1 | /*
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2 | -----------------------------------------------------------------------------
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3 | This source file is part of OGRE
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4 | (Object-oriented Graphics Rendering Engine)
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5 | For the latest info, see http://www.ogre3d.org/
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6 |
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7 | Copyright (c) 2000-2005 The OGRE Team
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8 | Also see acknowledgements in Readme.html
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9 |
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10 | This program is free software; you can redistribute it and/or modify it under
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11 | the terms of the GNU Lesser General Public License as published by the Free Software
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12 | Foundation; either version 2 of the License, or (at your option) any later
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13 | version.
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14 |
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15 | This program is distributed in the hope that it will be useful, but WITHOUT
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16 | ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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17 | FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details.
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18 |
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19 | You should have received a copy of the GNU Lesser General Public License along with
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20 | this program; if not, write to the Free Software Foundation, Inc., 59 Temple
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21 | Place - Suite 330, Boston, MA 02111-1307, USA, or go to
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22 | http://www.gnu.org/copyleft/lesser.txt.
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23 | -----------------------------------------------------------------------------
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24 | */
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25 | #include "OgreStableHeaders.h"
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26 | // NOTE THAT THIS FILE IS BASED ON MATERIAL FROM:
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27 |
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28 | // Magic Software, Inc.
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29 | // http://www.magic-software.com
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30 | // Copyright (c) 2000, All Rights Reserved
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31 | //
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32 | // Source code from Magic Software is supplied under the terms of a license
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33 | // agreement and may not be copied or disclosed except in accordance with the
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34 | // terms of that agreement. The various license agreements may be found at
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35 | // the Magic Software web site. This file is subject to the license
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36 | //
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37 | // FREE SOURCE CODE
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38 | // http://www.magic-software.com/License/free.pdf
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39 |
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40 | #include "OgreQuaternion.h"
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41 |
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42 | #include "OgreMath.h"
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43 | #include "OgreMatrix3.h"
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44 | #include "OgreVector3.h"
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45 |
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46 | namespace Ogre {
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47 |
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48 | const Real Quaternion::ms_fEpsilon = 1e-03;
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49 | const Quaternion Quaternion::ZERO(0.0,0.0,0.0,0.0);
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50 | const Quaternion Quaternion::IDENTITY(1.0,0.0,0.0,0.0);
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51 |
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52 | //-----------------------------------------------------------------------
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53 | void Quaternion::FromRotationMatrix (const Matrix3& kRot)
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54 | {
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55 | // Algorithm in Ken Shoemake's article in 1987 SIGGRAPH course notes
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56 | // article "Quaternion Calculus and Fast Animation".
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57 |
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58 | Real fTrace = kRot[0][0]+kRot[1][1]+kRot[2][2];
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59 | Real fRoot;
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60 |
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61 | if ( fTrace > 0.0 )
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62 | {
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63 | // |w| > 1/2, may as well choose w > 1/2
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64 | fRoot = Math::Sqrt(fTrace + 1.0); // 2w
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65 | w = 0.5*fRoot;
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66 | fRoot = 0.5/fRoot; // 1/(4w)
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67 | x = (kRot[2][1]-kRot[1][2])*fRoot;
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68 | y = (kRot[0][2]-kRot[2][0])*fRoot;
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69 | z = (kRot[1][0]-kRot[0][1])*fRoot;
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70 | }
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71 | else
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72 | {
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73 | // |w| <= 1/2
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74 | static size_t s_iNext[3] = { 1, 2, 0 };
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75 | size_t i = 0;
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76 | if ( kRot[1][1] > kRot[0][0] )
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77 | i = 1;
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78 | if ( kRot[2][2] > kRot[i][i] )
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79 | i = 2;
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80 | size_t j = s_iNext[i];
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81 | size_t k = s_iNext[j];
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82 |
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83 | fRoot = Math::Sqrt(kRot[i][i]-kRot[j][j]-kRot[k][k] + 1.0);
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84 | Real* apkQuat[3] = { &x, &y, &z };
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85 | *apkQuat[i] = 0.5*fRoot;
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86 | fRoot = 0.5/fRoot;
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87 | w = (kRot[k][j]-kRot[j][k])*fRoot;
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88 | *apkQuat[j] = (kRot[j][i]+kRot[i][j])*fRoot;
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89 | *apkQuat[k] = (kRot[k][i]+kRot[i][k])*fRoot;
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90 | }
