#ifndef Magnum_Math_DualQuaternion_h #define Magnum_Math_DualQuaternion_h /* Copyright © 2010, 2011, 2012 Vladimír Vondruš This file is part of Magnum. Magnum is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License version 3 only, as published by the Free Software Foundation. Magnum 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 version 3 for more details. */ /** @file * @brief Class Magnum::Math::DualQuaternion */ #include "Math/Dual.h" #include "Math/Matrix4.h" #include "Math/Quaternion.h" namespace Magnum { namespace Math { /** @brief %Dual quaternion @see Dual, Quaternion */ template class DualQuaternion: public Dual> { public: /** * @brief Rotation dual quaternion * @param angle Rotation angle (counterclockwise, in radians) * @param normalizedAxis Normalized rotation axis * * Expects that the rotation axis is normalized. @f[ * \hat q = [\boldsymbol a \cdot sin \frac \theta 2, cos \frac \theta 2] + \epsilon [\boldsymbol 0, 0] * @f] * @see rotationAngle(), rotationAxis(), Quaternion::rotation(), * Matrix4::rotation(), Vector3::xAxis(), Vector3::yAxis(), * Vector3::zAxis(), deg(), rad() */ inline static DualQuaternion rotation(T angle, const Vector3& normalizedAxis) { return {Quaternion::rotation(angle, normalizedAxis), {{}, T(0)}}; } /** * @brief Translation dual quaternion * @param vector Translation vector * * @f[ * \hat q = [\boldsymbol 0, 1] + \epsilon [\frac{\boldsymbol v}{2}, 0] * @f] * @see translation() const, Matrix3::translation(const Vector2&), * Vector3::xAxis(), Vector3::yAxis(), Vector3::zAxis() */ inline static DualQuaternion translation(const Vector3& vector) { return {{}, {vector/T(2), T(0)}}; } /** * @brief Default constructor * * @f[ * \hat q = [\boldsymbol 0, 1] + \epsilon [\boldsymbol 0, 0] * @f] * @todoc Remove workaround when Doxygen is predictable */ #ifdef DOXYGEN_GENERATING_OUTPUT inline constexpr /*implicit*/ DualQuaternion(); #else inline constexpr /*implicit*/ DualQuaternion(): Dual>({}, {{}, T(0)}) {} #endif /** * @brief Construct dual quaternion from real and dual part * * @f[ * \hat q = q_0 + \epsilon q_\epsilon * @f] */ inline constexpr /*implicit*/ DualQuaternion(const Quaternion& real, const Quaternion& dual): Dual>(real, dual) {} /** * @brief Construct dual quaternion from vector * * To be used in transformations later. @f[ * \hat q = [\boldsymbol 0, 1] + \epsilon [\boldsymbol v, 0] * @f] * @see transformPointNormalized() * @todoc Remove workaround when Doxygen is predictable */ #ifdef DOXYGEN_GENERATING_OUTPUT inline constexpr explicit DualQuaternion(const Vector3& vector); #else inline constexpr explicit DualQuaternion(const Vector3& vector): Dual>({}, {vector, T(0)}) {} #endif /** * @brief Rotation angle of unit dual quaternion * * Expects that the real part of the quaternion is normalized. @f[ * \theta = 2 \cdot acos q_{S 0} * @f] * @see rotationAxis(), rotation(), Quaternion::rotationAngle() */ inline T rotationAngle() const { return this->real().rotationAngle(); } /** * @brief Rotation axis of unit dual quaternion * * Expects that the quaternion is normalized. Returns either unit-length * vector for valid rotation quaternion or NaN vector for * default-constructed quaternion. @f[ * \boldsymbol a = \frac{\boldsymbol q_{V 0}}{\sqrt{1 - q_{S 0}^2}} * @f] * @see rotationAngle(), rotation(), Quaternion::rotationAxis() */ inline Vector3 rotationAxis() const { return this->real().rotationAxis(); } /** * @brief Translation part of unit dual quaternion * * @f[ * \boldsymbol a = 2 (q_\epsilon q_0^*)_V * @f] * @see translation(const Vector3&) */ inline Vector3 translation() const { return (this->dual()*this->real().conjugated()).vector()*T(2); } /** * @brief Convert dual quaternion to transformation matrix * * @see Quaternion::matrix() */ Matrix4 matrix() const { return Matrix4::from(this->real().matrix(), translation()); } /** * @brief