Eigen/src/Eigen2Support/Geometry/Quaternion.h - eigen/fuchsia - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2008 Gael Guennebaud <g.gael@free.fr>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 // no include guard, we'll include this twice from All.h from Eigen2Support, and it's internal anyway

 namespace Eigen {

 template<typename Other,
          int OtherRows=Other::RowsAtCompileTime,
          int OtherCols=Other::ColsAtCompileTime>
 struct ei_quaternion_assign_impl;

 /** \geometry_module \ingroup Geometry_Module
   *
   * \class Quaternion
   *
   * \brief The quaternion class used to represent 3D orientations and rotations
   *
   * \param _Scalar the scalar type, i.e., the type of the coefficients
   *
   * This class represents a quaternion \f$ w+xi+yj+zk \f$ that is a convenient representation of
   * orientations and rotations of objects in three dimensions. Compared to other representations
   * like Euler angles or 3x3 matrices, quatertions offer the following advantages:
   * \li \b compact storage (4 scalars)
   * \li \b efficient to compose (28 flops),
   * \li \b stable spherical interpolation
   *
   * The following two typedefs are provided for convenience:
   * \li \c Quaternionf for \c float
   * \li \c Quaterniond for \c double
   *
   * \sa  class AngleAxis, class Transform
   */

 template<typename _Scalar> struct ei_traits<Quaternion<_Scalar> >
 {
   typedef _Scalar Scalar;
 };

 template<typename _Scalar>
 class Quaternion : public RotationBase<Quaternion<_Scalar>,3>
 {
   typedef RotationBase<Quaternion<_Scalar>,3> Base;

 public:
   EIGEN_MAKE_ALIGNED_OPERATOR_NEW_IF_VECTORIZABLE_FIXED_SIZE(_Scalar,4)

   using Base::operator*;

   /** the scalar type of the coefficients */
   typedef _Scalar Scalar;

   /** the type of the Coefficients 4-vector */
   typedef Matrix<Scalar, 4, 1> Coefficients;
   /** the type of a 3D vector */
   typedef Matrix<Scalar,3,1> Vector3;
   /** the equivalent rotation matrix type */
   typedef Matrix<Scalar,3,3> Matrix3;
   /** the equivalent angle-axis type */
   typedef AngleAxis<Scalar> AngleAxisType;

   /** \returns the \c x coefficient */
   inline Scalar x() const { return m_coeffs.coeff(0); }
   /** \returns the \c y coefficient */
   inline Scalar y() const { return m_coeffs.coeff(1); }
   /** \returns the \c z coefficient */
   inline Scalar z() const { return m_coeffs.coeff(2); }
   /** \returns the \c w coefficient */
   inline Scalar w() const { return m_coeffs.coeff(3); }

   /** \returns a reference to the \c x coefficient */
   inline Scalar& x() { return m_coeffs.coeffRef(0); }
   /** \returns a reference to the \c y coefficient */
   inline Scalar& y() { return m_coeffs.coeffRef(1); }
   /** \returns a reference to the \c z coefficient */
   inline Scalar& z() { return m_coeffs.coeffRef(2); }
   /** \returns a reference to the \c w coefficient */
   inline Scalar& w() { return m_coeffs.coeffRef(3); }

   /** \returns a read-only vector expression of the imaginary part (x,y,z) */
   inline const Block<const Coefficients,3,1> vec() const { return m_coeffs.template start<3>(); }

   /** \returns a vector expression of the imaginary part (x,y,z) */
   inline Block<Coefficients,3,1> vec() { return m_coeffs.template start<3>(); }

   /** \returns a read-only vector expression of the coefficients (x,y,z,w) */
   inline const Coefficients& coeffs() const { return m_coeffs; }

   /** \returns a vector expression of the coefficients (x,y,z,w) */
   inline Coefficients& coeffs() { return m_coeffs; }

   /** Default constructor leaving the quaternion uninitialized. */
   inline Quaternion() {}

   /** Constructs and initializes the quaternion \f$ w+xi+yj+zk \f$ from
     * its four coefficients \a w, \a x, \a y and \a z.
     *
     * \warning Note the order of the arguments: the real \a w coefficient first,
     * while internally the coefficients are stored in the following order:
     * [\c x, \c y, \c z, \c w]
     */
   inline Quaternion(Scalar w, Scalar x, Scalar y, Scalar z)
   { m_coeffs << x, y, z, w; }

   /** Copy constructor */
   inline Quaternion(const Quaternion& other) { m_coeffs = other.m_coeffs; }

   /** Constructs and initializes a quaternion from the angle-axis \a aa */
   explicit inline Quaternion(const AngleAxisType& aa) { *this = aa; }

   /** Constructs and initializes a quaternion from either:
     *  - a rotation matrix expression,
     *  - a 4D vector expression representing quaternion coefficients.
     * \sa operator=(MatrixBase<Derived>)
     */
   template<typename Derived>
   explicit inline Quaternion(const MatrixBase<Derived>& other) { *this = other; }

