1168 lines
33 KiB
C++
1168 lines
33 KiB
C++
/*
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LA: linear algebra C++ interface library
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Copyright (C) 2020 Jiri Pittner <jiri.pittner@jh-inst.cas.cz> or <jiri@pittnerovi.com>
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include "vecmat3.h"
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#ifndef QUAT_NO_RANDOM
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#include "la_random.h"
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#endif
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namespace LA_Vecmat3 {
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//http://en.wikipedia.org/wiki/Fast_inverse_square_root
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float fast_sqrtinv(float number )
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{
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long i;
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float x2, y;
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const float threehalfs = 1.5F;
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x2 = number * 0.5F;
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y = number;
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i = * ( long * ) &y; // evil floating point bit level hacking
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i = 0x5f3759df - ( i >> 1 ); // what the fuck?
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y = * ( float * ) &i;
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y = y * ( threehalfs - ( x2 * y * y ) ); // 1st iteration
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y = y * ( threehalfs - ( x2 * y * y ) ); // 2nd iteration, this can be removed
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return y;
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}
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template<>
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Vec3<float> & Vec3<float>::fast_normalize(void) {*this *= fast_sqrtinv(normsqr()); return *this;};
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template<typename T>
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Vec3<T>& Vec3<T>::fast_normalize(void) {normalize(); return *this;};
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template<typename T>
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Mat3<T> Vec3<T>::outer(const Vec3<T> &rhs) const
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{
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Mat3<T> m;
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m[0][0]=q[0]*rhs.q[0];
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m[0][1]=q[0]*rhs.q[1];
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m[0][2]=q[0]*rhs.q[2];
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m[1][0]=q[1]*rhs.q[0];
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m[1][1]=q[1]*rhs.q[1];
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m[1][2]=q[1]*rhs.q[2];
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m[2][0]=q[2]*rhs.q[0];
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m[2][1]=q[2]*rhs.q[1];
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m[2][2]=q[2]*rhs.q[2];
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return m;
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}
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template<typename T>
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void Vec3<T>::addouter(Mat3<T> &m, const Vec3<T> &rhs, const T weight) const
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{
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m[0][0]+=weight* q[0]*rhs.q[0];
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m[0][1]+=weight* q[0]*rhs.q[1];
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m[0][2]+=weight* q[0]*rhs.q[2];
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m[1][0]+=weight* q[1]*rhs.q[0];
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m[1][1]+=weight* q[1]*rhs.q[1];
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m[1][2]+=weight* q[1]*rhs.q[2];
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m[2][0]+=weight* q[2]*rhs.q[0];
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m[2][1]+=weight* q[2]*rhs.q[1];
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m[2][2]+=weight* q[2]*rhs.q[2];
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}
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template<typename T>
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void Vec3<T>::inertia(Mat3<T> &m, const T weight) const
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{
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T r2 = q[0]*q[0]+q[1]*q[1]+q[2]*q[2];
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m[0][0] -= weight*(q[0]*q[0]-r2);
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m[0][1] -= weight*q[0]*q[1];
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m[0][2] -= weight*q[0]*q[2];
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m[1][0] -= weight*q[1]*q[0];
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m[1][1] -= weight*(q[1]*q[1]-r2);
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m[1][2] -= weight*q[1]*q[2];
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m[2][0] -= weight*q[2]*q[0];
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m[2][1] -= weight*q[2]*q[1];
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m[2][2] -= weight*(q[2]*q[2]-r2);
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}
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template<typename T>
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const Vec3<T> Vec3<T>::operator*(const Mat3<T> &rhs) const
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{
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Vec3<T> r;
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r[0] = q[0]*rhs.q[0][0] + q[1]*rhs.q[1][0] + q[2]*rhs.q[2][0];
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r[1] = q[0]*rhs.q[0][1] + q[1]*rhs.q[1][1] + q[2]*rhs.q[2][1];
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r[2] = q[0]*rhs.q[0][2] + q[1]*rhs.q[1][2] + q[2]*rhs.q[2][2];
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return r;
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};
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template<typename T>
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const Vec3<T> Vec3<T>::timesT(const Mat3<T> &rhs) const
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{
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Vec3<T> r;
