[u/mrichter/AliRoot.git] / FMD / AliFMDReconstructor.h

#ifndef ALIFMDRECONSTRUCTOR_H
#define ALIFMDRECONSTRUCTOR_H
//
//  Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights
//  reserved. 
//
//  See cxx source for full Copyright notice                               
//
//  AliFMDReconstructor.h 
//  Task Class for making TreeR for FMD                        
//
//-- Authors: Evgeny Karpechev (INR) and Alla Maevskaia (INR)
//   Latest changes by Christian Holm Christensen <cholm@nbi.dk>
/* $Id$ */
/** @file    AliFMDReconstructor.h
    @author  Christian Holm Christensen <cholm@nbi.dk>
    @date    Mon Mar 27 12:47:09 2006
    @brief   FMD reconstruction 
*/

//____________________________________________________________________
// Header guards in the header files speeds up the compilation
// considerably.  Please leave them in. 
#ifndef ALIRECONSTRUCTOR_H
# include <AliReconstructor.h>
#endif
#include "AliLog.h"

//____________________________________________________________________
class TTree;
class TClonesArray;
class AliFMDDigit;
class AliRawReader;
class AliESDEvent;
class AliESDFMD;
class TH1;


/** @defgroup FMD_rec Reconstruction */
//____________________________________________________________________
/** @brief This is a class that reconstructs AliFMDRecPoint objects from of
    Digits.  
    This class reads either digits from a TClonesArray or raw data
    from a DDL file (or similar), and applies calibrations to get
    psuedo-inclusive multiplicities per strip.

    @ingroup FMD_rec
 */
class AliFMDReconstructor: public AliReconstructor 
{
public:
  /** CTOR */
  AliFMDReconstructor();
  /** DTOR */
  virtual ~AliFMDReconstructor();

  /** Initialize the reconstructor.  Here, we initialize the geometry
      manager, and finds the local to global transformations from the
      geometry.   The calibration parameter manager is also
      initialized (meaning that the calibration parameters is read
      from CDB).
  */
  virtual void   Init();
  /** Flag that we can convert raw data into digits. 
      @return always @c true */
  virtual Bool_t HasDigitConversion() const { return kTRUE; }
  /** Convert raw data read from the AliRawReader @a reader into
      digits.  This is done using AliFMDRawReader and
      AliFMDAltroReader.  The digits are put in the passed TTree @a
      digitsTree. 
      @param reader     Raw reader. 
      @param digitsTree Tree to store read digits in. */
  virtual void   ConvertDigits(AliRawReader* reader, TTree* digitsTree) const;
  /** Reconstruct one event from the digits passed in @a digitsTree.
      The member function creates AliFMDRecPoint objects and stores
      them on the output tree @a clusterTree.  An FMD ESD object is
      created in parallel. 
      @todo Make sure we get a vertex. 
      @param digitsTree  Tree holding the digits of this event
      @param clusterTree Tree to store AliFMDRecPoint objects in. */
  virtual void   Reconstruct(TTree* digitsTree, TTree* clusterTree) const;
  /** Not used */
  virtual void   Reconstruct(AliRawReader *, TTree*) const;
  /** Put in the ESD data, the FMD ESD data.  The object created by
      the Reconstruct member function is copied to the ESD object. 
      @param digitsTree   Tree of digits for this event - not used
      @param clusterTree  Tree of reconstructed points for this event
      - not used. 
      @param esd ESD object to store data in. 
  */
  virtual void   FillESD(TTree* digitsTree, TTree* clusterTree, 
			 AliESDEvent* esd) const;
  /** Forwards to above member function */
  virtual void   FillESD(AliRawReader*, TTree* clusterTree, 
			 AliESDEvent* esd) const;
  /** Not used */
  virtual void   SetESD(AliESDEvent* esd) { fESD = esd; }
  /** Set the noise factor 
      @param f Factor to use */
  virtual void SetNoiseFactor(Float_t f=3) { fNoiseFactor = f; }
  /** Set whether we should do angle correction or nor 
      @param use If true, do angle correction */
  virtual void SetAngleCorrect(Bool_t use=kTRUE) { fAngleCorrect = use; }
  /** Set whether we want to do diagnostics.  If this is enabled, a
      file named @c FMD.Diag.root will be made.  It contains a set of
      histograms for each event, filed in separate directories in the
      file.  The histograms are 
      @verbatim 
      diagStep1   Read ADC vs. Noise surpressed ADC 
      diagStep2   Noise surpressed ADC vs. calculated Energy dep.
