// @(#)root/mathcore:$Id: EulerAngles.h 22516 2008-03-07 15:14:26Z moneta $ // Authors: W. Brown, M. Fischler, L. Moneta 2005 /********************************************************************** * * * Copyright (c) 2005 , LCG ROOT MathLib Team * * * * * **********************************************************************/ // Header file for class EulerAngles // // Created by: Lorenzo Moneta at Tue May 10 17:55:10 2005 // // Last update: Tue May 10 17:55:10 2005 // #ifndef ROOT_Math_GenVector_EulerAngles #define ROOT_Math_GenVector_EulerAngles 1 #include "Math/GenVector/Rotation3D.h" #include "Math/GenVector/DisplacementVector3D.h" #include "Math/GenVector/PositionVector3D.h" #include "Math/GenVector/LorentzVector.h" #include "Math/GenVector/3DConversions.h" #include <algorithm> #include <cassert> namespace ROOT { namespace Math { //__________________________________________________________________________________________ /** EulerAngles class describing rotation as three angles (Euler Angles). The Euler angles definition matches that of Classical Mechanics (Goldstein). It is also the same convention defined in <A HREF="http://mathworld.wolfram.com/EulerAngles.html">mathworld</A> and used in Mathematica and CLHEP. Note that the ROOT class TRotation defines a slightly different convention. @ingroup GenVector */ class EulerAngles { public: typedef double Scalar; /** Default constructor */ EulerAngles() : fPhi(0.0), fTheta(0.0), fPsi(0.0) { } /** Constructor from phi, theta and psi */ EulerAngles( Scalar phi, Scalar theta, Scalar psi ) : fPhi(phi), fTheta(theta), fPsi(psi) {Rectify();} // Added 27 Jan. 06 JMM /** Construct given a pair of pointers or iterators defining the beginning and end of an array of three Scalars, to be treated as the angles phi, theta and psi. */ template<class IT> EulerAngles(IT begin, IT end) { SetComponents(begin,end); } // The compiler-generated copy ctor, copy assignment, and dtor are OK. /** Re-adjust components place angles in canonical ranges */ void Rectify(); // ======== Construction and assignement from any other rotation ================== /** Create from any other supported rotation (see gv_detail::convert ) */ template <class OtherRotation> explicit EulerAngles(const OtherRotation & r) {gv_detail::convert(r,*this);} /** Assign from any other rotation (see gv_detail::convert ) */ template <class OtherRotation> EulerAngles & operator=( OtherRotation const & r ) { gv_detail::convert(r,*this); return *this; } #ifdef OLD explicit EulerAngles(const Rotation3D & r) {gv_detail::convert(r,*this);} /** Construct from a rotation matrix */ explicit EulerAngles(const Rotation3D & r) {gv_detail::convert(r,*this);} /** Construct from a rotation represented by a Quaternion */ explicit EulerAngles(const Quaternion & q) {gv_detail::convert(q,*this);} /** Construct from an AxisAngle */ explicit EulerAngles(const AxisAngle & a ) { gv_detail::convert(a, *this); } /** Construct from an axial rotation */ explicit EulerAngles( RotationZ const & r ) { gv_detail::convert(r, *this); } explicit EulerAngles( RotationY const & r ) { gv_detail::convert(r, *this); } explicit EulerAngles( RotationX const & r ) { gv_detail::convert(r, *this); } /** Assign from an AxisAngle */ EulerAngles & operator=( AxisAngle const & a ) { return operator=(EulerAngles(a)); } /** Assign from a Quaternion */ EulerAngles & operator=( Quaternion const & q ) {return operator=(EulerAngles(q)); } /** Assign from an axial rotation */ EulerAngles & operator=( RotationZ const & r ) { return operator=(EulerAngles(r)); } EulerAngles & operator=( RotationY const & r ) { return operator=(EulerAngles(r)); } EulerAngles & operator=( RotationX const & r ) { return operator=(EulerAngles(r)); } #endif // ======== Components ============== /** Set the three Euler angles given a pair of pointers or iterators defining the beginning and end of an array of three Scalars. */ template<class IT> void SetComponents(IT begin, IT end) { fPhi = *begin++; fTheta = *begin++; fPsi = *begin++; assert(begin == end); Rectify(); // Added 27 Jan. 06 JMM } /** Get the axis and then the angle into data specified by an iterator begin and another to the end of the desired data (4 past start). */ template<class IT> void GetComponents(IT begin, IT end) const { *begin++ = fPhi; *begin++ = fTheta; *begin++ = fPsi; assert(begin == end); } /** Get the axis and then the angle into data specified by an iterator begin */ template<class IT> void GetComponents(IT begin) const { *begin++ = fPhi; *begin++ = fTheta; *begin = fPsi; } /** Set the components phi, theta, psi based on three Scalars. */ void SetComponents(Scalar phi, Scalar theta, Scalar psi) { fPhi=phi; fTheta=theta; fPsi=psi; Rectify(); // Added 27 Jan. 