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r[0] = q[0]*rhs.q[0][0] + q[1]*rhs.q[0][1] + q[2]*rhs.q[0][2];
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r[1] = q[0]*rhs.q[1][0] + q[1]*rhs.q[1][1] + q[2]*rhs.q[1][2];
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r[2] = q[0]*rhs.q[2][0] + q[1]*rhs.q[2][1] + q[2]*rhs.q[2][2];
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return r;
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};
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template<typename T>
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Mat3<T>& Mat3<T>::operator+=(const Mat3 &rhs)
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{
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q[0][0]+=rhs.q[0][0];q[0][1]+=rhs.q[0][1];q[0][2]+=rhs.q[0][2]; q[1][0]+=rhs.q[1][0];q[1][1]+=rhs.q[1][1];q[1][2]+=rhs.q[1][2]; q[2][0]+=rhs.q[2][0];q[2][1]+=rhs.q[2][1];q[2][2]+=rhs.q[2][2];
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return *this;
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}
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template<typename T>
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Mat3<T>& Mat3<T>::operator-=(const Mat3 &rhs)
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{
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q[0][0]-=rhs.q[0][0];q[0][1]-=rhs.q[0][1];q[0][2]-=rhs.q[0][2]; q[1][0]-=rhs.q[1][0];q[1][1]-=rhs.q[1][1];q[1][2]-=rhs.q[1][2]; q[2][0]-=rhs.q[2][0];q[2][1]-=rhs.q[2][1];q[2][2]-=rhs.q[2][2];
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return *this;
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}
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template<typename T>
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const Mat3<T> Mat3<T>::operator*(const Mat3 &rhs) const
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{
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Mat3<T> r;
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r[0][0]= q[0][0]*rhs.q[0][0] + q[0][1]*rhs.q[1][0] + q[0][2]*rhs.q[2][0];
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r[0][1]= q[0][0]*rhs.q[0][1] + q[0][1]*rhs.q[1][1] + q[0][2]*rhs.q[2][1];
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r[0][2]= q[0][0]*rhs.q[0][2] + q[0][1]*rhs.q[1][2] + q[0][2]*rhs.q[2][2];
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r[1][0]= q[1][0]*rhs.q[0][0] + q[1][1]*rhs.q[1][0] + q[1][2]*rhs.q[2][0];
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r[1][1]= q[1][0]*rhs.q[0][1] + q[1][1]*rhs.q[1][1] + q[1][2]*rhs.q[2][1];
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r[1][2]= q[1][0]*rhs.q[0][2] + q[1][1]*rhs.q[1][2] + q[1][2]*rhs.q[2][2];
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r[2][0]= q[2][0]*rhs.q[0][0] + q[2][1]*rhs.q[1][0] + q[2][2]*rhs.q[2][0];
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r[2][1]= q[2][0]*rhs.q[0][1] + q[2][1]*rhs.q[1][1] + q[2][2]*rhs.q[2][1];
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r[2][2]= q[2][0]*rhs.q[0][2] + q[2][1]*rhs.q[1][2] + q[2][2]*rhs.q[2][2];
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return r;
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}
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template<typename T>
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const Mat3<T> Mat3<T>::Ttimes(const Mat3 &rhs) const
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{
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Mat3<T> r;
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r[0][0]= q[0][0]*rhs.q[0][0] + q[1][0]*rhs.q[1][0] + q[2][0]*rhs.q[2][0];
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r[0][1]= q[0][0]*rhs.q[0][1] + q[1][0]*rhs.q[1][1] + q[2][0]*rhs.q[2][1];
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r[0][2]= q[0][0]*rhs.q[0][2] + q[1][0]*rhs.q[1][2] + q[2][0]*rhs.q[2][2];
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r[1][0]= q[0][1]*rhs.q[0][0] + q[1][1]*rhs.q[1][0] + q[2][1]*rhs.q[2][0];
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r[1][1]= q[0][1]*rhs.q[0][1] + q[1][1]*rhs.q[1][1] + q[2][1]*rhs.q[2][1];
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r[1][2]= q[0][1]*rhs.q[0][2] + q[1][1]*rhs.q[1][2] + q[2][1]*rhs.q[2][2];
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r[2][0]= q[0][2]*rhs.q[0][0] + q[1][2]*rhs.q[1][0] + q[2][2]*rhs.q[2][0];
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r[2][1]= q[0][2]*rhs.q[0][1] + q[1][2]*rhs.q[1][1] + q[2][2]*rhs.q[2][1];
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r[2][2]= q[0][2]*rhs.q[0][2] + q[1][2]*rhs.q[1][2] + q[2][2]*rhs.q[2][2];
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return r;
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}
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template<typename T>
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const Mat3<T> Mat3<T>::timesT(const Mat3 &rhs) const
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{
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Mat3<T> r;
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r[0][0]= q[0][0]*rhs.q[0][0] + q[0][1]*rhs.q[0][1] + q[0][2]*rhs.q[0][2];
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r[0][1]= q[0][0]*rhs.q[1][0] + q[0][1]*rhs.q[1][1] + q[0][2]*rhs.q[1][2];
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r[0][2]= q[0][0]*rhs.q[2][0] + q[0][1]*rhs.q[2][1] + q[0][2]*rhs.q[2][2];
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r[1][0]= q[1][0]*rhs.q[0][0] + q[1][1]*rhs.q[0][1] + q[1][2]*rhs.q[0][2];
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r[1][1]= q[1][0]*rhs.q[1][0] + q[1][1]*rhs.q[1][1] + q[1][2]*rhs.q[1][2];
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r[1][2]= q[1][0]*rhs.q[2][0] + q[1][1]*rhs.q[2][1] + q[1][2]*rhs.q[2][2];
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r[2][0]= q[2][0]*rhs.q[0][0] + q[2][1]*rhs.q[0][1] + q[2][2]*rhs.q[0][2];
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r[2][1]= q[2][0]*rhs.q[1][0] + q[2][1]*rhs.q[1][1] + q[2][2]*rhs.q[1][2];
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r[2][2]= q[2][0]*rhs.q[2][0] + q[2][1]*rhs.q[2][1] + q[2][2]*rhs.q[2][2];
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return r;
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}
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template<typename T>
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const Mat3<T> Mat3<T>::TtimesT(const Mat3 &rhs) const
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{
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Mat3<T> r;
