/**************************************************************************
* Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
* *
* Author: The ALICE Off-line Project. *
* Contributors are mentioned in the code where appropriate. *
* *
* Permission to use, copy, modify and distribute this software and its *
* documentation strictly for non-commercial purposes is hereby granted *
* without fee, provided that the above copyright notice appears in all *
* copies and that both the copyright notice and this permission notice *
* appear in the supporting documentation. The authors make no claims *
* about the suitability of this software for any purpose. It is *
* provided "as is" without express or implied warranty. *
**************************************************************************/
/* $Id$ */
///////////////////////////////////////////////////////////////////////////////
//
// An overview of the basic philosophy of the ITS code development
// and analysis is show in the figure below.
//Begin_Html
/*
Roberto Barbera is in charge of the ITS Offline code (1999).
Roberto Barbera.
*/
//End_Html
//
// AliITS. Inner Traking System base class.
// This class contains the base procedures for the Inner Tracking System
//
//Begin_Html
/*
This show the class diagram of the different elements that are part of
the AliITS class.
*/
//End_Html
//
// Version: 0
// Written by Rene Brun, Federico Carminati, and Roberto Barbera
//
// Version: 1
// Modified and documented by Bjorn S. Nilsen
// July 11 1999
//
// Version: 2
// Modified and documented by A. Bologna
// October 18 1999
//
// AliITS is the general base class for the ITS. Also see AliDetector for
// futher information.
//
///////////////////////////////////////////////////////////////////////////////
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include
#include "AliConfig.h"
#include "AliHeader.h"
#include "AliITS.h"
#include "AliITSClusterFinderSDD.h"
#include "AliITSClusterFinderSPD.h"
#include "AliITSClusterFinderSSD.h"
#include "AliITSDetType.h"
#include "AliITSLoader.h"
#include "AliITSRawClusterSPD.h"
#include "AliITSRawClusterSDD.h"
#include "AliITSRawClusterSSD.h"
#include "AliITSRecPoint.h"
#include "AliITSdigitSPD.h"
#include "AliITSdigitSDD.h"
#include "AliITSdigitSSD.h"
#include "AliITSgeom.h"
#include "AliITShit.h"
#include "AliITSmodule.h"
#include "AliITSpList.h"
#include "AliITSresponseSDD.h"
#include "AliITSresponseSPD.h"
#include "AliITSresponseSSD.h"
#include "AliITSsegmentationSDD.h"
#include "AliITSsegmentationSPD.h"
#include "AliITSsegmentationSSD.h"
#include "AliITSsimulationSDD.h"
#include "AliITSsimulationSPD.h"
#include "AliITSsimulationSSD.h"
#include "AliMC.h"
#include "AliITSDigitizer.h"
#include "AliITSDDLRawData.h"
#include "AliRun.h"
ClassImp(AliITS)
//______________________________________________________________________
AliITS::AliITS() : AliDetector(),
fITSgeom(0),
fEuclidOut(0),
fITSmodules(0),
fOpt("All"),
fIdN(0),
fIdSens(0),
fIdName(0),
fNDetTypes(kNTYPES),
fDetTypes(0),
fSDigits(0),
fNSDigits(0),
fDtype(0),
fNdtype(0),
fCtype(0),
fNctype(0),
fRecPoints(0),
fNRecPoints(0),
fSelectedVertexer(0){
// Default initializer for ITS
// The default constructor of the AliITS class. In addition to
// creating the AliITS class it zeros the variables fIshunt (a member
// of AliDetector class), fEuclidOut, and fIdN, and zeros the pointers
// fITSpoints, fIdSens, and fIdName. The AliDetector default constructor
// is also called.
// Inputs:
// none.
// Outputs:
// none.
// Return:
// Blank ITS class.
fIshunt = 0; // not zeroed in AliDetector.
// AliITS variables.
// SetDetectors(); // default to fOpt="All". This variable not written out.
