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1 #include "vector.h"
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2 #include "vmath.h"
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3
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4 // ---------- Vector2 -----------
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5
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6 Vector2::Vector2(scalar_t x, scalar_t y)
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7 {
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8 this->x = x;
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9 this->y = y;
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10 }
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11
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12 Vector2::Vector2(const vec2_t &vec)
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13 {
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14 x = vec.x;
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15 y = vec.y;
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16 }
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17
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18 Vector2::Vector2(const Vector3 &vec)
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19 {
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20 x = vec.x;
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21 y = vec.y;
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22 }
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23
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24 Vector2::Vector2(const Vector4 &vec)
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25 {
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26 x = vec.x;
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27 y = vec.y;
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28 }
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29
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30 void Vector2::normalize()
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31 {
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32 scalar_t len = length();
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33 x /= len;
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34 y /= len;
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35 }
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36
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37 Vector2 Vector2::normalized() const
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38 {
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39 scalar_t len = length();
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40 return Vector2(x / len, y / len);
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41 }
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42
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43 void Vector2::transform(const Matrix3x3 &mat)
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44 {
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45 scalar_t nx = mat[0][0] * x + mat[0][1] * y + mat[0][2];
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46 y = mat[1][0] * x + mat[1][1] * y + mat[1][2];
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47 x = nx;
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48 }
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49
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50 Vector2 Vector2::transformed(const Matrix3x3 &mat) const
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51 {
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52 Vector2 vec;
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53 vec.x = mat[0][0] * x + mat[0][1] * y + mat[0][2];
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54 vec.y = mat[1][0] * x + mat[1][1] * y + mat[1][2];
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55 return vec;
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56 }
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57
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58 void Vector2::rotate(scalar_t angle)
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59 {
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60 *this = Vector2(cos(angle) * x - sin(angle) * y, sin(angle) * x + cos(angle) * y);
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61 }
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62
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63 Vector2 Vector2::rotated(scalar_t angle) const
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64 {
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65 return Vector2(cos(angle) * x - sin(angle) * y, sin(angle) * x + cos(angle) * y);
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66 }
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67
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68 Vector2 Vector2::reflection(const Vector2 &normal) const
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69 {
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70 return 2.0 * dot_product(*this, normal) * normal - *this;
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71 }
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72
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73 Vector2 Vector2::refraction(const Vector2 &normal, scalar_t src_ior, scalar_t dst_ior) const
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74 {
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75 // quick and dirty implementation :)
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76 Vector3 v3refr = Vector3(this->x, this->y, 1.0).refraction(Vector3(this->x, this->y, 1), src_ior, dst_ior);
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77 return Vector2(v3refr.x, v3refr.y);
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78 }
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79
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80 std::ostream &operator <<(std::ostream &out, const Vector2 &vec)
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81 {
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82 out << "[" << vec.x << " " << vec.y << "]";
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83 return out;
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84 }
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85
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86
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87
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88 // --------- Vector3 ----------
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89
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90 Vector3::Vector3(scalar_t x, scalar_t y, scalar_t z)
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91 {
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92 this->x = x;
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93 this->y = y;
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94 this->z = z;
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95 }
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96
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97 Vector3::Vector3(const vec3_t &vec)
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98 {
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99 x = vec.x;
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100 y = vec.y;
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101 z = vec.z;
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102 }
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103
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104 Vector3::Vector3(const Vector2 &vec)
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105 {
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106 x = vec.x;
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107 y = vec.y;
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108 z = 1;
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109 }
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110
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111 Vector3::Vector3(const Vector4 &vec)
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112 {
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113 x = vec.x;
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114 y = vec.y;