      diagStep3   Energy deposition vs. angle corrected Energy dep.
      diagStep4   Energy deposition vs. calculated multiplicity
      diagAll     Read ADC vs. calculated multiplicity
      @endverbatim 
      @param use If true, make the diagnostics file */
  void SetDiagnose(Bool_t use=kTRUE) { fDiagnostics = use; }
protected:
  /** Copy CTOR 
      @param other Object to copy from. */
  AliFMDReconstructor(const AliFMDReconstructor& other);
  /** Assignment operator 
      @param other Object to assign from
      @return reference to this object */
  AliFMDReconstructor& operator=(const AliFMDReconstructor& other);
  /** Try to get the vertex from either ESD or generator header.  Sets
      @c fCurrentVertex to the found Z posistion of the vertex (if 
      found), and sets the flag @c fVertexType accordingly */
  virtual void GetVertex() const;
  /** Process AliFMDDigit objects in @a digits.  For each digit, find
      the psuedo-rapidity @f$ \eta@f$, azimuthal angle @f$ \varphi@f$,
      energy deposited @f$ E@f$, and psuedo-inclusive multiplicity @f$
      M@f$.
      @param digits Array of digits. */
  virtual void     ProcessDigits(TClonesArray* digits) const;
  /** Substract pedestals from raw ADC in @a digit
      @param digit Digit data
      @return Pedestal subtracted ADC count. */
  virtual UShort_t SubtractPedestal(AliFMDDigit* digit) const;
  /** Converts number of ADC counts to energy deposited.   This is
      done by 
      @f[
      E_i = A_i g_i
      @f]
      where @f$ A_i@f$ is the pedestal subtracted ADC counts, and @f$
      g_i@f$ is the gain for the @f$ i^{\mbox{th}}@f$ strip. 
      @param digit Raw data
      @param eta   Psuedo-rapidity of digit.
      @param count Pedestal subtracted ADC counts
      @return Energy deposited @f$ E_i@f$ */
  virtual Float_t  Adc2Energy(AliFMDDigit* digit, Float_t eta, 
			      UShort_t count) const;
  /** Converts an energy signal to number of particles. In this
      implementation, it's done by 
      @f[
      M_i = E_i / E_{\mbox{MIP}}
      @f]
      where @f$ E_i@f$ is the energy deposited, and @f$
      E_{\mbox{MIP}}@f$ is the average energy deposited by a minimum
      ionizing particle
      @param digit Raw data
      @param edep Energy deposited @f$ E_i@f$
      @return Psuedo-inclusive multiplicity @f$ M@f$ */
  virtual Float_t  Energy2Multiplicity(AliFMDDigit* digit, Float_t edep) const;
  /** Calculate the physical coordinates psuedo-rapidity @f$ \eta@f$,
      azimuthal angle @f$ \varphi@f$ of the strip corresponding to
      the digit @a digit.   This is done by using the information
      obtained, and previously cached by AliFMDGeometry, from the
      TGeoManager. 
      @param digit Digit.
      @param eta   On return, psuedo-rapidity @f$ \eta@f$
      @param phi   On return, azimuthal angle @f$ \varphi@f$ */
  virtual void     PhysicalCoordinates(AliFMDDigit* digit, Float_t& eta, 
				       Float_t& phi) const;
  
  enum Vertex_t {
    kNoVertex,   // Got no vertex
    kGenVertex,  // Got generator vertex 
    kESDVertex   // Got ESD vertex 
  };
  mutable TClonesArray* fMult;          // Cache of RecPoints
  mutable Int_t         fNMult;         // Number of entries in fMult 
  mutable TTree*        fTreeR;         // Output tree 
  mutable Float_t       fCurrentVertex; // Z-coordinate of primary vertex
  mutable AliESDFMD*    fESDObj;        // ESD output object
  Float_t               fNoiseFactor;   // Factor of noise to check
  Bool_t                fAngleCorrect;  // Whether to angle correct
  mutable Vertex_t      fVertexType;    // What kind of vertex we got
  AliESDEvent*          fESD;           // ESD object(?)