   Quaternion& operator=(const Quaternion& other);
   Quaternion& operator=(const AngleAxisType& aa);
   template<typename Derived>
   Quaternion& operator=(const MatrixBase<Derived>& m);

   /** \returns a quaternion representing an identity rotation
     * \sa MatrixBase::Identity()
     */
   static inline Quaternion Identity() { return Quaternion(1, 0, 0, 0); }

   /** \sa Quaternion::Identity(), MatrixBase::setIdentity()
     */
   inline Quaternion& setIdentity() { m_coeffs << 0, 0, 0, 1; return *this; }

   /** \returns the squared norm of the quaternion's coefficients
     * \sa Quaternion::norm(), MatrixBase::squaredNorm()
     */
   inline Scalar squaredNorm() const { return m_coeffs.squaredNorm(); }

   /** \returns the norm of the quaternion's coefficients
     * \sa Quaternion::squaredNorm(), MatrixBase::norm()
     */
   inline Scalar norm() const { return m_coeffs.norm(); }

   /** Normalizes the quaternion \c *this
     * \sa normalized(), MatrixBase::normalize() */
   inline void normalize() { m_coeffs.normalize(); }
   /** \returns a normalized version of \c *this
     * \sa normalize(), MatrixBase::normalized() */
   inline Quaternion normalized() const { return Quaternion(m_coeffs.normalized()); }

   /** \returns the dot product of \c *this and \a other
     * Geometrically speaking, the dot product of two unit quaternions
     * corresponds to the cosine of half the angle between the two rotations.
     * \sa angularDistance()
     */
   inline Scalar eigen2_dot(const Quaternion& other) const { return m_coeffs.eigen2_dot(other.m_coeffs); }

   inline Scalar angularDistance(const Quaternion& other) const;

   Matrix3 toRotationMatrix(void) const;

   template<typename Derived1, typename Derived2>
   Quaternion& setFromTwoVectors(const MatrixBase<Derived1>& a, const MatrixBase<Derived2>& b);

   inline Quaternion operator* (const Quaternion& q) const;
   inline Quaternion& operator*= (const Quaternion& q);

   Quaternion inverse(void) const;
   Quaternion conjugate(void) const;

   Quaternion slerp(Scalar t, const Quaternion& other) const;

   template<typename Derived>
   Vector3 operator* (const MatrixBase<Derived>& vec) const;

   /** \returns \c *this with scalar type casted to \a NewScalarType
     *
     * Note that if \a NewScalarType is equal to the current scalar type of \c *this
     * then this function smartly returns a const reference to \c *this.
     */
   template<typename NewScalarType>
   inline typename internal::cast_return_type<Quaternion,Quaternion<NewScalarType> >::type cast() const
   { return typename internal::cast_return_type<Quaternion,Quaternion<NewScalarType> >::type(*this); }

   /** Copy constructor with scalar type conversion */
   template<typename OtherScalarType>
   inline explicit Quaternion(const Quaternion<OtherScalarType>& other)
   { m_coeffs = other.coeffs().template cast<Scalar>(); }

   /** \returns \c true if \c *this is approximately equal to \a other, within the precision
     * determined by \a prec.
     *
     * \sa MatrixBase::isApprox() */
   bool isApprox(const Quaternion& other, typename NumTraits<Scalar>::Real prec = precision<Scalar>()) const
   { return m_coeffs.isApprox(other.m_coeffs, prec); }

 protected:
   Coefficients m_coeffs;
 };

 /** \ingroup Geometry_Module
   * single precision quaternion type */
 typedef Quaternion<float> Quaternionf;
 /** \ingroup Geometry_Module
   * double precision quaternion type */
 typedef Quaternion<double> Quaterniond;

 // Generic Quaternion * Quaternion product
 template<typename Scalar> inline Quaternion<Scalar>
 ei_quaternion_product(const Quaternion<Scalar>& a, const Quaternion<Scalar>& b)
 {
   return Quaternion<Scalar>
   (
     a.w() * b.w() - a.x() * b.x() - a.y() * b.y() - a.z() * b.z(),
     a.w() * b.x() + a.x() * b.w() + a.y() * b.z() - a.z() * b.y(),
     a.w() * b.y() + a.y() * b.w() + a.z() * b.x() - a.x() * b.z(),
     a.w() * b.z() + a.z() * b.w() + a.x() * b.y() - a.y() * b.x()
   );
 }

 /** \returns the concatenation of two rotations as a quaternion-quaternion product */
 template <typename Scalar>
 inline Quaternion<Scalar> Quaternion<Scalar>::operator* (const Quaternion& other) const
 {
   return ei_quaternion_product(*this,other);
 }

 /** \sa operator*(Quaternion) */
 template <typename Scalar>
 inline Quaternion<Scalar>& Quaternion<Scalar>::operator*= (const Quaternion& other)
 {
   return (*this = *this * other);
 }