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115 z = vec.z;
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116 }
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117
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118 Vector3::Vector3(const SphVector &sph)
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119 {
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120 *this = sph;
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121 }
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122
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123 Vector3 &Vector3::operator =(const SphVector &sph)
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124 {
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125 x = sph.r * cos(sph.theta) * sin(sph.phi);
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126 z = sph.r * sin(sph.theta) * sin(sph.phi);
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127 y = sph.r * cos(sph.phi);
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128 return *this;
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129 }
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130
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131 void Vector3::normalize()
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132 {
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133 scalar_t len = length();
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134 x /= len;
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135 y /= len;
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136 z /= len;
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137 }
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138
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139 Vector3 Vector3::normalized() const
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140 {
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141 scalar_t len = length();
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142 return Vector3(x / len, y / len, z / len);
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143 }
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144
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145 Vector3 Vector3::reflection(const Vector3 &normal) const
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146 {
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147 return 2.0 * dot_product(*this, normal) * normal - *this;
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148 }
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149
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150 Vector3 Vector3::refraction(const Vector3 &normal, scalar_t src_ior, scalar_t dst_ior) const
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151 {
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152 return refraction(normal, src_ior / dst_ior);
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153 }
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154
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155 Vector3 Vector3::refraction(const Vector3 &normal, scalar_t ior) const
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156 {
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157 scalar_t cos_inc = dot_product(*this, -normal);
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158
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159 scalar_t radical = 1.0 + SQ(ior) * (SQ(cos_inc) - 1.0);
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160
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161 if(radical < 0.0) { // total internal reflection
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162 return -reflection(normal);
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163 }
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164
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165 scalar_t beta = ior * cos_inc - sqrt(radical);
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166
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167 return *this * ior + normal * beta;
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168 }
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169
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170 void Vector3::transform(const Matrix3x3 &mat)
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171 {
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172 scalar_t nx = mat[0][0] * x + mat[0][1] * y + mat[0][2] * z;
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173 scalar_t ny = mat[1][0] * x + mat[1][1] * y + mat[1][2] * z;
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174 z = mat[2][0] * x + mat[2][1] * y + mat[2][2] * z;
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175 x = nx;
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176 y = ny;
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177 }
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178
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179 Vector3 Vector3::transformed(const Matrix3x3 &mat) const
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180 {
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181 Vector3 vec;
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182 vec.x = mat[0][0] * x + mat[0][1] * y + mat[0][2] * z;
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183 vec.y = mat[1][0] * x + mat[1][1] * y + mat[1][2] * z;
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184 vec.z = mat[2][0] * x + mat[2][1] * y + mat[2][2] * z;
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185 return vec;
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186 }
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187
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188 void Vector3::transform(const Matrix4x4 &mat)
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189 {
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190 scalar_t nx = mat[0][0] * x + mat[0][1] * y + mat[0][2] * z + mat[0][3];
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191 scalar_t ny = mat[1][0] * x + mat[1][1] * y + mat[1][2] * z + mat[1][3];
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192 z = mat[2][0] * x + mat[2][1] * y + mat[2][2] * z + mat[2][3];
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193 x = nx;
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194 y = ny;
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195 }
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196
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197 Vector3 Vector3::transformed(const Matrix4x4 &mat) const
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198 {
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199 Vector3 vec;
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200 vec.x = mat[0][0] * x + mat[0][1] * y + mat[0][2] * z + mat[0][3];
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201 vec.y = mat[1][0] * x + mat[1][1] * y + mat[1][2] * z + mat[1][3];
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202 vec.z = mat[2][0] * x + mat[2][1] * y + mat[2][2] * z + mat[2][3];
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203 return vec;
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204 }
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205
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206 void Vector3::transform(const Quaternion &quat)
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207 {
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208 Quaternion vq(0.0f, *this);
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209 vq = quat * vq * quat.inverse();
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210 *this = vq.v;
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211 }
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212
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213 Vector3 Vector3::transformed(const Quaternion &quat) const
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214 {
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215 Quaternion vq(0.0f, *this);
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216 vq = quat * vq * quat.inverse();
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217 return vq.v;
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218 }
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219