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91 | }
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92 | //-----------------------------------------------------------------------
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93 | void Quaternion::ToRotationMatrix (Matrix3& kRot) const
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94 | {
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95 | Real fTx = 2.0*x;
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96 | Real fTy = 2.0*y;
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97 | Real fTz = 2.0*z;
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98 | Real fTwx = fTx*w;
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99 | Real fTwy = fTy*w;
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100 | Real fTwz = fTz*w;
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101 | Real fTxx = fTx*x;
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102 | Real fTxy = fTy*x;
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103 | Real fTxz = fTz*x;
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104 | Real fTyy = fTy*y;
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105 | Real fTyz = fTz*y;
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106 | Real fTzz = fTz*z;
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107 |
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108 | kRot[0][0] = 1.0-(fTyy+fTzz);
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109 | kRot[0][1] = fTxy-fTwz;
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110 | kRot[0][2] = fTxz+fTwy;
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111 | kRot[1][0] = fTxy+fTwz;
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112 | kRot[1][1] = 1.0-(fTxx+fTzz);
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113 | kRot[1][2] = fTyz-fTwx;
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114 | kRot[2][0] = fTxz-fTwy;
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115 | kRot[2][1] = fTyz+fTwx;
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116 | kRot[2][2] = 1.0-(fTxx+fTyy);
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117 | }
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118 | //-----------------------------------------------------------------------
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119 | void Quaternion::FromAngleAxis (const Radian& rfAngle,
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120 | const Vector3& rkAxis)
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121 | {
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122 | // assert: axis[] is unit length
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123 | //
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124 | // The quaternion representing the rotation is
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125 | // q = cos(A/2)+sin(A/2)*(x*i+y*j+z*k)
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126 |
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127 | Radian fHalfAngle ( 0.5*rfAngle );
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128 | Real fSin = Math::Sin(fHalfAngle);
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129 | w = Math::Cos(fHalfAngle);
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130 | x = fSin*rkAxis.x;
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131 | y = fSin*rkAxis.y;
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132 | z = fSin*rkAxis.z;
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133 | }
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134 | //-----------------------------------------------------------------------
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135 | void Quaternion::ToAngleAxis (Radian& rfAngle, Vector3& rkAxis) const
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136 | {
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137 | // The quaternion representing the rotation is
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138 | // q = cos(A/2)+sin(A/2)*(x*i+y*j+z*k)
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139 |
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140 | Real fSqrLength = x*x+y*y+z*z;
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141 | if ( fSqrLength > 0.0 )
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142 | {
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143 | rfAngle = 2.0*Math::ACos(w);
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144 | Real fInvLength = Math::InvSqrt(fSqrLength);
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145 | rkAxis.x = x*fInvLength;
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146 | rkAxis.y = y*fInvLength;
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147 | rkAxis.z = z*fInvLength;
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148 | }
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149 | else
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150 | {
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151 | // angle is 0 (mod 2*pi), so any axis will do
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152 | rfAngle = Radian(0.0);
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153 | rkAxis.x = 1.0;
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154 | rkAxis.y = 0.0;
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155 | rkAxis.z = 0.0;
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156 | }
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157 | }
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158 | //-----------------------------------------------------------------------
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159 | void Quaternion::FromAxes (const Vector3* akAxis)
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160 | {
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161 | Matrix3 kRot;
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162 |
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163 | for (size_t iCol = 0; iCol < 3; iCol++)
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164 | {
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165 | kRot[0][iCol] = akAxis[iCol].x;
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166 | kRot[1][iCol] = akAxis[iCol].y;
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167 | kRot[2][iCol] = akAxis[iCol].z;
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168 | }
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169 |
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170 | FromRotationMatrix(kRot);
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171 | }
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172 | //-----------------------------------------------------------------------
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173 | void Quaternion::FromAxes (const Vector3& xaxis, const Vector3& yaxis, const Vector3& zaxis)
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174 | {
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175 | Matrix3 kRot;
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176 |
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177 | kRot[0][0] = xaxis.x;
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178 | kRot[1][0] = xaxis.y;
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179 | kRot[2][0] = xaxis.z;
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180 |
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181 | kRot[0][1] = yaxis.x;
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182 | kRot[1][1] = yaxis.y;
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183 | kRot[2][1] = yaxis.z;
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184 |
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185 | kRot[0][2] = zaxis.x;
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186 | kRot[1][2] = zaxis.y;
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187 | kRot[2][2] = zaxis.z;
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188 |