 /** Rotation of a vector by a quaternion.
   * \remarks If the quaternion is used to rotate several points (>1)
   * then it is much more efficient to first convert it to a 3x3 Matrix.
   * Comparison of the operation cost for n transformations:
   *   - Quaternion:    30n
   *   - Via a Matrix3: 24 + 15n
   */
 template <typename Scalar>
 template<typename Derived>
 inline typename Quaternion<Scalar>::Vector3
 Quaternion<Scalar>::operator* (const MatrixBase<Derived>& v) const
 {
     // Note that this algorithm comes from the optimization by hand
     // of the conversion to a Matrix followed by a Matrix/Vector product.
     // It appears to be much faster than the common algorithm found
     // in the litterature (30 versus 39 flops). It also requires two
     // Vector3 as temporaries.
     Vector3 uv;
     uv = 2 * this->vec().cross(v);
     return v + this->w() * uv + this->vec().cross(uv);
 }

 template<typename Scalar>
 inline Quaternion<Scalar>& Quaternion<Scalar>::operator=(const Quaternion& other)
 {
   m_coeffs = other.m_coeffs;
   return *this;
 }

 /** Set \c *this from an angle-axis \a aa and returns a reference to \c *this
   */
 template<typename Scalar>
 inline Quaternion<Scalar>& Quaternion<Scalar>::operator=(const AngleAxisType& aa)
 {
   Scalar ha = Scalar(0.5)*aa.angle(); // Scalar(0.5) to suppress precision loss warnings
   this->w() = ei_cos(ha);
   this->vec() = ei_sin(ha) * aa.axis();
   return *this;
 }

 /** Set \c *this from the expression \a xpr:
   *   - if \a xpr is a 4x1 vector, then \a xpr is assumed to be a quaternion
   *   - if \a xpr is a 3x3 matrix, then \a xpr is assumed to be rotation matrix
   *     and \a xpr is converted to a quaternion
   */
 template<typename Scalar>
 template<typename Derived>
 inline Quaternion<Scalar>& Quaternion<Scalar>::operator=(const MatrixBase<Derived>& xpr)
 {
   ei_quaternion_assign_impl<Derived>::run(*this, xpr.derived());
   return *this;
 }

 /** Convert the quaternion to a 3x3 rotation matrix */
 template<typename Scalar>
 inline typename Quaternion<Scalar>::Matrix3
 Quaternion<Scalar>::toRotationMatrix(void) const
 {
   // NOTE if inlined, then gcc 4.2 and 4.4 get rid of the temporary (not gcc 4.3 !!)
   // if not inlined then the cost of the return by value is huge ~ +35%,
   // however, not inlining this function is an order of magnitude slower, so
   // it has to be inlined, and so the return by value is not an issue
   Matrix3 res;

   const Scalar tx  = Scalar(2)*this->x();
   const Scalar ty  = Scalar(2)*this->y();
   const Scalar tz  = Scalar(2)*this->z();
   const Scalar twx = tx*this->w();
   const Scalar twy = ty*this->w();
   const Scalar twz = tz*this->w();
   const Scalar txx = tx*this->x();
   const Scalar txy = ty*this->x();
   const Scalar txz = tz*this->x();
   const Scalar tyy = ty*this->y();
   const Scalar tyz = tz*this->y();
   const Scalar tzz = tz*this->z();

   res.coeffRef(0,0) = Scalar(1)-(tyy+tzz);
   res.coeffRef(0,1) = txy-twz;
   res.coeffRef(0,2) = txz+twy;
   res.coeffRef(1,0) = txy+twz;
   res.coeffRef(1,1) = Scalar(1)-(txx+tzz);
   res.coeffRef(1,2) = tyz-twx;
   res.coeffRef(2,0) = txz-twy;
   res.coeffRef(2,1) = tyz+twx;
   res.coeffRef(2,2) = Scalar(1)-(txx+tyy);

   return res;
 }

 /** Sets *this to be a quaternion representing a rotation sending the vector \a a to the vector \a b.
   *
   * \returns a reference to *this.
   *
   * Note that the two input vectors do \b not have to be normalized.
   */
 template<typename Scalar>
 template<typename Derived1, typename Derived2>
 inline Quaternion<Scalar>& Quaternion<Scalar>::setFromTwoVectors(const MatrixBase<Derived1>& a, const MatrixBase<Derived2>& b)
 {
   Vector3 v0 = a.normalized();
   Vector3 v1 = b.normalized();
   Scalar c = v0.eigen2_dot(v1);

   // if dot == 1, vectors are the same
   if (ei_isApprox(c,Scalar(1)))
   {
     // set to identity
     this->w() = 1; this->vec().setZero();
     return *this;
   }
   // if dot == -1, vectors are opposites
   if (ei_isApprox(c,Scalar(-1)))
   {
     this->vec() = v0.unitOrthogonal();
     this->w() = 0;
     return *this;
   }