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r[0][0]= q[0][0]*rhs.q[0][0] + q[1][0]*rhs.q[0][1] + q[2][0]*rhs.q[0][2];
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r[0][1]= q[0][0]*rhs.q[1][0] + q[1][0]*rhs.q[1][1] + q[2][0]*rhs.q[1][2];
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r[0][2]= q[0][0]*rhs.q[2][0] + q[1][0]*rhs.q[2][1] + q[2][0]*rhs.q[2][2];
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r[1][0]= q[0][1]*rhs.q[0][0] + q[1][1]*rhs.q[0][1] + q[2][1]*rhs.q[0][2];
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r[1][1]= q[0][1]*rhs.q[1][0] + q[1][1]*rhs.q[1][1] + q[2][1]*rhs.q[1][2];
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r[1][2]= q[0][1]*rhs.q[2][0] + q[1][1]*rhs.q[2][1] + q[2][1]*rhs.q[2][2];
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r[2][0]= q[0][2]*rhs.q[0][0] + q[1][2]*rhs.q[0][1] + q[2][2]*rhs.q[0][2];
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r[2][1]= q[0][2]*rhs.q[1][0] + q[1][2]*rhs.q[1][1] + q[2][2]*rhs.q[1][2];
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r[2][2]= q[0][2]*rhs.q[2][0] + q[1][2]*rhs.q[2][1] + q[2][2]*rhs.q[2][2];
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return r;
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}
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template<typename T>
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T Mat3<T>::determinant() const
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{
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return q[0][0]*(q[2][2]*q[1][1]-q[2][1]*q[1][2])-q[1][0]*(q[2][2]*q[0][1]-q[2][1]*q[0][2])+q[2][0]*(q[1][2]*q[0][1]-q[1][1]*q[0][2]);
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}
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template<typename T>
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void Mat3<T>::transposeme()
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{T t; t=q[0][1]; q[0][1]=q[1][0]; q[1][0]=t; t=q[0][2]; q[0][2]=q[2][0]; q[2][0]=t; t=q[1][2]; q[1][2]=q[2][1]; q[2][1]=t;};
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template<typename T>
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const Mat3<T> Mat3<T>::inverse(T *det) const
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{
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Mat3<T> r;
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r[0][0]= q[2][2]*q[1][1]-q[2][1]*q[1][2];
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r[0][1]= -q[2][2]*q[0][1]+q[2][1]*q[0][2];
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r[0][2]= q[1][2]*q[0][1]-q[1][1]*q[0][2];
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r[1][0]= -q[2][2]*q[1][0]+q[2][0]*q[1][2];
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r[1][1]= q[2][2]*q[0][0]-q[2][0]*q[0][2];
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r[1][2]= -q[1][2]*q[0][0]+q[1][0]*q[0][2];
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r[2][0]= q[2][1]*q[1][0]-q[2][0]*q[1][1];
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r[2][1]= -q[2][1]*q[0][0]+q[2][0]*q[0][1];
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r[2][2]= q[1][1]*q[0][0]-q[1][0]*q[0][1];
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T d=determinant();
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if(det) *det=d;
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return r/d;
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}
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template<typename T>
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const Vec3<T> Mat3<T>::linear_solve(const Vec3<T> &rhs, T *det) const
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{
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Vec3<T> r;
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r[0]= ( q[2][2]*q[1][1]-q[2][1]*q[1][2]) * rhs[0]
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+( -q[2][2]*q[0][1]+q[2][1]*q[0][2]) * rhs[1]
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+( +q[1][2]*q[0][1]-q[1][1]*q[0][2]) * rhs[2];
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r[1]= (-q[2][2]*q[1][0]+q[2][0]*q[1][2]) * rhs[0]
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+( +q[2][2]*q[0][0]-q[2][0]*q[0][2]) * rhs[1]
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+( -q[1][2]*q[0][0]+q[1][0]*q[0][2]) * rhs[2];
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r[2]= ( q[2][1]*q[1][0]-q[2][0]*q[1][1]) * rhs[0]
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+( -q[2][1]*q[0][0]+q[2][0]*q[0][1]) *rhs[1]
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+( q[1][1]*q[0][0]-q[1][0]*q[0][1]) * rhs[2];
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T d=determinant();
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if(det) *det=d;
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return r/d;
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}
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template<typename T>
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const Vec3<T> Mat3<T>::operator*(const Vec3<T> &rhs) const
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{
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Vec3<T> r;
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r[0] = q[0][0]*rhs.q[0] + q[0][1]*rhs.q[1] + q[0][2]*rhs.q[2];
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r[1] = q[1][0]*rhs.q[0] + q[1][1]*rhs.q[1] + q[1][2]*rhs.q[2];
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r[2] = q[2][0]*rhs.q[0] + q[2][1]*rhs.q[1] + q[2][2]*rhs.q[2];
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return r;
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}
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template<typename T>
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const Vec3<T> Mat3<T>::Ttimes(const Vec3<T> &rhs) const
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{
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Vec3<T> r;
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r[0] = q[0][0]*rhs.q[0] + q[1][0]*rhs.q[1] + q[2][0]*rhs.q[2];
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r[1] = q[0][1]*rhs.q[0] + q[1][1]*rhs.q[1] + q[2][1]*rhs.q[2];
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r[2] = q[0][2]*rhs.q[0] + q[1][2]*rhs.q[1] + q[2][2]*rhs.q[2];
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return r;
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}
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//cf. https://en.wikipedia.org/wiki/Euler_angles and NASA paper cited therein
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template<typename T>