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189 | FromRotationMatrix(kRot);
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190 |
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191 | }
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192 | //-----------------------------------------------------------------------
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193 | void Quaternion::ToAxes (Vector3* akAxis) const
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194 | {
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195 | Matrix3 kRot;
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196 |
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197 | ToRotationMatrix(kRot);
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198 |
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199 | for (size_t iCol = 0; iCol < 3; iCol++)
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200 | {
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201 | akAxis[iCol].x = kRot[0][iCol];
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202 | akAxis[iCol].y = kRot[1][iCol];
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203 | akAxis[iCol].z = kRot[2][iCol];
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204 | }
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205 | }
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206 | //-----------------------------------------------------------------------
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207 | Vector3 Quaternion::xAxis(void) const
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208 | {
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209 | Real fTx = 2.0*x;
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210 | Real fTy = 2.0*y;
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211 | Real fTz = 2.0*z;
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212 | Real fTwy = fTy*w;
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213 | Real fTwz = fTz*w;
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214 | Real fTxy = fTy*x;
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215 | Real fTxz = fTz*x;
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216 | Real fTyy = fTy*y;
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217 | Real fTzz = fTz*z;
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218 |
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219 | return Vector3(1.0-(fTyy+fTzz), fTxy+fTwz, fTxz-fTwy);
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220 | }
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221 | //-----------------------------------------------------------------------
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222 | Vector3 Quaternion::yAxis(void) const
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223 | {
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224 | Real fTx = 2.0*x;
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225 | Real fTy = 2.0*y;
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226 | Real fTz = 2.0*z;
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227 | Real fTwx = fTx*w;
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228 | Real fTwz = fTz*w;
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229 | Real fTxx = fTx*x;
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230 | Real fTxy = fTy*x;
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231 | Real fTyz = fTz*y;
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232 | Real fTzz = fTz*z;
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233 |
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234 | return Vector3(fTxy-fTwz, 1.0-(fTxx+fTzz), fTyz+fTwx);
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235 | }
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236 | //-----------------------------------------------------------------------
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237 | Vector3 Quaternion::zAxis(void) const
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238 | {
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239 | Real fTx = 2.0*x;
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240 | Real fTy = 2.0*y;
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241 | Real fTz = 2.0*z;
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242 | Real fTwx = fTx*w;
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243 | Real fTwy = fTy*w;
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244 | Real fTxx = fTx*x;
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245 | Real fTxz = fTz*x;
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246 | Real fTyy = fTy*y;
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247 | Real fTyz = fTz*y;
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248 |
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249 | return Vector3(fTxz+fTwy, fTyz-fTwx, 1.0-(fTxx+fTyy));
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250 | }
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251 | //-----------------------------------------------------------------------
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252 | void Quaternion::ToAxes (Vector3& xaxis, Vector3& yaxis, Vector3& zaxis) const
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253 | {
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254 | Matrix3 kRot;
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255 |
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256 | ToRotationMatrix(kRot);
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257 |
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258 | xaxis.x = kRot[0][0];
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259 | xaxis.y = kRot[1][0];
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260 | xaxis.z = kRot[2][0];
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261 |
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262 | yaxis.x = kRot[0][1];
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263 | yaxis.y = kRot[1][1];
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264 | yaxis.z = kRot[2][1];
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265 |
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266 | zaxis.x = kRot[0][2];
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267 | zaxis.y = kRot[1][2];
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268 | zaxis.z = kRot[2][2];
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269 | }
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270 |
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271 | //-----------------------------------------------------------------------
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272 | Quaternion Quaternion::operator+ (const Quaternion& rkQ) const
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273 | {
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274 | return Quaternion(w+rkQ.w,x+rkQ.x,y+rkQ.y,z+rkQ.z);
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275 | }
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276 | //-----------------------------------------------------------------------
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277 | Quaternion Quaternion::operator- (const Quaternion& rkQ) const
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278 | {
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279 | return Quaternion(w-rkQ.w,x-rkQ.x,y-rkQ.y,z-rkQ.z);
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280 | }
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281 | //-----------------------------------------------------------------------
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282 | Quaternion Quaternion::operator* (const Quaternion& rkQ) const
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283 | {
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284 | // NOTE: Multiplication is not generally commutative, so in most
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285 | // cases p*q != q*p.