   Vector3 axis = v0.cross(v1);
   Scalar s = ei_sqrt((Scalar(1)+c)*Scalar(2));
   Scalar invs = Scalar(1)/s;
   this->vec() = axis * invs;
   this->w() = s * Scalar(0.5);

   return *this;
 }

 /** \returns the multiplicative inverse of \c *this
   * Note that in most cases, i.e., if you simply want the opposite rotation,
   * and/or the quaternion is normalized, then it is enough to use the conjugate.
   *
   * \sa Quaternion::conjugate()
   */
 template <typename Scalar>
 inline Quaternion<Scalar> Quaternion<Scalar>::inverse() const
 {
   // FIXME should this function be called multiplicativeInverse and conjugate() be called inverse() or opposite()  ??
   Scalar n2 = this->squaredNorm();
   if (n2 > 0)
     return Quaternion(conjugate().coeffs() / n2);
   else
   {
     // return an invalid result to flag the error
     return Quaternion(Coefficients::Zero());
   }
 }

 /** \returns the conjugate of the \c *this which is equal to the multiplicative inverse
   * if the quaternion is normalized.
   * The conjugate of a quaternion represents the opposite rotation.
   *
   * \sa Quaternion::inverse()
   */
 template <typename Scalar>
 inline Quaternion<Scalar> Quaternion<Scalar>::conjugate() const
 {
   return Quaternion(this->w(),-this->x(),-this->y(),-this->z());
 }

 /** \returns the angle (in radian) between two rotations
   * \sa eigen2_dot()
   */
 template <typename Scalar>
 inline Scalar Quaternion<Scalar>::angularDistance(const Quaternion& other) const
 {
   double d = ei_abs(this->eigen2_dot(other));
   if (d>=1.0)
     return 0;
   return Scalar(2) * std::acos(d);
 }

 /** \returns the spherical linear interpolation between the two quaternions
   * \c *this and \a other at the parameter \a t
   */
 template <typename Scalar>
 Quaternion<Scalar> Quaternion<Scalar>::slerp(Scalar t, const Quaternion& other) const
 {
   static const Scalar one = Scalar(1) - machine_epsilon<Scalar>();
   Scalar d = this->eigen2_dot(other);
   Scalar absD = ei_abs(d);

   Scalar scale0;
   Scalar scale1;

   if (absD>=one)
   {
     scale0 = Scalar(1) - t;
     scale1 = t;
   }
   else
   {
     // theta is the angle between the 2 quaternions
     Scalar theta = std::acos(absD);
     Scalar sinTheta = ei_sin(theta);

     scale0 = ei_sin( ( Scalar(1) - t ) * theta) / sinTheta;
     scale1 = ei_sin( ( t * theta) ) / sinTheta;
     if (d<0)
       scale1 = -scale1;
   }

   return Quaternion<Scalar>(scale0 * coeffs() + scale1 * other.coeffs());
 }

 // set from a rotation matrix
 template<typename Other>
 struct ei_quaternion_assign_impl<Other,3,3>
 {
   typedef typename Other::Scalar Scalar;
   static inline void run(Quaternion<Scalar>& q, const Other& mat)
   {
     // This algorithm comes from  "Quaternion Calculus and Fast Animation",
     // Ken Shoemake, 1987 SIGGRAPH course notes
     Scalar t = mat.trace();
     if (t > 0)
     {
       t = ei_sqrt(t + Scalar(1.0));
       q.w() = Scalar(0.5)*t;
       t = Scalar(0.5)/t;
       q.x() = (mat.coeff(2,1) - mat.coeff(1,2)) * t;
       q.y() = (mat.coeff(0,2) - mat.coeff(2,0)) * t;
       q.z() = (mat.coeff(1,0) - mat.coeff(0,1)) * t;
     }
     else
     {
       int i = 0;
       if (mat.coeff(1,1) > mat.coeff(0,0))
         i = 1;
       if (mat.coeff(2,2) > mat.coeff(i,i))
         i = 2;
       int j = (i+1)%3;
       int k = (j+1)%3;

       t = ei_sqrt(mat.coeff(i,i)-mat.coeff(j,j)-mat.coeff(k,k) + Scalar(1.0));
       q.coeffs().coeffRef(i) = Scalar(0.5) * t;
       t = Scalar(0.5)/t;
       q.w() = (mat.coeff(k,j)-mat.coeff(j,k))*t;
       q.coeffs().coeffRef(j) = (mat.coeff(j,i)+mat.coeff(i,j))*t;
       q.coeffs().coeffRef(k) = (mat.coeff(k,i)+mat.coeff(i,k))*t;
     }
   }
 };

 // set from a vector of coefficients assumed to be a quaternion
 template<typename Other>
 struct ei_quaternion_assign_impl<Other,4,1>
 {
   typedef typename Other::Scalar Scalar;
   static inline void run(Quaternion<Scalar>& q, const Other& vec)
   {
     q.coeffs() = vec;
   }
 };

