/usr/include/CLHEP/Vector/RotationY.h is in libclhep-dev 2.1.4.1+dfsg-1.
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// CLASSDOC OFF
// ---------------------------------------------------------------------------
// CLASSDOC ON
//
// This file is a part of the CLHEP - a Class Library for High Energy Physics.
//
// This is the definition of the HepRotationY class for performing rotations
// around the X axis on objects of the Hep3Vector (and HepLorentzVector) class.
//
// HepRotationY is a concrete implementation of Hep3RotationInterface.
//
// .SS See Also
// RotationInterfaces.h
// ThreeVector.h, LorentzVector.h, LorentzRotation.h
//
// .SS Author
// Mark Fischler
#ifndef HEP_ROTATIONY_H
#define HEP_ROTATIONY_H
#ifdef GNUPRAGMA
#pragma interface
#endif
#include "CLHEP/Vector/defs.h"
#include "CLHEP/Vector/RotationInterfaces.h"
namespace CLHEP {
class HepRotationY;
class HepRotation;
class HepBoost;
inline HepRotationY inverseOf(const HepRotationY & r);
// Returns the inverse of a RotationY.
/**
* @author
* @ingroup vector
*/
class HepRotationY {
public:
// ---------- Constructors and Assignment:
inline HepRotationY();
// Default constructor. Gives an identity rotation.
HepRotationY(double delta);
// supply angle of rotation
inline HepRotationY(const HepRotationY & orig);
// Copy constructor.
inline HepRotationY & operator = (const HepRotationY & r);
// Assignment from a Rotation, which must be RotationY
HepRotationY & set ( double delta );
// set angle of rotation
inline ~HepRotationY();
// Trivial destructor.
// ---------- Accessors:
inline Hep3Vector colX() const;
inline Hep3Vector colY() const;
inline Hep3Vector colZ() const;
// orthogonal unit-length column vectors
inline Hep3Vector rowX() const;
inline Hep3Vector rowY() const;
inline Hep3Vector rowZ() const;
// orthogonal unit-length row vectors
inline double xx() const;
inline double xy() const;
inline double xz() const;
inline double yx() const;
inline double yy() const;
inline double yz() const;
inline double zx() const;
inline double zy() const;
inline double zz() const;
// Elements of the rotation matrix (Geant4).
inline HepRep3x3 rep3x3() const;
// 3x3 representation:
// ------------ Euler angles:
inline double getPhi () const;
inline double getTheta() const;
inline double getPsi () const;
double phi () const;
double theta() const;
double psi () const;
HepEulerAngles eulerAngles() const;
// ------------ axis & angle of rotation:
inline double getDelta() const;
inline Hep3Vector getAxis () const;
inline double delta() const;
inline Hep3Vector axis () const;
inline HepAxisAngle axisAngle() const;
inline void getAngleAxis(double & delta, Hep3Vector & axis) const;
// Returns the rotation angle and rotation axis (Geant4).
// ------------- Angles of rotated axes
double phiX() const;
double phiY() const;
double phiZ() const;
double thetaX() const;
double thetaY() const;
double thetaZ() const;
// Return angles (RADS) made by rotated axes against original axes (Geant4).
// ---------- Other accessors treating pure rotation as a 4-rotation
inline HepLorentzVector col1() const;
inline HepLorentzVector col2() const;
inline HepLorentzVector col3() const;
// orthosymplectic 4-vector columns - T component will be zero
inline HepLorentzVector col4() const;
// Will be (0,0,0,1) for this pure Rotation.
inline HepLorentzVector row1() const;
inline HepLorentzVector row2() const;
inline HepLorentzVector row3() const;
// orthosymplectic 4-vector rows - T component will be zero
inline HepLorentzVector row4() const;
// Will be (0,0,0,1) for this pure Rotation.
inline double xt() const;
inline double yt() const;
inline double zt() const;
inline double tx() const;
inline double ty() const;
inline double tz() const;
// Will be zero for this pure Rotation
inline double tt() const;
// Will be one for this pure Rotation
inline HepRep4x4 rep4x4() const;
// 4x4 representation.
// --------- Mutators
void setDelta (double delta);
// change angle of rotation, leaving rotation axis unchanged.