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void euler2rotmat(const T *eul, Mat3<T> &a, const char *type, bool transpose, bool direction, bool reverse)
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{
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T c2=cos(eul[1]);
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T s2=sin(eul[1]);
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T c1=cos(eul[reverse?2:0]);
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T s1=sin(eul[reverse?2:0]);
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T c3=cos(eul[reverse?0:2]);
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T s3=sin(eul[reverse?0:2]);
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if(direction) {s1= -s1; s2= -s2; s3= -s3;}
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switch(Euler_case(type[0],type[1],type[2]))
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{
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case Euler_case('x','z','x'):
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{
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a[0][0]= c2;
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a[0][1]= -c3*s2;
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a[0][2]= s2*s3;
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a[1][0]= c1*s2;
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a[1][1]= c1*c2*c3-s1*s3;
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a[1][2]= -c3*s1-c1*c2*s3;
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a[2][0]= s1*s2;
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a[2][1]= c1*s3+c2*c3*s1;
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a[2][2]= c1*c3-c2*s1*s3;
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}
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break;
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case Euler_case('x','y','x'):
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{
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a[0][0]= c2;
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a[0][1]= s2*s3;
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a[0][2]= c3*s2;
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a[1][0]= s1*s2;
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a[1][1]= c1*c3-c2*s1*s3;
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a[1][2]= -c1*s3-c2*c3*s1;
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a[2][0]= -c1*s2;
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a[2][1]= c3*s1+c1*c2*s3;
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a[2][2]= c1*c2*c3-s1*s3;
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}
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break;
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case Euler_case('y','x','y'):
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{
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a[0][0]= c1*c3-c2*s1*s3;
|
|
a[0][1]= s1*s2;
|
|
a[0][2]= c1*s3+c2*c3*s1;
|
|
a[1][0]= s2*s3;
|
|
a[1][1]= c2;
|
|
a[1][2]= -c3*s2;
|
|
a[2][0]= -c3*s1-c1*c2*s3;
|
|
a[2][1]= c1*s2;
|
|
a[2][2]= c1*c2*c3-s1*s3;
|
|
}
|
|
break;
|
|
|
|
case Euler_case('y','z','y'):
|
|
{
|
|
a[0][0]= c1*c2*c3-s1*s3;
|
|
a[0][1]= -c1*s2;
|
|
a[0][2]= c3*s1+c1*c2*s3;
|
|
a[1][0]= c3*s2;
|
|
a[1][1]= c2;
|
|
a[1][2]= s2*s3;
|
|
a[2][0]= -c1*s3;
|
|
a[2][1]= s1*s2;
|
|
a[2][2]= c1*c3-c2*s1*s3;
|
|
}
|
|
break;
|
|
|
|
case Euler_case('z','y','z'):
|
|
{
|
|
a[0][0]= c1*c2*c3-s1*s3;
|
|
a[0][1]= -c3*s1-c1*c2*s3;
|
|
a[0][2]= c1*s2;
|
|
a[1][0]= c1*s3+c2*c3*s1;
|
|
a[1][1]= c1*c3-c2*s1*s3;
|
|
a[1][2]= s1*s2;
|
|
a[2][0]= -c3*s2;
|
|
a[2][1]= s2*s3;
|
|
a[2][2]= c2;
|
|
}
|
|
break;
|
|
|
|
case Euler_case('z','x','z'):
|
|
{
|
|
a[0][0]= c1*c3-c2*s1*s3;
|
|
a[0][1]= -c1*s3-c2*c3*s1;
|
|
a[0][2]= s1*s2;
|
|
a[1][0]= c3*s1+c1*c2*s3;
|
|
a[1][1]= c1*c2*c3-s1*s3;
|
|
a[1][2]= -c1*s2;
|
|
a[2][0]= s2*s3;
|
|
a[2][1]= c3*s2;
|
|
a[2][2]= c2;
|
|
}
|
|
break;
|
|
|
|
case Euler_case('x','z','y'):
|
|
{
|
|
a[0][0]= c2*c3;
|
|
a[0][1]= -s2;
|
|
a[0][2]= c2*s3;
|
|
a[1][0]= s1*s3+c1*c3*s2;
|
|
a[1][1]= c1*c2;
|
|
a[1][2]= c1*s2*s3-c3*s1;
|
|
a[2][0]= c3*s1*s2-c1*s3;
|
|
a[2][1]= c2*s1;
|
|
a[2][2]= c1*c3+s1*s2*s3;
|
|
}
|
|
break;
|
|
|
|
case Euler_case('x','y','z'):
|
|
{
|
|
a[0][0]= c2*c3;
|
|
a[0][1]= -c2*s3;
|
|
a[0][2]= s2;
|
|
a[1][0]= c1*s3+c3*s1*s2;
|
|
a[1][1]= c1*c3-s1*s2*s3;
|
|
a[1][2]= -c2*s1;
|
|
a[2][0]= s1*s3-c1*c3*s2;
|
|
a[2][1]= c3*s1+c1*s2*s3;
|
|
a[2][2]= c1*c2;
|
|
}
|
|
break;
|
|
|
|
case Euler_case('y','x','z'):
|
|
{
|
|
a[0][0]= c1*c3+s1*s2*s3;
|
|
a[0][1]= c3*s1*s2-c1*s3;
|
|
a[0][2]= c2*s1;
|
|
a[1][0]= c2*s3;
|
|
a[1][1]= c2*c3;
|
|
a[1][2]= -s2;
|
|
a[2][0]= c1*s2*s3-c3*s1;
|
|
a[2][1]= c1*c3*s2+s1*s3;
|
|
a[2][2]= c1*c2;
|
|
}
|
|
break;
|
|
|
|
case Euler_case('y','z','x'):
|
|
{
|
|
a[0][0]= c1*c2;
|
|
a[0][1]= s1*s3-c1*c3*s2;
|
|
a[0][2]= c3*s1+c1*s2*s3;
|
|
a[1][0]= s2;
|
|
a[1][1]= c2*c3;
|
|
a[1][2]= -c2*s3;
|
|
a[2][0]= -c2*s1;
|
|
a[2][1]= c1*s3+c3*s1*s2;
|
|
a[2][2]= c1*c3-s1*s2*s3;
|
|
}
|
|
break;
|
|
|
|
case Euler_case('z','y','x'):
|
|
{
|
|
a[0][0]= c1*c2;
|
|
a[0][1]= c1*s2*s3-c3*s1;
|
|
a[0][2]= s1*s2+c1*c3*s2;
|
|
a[1][0]= c2*s1;
|
|
a[1][1]= c1*c3+s1*s2*s3;
|
|
a[1][2]= c3*s1*s2-c1*s3;
|
|
a[2][0]= -s2;
|
|
a[2][1]= c2*s3;
|
|
a[2][2]= c2*c3;
|
|
}
|
|
break;
|
|
|
|
case Euler_case('z','x','y'):
|
|
{
|
|
a[0][0]= c1*c3-s1*s2*s3;
|
|
a[0][1]= -c2*s1;
|
|
a[0][2]= c1*s3+c3*s1*s2;
|
|
a[1][0]= c3*s1+c1*s2*s3;
|
|
a[1][1]= c1*c2;
|
|
a[1][2]= s1*s3-c1*c3*s2;
|
|
a[2][0]= -c2*s3;
|
|
a[2][1]= s2;
|
|
a[2][2]= c2*c3;
|
|
}
|
|
break;
|
|
}//switch
|
|
|
|
if(transpose) a.transposeme();
|
|
}
|
|
|
|
|
|
template<typename T>
|
|
void rotmat2euler(T *eul, const Mat3<T> &a, const char *type, bool transpose, bool direction, bool reverse)
|
|
{
|
|
T m11=a[0][0];
|
|
T m22=a[1][1];
|
|
T m33=a[2][2];
|
|
T m12=transpose?a[1][0]:a[0][1];
|
|
T m21=transpose?a[0][1]:a[1][0];
|
|
T m13=transpose?a[2][0]:a[0][2];
|
|
T m31=transpose?a[0][2]:a[2][0];
|
|
T m23=transpose?a[2][1]:a[1][2];
|
|
T m32=transpose?a[1][2]:a[2][1];
|
|
|
|
switch(Euler_case(type[0],type[1],type[2]))
|
|
{
|
|
|
|
case Euler_case('x','z','x'):
|
|
{
|
|
eul[0]=atan2(m31,m21);
|
|
eul[1]=atan2(sqrt(1-m11*m11),m11);
|
|
eul[2]=atan2(m13,-m12);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('x','y','x'):
|
|
{
|
|
eul[0]=atan2(m21,-m31);
|
|
eul[1]=atan2(sqrt(1-m11*m11),m11);
|
|
eul[2]=atan2(m12,m13);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('y','x','y'):
|
|
{
|
|
eul[0]=atan2(m12,m32);
|
|
eul[1]=atan2(sqrt(1-m22*m22),m22);
|
|