SetMarkerColor(kRed);
SelectVertexer(" ");
}
//______________________________________________________________________
AliITS::AliITS(const char *name, const char *title):AliDetector(name,title),
fITSgeom(0),
fEuclidOut(0),
fITSmodules(0),
fOpt("All"),
fIdN(0),
fIdSens(0),
fIdName(0),
fNDetTypes(kNTYPES),
fDetTypes(0),
fSDigits(0),
fNSDigits(0),
fDtype(0),
fNdtype(0),
fCtype(0),
fNctype(0),
fRecPoints(0),
fNRecPoints(0),
fSelectedVertexer(0){
// The standard Constructor for the ITS class. In addition to
// creating the AliITS class, it allocates memory for the TClonesArrays
// fHits, fSDigits, fDigits, fITSpoints, and the TObjArray of fCtype
// (clusters). It also zeros the variables
// fIshunt (a member of AliDetector class), fEuclidOut, and fIdN, and zeros
// the pointers fIdSens and fIdName. To help in displaying hits via the
// ROOT macro display.C AliITS also sets the marker color to red. The
// variables passes with this constructor, const char *name and *title,
// are used by the constructor of AliDetector class. See AliDetector
// class for a description of these parameters and its constructor
// functions.
// Inputs:
// const char *name Detector name. Should always be "ITS"
// const char *title Detector title.
// Outputs:
// none.
// Return:
// An ITS class.
fIshunt = 0; // not zeroed in AliDetector
fHits = new TClonesArray("AliITShit", 1560);//not done in AliDetector
if(gAlice->GetMCApp()) gAlice->GetMCApp()->AddHitList(fHits);// Not done in AliDetector.
fEuclidOut = 0;
fITSgeom = 0;
fITSmodules = 0;
SetDetectors(); // default to fOpt="All". This variable not written out.
fIdN = 0;
fIdName = 0;
fIdSens = 0;
fNDetTypes = kNTYPES;
fDetTypes = new TObjArray(fNDetTypes);
fSDigits = new TClonesArray("AliITSpListItem",1000);
fNSDigits = 0;
fNdtype = new Int_t[fNDetTypes];
fDtype = new TObjArray(fNDetTypes);
fCtype = new TObjArray(fNDetTypes);
fNctype = new Int_t[fNDetTypes];
fRecPoints = new TClonesArray("AliITSRecPoint",1000);
fNRecPoints = 0;
Int_t i;
for(i=0;iAddAt(new AliITSDetType(),i);
fNdtype[i] = 0;
fNctype[i] = 0;
} // end for i
SetMarkerColor(kRed);
SelectVertexer(" ");
}
//______________________________________________________________________
AliITS::~AliITS(){
// Default destructor for ITS.
// The default destructor of the AliITS class. In addition to deleting
// the AliITS class it deletes the memory pointed to by the fHits, fDigits,
// fSDigits, fCtype, fITSmodules, fITSgeom, fRecPoints, fIdSens, fIdName,
// fITSpoints, fDetType and it's contents.
// Inputs:
// none.
// Outputs:
// none.
// Return:
// none.
if (fHits) {
fHits->Delete();
delete fHits;
fHits=0;
}
if (fSDigits) {
fSDigits->Delete();
delete fSDigits;
fSDigits=0;
}
if (fDigits) {
fDigits->Delete();
delete fDigits;
fDigits=0;
}
if (fRecPoints) {
fRecPoints->Delete();
delete fRecPoints;
fRecPoints=0;
}
delete[] fIdName; // Array of TStrings
delete[] fIdSens;
if(fITSmodules) {
this->ClearModules();
delete fITSmodules;
fITSmodules = 0;
}// end if fITSmodules!=0
if(fDtype) {
fDtype->Delete();
delete fDtype;
} // end if fDtype
delete [] fNdtype;
if (fCtype) {
fCtype->Delete();
delete fCtype;
fCtype = 0;
} // end if fCtype
delete [] fNctype;
if (fDetTypes) {
fDetTypes->Delete();
delete fDetTypes;
fDetTypes = 0;
} // end if fDetTypes
if (fITSgeom) delete fITSgeom;
}
//______________________________________________________________________
AliITS::AliITS(const AliITS &source) : AliDetector(source){
// Copy constructor. This is a function which is not allowed to be
// done to the ITS. It exits with an error.
// Inputs:
// AliITS &source An AliITS class.
// Outputs:
// none.
// Return:
// none.
if(this==&source) return;
Error("Copy constructor",
"You are not allowed to make a copy of the AliITS");
exit(1);
}
//______________________________________________________________________
AliITS& AliITS::operator=(AliITS &source){
// Assignment operator. This is a function which is not allowed to be
// done to the ITS. It exits with an error.