// ---------- Decomposition:
void decompose (HepAxisAngle & rotation, Hep3Vector & boost) const;
void decompose (Hep3Vector & boost, HepAxisAngle & rotation) const;
void decompose (HepRotation & rotation, HepBoost & boost) const;
void decompose (HepBoost & boost, HepRotation & rotation) const;
// These are trivial, as the boost vector is 0.
// ---------- Comparisons:
inline bool isIdentity() const;
// Returns true if the identity matrix (Geant4).
inline int compare( const HepRotationY & r ) const;
// Dictionary-order comparison, in order of delta
// Used in operator<, >, <=, >=
inline bool operator== ( const HepRotationY & r ) const;
inline bool operator!= ( const HepRotationY & r ) const;
inline bool operator< ( const HepRotationY & r ) const;
inline bool operator> ( const HepRotationY & r ) const;
inline bool operator<= ( const HepRotationY & r ) const;
inline bool operator>= ( const HepRotationY & r ) const;
double distance2( const HepRotationY & r ) const;
// 3 - Tr ( this/r )
double distance2( const HepRotation & r ) const;
// 3 - Tr ( this/r ) -- This works with RotationY or Z also
double howNear( const HepRotationY & r ) const;
double howNear( const HepRotation & r ) const;
bool isNear( const HepRotationY & r,
double epsilon=Hep4RotationInterface::tolerance) const;
bool isNear( const HepRotation & r,
double epsilon=Hep4RotationInterface::tolerance) const;
double distance2( const HepBoost & lt ) const;
// 3 - Tr ( this ) + |b|^2 / (1-|b|^2)
double distance2( const HepLorentzRotation & lt ) const;
// 3 - Tr ( this/r ) + |b|^2 / (1-|b|^2) where b is the boost vector of lt
double howNear( const HepBoost & lt ) const;
double howNear( const HepLorentzRotation & lt ) const;
bool isNear( const HepBoost & lt,
double epsilon=Hep4RotationInterface::tolerance) const;
bool isNear( const HepLorentzRotation & lt,
double epsilon=Hep4RotationInterface::tolerance) const;
// ---------- Properties:
double norm2() const;
// distance2 (IDENTITY), which is 3 - Tr ( *this )
inline void rectify();
// non-const but logically moot correction for accumulated roundoff errors
// ---------- Application:
inline Hep3Vector operator() (const Hep3Vector & p) const;
// Rotate a Hep3Vector.
inline Hep3Vector operator * (const Hep3Vector & p) const;
// Multiplication with a Hep3Vector.
inline HepLorentzVector operator()( const HepLorentzVector & w ) const;
// Rotate (the space part of) a HepLorentzVector.
inline HepLorentzVector operator* ( const HepLorentzVector & w ) const;
// Multiplication with a HepLorentzVector.
// ---------- Operations in the group of Rotations
inline HepRotationY operator * (const HepRotationY & ry) const;
// Product of two Y rotations (this) * ry is known to be RotationY.
inline HepRotationY & operator *= (const HepRotationY & r);
inline HepRotationY & transform (const HepRotationY & r);
// Matrix multiplication.
// Note a *= b; <=> a = a * b; while a.transform(b); <=> a = b * a;
// However, in this special case, they commute: Both just add deltas.
inline HepRotationY inverse() const;
// Returns the inverse.
friend HepRotationY inverseOf(const HepRotationY & r);
// Returns the inverse of a RotationY.
inline HepRotationY & invert();
// Inverts the Rotation matrix (be negating delta).
// ---------- I/O:
std::ostream & print( std::ostream & os ) const;
// Output, identifying type of rotation and delta.
// ---------- Tolerance
static inline double getTolerance();
static inline double setTolerance(double tol);
protected:
double its_d;
// The angle of rotation.
double its_s;
double its_c;
// Cache the trig functions, for rapid operations.
inline HepRotationY ( double dd, double ss, double cc );
// Unchecked load-the-data-members
static inline double proper (double delta);
// Put an angle into the range of (-PI, PI]. Useful helper method.
}; // HepRotationY
// ---------- Free-function operations in the group of Rotations
inline
std::ostream & operator <<
( std::ostream & os, const HepRotationY & r ) {return r.print(os);}
} // namespace CLHEP
#include "CLHEP/Vector/RotationY.icc"
#ifdef ENABLE_BACKWARDS_COMPATIBILITY
// backwards compatibility will be enabled ONLY in CLHEP 1.9
using namespace CLHEP;
#endif
#endif /* HEP_ROTATIONY_H */
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