eul[2]=atan2(m21,-m23);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('y','z','y'):
|
|
{
|
|
eul[0]=atan2(m32,-m12);
|
|
eul[1]=atan2(sqrt(1-m22*m22),m22);
|
|
eul[2]=atan2(m23,m21);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('z','y','z'):
|
|
{
|
|
eul[0]=atan2(m23,m13);
|
|
eul[1]=atan2(sqrt(1-m33*m33),m33);
|
|
eul[2]=atan2(m32,-m31);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('z','x','z'):
|
|
{
|
|
eul[0]=atan2(m13,-m23);
|
|
eul[1]=atan2(sqrt(1-m33*m33),m33);
|
|
eul[2]=atan2(m31,m32);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('x','z','y'):
|
|
{
|
|
eul[0]=atan2(m32,m22);
|
|
eul[1]=atan2(-m12,sqrt(1-m12*m12));
|
|
eul[2]=atan2(m13,m11);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('x','y','z'):
|
|
{
|
|
eul[0]=atan2(-m23,m33);
|
|
eul[1]=atan2(m13,sqrt(1-m13*m13));
|
|
eul[2]=atan2(-m12,m11);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('y','x','z'):
|
|
{
|
|
eul[0]=atan2(m31,m33);
|
|
eul[1]=atan2(-m23,sqrt(1-m23*m23));
|
|
eul[2]=atan2(m21,m22);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('y','z','x'):
|
|
{
|
|
eul[0]=atan2(-m31,m11);
|
|
eul[1]=atan2(m21,sqrt(1-m21*m21));
|
|
eul[2]=atan2(-m23,m22);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('z','y','x'):
|
|
{
|
|
eul[0]=atan2(m21,m11);
|
|
eul[1]=atan2(-m31,sqrt(1-m31*m31));
|
|
eul[2]=atan2(m32,m33);
|
|
}
|
|
break;
|
|
|
|
case Euler_case('z','x','y'):
|
|
{
|
|
eul[0]=atan2(-m12,m22);
|
|
eul[1]=atan2(m32,sqrt(1-m32*m32));
|
|
eul[2]=atan2(-m31,m33);
|
|
}
|
|
break;
|
|
|
|
}//switch
|
|
|
|
if(reverse)
|
|
{
|
|
T t=eul[0]; eul[0]=eul[2]; eul[2]=t;
|
|
}
|
|
if(direction)
|
|
{
|
|
eul[0] *= (T)-1;
|
|
eul[1] *= (T)-1;
|
|
eul[2] *= (T)-1;
|
|
}
|
|
}
|
|
|
|
|
|
//stream I/O
|
|
#ifndef AVOID_STDSTREAM
|
|
template <typename T>
|
|
std::istream& operator>>(std::istream &s, Vec3<T> &x)
|
|
{
|
|
s >> x.q[0];
|
|
s >> x.q[1];
|
|
s >> x.q[2];
|
|
return s;
|
|
}
|
|
|
|
template <typename T>
|
|
std::ostream& operator<<(std::ostream &s, const Vec3<T> &x) {
|
|
s << x.q[0]<<" ";
|
|
s << x.q[1]<<" ";
|
|
s << x.q[2];
|
|
return s;
|
|
}
|
|
|
|
template <typename T>
|
|
std::istream& operator>>(std::istream &s, Mat3<T> &x)
|
|
{
|
|
s >> x.q[0][0];
|
|
s >> x.q[0][1];
|
|
s >> x.q[0][2];
|
|
s >> x.q[1][0];
|
|
s >> x.q[1][1];
|
|
s >> x.q[1][2];
|
|
s >> x.q[2][0];
|
|
s >> x.q[2][1];
|
|
s >> x.q[2][2];
|
|
return s;
|
|
}
|
|
|
|
template <typename T>
|
|
std::ostream& operator<<(std::ostream &s, const Mat3<T> &x) {
|
|
s << x.q[0][0]<<" "<< x.q[0][1]<<" " << x.q[0][2]<<std::endl;
|
|
s << x.q[1][0]<<" "<< x.q[1][1]<<" " << x.q[1][2]<<std::endl;
|
|
s << x.q[2][0]<<" "<< x.q[2][1]<<" " << x.q[2][2]<<std::endl;
|
|
return s;
|
|
}
|
|
#endif
|
|
|
|
|
|
template <typename T>
|
|
void Mat3<T>::symmetrize()
|
|
{
|
|
T tmp=(q[0][1]+q[1][0])/2;
|
|
q[0][1]=q[1][0]=tmp;
|
|
tmp=(q[0][2]+q[2][0])/2;
|
|
q[0][2]=q[2][0]=tmp;
|
|
tmp=(q[2][1]+q[1][2])/2;
|
|
q[2][1]=q[1][2]=tmp;
|
|
}
|
|
|
|
|
|
#ifndef QUAT_NO_RANDOM
|
|
template <>
|
|
void Vec3<double>::randomize(const double x)
|
|
{
|
|
for(int i=0;i<3;++i) q[i]=x*RANDDOUBLESIGNED();
|
|
}
|
|
|
|
|
|
template <>
|
|
void Mat3<double>::randomize(const double x, const bool symmetric)
|
|
{
|
|
if(symmetric) for(int i=0;i<3;++i) for(int j=0; j<=i; ++j) q[j][i]=q[i][j]=x*RANDDOUBLESIGNED();
|
|
else for(int i=0;i<3;++i) for(int j=0; j<3; ++j) q[i][j]=x*RANDDOUBLESIGNED();
|
|
}
|
|
|
|
#endif
|
|
|
|
//eigensolver for 3x3 matrix by Joachim Kopp - analytic formula version,
|
|
//might be unstable for ill-conditioned ones, then use other methods
|
|
//cf. arxiv physics 0610206v3
|
|
//
|
|
//// Numerical diagonalization of 3x3 matrcies
|
|
//// Copyright (C) 2006 Joachim Kopp
|
|
//// ----------------------------------------------------------------------------
|
|
//// This library is free software; you can redistribute it and/or
|
|
//// modify it under the terms of the GNU Lesser General Public
|
|
//// License as published by the Free Software Foundation; either
|
|
//// version 2.1 of the License, or (at your option) any later version.
|
|
////
|
|
//// This library is distributed in the hope that it will be useful,
|
|
//// but WITHOUT ANY WARRANTY; without even the implied warranty of
|
|
//// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
|
|
//// Lesser General Public License for more details.
|
|
////
|
|
//// You should have received a copy of the GNU Lesser General Public
|
|
//// License along with this library; if not, write to the Free Software
|
|
//// Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
|
|
//// ----------------------------------------------------------------------------
|
|
//
|
|
|
|
//numeric_limits not available on some crosscompilers for small MCUs
|
|
#ifdef QUAT_NO_DOUBLE
|
|
#define NO_NUMERIC_LIMITS
|
|
#endif
|
|
|
|
#define M_SQRT3 1.73205080756887729352744634151 // sqrt(3)
|
|
#define SQR(x) ((x)*(x)) // x^2
|
|
//
|
|
template <typename T>
|
|
void Mat3<T>::eival_sym(Vec3<T> &w, const bool sortdown) const
|
|
{
|
|
T m, c1, c0;
|
|
|
|
// Determine coefficients of characteristic poynomial. We write
|
|
// | a d f |
|
|
// A = | d* b e |
|
|
// | f* e* c |
|
|
T de = q[0][1] * q[1][2]; // d * e
|
|
T dd = SQR(q[0][1]); // d^2
|
|
T ee = SQR(q[1][2]); // e^2
|
|
T ff = SQR(q[0][2]); // f^2
|
|
m = q[0][0] + q[1][1] + q[2][2];
|
|
c1 = (q[0][0]*q[1][1] + q[0][0]*q[2][2] + q[1][1]*q[2][2]) // a*b + a*c + b*c - d^2 - e^2 - f^2
|
|
- (dd + ee + ff);
|
|
c0 = q[2][2]*dd + q[0][0]*ee + q[1][1]*ff - q[0][0]*q[1][1]*q[2][2]
|
|
- 2.0 * q[0][2]*de; // c*d^2 + a*e^2 + b*f^2 - a*b*c - 2*f*d*e)
|
|
|
|
T p, sqrt_p, q, c, s, phi;
|
|
p = SQR(m) - 3.0*c1;
|
|
q = m*(p - (3.0/2.0)*c1) - (27.0/2.0)*c0;
|
|
sqrt_p = sqrt(abs(p));
|
|
|
|
phi = 27.0 * ( 0.25*SQR(c1)*(p - c1) + c0*(q + 27.0/4.0*c0));
|
|
phi = (1.0/3.0) * atan2(sqrt(abs(phi)), q);
|
|
|
|
c = sqrt_p*cos(phi);
|
|
s = (1.0/M_SQRT3)*sqrt_p*sin(phi);
|
|
|
|
w[1] = (1.0/3.0)*(m - c);
|
|
w[2] = w[1] + s;
|
|
w[0] = w[1] + c;
|
|
w[1] -= s;
|
|
|
|
if(sortdown)
|
|
{
|
|
if(w[0]<w[1]) {T tmp=w[0]; w[0]=w[1]; w[1]=tmp;}
|
|
if(w[0]<w[2]) {T tmp=w[0]; w[0]=w[2]; w[2]=tmp;}
|
|
if(w[1]<w[2]) {T tmp=w[1]; w[1]=w[2]; w[2]=tmp;}
|
|
}
|
|
else
|
|
//sort in ascending order
|
|
{
|
|
if(w[0]>w[1]) {T tmp=w[0]; w[0]=w[1]; w[1]=tmp;}
|
|
if(w[0]>w[2]) {T tmp=w[0]; w[0]=w[2]; w[2]=tmp;}
|
|
if(w[1]>w[2]) {T tmp=w[1]; w[1]=w[2]; w[2]=tmp;}
|
|
}
|
|
}
|
|
|
|
// Calculates the eigenvalues and normalized eigenvectors of a symmetric 3x3
|
|
// matrix A using Cardano's method for the eigenvalues and an analytical
|
|
// method based on vector cross products for the eigenvectors.