// Inputs:
// AliITS &source An AliITS class.
// Outputs:
// none.
// Return:
// none.
if(this==&source) return *this;
Error("operator=","You are not allowed to make a copy of the AliITS");
exit(1);
return *this; //fake return
}
//______________________________________________________________________
Int_t AliITS::DistancetoPrimitive(Int_t,Int_t) const{
// Distance from mouse to ITS on the screen. Dummy routine
// A dummy routine used by the ROOT macro display.C to allow for the
// use of the mouse (pointing device) in the macro. In general this should
// never be called. If it is it returns the number 9999 for any value of
// x and y.
// Inputs:
// Int_t Dummy screen coordinate.
// Int_t Dummy screen coordinate.
// Outputs:
// none.
// Return:
// Int_t Dummy = 9999 distance to ITS.
return 9999;
}
//______________________________________________________________________
void AliITS::Init(){
// Initializer ITS after it has been built
// This routine initializes the AliITS class. It is intended to be
// called from the Init function in AliITSv?. Besides displaying a banner
// indicating that it has been called it initializes the array fIdSens
// and sets the default segmentation, response, digit and raw cluster
// classes therefore it should be called after a call to CreateGeometry.
// Inputs:
// none.
// Outputs:
// none.
// Return:
// none.
Int_t i;
SetDefaults();
// Array of TStrings
if(gMC) for(i=0;iVolId(fIdName[i]);
}
//______________________________________________________________________
void AliITS::SetDefaults(){
// sets the default segmentation, response, digit and raw cluster classes.
// Inputs:
// none.
// Outputs:
// none.
// Return:
// none.
if(fDebug) printf("%s: SetDefaults\n",ClassName());
AliITSDetType *iDetType;
//SPD
iDetType=DetType(0);
if (!iDetType->GetSegmentationModel()) {
AliITSsegmentationSPD *seg0=new AliITSsegmentationSPD(fITSgeom);
SetSegmentationModel(0,seg0);
} // end if
if (!iDetType->GetResponseModel()) {
SetResponseModel(0,new AliITSresponseSPD());
} // end if
// set digit and raw cluster classes to be used
const char *kData0=(iDetType->GetResponseModel())->DataType();
if (strstr(kData0,"real")) {
iDetType->ClassNames("AliITSdigit","AliITSRawClusterSPD");
} else iDetType->ClassNames("AliITSdigitSPD","AliITSRawClusterSPD");
// SDD
iDetType=DetType(1);
if (!iDetType->GetResponseModel()) {
SetResponseModel(1,new AliITSresponseSDD("simulated"));
} // end if
AliITSresponse *resp1=iDetType->GetResponseModel();
if (!iDetType->GetSegmentationModel()) {
AliITSsegmentationSDD *seg1=new AliITSsegmentationSDD(fITSgeom,resp1);
SetSegmentationModel(1,seg1);
} // end if
const char *kData1=(iDetType->GetResponseModel())->DataType();
const char *kopt=iDetType->GetResponseModel()->ZeroSuppOption();
if((!strstr(kopt,"2D"))&&(!strstr(kopt,"1D")) || strstr(kData1,"real") ){
iDetType->ClassNames("AliITSdigit","AliITSRawClusterSDD");
} else iDetType->ClassNames("AliITSdigitSDD","AliITSRawClusterSDD");
// SSD
iDetType=DetType(2);
if (!iDetType->GetSegmentationModel()) {
AliITSsegmentationSSD *seg2=new AliITSsegmentationSSD(fITSgeom);
SetSegmentationModel(2,seg2);
} // end if
if (!iDetType->GetResponseModel()) {
SetResponseModel(2,new AliITSresponseSSD("simulated"));
} // end if
const char *kData2=(iDetType->GetResponseModel())->DataType();
if (strstr(kData2,"real")) {
iDetType->ClassNames("AliITSdigit","AliITSRawClusterSSD");
} else iDetType->ClassNames("AliITSdigitSSD","AliITSRawClusterSSD");
if (kNTYPES>3) {
Warning("SetDefaults",
"Only the three basic detector types are initialized!");
} // end if
}
//______________________________________________________________________
void AliITS::SetDefaultSimulation(){
// sets the default simulation.