06 JMM } /** Get the components phi, theta, psi into three Scalars. */ void GetComponents(Scalar & phi, Scalar & theta, Scalar & psi) const { phi=fPhi; theta=fTheta; psi=fPsi; } /** Set Phi Euler angle // JMM 30 Jan. 2006 */ void SetPhi(Scalar phi) { fPhi=phi; Rectify(); } /** Return Phi Euler angle */ Scalar Phi() const { return fPhi; } /** Set Theta Euler angle // JMM 30 Jan. 2006 */ void SetTheta(Scalar theta) { fTheta=theta; Rectify(); } /** Return Theta Euler angle */ Scalar Theta() const { return fTheta; } /** Set Psi Euler angle // JMM 30 Jan. 2006 */ void SetPsi(Scalar psi) { fPsi=psi; Rectify(); } /** Return Psi Euler angle */ Scalar Psi() const { return fPsi; } // =========== operations ============== /** Rotation operation on a displacement vector in any coordinate system and tag */ template <class CoordSystem, class U> DisplacementVector3D<CoordSystem,U> operator() (const DisplacementVector3D<CoordSystem,U> & v) const { return Rotation3D(*this) ( v ); } /** Rotation operation on a position vector in any coordinate system */ template <class CoordSystem, class U> PositionVector3D<CoordSystem, U> operator() (const PositionVector3D<CoordSystem,U> & v) const { DisplacementVector3D< Cartesian3D<double>,U > xyz(v); DisplacementVector3D< Cartesian3D<double>,U > rxyz = operator()(xyz); return PositionVector3D<CoordSystem,U> ( rxyz ); } /** Rotation operation on a Lorentz vector in any 4D coordinate system */ template <class CoordSystem> LorentzVector<CoordSystem> operator() (const LorentzVector<CoordSystem> & v) const { DisplacementVector3D< Cartesian3D<double> > xyz(v.Vect()); xyz = operator()(xyz); LorentzVector< PxPyPzE4D<double> > xyzt (xyz.X(), xyz.Y(), xyz.Z(), v.E()); return LorentzVector<CoordSystem> ( xyzt ); } /** Rotation operation on an arbitrary vector v. Preconditions: v must implement methods x(), y(), and z() and the arbitrary vector type must have a constructor taking (x,y,z) */ template <class ForeignVector> ForeignVector operator() (const ForeignVector & v) const { DisplacementVector3D< Cartesian3D<double> > xyz(v); DisplacementVector3D< Cartesian3D<double> > rxyz = operator()(xyz); return ForeignVector ( rxyz.X(), rxyz.Y(), rxyz.Z() ); } /** Overload operator * for rotation on a vector */ template <class AVector> inline AVector operator* (const AVector & v) const { return operator()(v); } /** Invert a rotation in place */ // theta stays the same and negative rotation in Theta is done via a rotation // of + PI in pohi and Psi void Invert() { Scalar tmp = -fPhi; fPhi = -fPsi + Pi(); fTheta = fTheta; fPsi=tmp + Pi(); } /** Return inverse of a rotation */ EulerAngles Inverse() const { return EulerAngles(-fPsi + Pi(), fTheta, -fPhi + Pi()); } // ========= Multi-Rotation Operations =============== /** Multiply (combine) two rotations */ EulerAngles operator * (const Rotation3D & r) const; EulerAngles operator * (const AxisAngle & a) const; EulerAngles operator * (const EulerAngles & e) const; EulerAngles operator * (const Quaternion & q) const; EulerAngles operator * (const RotationX & rx) const; EulerAngles operator * (const RotationY & ry) const; EulerAngles operator * (const RotationZ & rz) const; /** Post-Multiply (on right) by another rotation : T = T*R */ template <class R> EulerAngles & operator *= (const R & r) { return *this = (*this)*r; } /** Distance between two rotations */ template <class R> Scalar Distance ( const R & r ) const {return gv_detail::dist(*this,r);} /** Equality/inequality operators */ bool operator == (const EulerAngles & rhs) const { if( fPhi != rhs.fPhi ) return false; if( fTheta != rhs.fTheta ) return false; if( fPsi != rhs.fPsi ) return false; return true; } bool operator != (const EulerAngles & rhs) const { return ! operator==(rhs); } private: double fPhi; // Z rotation angle (first) defined in [-PI,PI] double fTheta; // X rotation angle (second) defined only [0,PI] double fPsi; // Z rotation angle (third) defined in [-PI,PI] static double Pi() { return M_PI; } }; // EulerAngles /** Distance between two rotations */ template <class R> inline typename EulerAngles::Scalar Distance ( const EulerAngles& r1, const R & r2) {return gv_detail::dist(r1,r2);} /** Multiplication of an axial rotation by an AxisAngle */ EulerAngles operator* (RotationX const & r1, EulerAngles const & r2); EulerAngles operator* (RotationY const & r1, EulerAngles const & r2); EulerAngles operator* (RotationZ const & r1, EulerAngles const & r2); /** Stream Output and Input */ // TODO - I/O should be put in the manipulator form std::ostream & operator<< (std::ostream & os, const EulerAngles & e); } // namespace Math } // namespace ROOT #endif /* ROOT_Math_GenVector_EulerAngles */
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