  Bool_t                fDiagnostics;   // Wheter to do diagnostics
  TH1*                  fDiagStep1;	// Diagnostics histogram
  TH1*                  fDiagStep2;	// Diagnostics histogram
  TH1*                  fDiagStep3;	// Diagnostics histogram
  TH1*                  fDiagStep4;	// Diagnostics histogram
  TH1*                  fDiagAll;	// Diagnostics histogram
  mutable Bool_t        fZS[3];         // Zero-suppredded?
  mutable UShort_t      fZSFactor[3];   // Noise factor for Zero-suppression
private:
   
  ClassDef(AliFMDReconstructor, 3)  // class for the FMD reconstruction
}; 
#endif
//____________________________________________________________________
//
// Local Variables:
//   mode: C++
// End:
//
// EOF
//
Commit	Line	Data
8f1cfb0c	1	#ifndef ALIFMDRECONSTRUCTOR_H
8f1cfb0c	2	#define ALIFMDRECONSTRUCTOR_H
4347b38f	3	//
	4	// Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights
	5	// reserved.
	6	//
121a60bd	7	// See cxx source for full Copyright notice
4347b38f	8	//
121a60bd	9	// AliFMDReconstructor.h
4347b38f	10	// Task Class for making TreeR for FMD
4347b38f	11	//
121a60bd	12	//-- Authors: Evgeny Karpechev (INR) and Alla Maevskaia (INR)
4347b38f	13	// Latest changes by Christian Holm Christensen <cholm@nbi.dk>
121a60bd	14	/* $Id$ */
c2fc1258	15	/** @file AliFMDReconstructor.h
	16	@author Christian Holm Christensen <cholm@nbi.dk>
	17	@date Mon Mar 27 12:47:09 2006
	18	@brief FMD reconstruction
	19	*/
8f1cfb0c	20
42403906	21	//____________________________________________________________________
0d0e6995	22	// Header guards in the header files speeds up the compilation
	23	// considerably. Please leave them in.
	24	#ifndef ALIRECONSTRUCTOR_H
	25	# include <AliReconstructor.h>
	26	#endif
d76c31f4	27	#include "AliLog.h"
d76c31f4	28
4347b38f	29	//____________________________________________________________________
1a1fdef7	30	class TTree;
4347b38f	31	class TClonesArray;
4347b38f	32	class AliFMDDigit;
4347b38f	33	class AliRawReader;
af885e0f	34	class AliESDEvent;
8f6ee336	35	class AliESDFMD;
9684be2f	36	class TH1;
9684be2f	37
e802be3e	38
9f662337	39	/** @defgroup FMD_rec Reconstruction */
4347b38f	40	//____________________________________________________________________
c2fc1258	41	/** @brief This is a class that reconstructs AliFMDRecPoint objects from of
	42	Digits.
	43	This class reads either digits from a TClonesArray or raw data
	44	from a DDL file (or similar), and applies calibrations to get
9f662337	45	psuedo-inclusive multiplicities per strip.
c2fc1258	46
9f662337	47	@ingroup FMD_rec
9f662337	48	*/
121a60bd	49	class AliFMDReconstructor: public AliReconstructor
121a60bd	50	{
4347b38f	51	public:
9f662337	52	/** CTOR */
4347b38f	53	AliFMDReconstructor();
9f662337	54	/** DTOR */
56b1929b	55	virtual ~AliFMDReconstructor();
4347b38f	56
9f662337	57	/** Initialize the reconstructor. Here, we initialize the geometry
	58	manager, and finds the local to global transformations from the
	59	geometry. The calibration parameter manager is also
	60	initialized (meaning that the calibration parameters is read
f011bd38	61	from CDB).
9f662337	62	*/
d76c31f4	63	virtual void Init();
9f662337	64	/** Flag that we can convert raw data into digits.