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286 |
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287 | return Quaternion
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288 | (
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289 | w * rkQ.w - x * rkQ.x - y * rkQ.y - z * rkQ.z,
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290 | w * rkQ.x + x * rkQ.w + y * rkQ.z - z * rkQ.y,
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291 | w * rkQ.y + y * rkQ.w + z * rkQ.x - x * rkQ.z,
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292 | w * rkQ.z + z * rkQ.w + x * rkQ.y - y * rkQ.x
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293 | );
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294 | }
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295 | //-----------------------------------------------------------------------
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296 | Quaternion Quaternion::operator* (Real fScalar) const
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297 | {
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298 | return Quaternion(fScalar*w,fScalar*x,fScalar*y,fScalar*z);
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299 | }
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300 | //-----------------------------------------------------------------------
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301 | Quaternion operator* (Real fScalar, const Quaternion& rkQ)
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302 | {
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303 | return Quaternion(fScalar*rkQ.w,fScalar*rkQ.x,fScalar*rkQ.y,
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304 | fScalar*rkQ.z);
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305 | }
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306 | //-----------------------------------------------------------------------
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307 | Quaternion Quaternion::operator- () const
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308 | {
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309 | return Quaternion(-w,-x,-y,-z);
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310 | }
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311 | //-----------------------------------------------------------------------
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312 | Real Quaternion::Dot (const Quaternion& rkQ) const
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313 | {
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314 | return w*rkQ.w+x*rkQ.x+y*rkQ.y+z*rkQ.z;
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315 | }
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316 | //-----------------------------------------------------------------------
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317 | Real Quaternion::Norm () const
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318 | {
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319 | return w*w+x*x+y*y+z*z;
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320 | }
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321 | //-----------------------------------------------------------------------
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322 | Quaternion Quaternion::Inverse () const
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323 | {
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324 | Real fNorm = w*w+x*x+y*y+z*z;
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325 | if ( fNorm > 0.0 )
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326 | {
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327 | Real fInvNorm = 1.0/fNorm;
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328 | return Quaternion(w*fInvNorm,-x*fInvNorm,-y*fInvNorm,-z*fInvNorm);
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329 | }
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330 | else
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331 | {
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332 | // return an invalid result to flag the error
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333 | return ZERO;
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334 | }
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335 | }
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336 | //-----------------------------------------------------------------------
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337 | Quaternion Quaternion::UnitInverse () const
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338 | {
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339 | // assert: 'this' is unit length
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340 | return Quaternion(w,-x,-y,-z);
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341 | }
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342 | //-----------------------------------------------------------------------
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343 | Quaternion Quaternion::Exp () const
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344 | {
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345 | // If q = A*(x*i+y*j+z*k) where (x,y,z) is unit length, then
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346 | // exp(q) = cos(A)+sin(A)*(x*i+y*j+z*k). If sin(A) is near zero,
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347 | // use exp(q) = cos(A)+A*(x*i+y*j+z*k) since A/sin(A) has limit 1.
