 points, at least 1 point.
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363 | static const int fvertices[27][9];
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364 | static const int fsvertices[27][9];
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365 |
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366 | // input and output operator with stream
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367 | friend ostream& operator<<(ostream &s, const AxisAlignedBox3 &A);
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368 | friend istream& operator>>(istream &s, AxisAlignedBox3 &A);
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369 |
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370 | protected:
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371 | // definition of friend functions
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372 | friend class Ray;
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373 | };
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374 |
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375 | // --------------------------------------------------------------------------
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376 | // Implementation of inline (member) functions
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377 |
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378 | inline bool
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379 | Overlap(const AxisAlignedBox3 &x, const AxisAlignedBox3 &y)
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380 | {
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381 | if (x.mMax.x < y.mMin.x ||
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382 | x.mMin.x > y.mMax.x ||
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383 | x.mMax.y < y.mMin.y ||
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384 | x.mMin.y > y.mMax.y ||
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385 | x.mMax.z < y.mMin.z ||
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386 | x.mMin.z > y.mMax.z) {
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387 | return false;
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388 | }
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389 | return true;
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390 | }
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391 |
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392 | inline bool
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393 | OverlapS(const AxisAlignedBox3 &x, const AxisAlignedBox3 &y)
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394 | {
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395 | if (x.mMax.x <= y.mMin.x ||
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396 | x.mMin.x >= y.mMax.x ||
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397 | x.mMax.y <= y.mMin.y ||
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398 | x.mMin.y >= y.mMax.y ||
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399 | x.mMax.z <= y.mMin.z ||
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400 | x.mMin.z >= y.mMax.z) {
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401 | return false;
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402 | }
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403 | return true;
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404 | }
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405 |
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406 | inline bool
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407 | Overlap(const AxisAlignedBox3 &x, const AxisAlignedBox3 &y, float eps)
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408 | {
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409 | if ( (x.mMax.x - eps) < y.mMin.x ||
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410 | (x.mMin.x + eps) > y.mMax.x ||
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411 | (x.mMax.y - eps) < y.mMin.y ||
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412 | (x.mMin.y + eps) > y.mMax.y ||
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413 | (x.mMax.z - eps) < y.mMin.z ||
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414 | (x.mMin.z + eps) > y.mMax.z ) {
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415 | return false;
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416 | }
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417 | return true;
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418 | }
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419 |
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420 | inline AxisAlignedBox3
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421 | Intersect(const AxisAlignedBox3 &x, const AxisAlignedBox3 &y)
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422 | {
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423 | if (x.Unbounded())
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424 | return y;
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425 | else
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426 | if (y.Unbounded())
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427 | return x;
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428 | AxisAlignedBox3 ret = x;
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429 | if (Overlap(ret, y)) {
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430 | Maximize(ret.mMin, y.mMin);
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431 | Minimize(ret.mMax, y.mMax);
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432 | return ret;
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433 | }
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434 | else // Null intersection.
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435 | return AxisAlignedBox3(Vector3(0), Vector3(0));
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436 | // return AxisAlignedBox3(Vector3(0), Vector3(-1));
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437 | }
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438 |
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439 | inline AxisAlignedBox3
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440 | Union(const AxisAlignedBox3 &x, const AxisAlignedBox3 &y)
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441 | {
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442 | Vector3 min = x.mMin;
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443 | Vector3 max = x.mMax;
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444 | Minimize(min, y.mMin);
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445 | Maximize(max, y.mMax);
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446 | return AxisAlignedBox3(min, max);
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447 | }
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448 |
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449 | inline AxisAlignedBox3
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450 | Transform(const AxisAlignedBox3 &box, const Matrix4x4 &tform)
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451 | {
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452 | Vector3 mmin(MAXFLOAT);
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453 | Vector3 mmax(-MAXFLOAT);
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454 |
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455 | AxisAlignedBox3 ret(mmin, mmax);
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456 | ret.Include(tform * Vector3(box.mMin.x, box.mMin.y, box.mMin.z));
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457 | ret.Include(tform * Vector3(box.mMin.x, box.mMin.y, box.mMax.z));
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458 | ret.Include(tform * Vector3(box.mMin.x, box.mMax.y, box.mMin.z));
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459 | ret.Include(tform * Vector3(box.mMin.x, box.mMax.y, box.mMax.z));
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460 | ret.Include(tform * Vector3(box.mMax.x, box.mMin.y, box.mMin.z));
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461 | ret.Include(tform * Vector3(box.mMax.x, box.mMin.y, box.mMax.z));
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462 | ret.Include(tform * Vector3(box.mMax.x, box.mMax.y, box.mMin.z));
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463 | ret.Include(tform * Vector3(box.mMax.x, box.mMax.y, box.mMax.z));
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464 | return ret;
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465 | }
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466 |
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467 |
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468 | inline int operator==(const AxisAlignedBox3 &A, const AxisAlignedBox3 &B)
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469 | {
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470 | return (A.mMin == B.mMin) && (A.mMax == B.mMax);
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471 | }
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472 |
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473 |
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474 |
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475 |
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476 |
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477 | #endif
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