9f662337	65	@return always @c true */
1a1fdef7	66	virtual Bool_t HasDigitConversion() const { return kTRUE; }
9f662337	67	/** Convert raw data read from the AliRawReader @a reader into
	68	digits. This is done using AliFMDRawReader and
	69	AliFMDAltroReader. The digits are put in the passed TTree @a
	70	digitsTree.
	71	@param reader Raw reader.
	72	@param digitsTree Tree to store read digits in. */
1a1fdef7	73	virtual void ConvertDigits(AliRawReader* reader, TTree* digitsTree) const;
9f662337	74	/** Reconstruct one event from the digits passed in @a digitsTree.
	75	The member function creates AliFMDRecPoint objects and stores
	76	them on the output tree @a clusterTree. An FMD ESD object is
	77	created in parallel.
	78	@todo Make sure we get a vertex.
	79	@param digitsTree Tree holding the digits of this event
	80	@param clusterTree Tree to store AliFMDRecPoint objects in. */
1a1fdef7	81	virtual void Reconstruct(TTree* digitsTree, TTree* clusterTree) const;
ddaa8027	82	/** Not used */
ddaa8027	83	virtual void Reconstruct(AliRawReader , TTree) const;
9f662337	84	/** Put in the ESD data, the FMD ESD data. The object created by
	85	the Reconstruct member function is copied to the ESD object.
	86	@param digitsTree Tree of digits for this event - not used
	87	@param clusterTree Tree of reconstructed points for this event
	88	- not used.
	89	@param esd ESD object to store data in.
	90	*/
1a1fdef7	91	virtual void FillESD(TTree* digitsTree, TTree* clusterTree,
af885e0f	92	AliESDEvent* esd) const;
ddaa8027	93	/** Forwards to above member function */
	94	virtual void FillESD(AliRawReader, TTree clusterTree,
	95	AliESDEvent* esd) const;
9f662337	96	/** Not used */
af885e0f	97	virtual void SetESD(AliESDEvent* esd) { fESD = esd; }
a9579262	98	/** Set the noise factor
	99	@param f Factor to use */
	100	virtual void SetNoiseFactor(Float_t f=3) { fNoiseFactor = f; }
	101	/** Set whether we should do angle correction or nor
	102	@param use If true, do angle correction */
	103	virtual void SetAngleCorrect(Bool_t use=kTRUE) { fAngleCorrect = use; }
9684be2f	104	/** Set whether we want to do diagnostics. If this is enabled, a
	105	file named @c FMD.Diag.root will be made. It contains a set of
	106	histograms for each event, filed in separate directories in the
	107	file. The histograms are
	108	@verbatim
	109	diagStep1 Read ADC vs. Noise surpressed ADC
	110	diagStep2 Noise surpressed ADC vs. calculated Energy dep.
	111	diagStep3 Energy deposition vs. angle corrected Energy dep.
	112	diagStep4 Energy deposition vs. calculated multiplicity
	113	diagAll Read ADC vs. calculated multiplicity
	114	@endverbatim
	115	@param use If true, make the diagnostics file */
	116	void SetDiagnose(Bool_t use=kTRUE) { fDiagnostics = use; }
4347b38f	117	protected:
0e73cae6	118	/** Copy CTOR
	119	@param other Object to copy from. */
	120	AliFMDReconstructor(const AliFMDReconstructor& other);
	121	/** Assignment operator
	122	@param other Object to assign from
	123	@return reference to this object */
	124	AliFMDReconstructor& operator=(const AliFMDReconstructor& other);
9684be2f	125	/** Try to get the vertex from either ESD or generator header. Sets
	126	@c fCurrentVertex to the found Z posistion of the vertex (if
	127	found), and sets the flag @c fVertexType accordingly */
	128	virtual void GetVertex() const;
9f662337	129	/** Process AliFMDDigit objects in @a digits. For each digit, find
	130	the psuedo-rapidity @f$ \eta@f$, azimuthal angle @f$ \varphi@f$,
	131	energy deposited @f$ E@f$, and psuedo-inclusive multiplicity @f$
	132	M@f$.
	133	@param digits Array of digits. */
e802be3e	134	virtual void ProcessDigits(TClonesArray* digits) const;
9f662337	135	/** Substract pedestals from raw ADC in @a digit
	136	@param digit Digit data
	137	@return Pedestal subtracted ADC count. */
4347b38f	138	virtual UShort_t SubtractPedestal(AliFMDDigit* digit) const;
9f662337	139	/** Converts number of ADC counts to energy deposited. This is
	140	done by
	141	@f[
	142	E_i = A_i g_i
	143	@f]
	144	where @f$ A_i@f$ is the pedestal subtracted ADC counts, and @f$
	145	g_i@f$ is the gain for the @f$ i^{\mbox{th}}@f$ strip.