 } // end namespace Eigen
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2008 Gael Guennebaud <g.gael@free.fr>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	// no include guard, we'll include this twice from All.h from Eigen2Support, and it's internal anyway

	namespace Eigen {

	template<typename Other,
	int OtherRows=Other::RowsAtCompileTime,
	int OtherCols=Other::ColsAtCompileTime>
	struct ei_quaternion_assign_impl;

	/** \geometry_module \ingroup Geometry_Module
	*
	* \class Quaternion
	*
	* \brief The quaternion class used to represent 3D orientations and rotations
	*
	* \param _Scalar the scalar type, i.e., the type of the coefficients
	*
	* This class represents a quaternion \f$ w+xi+yj+zk \f$ that is a convenient representation of
	* orientations and rotations of objects in three dimensions. Compared to other representations
	* like Euler angles or 3x3 matrices, quatertions offer the following advantages:
	* \li \b compact storage (4 scalars)
	* \li \b efficient to compose (28 flops),
	* \li \b stable spherical interpolation
	*
	* The following two typedefs are provided for convenience:
	* \li \c Quaternionf for \c float
	* \li \c Quaterniond for \c double
	*
	* \sa class AngleAxis, class Transform
	*/

	template<typename _Scalar> struct ei_traits<Quaternion<_Scalar> >
	{
	typedef _Scalar Scalar;
	};

	template<typename _Scalar>
	class Quaternion : public RotationBase<Quaternion<_Scalar>,3>
	{
	typedef RotationBase<Quaternion<_Scalar>,3> Base;

	public:
	EIGEN_MAKE_ALIGNED_OPERATOR_NEW_IF_VECTORIZABLE_FIXED_SIZE(_Scalar,4)

	using Base::operator*;

	/** the scalar type of the coefficients */
	typedef _Scalar Scalar;

	/** the type of the Coefficients 4-vector */
	typedef Matrix<Scalar, 4, 1> Coefficients;
	/** the type of a 3D vector */
	typedef Matrix<Scalar,3,1> Vector3;
	/** the equivalent rotation matrix type */
	typedef Matrix<Scalar,3,3> Matrix3;
	/** the equivalent angle-axis type */
	typedef AngleAxis<Scalar> AngleAxisType;

	/** \returns the \c x coefficient */
	inline Scalar x() const { return m_coeffs.coeff(0); }
	/** \returns the \c y coefficient */
	inline Scalar y() const { return m_coeffs.coeff(1); }
	/** \returns the \c z coefficient */
	inline Scalar z() const { return m_coeffs.coeff(2); }
	/** \returns the \c w coefficient */
	inline Scalar w() const { return m_coeffs.coeff(3); }

	/** \returns a reference to the \c x coefficient */
	inline Scalar& x() { return m_coeffs.coeffRef(0); }
	/** \returns a reference to the \c y coefficient */
	inline Scalar& y() { return m_coeffs.coeffRef(1); }
	/** \returns a reference to the \c z coefficient */
	inline Scalar& z() { return m_coeffs.coeffRef(2); }
	/** \returns a reference to the \c w coefficient */
	inline Scalar& w() { return m_coeffs.coeffRef(3); }

	/** \returns a read-only vector expression of the imaginary part (x,y,z) */
	inline const Block<const Coefficients,3,1> vec() const { return m_coeffs.template start<3>(); }

	/** \returns a vector expression of the imaginary part (x,y,z) */
	inline Block<Coefficients,3,1> vec() { return m_coeffs.template start<3>(); }

	/** \returns a read-only vector expression of the coefficients (x,y,z,w) */
	inline const Coefficients& coeffs() const { return m_coeffs; }

	/** \returns a vector expression of the coefficients (x,y,z,w) */
	inline Coefficients& coeffs() { return m_coeffs; }

	/** Default constructor leaving the quaternion uninitialized. */
	inline Quaternion() {}

	/** Constructs and initializes the quaternion \f$ w+xi+yj+zk \f$ from
	* its four coefficients \a w, \a x, \a y and \a z.
	*
	* \warning Note the order of the arguments: the real \a w coefficient first,
	* while internally the coefficients are stored in the following order:
	* [\c x, \c y, \c z, \c w]
	*/
	inline Quaternion(Scalar w, Scalar x, Scalar y, Scalar z)
	{ m_coeffs << x, y, z, w; }

	/** Copy constructor */
	inline Quaternion(const Quaternion& other) { m_coeffs = other.m_coeffs; }

	/** Constructs and initializes a quaternion from the angle-axis \a aa */
	explicit inline Quaternion(const AngleAxisType& aa) { *this = aa; }

	/** Constructs and initializes a quaternion from either:
	* - a rotation matrix expression,
	* - a 4D vector expression representing quaternion coefficients.
	* \sa operator=(MatrixBase<Derived>)
	*/
	template<typename Derived>
	explicit inline Quaternion(const MatrixBase<Derived>& other) { *this = other; }