// Inputs:
// none.
// Outputs:
// none.
// Return:
// none.
AliITSDetType *iDetType;
AliITSsimulation *sim;
iDetType=DetType(0);
sim = iDetType->GetSimulationModel();
if (!sim) {
AliITSsegmentation *seg0=
(AliITSsegmentation*)iDetType->GetSegmentationModel();
AliITSresponse *res0 = (AliITSresponse*)iDetType->GetResponseModel();
AliITSsimulationSPD *sim0=new AliITSsimulationSPD(seg0,res0);
SetSimulationModel(0,sim0);
}else{ // simulation exists, make sure it is set up properly.
((AliITSsimulationSPD*)sim)->Init(
(AliITSsegmentationSPD*) iDetType->GetSegmentationModel(),
(AliITSresponseSPD*) iDetType->GetResponseModel());
// if(sim->GetResponseModel()==0) sim->SetResponseModel(
// (AliITSresponse*)iDetType->GetResponseModel());
// if(sim->GetSegmentationModel()==0) sim->SetSegmentationModel(
// (AliITSsegmentation*)iDetType->GetSegmentationModel());
} // end if
iDetType=DetType(1);
sim = iDetType->GetSimulationModel();
if (!sim) {
AliITSsegmentation *seg1=
(AliITSsegmentation*)iDetType->GetSegmentationModel();
AliITSresponse *res1 = (AliITSresponse*)iDetType->GetResponseModel();
AliITSsimulationSDD *sim1=new AliITSsimulationSDD(seg1,res1);
SetSimulationModel(1,sim1);
}else{ // simulation exists, make sure it is set up properly.
((AliITSsimulationSDD*)sim)->Init(
(AliITSsegmentationSDD*) iDetType->GetSegmentationModel(),
(AliITSresponseSDD*) iDetType->GetResponseModel());
// if(sim->GetResponseModel()==0) sim->SetResponseModel(
// (AliITSresponse*)iDetType->GetResponseModel());
// if(sim->GetSegmentationModel()==0) sim->SetSegmentationModel(
// (AliITSsegmentation*)iDetType->GetSegmentationModel());
} //end if
iDetType=DetType(2);
sim = iDetType->GetSimulationModel();
if (!sim) {
AliITSsegmentation *seg2=
(AliITSsegmentation*)iDetType->GetSegmentationModel();
AliITSresponse *res2 = (AliITSresponse*)iDetType->GetResponseModel();
AliITSsimulationSSD *sim2=new AliITSsimulationSSD(seg2,res2);
SetSimulationModel(2,sim2);
}else{ // simulation exists, make sure it is set up properly.
((AliITSsimulationSSD*)sim)->Init(
(AliITSsegmentationSSD*) iDetType->GetSegmentationModel(),
(AliITSresponseSSD*) iDetType->GetResponseModel());
// if(sim->GetResponseModel()==0) sim->SetResponseModel(
// (AliITSresponse*)iDetType->GetResponseModel());
// if(sim->GetSegmentationModel()==0) sim->SetSegmentationModel(
// (AliITSsegmentation*)iDetType->GetSegmentationModel());
} // end if
}
//______________________________________________________________________
void AliITS::SetDefaultClusterFinders(){
// Sets the default cluster finders. Used in finding RecPoints.
// Inputs:
// none.
// Outputs:
// none.
// Return:
// none.
MakeTreeC();
AliITSDetType *iDetType;
// SPD
iDetType=DetType(0);
if (!iDetType->GetReconstructionModel()) {
AliITSsegmentation *seg0 =
(AliITSsegmentation*)iDetType->GetSegmentationModel();
TClonesArray *dig0=DigitsAddress(0);
TClonesArray *recp0=ClustersAddress(0);
AliITSClusterFinderSPD *rec0 = new AliITSClusterFinderSPD(seg0,dig0,
recp0);
SetReconstructionModel(0,rec0);
} // end if
// SDD
iDetType=DetType(1);
if (!iDetType->GetReconstructionModel()) {
AliITSsegmentation *seg1 =
(AliITSsegmentation*)iDetType->GetSegmentationModel();
AliITSresponse *res1 = (AliITSresponse*)iDetType->GetResponseModel();
TClonesArray *dig1=DigitsAddress(1);
TClonesArray *recp1=ClustersAddress(1);
AliITSClusterFinderSDD *rec1 =
new AliITSClusterFinderSDD(seg1,res1,dig1,recp1);
SetReconstructionModel(1,rec1);
} // end if
// SSD
iDetType=DetType(2);
if (!iDetType->GetReconstructionModel()) {
AliITSsegmentation *seg2=
(AliITSsegmentation*)iDetType->GetSegmentationModel();
TClonesArray *dig2=DigitsAddress(2);
AliITSClusterFinderSSD *rec2= new AliITSClusterFinderSSD(seg2,dig2);
SetReconstructionModel(2,rec2);
} // end if
}
//______________________________________________________________________
void AliITS::MakeBranch(Option_t* option){
// Creates Tree branches for the ITS.
