[u/mrichter/AliRoot.git] / STEER / AliAlignObjAngles.h

#ifndef ALIALIGNOBJANGLES_H
#define ALIALIGNOBJANGLES_H

/*****************************************************************************
 * AliAlignObjAngles: derived alignment class storing alignment information  *
 *   for a single volume in form of three doubles for the translation        *
 *   and three doubles for the rotation expressed with the euler angles      *
 *   in the xyz-convention (http://mathworld.wolfram.com/EulerAngles.html),  *
 *   also known as roll, pitch, yaw. PLEASE NOTE THE ANGLES SIGNS ARE        *
 *   INVERSE WITH RESPECT TO THIS REFERENCE!!! In this way the representation*
 *   is fully consistent with the TGeo Rotation methods.                     *
 *****************************************************************************/
#include "TObject.h"
#include "TString.h"
#include "TGeoMatrix.h"

class AliAlignObjAngles : public AliAlignObj{
 public:
  AliAlignObjAngles();
  AliAlignObjAngles(const char* volpath, UShort_t voluid, Double_t x, Double_t y, Double_t z, Double_t psi, Double_t theta, Double_t phi);
  AliAlignObjAngles(const char* volpath, ELayerID detId, Int_t volId, Double_t x, Double_t y, Double_t z, Double_t psi, Double_t theta, Double_t phi);
  AliAlignObjAngles(const char* volpath, UShort_t voluid, TGeoMatrix& m);
  AliAlignObjAngles(const AliAlignObjAngles& theAlignObj);
  AliAlignObjAngles& operator= (const AliAlignObjAngles& theAlignObj);
  virtual ~AliAlignObjAngles();
  
  //Setters
  virtual void SetTranslation(Double_t x, Double_t y, Double_t z){
    fTranslation[0]=x; fTranslation[1]=y; fTranslation[2]=z;}
  virtual void SetTranslation(const TGeoMatrix& m);
  virtual void SetRotation(Double_t psi, Double_t theta, Double_t phi){
    fRotation[0]=psi; fRotation[1]=theta; fRotation[2]=phi;}
  virtual Bool_t SetRotation(const TGeoMatrix& m);
  virtual void SetMatrix(const TGeoMatrix& m);
  virtual void SetPars(Double_t x, Double_t y, Double_t z, Double_t psi,
		   Double_t theta, Double_t phi){
    fTranslation[0]=x; fTranslation[1]=y; fTranslation[2]=z;
    fRotation[0]=psi; fRotation[1]=theta; fRotation[2]=phi;}
  
  //Getters
  virtual void GetTranslation(Double_t *tr)  const {
    tr[0] = fTranslation[0]; tr[1] = fTranslation[1]; tr[2] = fTranslation[2];}
  virtual Bool_t GetAngles(Double_t* angles)   const {
    angles[0] = fRotation[0]; angles[1] = fRotation[1];
    angles[2] = fRotation[2]; return kTRUE;}
  virtual void GetPars(Double_t tr[], Double_t angles[]) const;
  virtual void GetMatrix(TGeoHMatrix& m) const;
  
 protected:
  Double_t fTranslation[3]; // Translation vector
  Double_t fRotation[3]; // Roll-pitch-yaw angles
  
  ClassDef(AliAlignObjAngles, 1)
};

#endif
Commit	Line	Data
befe2c08	1	#ifndef ALIALIGNOBJANGLES_H
	2	#define ALIALIGNOBJANGLES_H
	3
	4	/*****************************************************************************
	5	* AliAlignObjAngles: derived alignment class storing alignment information *
	6	* for a single volume in form of three doubles for the translation *
	7	* and three doubles for the rotation expressed with the euler angles *
	8	* in the xyz-convention (http://mathworld.wolfram.com/EulerAngles.html), *
	9	* also known as roll, pitch, yaw. PLEASE NOTE THE ANGLES SIGNS ARE *
	10	* INVERSE WITH RESPECT TO THIS REFERENCE!!! In this way the representation*
	11	* is fully consistent with the TGeo Rotation methods. *
	12	*****************************************************************************/
	13	#include "TObject.h"
	14	#include "TString.h"
	15	#include "TGeoMatrix.h"
	16
	17	class AliAlignObjAngles : public AliAlignObj{
	18	public:
	19	AliAlignObjAngles();
	20	AliAlignObjAngles(const char* volpath, UShort_t voluid, Double_t x, Double_t y, Double_t z, Double_t psi, Double_t theta, Double_t phi);
	21	AliAlignObjAngles(const char* volpath, ELayerID detId, Int_t volId, Double_t x, Double_t y, Double_t z, Double_t psi, Double_t theta, Double_t phi);
	22	AliAlignObjAngles(const char* volpath, UShort_t voluid, TGeoMatrix& m);
	23	AliAlignObjAngles(const AliAlignObjAngles& theAlignObj);
	24	AliAlignObjAngles& operator= (const AliAlignObjAngles& theAlignObj);
	25	virtual ~AliAlignObjAngles();
	26
	27	//Setters
	28	virtual void SetTranslation(Double_t x, Double_t y, Double_t z){
	29	fTranslation[0]=x; fTranslation[1]=y; fTranslation[2]=z;}
	30	virtual void SetTranslation(const TGeoMatrix& m);
	31	virtual void SetRotation(Double_t psi, Double_t theta, Double_t phi){
	32	fRotation[0]=psi; fRotation[1]=theta; fRotation[2]=phi;}
	33	virtual Bool_t SetRotation(const TGeoMatrix& m);
	34	virtual void SetMatrix(const TGeoMatrix& m);
	35	virtual void SetPars(Double_t x, Double_t y, Double_t z, Double_t psi,
	36	Double_t theta, Double_t phi){
	37	fTranslation[0]=x; fTranslation[1]=y; fTranslation[2]=z;
	38	fRotation[0]=psi; fRotation[1]=theta; fRotation[2]=phi;}
	39
	40	//Getters
	41	virtual void GetTranslation(Double_t *tr) const {
	42	tr[0] = fTranslation[0]; tr[1] = fTranslation[1]; tr[2] = fTranslation[2];}
	43	virtual Bool_t GetAngles(Double_t* angles) const {
	44	angles[0] = fRotation[0]; angles[1] = fRotation[1];
	45	angles[2] = fRotation[2]; return kTRUE;}
	46	virtual void GetPars(Double_t tr[], Double_t angles[]) const;
	47	virtual void GetMatrix(TGeoHMatrix& m) const;
	48
	49	protected:
	50	Double_t fTranslation[3]; // Translation vector
	51	Double_t fRotation[3]; // Roll-pitch-yaw angles
	52
	53	ClassDef(AliAlignObjAngles, 1)
	54	};
	55
	56	#endif