	Quaternion& operator=(const Quaternion& other);
	Quaternion& operator=(const AngleAxisType& aa);
	template<typename Derived>
	Quaternion& operator=(const MatrixBase<Derived>& m);

	/** \returns a quaternion representing an identity rotation
	* \sa MatrixBase::Identity()
	*/
	static inline Quaternion Identity() { return Quaternion(1, 0, 0, 0); }

	/** \sa Quaternion::Identity(), MatrixBase::setIdentity()
	*/
	inline Quaternion& setIdentity() { m_coeffs << 0, 0, 0, 1; return *this; }

	/** \returns the squared norm of the quaternion's coefficients
	* \sa Quaternion::norm(), MatrixBase::squaredNorm()
	*/
	inline Scalar squaredNorm() const { return m_coeffs.squaredNorm(); }

	/** \returns the norm of the quaternion's coefficients
	* \sa Quaternion::squaredNorm(), MatrixBase::norm()
	*/
	inline Scalar norm() const { return m_coeffs.norm(); }

	/** Normalizes the quaternion \c *this
	* \sa normalized(), MatrixBase::normalize() */
	inline void normalize() { m_coeffs.normalize(); }
	/** \returns a normalized version of \c *this
	* \sa normalize(), MatrixBase::normalized() */
	inline Quaternion normalized() const { return Quaternion(m_coeffs.normalized()); }

	/** \returns the dot product of \c *this and \a other
	* Geometrically speaking, the dot product of two unit quaternions
	* corresponds to the cosine of half the angle between the two rotations.
	* \sa angularDistance()
	*/
	inline Scalar eigen2_dot(const Quaternion& other) const { return m_coeffs.eigen2_dot(other.m_coeffs); }

	inline Scalar angularDistance(const Quaternion& other) const;

	Matrix3 toRotationMatrix(void) const;

	template<typename Derived1, typename Derived2>
	Quaternion& setFromTwoVectors(const MatrixBase<Derived1>& a, const MatrixBase<Derived2>& b);

	inline Quaternion operator* (const Quaternion& q) const;
	inline Quaternion& operator*= (const Quaternion& q);

	Quaternion inverse(void) const;
	Quaternion conjugate(void) const;

	Quaternion slerp(Scalar t, const Quaternion& other) const;

	template<typename Derived>
	Vector3 operator* (const MatrixBase<Derived>& vec) const;

	/** \returns \c *this with scalar type casted to \a NewScalarType
	*
	* Note that if \a NewScalarType is equal to the current scalar type of \c *this
	* then this function smartly returns a const reference to \c *this.
	*/
	template<typename NewScalarType>
	inline typename internal::cast_return_type<Quaternion,Quaternion<NewScalarType> >::type cast() const
	{ return typename internal::cast_return_type<Quaternion,Quaternion<NewScalarType> >::type(*this); }

	/** Copy constructor with scalar type conversion */
	template<typename OtherScalarType>
	inline explicit Quaternion(const Quaternion<OtherScalarType>& other)
	{ m_coeffs = other.coeffs().template cast<Scalar>(); }

	/** \returns \c true if \c *this is approximately equal to \a other, within the precision
	* determined by \a prec.
	*
	* \sa MatrixBase::isApprox() */
	bool isApprox(const Quaternion& other, typename NumTraits<Scalar>::Real prec = precision<Scalar>()) const
	{ return m_coeffs.isApprox(other.m_coeffs, prec); }

	protected:
	Coefficients m_coeffs;
	};

	/** \ingroup Geometry_Module
	* single precision quaternion type */
	typedef Quaternion<float> Quaternionf;
	/** \ingroup Geometry_Module
	* double precision quaternion type */
	typedef Quaternion<double> Quaterniond;

	// Generic Quaternion * Quaternion product
	template<typename Scalar> inline Quaternion<Scalar>
	ei_quaternion_product(const Quaternion<Scalar>& a, const Quaternion<Scalar>& b)
	{
	return Quaternion<Scalar>
	(
	a.w() * b.w() - a.x() * b.x() - a.y() * b.y() - a.z() * b.z(),
	a.w() * b.x() + a.x() * b.w() + a.y() * b.z() - a.z() * b.y(),
	a.w() * b.y() + a.y() * b.w() + a.z() * b.x() - a.x() * b.z(),
	a.w() * b.z() + a.z() * b.w() + a.x() * b.y() - a.y() * b.x()
	);
	}

	/** \returns the concatenation of two rotations as a quaternion-quaternion product */
	template <typename Scalar>
	inline Quaternion<Scalar> Quaternion<Scalar>::operator* (const Quaternion& other) const
	{
	return ei_quaternion_product(*this,other);
	}

	/** \sa operator(Quaternion) /
	template <typename Scalar>
	inline Quaternion<Scalar>& Quaternion<Scalar>::operator*= (const Quaternion& other)
	{
	return (this = this * other);
	}