|
|
// Only the diagonal and upper triangular parts of A need to contain meaningful
|
|
// values. However, all of A may be used as temporary storage and may hence be
|
|
// destroyed.
|
|
// ----------------------------------------------------------------------------
|
|
// Parameters:
|
|
// A: The symmetric input matrix
|
|
// Q: Storage buffer for eigenvectors
|
|
// w: Storage buffer for eigenvalues
|
|
// ----------------------------------------------------------------------------
|
|
// Return value:
|
|
// 0: Success
|
|
// -1: Error
|
|
// ----------------------------------------------------------------------------
|
|
// Dependencies:
|
|
// dsyevc3()
|
|
// ----------------------------------------------------------------------------
|
|
// Version history:
|
|
// v1.1 (12 Mar 2012): Removed access to lower triangualr part of A
|
|
// (according to the documentation, only the upper triangular part needs
|
|
// to be filled)
|
|
// v1.0: First released version
|
|
// ----------------------------------------------------------------------------
|
|
template <typename T>
|
|
void Mat3<T>::eivec_sym(Vec3<T> &w, Mat3 &v, const bool sortdown) const
|
|
{
|
|
T norm; // Squared norm or inverse norm of current eigenvector
|
|
T n0, n1; // Norm of first and second columns of A
|
|
T n0tmp, n1tmp; // "Templates" for the calculation of n0/n1 - saves a few FLOPS
|
|
T thresh; // Small number used as threshold for floating point comparisons
|
|
T error; // Estimated maximum roundoff error in some steps
|
|
T wmax; // The eigenvalue of maximum modulus
|
|
T f, t; // Intermediate storage
|
|
int i, j; // Loop counters
|
|
|
|
// Calculate eigenvalues
|
|
eival_sym(w,sortdown);
|
|
Mat3<T> A(*this); //scratch copy
|
|
|
|
wmax = fabs(w[0]);
|
|
if ((t=fabs(w[1])) > wmax)
|
|
wmax = t;
|
|
if ((t=fabs(w[2])) > wmax)
|
|
wmax = t;
|
|
thresh = SQR(8.0 * DBL_EPSILON * wmax);
|
|
|
|
// Prepare calculation of eigenvectors
|
|
n0tmp = SQR(A[0][1]) + SQR(A[0][2]);
|
|
n1tmp = SQR(A[0][1]) + SQR(A[1][2]);
|
|
v[0][1] = A[0][1]*A[1][2] - A[0][2]*A[1][1];
|
|
v[1][1] = A[0][2]*A[0][1] - A[1][2]*A[0][0];
|
|
v[2][1] = SQR(A[0][1]);
|
|
|
|
// Calculate first eigenvector by the formula
|
|
// v[0] = (A - w[0]).e1 x (A - w[0]).e2
|
|
A[0][0] -= w[0];
|
|
A[1][1] -= w[0];
|
|
v[0][0] = v[0][1] + A[0][2]*w[0];
|
|
v[1][0] = v[1][1] + A[1][2]*w[0];
|
|
v[2][0] = A[0][0]*A[1][1] - v[2][1];
|
|
norm = SQR(v[0][0]) + SQR(v[1][0]) + SQR(v[2][0]);
|
|
n0 = n0tmp + SQR(A[0][0]);
|
|
n1 = n1tmp + SQR(A[1][1]);
|
|
error = n0 * n1;
|
|
|
|
if (n0 <= thresh) // If the first column is zero, then (1,0,0) is an eigenvector
|
|
{
|
|
v[0][0] = 1.0;
|
|
v[1][0] = 0.0;
|
|
v[2][0] = 0.0;
|
|
}
|
|
else if (n1 <= thresh) // If the second column is zero, then (0,1,0) is an eigenvector
|
|
{
|
|
v[0][0] = 0.0;
|
|
v[1][0] = 1.0;
|
|
v[2][0] = 0.0;
|
|
}
|
|
else if (norm < SQR(64.0 * DBL_EPSILON) * error)
|
|
{ // If angle between A[0] and A[1] is too small, don't use
|
|
t = SQR(A[0][1]); // cross product, but calculate v ~ (1, -A0/A1, 0)
|
|
f = -A[0][0] / A[0][1];
|
|
if (SQR(A[1][1]) > t)
|
|
{
|
|
t = SQR(A[1][1]);
|
|
f = -A[0][1] / A[1][1];
|
|
}
|
|
if (SQR(A[1][2]) > t)
|
|
f = -A[0][2] / A[1][2];
|
|
norm = 1.0/sqrt(1 + SQR(f));
|
|
v[0][0] = norm;
|
|
v[1][0] = f * norm;
|
|
v[2][0] = 0.0;
|
|
}
|
|
else // This is the standard branch
|
|
{
|
|
norm = sqrt(1.0 / norm);
|
|
for (j=0; j < 3; j++)
|
|
v[j][0] = v[j][0] * norm;
|
|
}
|
|
|
|
|
|
// Prepare calculation of second eigenvector
|
|
t = w[0] - w[1];
|
|
if (fabs(t) > 8.0 * DBL_EPSILON * wmax)
|
|
{
|
|
// For non-degenerate eigenvalue, calculate second eigenvector by the formula
|
|
// v[1] = (A - w[1]).e1 x (A - w[1]).e2
|
|
A[0][0] += t;
|
|
A[1][1] += t;
|
|
v[0][1] = v[0][1] + A[0][2]*w[1];
|
|
v[1][1] = v[1][1] + A[1][2]*w[1];
|
|
v[2][1] = A[0][0]*A[1][1] - v[2][1];
|
|
norm = SQR(v[0][1]) + SQR(v[1][1]) + SQR(v[2][1]);
|
|
n0 = n0tmp + SQR(A[0][0]);
|
|
n1 = n1tmp + SQR(A[1][1]);
|
|
error = n0 * n1;
|
|
|
|
if (n0 <= thresh) // If the first column is zero, then (1,0,0) is an eigenvector
|
|
{
|
|
v[0][1] = 1.0;
|
|
v[1][1] = 0.0;
|
|
v[2][1] = 0.0;
|
|
}
|
|
else if (n1 <= thresh) // If the second column is zero, then (0,1,0) is an eigenvector
|
|
{
|
|
v[0][1] = 0.0;
|
|
v[1][1] = 1.0;
|
|
v[2][1] = 0.0;
|
|
}
|
|
else if (norm < SQR(64.0 * DBL_EPSILON) * error)
|
|
{ // If angle between A[0] and A[1] is too small, don't use
|
|
t = SQR(A[0][1]); // cross product, but calculate v ~ (1, -A0/A1, 0)
|
|
f = -A[0][0] / A[0][1];
|
|
if (SQR(A[1][1]) > t)
|
|
{
|
|
t = SQR(A[1][1]);
|
|
f = -A[0][1] / A[1][1];
|
|
}
|
|
if (SQR(A[1][2]) > t)
|
|
f = -A[0][2] / A[1][2];
|
|
norm = 1.0/sqrt(1 + SQR(f));
|
|
v[0][1] = norm;
|
|
v[1][1] = f * norm;
|
|
v[2][1] = 0.0;
|
|
}
|
|
else
|
|
{
|
|
norm = sqrt(1.0 / norm);
|
|
for (j=0; j < 3; j++)
|
|
v[j][1] = v[j][1] * norm;
|
|
}
|
|
}
|
|
else
|
|
{
|
|
// For degenerate eigenvalue, calculate second eigenvector according to
|
|
// v[1] = v[0] x (A - w[1]).e[i]
|
|
//
|
|
// This would really get to complicated if we could not assume all of A to
|
|
// contain meaningful values.