	146	@param digit Raw data
	147	@param eta Psuedo-rapidity of digit.
	148	@param count Pedestal subtracted ADC counts
	149	@return Energy deposited @f$ E_i@f$ */
8f6ee336	150	virtual Float_t Adc2Energy(AliFMDDigit* digit, Float_t eta,
8f6ee336	151	UShort_t count) const;
9f662337	152	/** Converts an energy signal to number of particles. In this
	153	implementation, it's done by
	154	@f[
	155	M_i = E_i / E_{\mbox{MIP}}
	156	@f]
	157	where @f$ E_i@f$ is the energy deposited, and @f$
	158	E_{\mbox{MIP}}@f$ is the average energy deposited by a minimum
	159	ionizing particle
	160	@param digit Raw data
	161	@param edep Energy deposited @f$ E_i@f$
	162	@return Psuedo-inclusive multiplicity @f$ M@f$ */
8f6ee336	163	virtual Float_t Energy2Multiplicity(AliFMDDigit* digit, Float_t edep) const;
9f662337	164	/** Calculate the physical coordinates psuedo-rapidity @f$ \eta@f$,
	165	azimuthal angle @f$ \varphi@f$ of the strip corresponding to
	166	the digit @a digit. This is done by using the information
	167	obtained, and previously cached by AliFMDGeometry, from the
	168	TGeoManager.
	169	@param digit Digit.
	170	@param eta On return, psuedo-rapidity @f$ \eta@f$
	171	@param phi On return, azimuthal angle @f$ \varphi@f$ */
8f6ee336	172	virtual void PhysicalCoordinates(AliFMDDigit* digit, Float_t& eta,
8f6ee336	173	Float_t& phi) const;
42403906	174
9684be2f	175	enum Vertex_t {
	176	kNoVertex, // Got no vertex
	177	kGenVertex, // Got generator vertex
	178	kESDVertex // Got ESD vertex
	179	};
8f6ee336	180	mutable TClonesArray* fMult; // Cache of RecPoints
	181	mutable Int_t fNMult; // Number of entries in fMult
	182	mutable TTree* fTreeR; // Output tree
e802be3e	183	mutable Float_t fCurrentVertex; // Z-coordinate of primary vertex
8f6ee336	184	mutable AliESDFMD* fESDObj; // ESD output object
9684be2f	185	Float_t fNoiseFactor; // Factor of noise to check
	186	Bool_t fAngleCorrect; // Whether to angle correct
	187	mutable Vertex_t fVertexType; // What kind of vertex we got
af885e0f	188	AliESDEvent* fESD; // ESD object(?)
9684be2f	189	Bool_t fDiagnostics; // Wheter to do diagnostics
	190	TH1* fDiagStep1; // Diagnostics histogram
	191	TH1* fDiagStep2; // Diagnostics histogram
	192	TH1* fDiagStep3; // Diagnostics histogram
	193	TH1* fDiagStep4; // Diagnostics histogram
	194	TH1* fDiagAll; // Diagnostics histogram
5cf05dbb	195	mutable Bool_t fZS[3]; // Zero-suppredded?
5cf05dbb	196	mutable UShort_t fZSFactor[3]; // Noise factor for Zero-suppression
02a27b50	197	private:
d76c31f4	198
d76c31f4	199	ClassDef(AliFMDReconstructor, 3) // class for the FMD reconstruction
121a60bd	200	};
121a60bd	201	#endif
4347b38f	202	//____________________________________________________________________
4347b38f	203	//
0d0e6995	204	// Local Variables:
	205	// mode: C++
	206	// End:
	207	//
4347b38f	208	// EOF
4347b38f	209	//