	/** Rotation of a vector by a quaternion.
	* \remarks If the quaternion is used to rotate several points (>1)
	* then it is much more efficient to first convert it to a 3x3 Matrix.
	* Comparison of the operation cost for n transformations:
	* - Quaternion: 30n
	* - Via a Matrix3: 24 + 15n
	*/
	template <typename Scalar>
	template<typename Derived>
	inline typename Quaternion<Scalar>::Vector3
	Quaternion<Scalar>::operator* (const MatrixBase<Derived>& v) const
	{
	// Note that this algorithm comes from the optimization by hand
	// of the conversion to a Matrix followed by a Matrix/Vector product.
	// It appears to be much faster than the common algorithm found
	// in the litterature (30 versus 39 flops). It also requires two
	// Vector3 as temporaries.
	Vector3 uv;
	uv = 2 * this->vec().cross(v);
	return v + this->w() * uv + this->vec().cross(uv);
	}

	template<typename Scalar>
	inline Quaternion<Scalar>& Quaternion<Scalar>::operator=(const Quaternion& other)
	{
	m_coeffs = other.m_coeffs;
	return *this;
	}

	/** Set \c this from an angle-axis \a aa and returns a reference to \c this
	*/
	template<typename Scalar>
	inline Quaternion<Scalar>& Quaternion<Scalar>::operator=(const AngleAxisType& aa)
	{
	Scalar ha = Scalar(0.5)*aa.angle(); // Scalar(0.5) to suppress precision loss warnings
	this->w() = ei_cos(ha);
	this->vec() = ei_sin(ha) * aa.axis();
	return *this;
	}

	/** Set \c *this from the expression \a xpr:
	* - if \a xpr is a 4x1 vector, then \a xpr is assumed to be a quaternion
	* - if \a xpr is a 3x3 matrix, then \a xpr is assumed to be rotation matrix
	* and \a xpr is converted to a quaternion
	*/
	template<typename Scalar>
	template<typename Derived>
	inline Quaternion<Scalar>& Quaternion<Scalar>::operator=(const MatrixBase<Derived>& xpr)
	{
	ei_quaternion_assign_impl<Derived>::run(*this, xpr.derived());
	return *this;
	}

	/** Convert the quaternion to a 3x3 rotation matrix */
	template<typename Scalar>
	inline typename Quaternion<Scalar>::Matrix3
	Quaternion<Scalar>::toRotationMatrix(void) const
	{
	// NOTE if inlined, then gcc 4.2 and 4.4 get rid of the temporary (not gcc 4.3 !!)
	// if not inlined then the cost of the return by value is huge ~ +35%,
	// however, not inlining this function is an order of magnitude slower, so
	// it has to be inlined, and so the return by value is not an issue
	Matrix3 res;

	const Scalar tx = Scalar(2)*this->x();
	const Scalar ty = Scalar(2)*this->y();
	const Scalar tz = Scalar(2)*this->z();
	const Scalar twx = tx*this->w();
	const Scalar twy = ty*this->w();
	const Scalar twz = tz*this->w();
	const Scalar txx = tx*this->x();
	const Scalar txy = ty*this->x();
	const Scalar txz = tz*this->x();
	const Scalar tyy = ty*this->y();
	const Scalar tyz = tz*this->y();
	const Scalar tzz = tz*this->z();

	res.coeffRef(0,0) = Scalar(1)-(tyy+tzz);
	res.coeffRef(0,1) = txy-twz;
	res.coeffRef(0,2) = txz+twy;
	res.coeffRef(1,0) = txy+twz;
	res.coeffRef(1,1) = Scalar(1)-(txx+tzz);
	res.coeffRef(1,2) = tyz-twx;
	res.coeffRef(2,0) = txz-twy;
	res.coeffRef(2,1) = tyz+twx;
	res.coeffRef(2,2) = Scalar(1)-(txx+tyy);

	return res;
	}

	/** Sets *this to be a quaternion representing a rotation sending the vector \a a to the vector \a b.
	*
	* \returns a reference to *this.
	*
	* Note that the two input vectors do \b not have to be normalized.
	*/
	template<typename Scalar>
	template<typename Derived1, typename Derived2>
	inline Quaternion<Scalar>& Quaternion<Scalar>::setFromTwoVectors(const MatrixBase<Derived1>& a, const MatrixBase<Derived2>& b)
	{
	Vector3 v0 = a.normalized();
	Vector3 v1 = b.normalized();
	Scalar c = v0.eigen2_dot(v1);

	// if dot == 1, vectors are the same
	if (ei_isApprox(c,Scalar(1)))
	{
	// set to identity
	this->w() = 1; this->vec().setZero();
	return *this;
	}
	// if dot == -1, vectors are opposites
	if (ei_isApprox(c,Scalar(-1)))
	{
	this->vec() = v0.unitOrthogonal();
	this->w() = 0;
	return *this;
	}