|
|
A[1][0] = A[0][1];
|
|
A[2][0] = A[0][2];
|
|
A[2][1] = A[1][2];
|
|
A[0][0] += w[0];
|
|
A[1][1] += w[0];
|
|
for (i=0; i < 3; i++)
|
|
{
|
|
A[i][i] -= w[1];
|
|
n0 = SQR(A[0][i]) + SQR(A[1][i]) + SQR(A[2][i]);
|
|
if (n0 > thresh)
|
|
{
|
|
v[0][1] = v[1][0]*A[2][i] - v[2][0]*A[1][i];
|
|
v[1][1] = v[2][0]*A[0][i] - v[0][0]*A[2][i];
|
|
v[2][1] = v[0][0]*A[1][i] - v[1][0]*A[0][i];
|
|
norm = SQR(v[0][1]) + SQR(v[1][1]) + SQR(v[2][1]);
|
|
if (norm > SQR(256.0 * DBL_EPSILON) * n0) // Accept cross product only if the angle between
|
|
{ // the two vectors was not too small
|
|
norm = sqrt(1.0 / norm);
|
|
for (j=0; j < 3; j++)
|
|
v[j][1] = v[j][1] * norm;
|
|
break;
|
|
}
|
|
}
|
|
}
|
|
|
|
if (i == 3) // This means that any vector orthogonal to v[0] is an EV.
|
|
{
|
|
for (j=0; j < 3; j++)
|
|
if (v[j][0] != 0.0) // Find nonzero element of v[0] ...
|
|
{ // ... and swap it with the next one
|
|
norm = 1.0 / sqrt(SQR(v[j][0]) + SQR(v[(j+1)%3][0]));
|
|
v[j][1] = v[(j+1)%3][0] * norm;
|
|
v[(j+1)%3][1] = -v[j][0] * norm;
|
|
v[(j+2)%3][1] = 0.0;
|
|
break;
|
|
}
|
|
}
|
|
}
|
|
|
|
|
|
// Calculate third eigenvector according to
|
|
// v[2] = v[0] x v[1]
|
|
v[0][2] = v[1][0]*v[2][1] - v[2][0]*v[1][1];
|
|
v[1][2] = v[2][0]*v[0][1] - v[0][0]*v[2][1];
|
|
v[2][2] = v[0][0]*v[1][1] - v[1][0]*v[0][1];
|
|
|
|
}
|
|
|
|
#undef SQR
|
|
//end eigensolver for 3x3 matrix
|
|
/////////////////////////////////////////////////////////////////////////////////////////////
|
|
|
|
template<typename T>
|
|
T Mat3<T>::norm(const T scalar) const
|
|
{
|
|
T sum(0);
|
|
for(int i=0; i<3; i++)
|
|
for(int j=0; j<3; j++) {
|
|
T tmp = q[i][j];
|
|
if(i == j) tmp -= scalar;
|
|
sum += tmp*tmp;
|
|
}
|
|
return sqrt(sum);
|
|
}
|
|
|
|
//efficient SVD for 3x3 matrices cf. Mc.Adams et al. UWM technical report 1690 (2011)
|
|
//
|
|
|
|
|
|
template<typename T>
|
|
static inline T ABS(const T a)
|
|
{
|
|
return a<0?-a:a;
|
|
}
|
|
|
|
template<typename T>
|
|
static inline T MAX(const T a, const T b)
|
|
{
|
|
return a>b ? a : b;
|
|
}
|
|
|
|
|
|
|
|
template<typename T>
|
|
void QRGivensQuaternion(T a1, T a2, T &ch, T &sh)
|
|
{
|
|
// a1 = pivot point on diagonal
|
|
// a2 = lower triangular entry we want to annihilate
|
|
T rho = sqrt(a1*a1 + a2*a2);
|
|
|
|
sh = rho > DBL_EPSILON ? a2 : 0;
|
|
ch = ABS(a1) + MAX(rho,DBL_EPSILON);
|
|
if(a1 < 0)
|
|
{
|
|
T tmp=sh;
|
|
sh=ch;
|
|
ch=tmp;
|
|
}
|
|
T w = (T)1/sqrt(ch*ch+sh*sh);
|
|
ch *= w;
|
|
sh *= w;
|
|
}
|
|
|
|
|
|
template<typename T>
|
|
void Mat3<T>::qrd(Mat3 &Q, Mat3 &R)
|
|
{
|
|
|
|
T ch1,sh1,ch2,sh2,ch3,sh3;
|
|
T a,b;
|
|
|
|
// first givens rotation (ch,0,0,sh)
|
|
QRGivensQuaternion(q[0][0],q[1][0],ch1,sh1);
|
|
a=1-2*sh1*sh1;
|
|
b=2*ch1*sh1;
|
|
// apply B = Q' * B
|
|
R[0][0]= a*q[0][0]+b*q[1][0]; R[0][1]= a*q[0][1]+b*q[1][1]; R[0][2]= a*q[0][2]+b*q[1][2];
|
|
R[1][0]= -b*q[0][0]+a*q[1][0]; R[1][1]= -b*q[0][1]+a*q[1][1]; R[1][2]= -b*q[0][2]+a*q[1][2];
|
|
R[2][0]= q[2][0]; R[2][1]= q[2][1]; R[2][2]= q[2][2];
|
|
|
|
// second givens rotation (ch,0,-sh,0)
|
|
QRGivensQuaternion(R[0][0],R[2][0],ch2,sh2);
|
|
a= 1-2*sh2*sh2;
|
|
b= 2*ch2*sh2;
|
|
// apply B = Q' * B;
|
|
q[0][0]= a*R[0][0]+b*R[2][0]; q[0][1]= a*R[0][1]+b*R[2][1]; q[0][2]= a*R[0][2]+b*R[2][2];
|
|
q[1][0]= R[1][0]; q[1][1]= R[1][1]; q[1][2]= R[1][2];
|
|
q[2][0]= -b*R[0][0]+a*R[2][0]; q[2][1]= -b*R[0][1]+a*R[2][1]; q[2][2]= -b*R[0][2]+a*R[2][2];
|
|
|
|
// third givens rotation (ch,sh,0,0)
|
|
QRGivensQuaternion(q[1][1],q[2][1],ch3,sh3);
|
|
a= 1-2*sh3*sh3;
|
|
b= 2*ch3*sh3;
|
|
// R is now set to desired value
|
|
R[0][0]= q[0][0]; R[0][1]= q[0][1]; R[0][2]= q[0][2];
|
|
R[1][0]= a*q[1][0]+b*q[2][0]; R[1][1]= a*q[1][1]+b*q[2][1]; R[1][2]= a*q[1][2]+b*q[2][2];
|
|
R[2][0]= -b*q[1][0]+a*q[2][0]; R[2][1]= -b*q[1][1]+a*q[2][1]; R[2][2]= -b*q[1][2]+a*q[2][2];
|
|
|
|
// construct the cumulative rotation Q=Q1 * Q2 * Q3
|
|
// the number of floating point operations for three quaternion multiplications
|
|
// is more or less comparable to the explicit form of the joined matrix.