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220 void Vector3::rotate(const Vector3 &euler)
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221 {
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222 Matrix4x4 rot;
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223 rot.set_rotation(euler);
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224 transform(rot);
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225 }
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226
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227 Vector3 Vector3::rotated(const Vector3 &euler) const
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228 {
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229 Matrix4x4 rot;
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230 rot.set_rotation(euler);
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231 return transformed(rot);
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232 }
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233
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234 std::ostream &operator <<(std::ostream &out, const Vector3 &vec)
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235 {
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236 out << "[" << vec.x << " " << vec.y << " " << vec.z << "]";
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237 return out;
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238 }
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239
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240
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241 // -------------- Vector4 --------------
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242 Vector4::Vector4(scalar_t x, scalar_t y, scalar_t z, scalar_t w)
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243 {
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244 this->x = x;
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245 this->y = y;
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246 this->z = z;
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247 this->w = w;
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248 }
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249
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250 Vector4::Vector4(const vec4_t &vec)
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251 {
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252 x = vec.x;
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253 y = vec.y;
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254 z = vec.z;
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255 w = vec.w;
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256 }
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257
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258 Vector4::Vector4(const Vector2 &vec)
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259 {
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260 x = vec.x;
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261 y = vec.y;
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262 z = 1;
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263 w = 1;
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264 }
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265
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266 Vector4::Vector4(const Vector3 &vec)
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267 {
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268 x = vec.x;
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269 y = vec.y;
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270 z = vec.z;
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271 w = 1;
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272 }
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273
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274 void Vector4::normalize()
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275 {
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276 scalar_t len = (scalar_t)sqrt(x*x + y*y + z*z + w*w);
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277 x /= len;
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278 y /= len;
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279 z /= len;
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280 w /= len;
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281 }
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282
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283 Vector4 Vector4::normalized() const
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284 {
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285 scalar_t len = (scalar_t)sqrt(x*x + y*y + z*z + w*w);
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286 return Vector4(x / len, y / len, z / len, w / len);
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287 }
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288
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289 void Vector4::transform(const Matrix4x4 &mat)
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290 {
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291 scalar_t nx = mat[0][0] * x + mat[0][1] * y + mat[0][2] * z + mat[0][3] * w;
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292 scalar_t ny = mat[1][0] * x + mat[1][1] * y + mat[1][2] * z + mat[1][3] * w;
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293 scalar_t nz = mat[2][0] * x + mat[2][1] * y + mat[2][2] * z + mat[2][3] * w;
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294 w = mat[3][0] * x + mat[3][1] * y + mat[3][2] * z + mat[3][3] * w;
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295 x = nx;
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296 y = ny;
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297 z = nz;
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298 }
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299
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300 Vector4 Vector4::transformed(const Matrix4x4 &mat) const
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301 {
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302 Vector4 vec;
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303 vec.x = mat[0][0] * x + mat[0][1] * y + mat[0][2] * z + mat[0][3] * w;
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304 vec.y = mat[1][0] * x + mat[1][1] * y + mat[1][2] * z + mat[1][3] * w;
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305 vec.z = mat[2][0] * x + mat[2][1] * y + mat[2][2] * z + mat[2][3] * w;
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306 vec.w = mat[3][0] * x + mat[3][1] * y + mat[3][2] * z + mat[3][3] * w;
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307 return vec;
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308 }
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309
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310 // TODO: implement 4D vector reflection
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311 Vector4 Vector4::reflection(const Vector4 &normal) const
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312 {
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313 return *this;
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314 }
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315
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316 // TODO: implement 4D vector refraction
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317 Vector4 Vector4::refraction(const Vector4 &normal, scalar_t src_ior, scalar_t dst_ior) const
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318 {
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319 return *this;
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320 }
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321
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322 std::ostream &operator <<(std::ostream &out, const Vector4 &vec)
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323 {
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324 out << "[" << vec.x << " " << vec.y << " " << vec.z << " " << vec.w << "]";
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325 return out;
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326 }
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