	Vector3 axis = v0.cross(v1);
	Scalar s = ei_sqrt((Scalar(1)+c)*Scalar(2));
	Scalar invs = Scalar(1)/s;
	this->vec() = axis * invs;
	this->w() = s * Scalar(0.5);

	return *this;
	}

	/** \returns the multiplicative inverse of \c *this
	* Note that in most cases, i.e., if you simply want the opposite rotation,
	* and/or the quaternion is normalized, then it is enough to use the conjugate.
	*
	* \sa Quaternion::conjugate()
	*/
	template <typename Scalar>
	inline Quaternion<Scalar> Quaternion<Scalar>::inverse() const
	{
	// FIXME should this function be called multiplicativeInverse and conjugate() be called inverse() or opposite() ??
	Scalar n2 = this->squaredNorm();
	if (n2 > 0)
	return Quaternion(conjugate().coeffs() / n2);
	else
	{
	// return an invalid result to flag the error
	return Quaternion(Coefficients::Zero());
	}
	}

	/** \returns the conjugate of the \c *this which is equal to the multiplicative inverse
	* if the quaternion is normalized.
	* The conjugate of a quaternion represents the opposite rotation.
	*
	* \sa Quaternion::inverse()
	*/
	template <typename Scalar>
	inline Quaternion<Scalar> Quaternion<Scalar>::conjugate() const
	{
	return Quaternion(this->w(),-this->x(),-this->y(),-this->z());
	}

	/** \returns the angle (in radian) between two rotations
	* \sa eigen2_dot()
	*/
	template <typename Scalar>
	inline Scalar Quaternion<Scalar>::angularDistance(const Quaternion& other) const
	{
	double d = ei_abs(this->eigen2_dot(other));
	if (d>=1.0)
	return 0;
	return Scalar(2) * std::acos(d);
	}

	/** \returns the spherical linear interpolation between the two quaternions
	* \c *this and \a other at the parameter \a t
	*/
	template <typename Scalar>
	Quaternion<Scalar> Quaternion<Scalar>::slerp(Scalar t, const Quaternion& other) const
	{
	static const Scalar one = Scalar(1) - machine_epsilon<Scalar>();
	Scalar d = this->eigen2_dot(other);
	Scalar absD = ei_abs(d);

	Scalar scale0;
	Scalar scale1;

	if (absD>=one)
	{
	scale0 = Scalar(1) - t;
	scale1 = t;
	}
	else
	{
	// theta is the angle between the 2 quaternions
	Scalar theta = std::acos(absD);
	Scalar sinTheta = ei_sin(theta);

	scale0 = ei_sin( ( Scalar(1) - t ) * theta) / sinTheta;
	scale1 = ei_sin( ( t * theta) ) / sinTheta;
	if (d<0)
	scale1 = -scale1;
	}

	return Quaternion<Scalar>(scale0 * coeffs() + scale1 * other.coeffs());
	}

	// set from a rotation matrix
	template<typename Other>
	struct ei_quaternion_assign_impl<Other,3,3>
	{
	typedef typename Other::Scalar Scalar;
	static inline void run(Quaternion<Scalar>& q, const Other& mat)
	{
	// This algorithm comes from "Quaternion Calculus and Fast Animation",
	// Ken Shoemake, 1987 SIGGRAPH course notes
	Scalar t = mat.trace();
	if (t > 0)
	{
	t = ei_sqrt(t + Scalar(1.0));
	q.w() = Scalar(0.5)*t;
	t = Scalar(0.5)/t;
	q.x() = (mat.coeff(2,1) - mat.coeff(1,2)) * t;
	q.y() = (mat.coeff(0,2) - mat.coeff(2,0)) * t;
	q.z() = (mat.coeff(1,0) - mat.coeff(0,1)) * t;
	}
	else
	{
	int i = 0;
	if (mat.coeff(1,1) > mat.coeff(0,0))
	i = 1;
	if (mat.coeff(2,2) > mat.coeff(i,i))
	i = 2;
	int j = (i+1)%3;
	int k = (j+1)%3;

	t = ei_sqrt(mat.coeff(i,i)-mat.coeff(j,j)-mat.coeff(k,k) + Scalar(1.0));
	q.coeffs().coeffRef(i) = Scalar(0.5) * t;
	t = Scalar(0.5)/t;
	q.w() = (mat.coeff(k,j)-mat.coeff(j,k))*t;
	q.coeffs().coeffRef(j) = (mat.coeff(j,i)+mat.coeff(i,j))*t;
	q.coeffs().coeffRef(k) = (mat.coeff(k,i)+mat.coeff(i,k))*t;
	}
	}
	};

	// set from a vector of coefficients assumed to be a quaternion
	template<typename Other>
	struct ei_quaternion_assign_impl<Other,4,1>
	{
	typedef typename Other::Scalar Scalar;
	static inline void run(Quaternion<Scalar>& q, const Other& vec)
	{
	q.coeffs() = vec;
	}
	};

	} // end namespace Eigen