// Inputs:
// Option_t *option String of Tree types S,D, and/or R.
// const char *file String of the file name where these branches
// are to be stored. If blank then these branches
// are written to the same tree as the Hits were
// read from.
// Outputs:
// none.
// Return:
// none.
Bool_t cH = (strstr(option,"H")!=0);
Bool_t cS = (strstr(option,"S")!=0);
Bool_t cD = (strstr(option,"D")!=0);
Bool_t cR = (strstr(option,"R")!=0);
Bool_t cRF = (strstr(option,"RF")!=0);
if(cRF)cR = kFALSE;
if(cH && (fHits == 0x0)) fHits = new TClonesArray("AliITShit", 1560);
AliDetector::MakeBranch(option);
if(cS) MakeBranchS(0);
if(cD) MakeBranchD(0);
if(cR) MakeBranchR(0);
if(cRF) MakeBranchRF(0);
}
//______________________________________________________________________
void AliITS::SetTreeAddress(){
// Set branch address for the Trees.
// Inputs:
// none.
// Outputs:
// none.
// Return:
// none.
TTree *treeS = fLoader->TreeS();
TTree *treeD = fLoader->TreeD();
TTree *treeR = fLoader->TreeR();
if (fLoader->TreeH() && (fHits == 0x0)) fHits = new TClonesArray("AliITShit", 1560);
AliDetector::SetTreeAddress();
SetTreeAddressS(treeS);
SetTreeAddressD(treeD);
SetTreeAddressR(treeR);
}
//______________________________________________________________________
AliITSDetType* AliITS::DetType(Int_t id){
// Return pointer to id detector type.
// Inputs:
// Int_t id detector id number.
// Outputs:
// none.
// Return:
// returned, a pointer to a AliITSDetType.
return ((AliITSDetType*) fDetTypes->At(id));
}
//______________________________________________________________________
void AliITS::SetResponseModel(Int_t id, AliITSresponse *response){
// Set the response model for the id detector type.
// Inputs:
// Int_t id detector id number.
// AliITSresponse* a pointer containing an instance of AliITSresponse
// to be stored/owned b y AliITSDetType.
// Outputs:
// none.
// Return:
// none.
((AliITSDetType*) fDetTypes->At(id))->ResponseModel(response);
}
//______________________________________________________________________
void AliITS::SetSegmentationModel(Int_t id, AliITSsegmentation *seg){
// Set the segmentation model for the id detector type.
// Inputs:
// Int_t id detector id number.
// AliITSsegmentation* a pointer containing an instance of
// AliITSsegmentation to be stored/owned b y
// AliITSDetType.
// Outputs:
// none.
// Return:
// none.
((AliITSDetType*) fDetTypes->At(id))->SegmentationModel(seg);
}
//______________________________________________________________________
void AliITS::SetSimulationModel(Int_t id, AliITSsimulation *sim){
// Set the simulation model for the id detector type.
// Inputs:
// Int_t id detector id number.
// AliITSresponse* a pointer containing an instance of AliITSresponse
// to be stored/owned b y AliITSDetType.
// Outputs:
// none.
// Return:
// none.
((AliITSDetType*) fDetTypes->At(id))->SimulationModel(sim);
}
//______________________________________________________________________
void AliITS::SetReconstructionModel(Int_t id, AliITSClusterFinder *reconst){
// Set the cluster finder model for the id detector type.
// Inputs:
// Int_t id detector id number.
// AliITSClusterFinder* a pointer containing an instance of
// AliITSClusterFinder to be stored/owned b y
// AliITSDetType.