Quaternion-conjugated dual quaternion * * @f[ * \hat q^* = q_0^* + q_\epsilon^* * @f] * @see dualConjugated(), conjugated(), Quaternion::conjugated() */ inline DualQuaternion quaternionConjugated() const { return {this->real().conjugated(), this->dual().conjugated()}; } /** * @brief Dual-conjugated dual quaternion * * @f[ * \overline{\hat q} = q_0 - \epsilon q_\epsilon * @f] * @see quaternionConjugated(), conjugated(), Dual::conjugated() */ inline DualQuaternion dualConjugated() const { return Dual>::conjugated(); } /** * @brief Conjugated dual quaternion * * Both quaternion and dual conjugation. @f[ * \overline{\hat q^*} = q_0^* - \epsilon q_\epsilon^* = q_0^* + \epsilon [\boldsymbol q_{V \epsilon}, -q_{S \epsilon}] * @f] * @see quaternionConjugated(), dualConjugated(), Quaternion::conjugated(), * Dual::conjugated() */ inline DualQuaternion conjugated() const { return {this->real().conjugated(), {this->dual().vector(), -this->dual().scalar()}}; } /** * @brief %Dual quaternion norm * * @f[ * ||\hat q|| = \sqrt{\hat q^* \hat q} = ||q_0|| + \epsilon \frac{q_0 \cdot q_\epsilon}{||q_0||} * @f] */ inline Dual norm() const { T norm = this->real().length(); return {norm, Quaternion::dot(this->real(), this->dual())/norm}; } /** * @brief Inverted dual quaternion * * See invertedNormalized() which is faster for normalized * dual quaternions. @f[ * \hat q^{-1} = \frac{\hat q^*}{||\hat q||^2} * @f] */ inline DualQuaternion inverted() const { return quaternionConjugated()/Math::pow<2>(norm()); } /** * @brief Inverted normalized dual quaternion * * Equivalent to quaternionConjugated(). Expects that the quaternion is * normalized. @f[ * \hat q^{-1} = \frac{\hat q^*}{||\hat q||^2} = \hat q^* * @f] */ inline DualQuaternion invertedNormalized() const { CORRADE_ASSERT(MathTypeTraits::equals(norm(), T(1)), "Math::DualQuaternion::invertedNormalized(): dual quaternion must be normalized", {}); return quaternionConjugated(); } /** * @brief Rotate and translate point with normalized dual quaternion * * Expects that the dual quaternion is normalized. @f[ * v' = qv \overline{\hat q^*} = q ([\boldsymbol 0, 1] + \epsilon [\boldsymbol v, 0]) \overline{\hat q^*} * @f] * @see DualQuaternion(const Vector3&), Matrix4::transformPoint(), Quaternion::rotateVectorNormalized() */ inline Vector3 transformPointNormalized(const Vector3& vector) const { CORRADE_ASSERT(MathTypeTraits>::equals(norm(), Dual(1)), "Math::DualQuaternion::transformPointNormalized(): dual quaternion must be normalized", Vector3(std::numeric_limits::quiet_NaN())); return ((*this)*DualQuaternion(vector)*conjugated()).dual().vector(); } MAGNUM_DUAL_SUBCLASS_IMPLEMENTATION(DualQuaternion, Quaternion) private: /* Used by Dual operators and dualConjugated() */ DualQuaternion(const Dual>& other): Dual>(other) {} }; /** @debugoperator{Magnum::Math::DualQuaternion} */ template Corrade::Utility::Debug operator<<(Corrade::Utility::Debug debug, const DualQuaternion& value) { debug << "DualQuaternion({{"; debug.setFlag(Corrade::Utility::Debug::SpaceAfterEachValue, false); debug << value.real().vector().x() << ", " << value.real().vector().y() << ", " << value.real().vector().z() << "}, " << value.real().scalar() << "}, {{" << value.dual().vector().x() << ", " << value.dual().vector().y() << ", " << value.dual().vector().z() << "}, " << value.dual().scalar() << "})"; debug.setFlag(Corrade::Utility::Debug::SpaceAfterEachValue, true); return debug; } /* Explicit instantiation for commonly used types */ #ifndef DOXYGEN_GENERATING_OUTPUT extern template Corrade::Utility::Debug MAGNUM_EXPORT operator<<(Corrade::Utility::Debug, const DualQuaternion&); #ifndef MAGNUM_TARGET_GLES extern template Corrade::Utility::Debug MAGNUM_EXPORT operator<<(Corrade::Utility::Debug, const DualQuaternion&); #endif #endif }} #endif