|
|
// certainly more memory-efficient!
|
|
T sh12= sh1*sh1;
|
|
T sh22= sh2*sh2;
|
|
T sh32= sh3*sh3;
|
|
|
|
Q[0][0]= (-1+2*sh12)*(-1+2*sh22);
|
|
Q[0][1]= 4*ch2*ch3*(-1+2*sh12)*sh2*sh3+2*ch1*sh1*(-1+2*sh32);
|
|
Q[0][2]= 4*ch1*ch3*sh1*sh3-2*ch2*(-1+2*sh12)*sh2*(-1+2*sh32);
|
|
|
|
Q[1][0]= 2*ch1*sh1*(1-2*sh22);
|
|
Q[1][1]= -8*ch1*ch2*ch3*sh1*sh2*sh3+(-1+2*sh12)*(-1+2*sh32);
|
|
Q[1][2]= -2*ch3*sh3+4*sh1*(ch3*sh1*sh3+ch1*ch2*sh2*(-1+2*sh32));
|
|
|
|
Q[2][0]= 2*ch2*sh2;
|
|
Q[2][1]= 2*ch3*(1-2*sh22)*sh3;
|
|
Q[2][2]= (-1+2*sh22)*(-1+2*sh32);
|
|
}
|
|
|
|
|
|
template<typename T>
|
|
void Mat3<T>::svd(Mat3 &u, Vec3<T> &w, Mat3 &v, bool proper_rotations) const
|
|
{
|
|
Mat3 ata= this->Ttimes(*this);
|
|
Vec3<T> ww; //actually not needed squares of singular values
|
|
ata.eivec_sym(ww,v,true);
|
|
Mat3 uw = (*this)*v;
|
|
Mat3 r;
|
|
uw.qrd(u,r);
|
|
w[0]= r[0][0];
|
|
w[1]= r[1][1];
|
|
w[2]= r[2][2];
|
|
|
|
if(proper_rotations) return;
|
|
if(w[2]<0)
|
|
{
|
|
w[2] = -w[2];
|
|
u[0][2] = -u[0][2];
|
|
u[1][2] = -u[1][2];
|
|
u[2][2] = -u[2][2];
|
|
}
|
|
}
|
|
|
|
|
|
template<typename T>
|
|
void Mat3<T>::diagmultl(const Vec3<T> &rhs)
|
|
{
|
|
for(int i=0; i<3; ++i) for(int j=0; j<3; ++j) q[i][j] *= rhs[i];
|
|
}
|
|
|
|
template<typename T>
|
|
void Mat3<T>::diagmultr(const Vec3<T> &rhs)
|
|
{
|
|
for(int i=0; i<3; ++i) for(int j=0; j<3; ++j) q[i][j] *= rhs[j];
|
|
}
|
|
|
|
|
|
template<typename T>
|
|
const Mat3<T> Mat3<T>::svdinverse(const T thr) const
|
|
{
|
|
Mat3 u,v;
|
|
Vec3<T> w;
|
|
svd(u,w,v);
|
|
for(int i=0; i<3; ++i) w[i] = (w[i]<thr)? 0 : 1/w[i];
|
|
v.diagmultr(w);
|
|
return v.timesT(u);
|
|
}
|
|
|
|
|
|
//cf. https://en.wikipedia.org/wiki/3D_projection
|
|
template<typename T>
|
|
void perspective(T *proj_xy, const Vec3<T> &point, const Mat3<T> &rot_angle, const Vec3<T> &camera, const Vec3<T> &plane_to_camera)
|
|
{
|
|
Vec3<T> d=rot_angle*point-camera;
|
|
T scale = plane_to_camera[2]/d[2];
|
|
for(int i=0; i<2; ++i) proj_xy[i]= scale*d[i] + plane_to_camera[i];
|
|
}
|
|
|
|
|
|
//force instantization
|
|
#define INSTANTIZE(T) \
|
|
template class Vec3<T>; \
|
|
template class Mat3<T>; \
|
|
template void euler2rotmat(const T *eul, Mat3<T> &a, const char *type, bool transpose=0, bool direction=0, bool reverse=0); \
|
|
template void rotmat2euler(T *eul, const Mat3<T> &a, const char *type, bool transpose=0, bool direction=0, bool reverse=0); \
|
|
template void perspective(T *proj_xy, const Vec3<T> &point, const Mat3<T> &rot_angle, const Vec3<T> &camera, const Vec3<T> &plane_to_camera); \
|
|
|
|
|
|
#ifndef AVOID_STDSTREAM
|
|
#define INSTANTIZE2(T) \
|
|
template std::istream& operator>>(std::istream &s, Vec3<T> &x); \
|
|
template std::ostream& operator<<(std::ostream &s, const Vec3<T> &x); \
|
|
template std::istream& operator>>(std::istream &s, Mat3<T> &x); \
|
|
template std::ostream& operator<<(std::ostream &s, const Mat3<T> &x); \
|
|
|
|
#endif
|
|
|
|
|
|
|
|
INSTANTIZE(float)
|
|
#ifndef QUAT_NO_DOUBLE
|
|
INSTANTIZE(double)
|
|
#endif
|
|
|
|
#ifndef AVOID_STDSTREAM
|
|
INSTANTIZE2(float)
|
|
#ifndef QUAT_NO_DOUBLE
|
|
INSTANTIZE2(double)
|
|
#endif
|
|
#endif
|
|
|
|
}//namespace
|