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348 |
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349 | Radian fAngle ( Math::Sqrt(x*x+y*y+z*z) );
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350 | Real fSin = Math::Sin(fAngle);
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351 |
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352 | Quaternion kResult;
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353 | kResult.w = Math::Cos(fAngle);
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354 |
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355 | if ( Math::Abs(fSin) >= ms_fEpsilon )
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356 | {
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357 | Real fCoeff = fSin/(fAngle.valueRadians());
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358 | kResult.x = fCoeff*x;
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359 | kResult.y = fCoeff*y;
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360 | kResult.z = fCoeff*z;
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361 | }
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362 | else
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363 | {
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364 | kResult.x = x;
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365 | kResult.y = y;
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366 | kResult.z = z;
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367 | }
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368 |
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369 | return kResult;
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370 | }
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371 | //-----------------------------------------------------------------------
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372 | Quaternion Quaternion::Log () const
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373 | {
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374 | // If q = cos(A)+sin(A)*(x*i+y*j+z*k) where (x,y,z) is unit length, then
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375 | // log(q) = A*(x*i+y*j+z*k). If sin(A) is near zero, use log(q) =
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376 | // sin(A)*(x*i+y*j+z*k) since sin(A)/A has limit 1.
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377 |
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378 | Quaternion kResult;
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379 | kResult.w = 0.0;
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380 |
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381 | if ( Math::Abs(w) < 1.0 )
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382 | {
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383 | Radian fAngle ( Math::ACos(w) );
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384 | Real fSin = Math::Sin(fAngle);
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385 | if ( Math::Abs(fSin) >= ms_fEpsilon )
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386 | {
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387 | Real fCoeff = fAngle.valueRadians()/fSin;
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388 | kResult.x = fCoeff*x;
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389 | kResult.y = fCoeff*y;
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390 | kResult.z = fCoeff*z;
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391 | return kResult;
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392 | }
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393 | }
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394 |
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395 | kResult.x = x;
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396 | kResult.y = y;
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397 | kResult.z = z;
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398 |
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399 | return kResult;
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400 | }
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401 | //-----------------------------------------------------------------------
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402 | Vector3 Quaternion::operator* (const Vector3& v) const
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403 | {
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404 | // nVidia SDK implementation
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405 | Vector3 uv, uuv;
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406 | Vector3 qvec(x, y, z);
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407 | uv = qvec.crossProduct(v);
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408 | uuv = qvec.crossProduct(uv);
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409 | uv *= (2.0f * w);
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410 | uuv *= 2.0f;
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411 |
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412 | return v + uv + uuv;
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413 |
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414 | }
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415 | //-----------------------------------------------------------------------
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416 | bool Quaternion::equals(const Quaternion& rhs, const Radian& tolerance) const
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417 | {
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418 | Real fCos = Dot(rhs);
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419 | Radian angle = Math::ACos(fCos);
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420 |
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421 | return (Math::Abs(angle.valueRadians()) <= tolerance.valueRadians())
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422 | || Math::RealEqual(angle.valueRadians(), Math::PI, tolerance.valueRadians());
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423 |
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424 |
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425 | }
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426 | //-----------------------------------------------------------------------
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427 | Quaternion Quaternion::Slerp (Real fT, const Quaternion& rkP,
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428 | const Quaternion& rkQ, bool shortestPath)
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429 | {
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430 | Real fCos = rkP.Dot(rkQ);
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431 | Radian fAngle ( Math::ACos(fCos) );
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432 |
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433 | if ( Math::Abs(fAngle.valueRadians()) < ms_fEpsilon )
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434 | return rkP;
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435 |
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436 | Real fSin = Math::Sin(fAngle);
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437 | Real fInvSin = 1.0/fSin;
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438 | Real fCoeff0 = Math::Sin((1.0-fT)*fAngle)*fInvSin;
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439 | Real fCoeff1 = Math::Sin(fT*fAngle)*fInvSin;
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440 | // Do we need to invert rotation?
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441 | if (fCos < 0.0f && shortestPath)
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442 | {
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443 | fCoeff0 = -fCoeff0;
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444 | // taking the complement requires renormalisation
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445 | Quaternion t(fCoeff0*rkP + fCoeff1*rkQ);
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446 | t.normalise();
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447 | return t;
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448 | }
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449 | else
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450 | {
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451 | return fCoeff0*rkP + fCoeff1*rkQ;
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452 | }
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453 | }
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454 | //-----------------------------------------------------------------------
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455 | Quaternion Quaternion::SlerpExtraSpins (Real fT,
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456 | const Quaternion& rkP, const Quaternion& rkQ, int iExtraSpins)
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457 | {
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458 | Real fCos = rkP.Dot(rkQ);
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459 | Radian fAngle ( Math::ACos(fCos) );
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460 |
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461 | if ( Math::Abs(fAngle.valueRadians()) < ms_fEpsilon )
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462 | return rkP;
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463 |
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464 | Real fSin = Math::Sin(fAngle);
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465 | Radian fPhase ( Math::PI*iExtraSpins*fT );
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466 | Real fInvSin = 1.0/fSin;
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467 | Real fCoeff0 = Math::Sin((1.0-fT)*fAngle - fPhase)*fInvSin;
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468 | Real fCoeff1 = Math::Sin(fT*fAngle + fPhase)*fInvSin;
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469 | return fCoeff0*rkP + fCoeff1*rkQ;
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470 | }
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471 | //-----------------------------------------------------------------------
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472 | void Quaternion::Intermediate (const Quaternion& rkQ0,
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473 | const Quaternion& rkQ1, const Quaternion& rkQ2,
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474 | Quaternion& rkA, Quaternion& rkB)
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475 | {
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476 | // assert: q0, q1, q2 are unit quaternions
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477 |
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478 | Quaternion kQ0inv = rkQ0.UnitInverse();
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479 | Quaternion kQ1inv = rkQ1.UnitInverse();
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480 | Quaternion rkP0 = kQ0inv*rkQ1;
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481 | Quaternion rkP1 = kQ1inv*rkQ2;
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482 | Quaternion kArg = 0.25*(rkP0.Log()-rkP1.Log());
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483 | Quaternion kMinusArg = -kArg;
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484 |
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485 | rkA = rkQ1*kArg.Exp();
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486 | rkB = rkQ1*kMinusArg.Exp();
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487 | }
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488 | //-----------------------------------------------------------------------
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489 | Quaternion Quaternion::Squad (Real fT,
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490 | const Quaternion& rkP, const Quaternion& rkA,
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491 | const Quaternion& rkB, const Quaternion& rkQ, bool shortestPath)
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492 | {
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493 | Real fSlerpT = 2.0*fT*(1.0-fT);
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494 | Quaternion kSlerpP = Slerp(fT, rkP, rkQ, shortestPath);
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495 | Quaternion kSlerpQ = Slerp(fT, rkA, rkB);
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496 | return Slerp(fSlerpT, kSlerpP ,kSlerpQ);
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497 | }
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498 | //-----------------------------------------------------------------------
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499 | Real Quaternion::normalise(void)
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500 | {
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501 | Real len = Norm();
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502 | Real factor = 1.0f / Math::Sqrt(len);
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503 | *this = *this * factor;
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504 | return len;
|
---|
505 | }
|
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506 | //-----------------------------------------------------------------------
|
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507 | Radian Quaternion::getRoll(void) const
|
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508 | {
|
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509 | return Radian(Math::ATan2(2*(x*y + w*z), w*w + x*x - y*y - z*z));
|
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510 | }
|
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511 | //-----------------------------------------------------------------------
|
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512 | Radian Quaternion::getPitch(void) const
|
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513 | {
|
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514 | return Radian(Math::ATan2(2*(y*z + w*x), w*w - x*x - y*y + z*z));
|
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515 | }
|
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516 | //-----------------------------------------------------------------------
|
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517 | Radian Quaternion::getYaw(void) const
|
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518 | {
|
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519 | return Radian(Math::ASin(-2*(x*z - w*y)));
|
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520 | }
|
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521 | //-----------------------------------------------------------------------
|
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522 | Quaternion Quaternion::nlerp(Real fT, const Quaternion& rkP,
|
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523 | const Quaternion& rkQ, bool shortestPath)
|
---|
524 | {
|
---|
525 | Quaternion result;
|
---|
526 | Real fCos = rkP.Dot(rkQ);
|
---|
527 | if (fCos < 0.0f && shortestPath)
|
---|
528 | {
|
---|
529 | result = rkP + fT * ((-rkQ) - rkP);
|
---|
530 | }
|
---|
531 | else
|
---|
532 | {
|
---|
533 | result = rkP + fT * (rkQ - rkP);
|
---|
534 | }
|
---|
535 | result.normalise();
|
---|
536 | return result;
|
---|
537 | }
|
---|
538 | }
|
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