// Outputs:
// none.
// Return:
// none.
((AliITSDetType*) fDetTypes->At(id))->ReconstructionModel(reconst);
}
//______________________________________________________________________
void AliITS::SetClasses(Int_t id, const char *digit, const char *cluster){
// Set the digit and cluster classes name to be used for the id detector
// type.
// Inputs:
// Int_t id detector id number.
// const char *digit Digit class name for detector id.
// const char *cluster Cluster class name for detector id.
// Outputs:
// none.
// Return:
// none.
((AliITSDetType*) fDetTypes->At(id))->ClassNames(digit,cluster);
}
//______________________________________________________________________
void AliITS::AddHit(Int_t track, Int_t *vol, Float_t *hits){
// Add an ITS hit
// The function to add information to the AliITShit class. See the
// AliITShit class for a full description. This function allocates the
// necessary new space for the hit information and passes the variable
// track, and the pointers *vol and *hits to the AliITShit constructor
// function.
// Inputs:
// Int_t track Track number which produced this hit.
// Int_t *vol Array of Integer Hit information. See AliITShit.h
// Float_t *hits Array of Floating Hit information. see AliITShit.h
// Outputs:
// none.
// Return:
// none.
TClonesArray &lhits = *fHits;
new(lhits[fNhits++]) AliITShit(fIshunt,track,vol,hits);
}
//______________________________________________________________________
void AliITS::InitModules(Int_t size,Int_t &nmodules){
// Initialize the modules array.
// Inputs:
// Int_t size Size of array of the number of modules to be
// created. If size <=0 then the number of modules
// is gotten from AliITSgeom class kept in fITSgeom.
// Outputs:
// Int_t &nmodules The number of modules existing.
// Return:
// none.
if(fITSmodules){
fITSmodules->Delete();
delete fITSmodules;
} // end fir fITSmoudles
Int_t nl,indexMAX,index;
if(size<=0){ // default to using data stored in AliITSgeom
if(fITSgeom==0) {
Error("InitModules","fITSgeom not defined");
return;
} // end if fITSgeom==0
nl = fITSgeom->GetNlayers();
indexMAX = fITSgeom->GetModuleIndex(nl,fITSgeom->GetNladders(nl),
fITSgeom->GetNdetectors(nl))+1;
nmodules = indexMAX;
fITSmodules = new TObjArray(indexMAX);
for(index=0;indexAddAt( new AliITSmodule(index),index);
} // end for index
}else{
fITSmodules = new TObjArray(size);
for(index=0;indexAddAt( new AliITSmodule(index),index);
} // end for index
nmodules = size;
} // end i size<=0
}
//______________________________________________________________________
void AliITS::FillModules(Int_t evnt,Int_t bgrev,Int_t nmodules,
Option_t *option, const char *filename){
// fill the modules with the sorted by module hits; add hits from
// background if option=Add.
// Inputs:
// Int_t evnt Event to be processed.
// Int_t bgrev Background Hit tree number.
// Int_t nmodules Not used.
// Option_t *option String indicating if merging hits or not. To
// merge hits set equal to "Add". Otherwise no
// background hits are considered.
// Test_t *filename File name containing the background hits..
// Outputs:
// none.
// Return:
// none.
static TTree *trH1; //Tree with background hits
static Bool_t first=kTRUE;
static TFile *file;
const char *addBgr = strstr(option,"Add");
evnt = nmodules; // Dummy use of variables to remove warnings
if (addBgr ) {
if(first) {
file=new TFile(filename);
} // end if first
first=kFALSE;
file->cd();
file->ls();
// Get Hits Tree header from file
if(trH1) delete trH1;
trH1=0;
char treeName[20];
sprintf(treeName,"TreeH%d",bgrev);
trH1 = (TTree*)gDirectory->Get(treeName);
if (!trH1) {
Error("FillModules","cannot find Hits Tree for event:%d",bgrev);
} // end if !trH1
// Set branch addresses
} // end if addBgr
FillModules(fLoader->TreeH(),0); // fill from this file's tree.
if (addBgr ) {
FillModules(trH1,10000000); // Default mask 10M.
TTree *fAli=fLoader->GetRunLoader()->TreeK();
TFile *fileAli=0;
if (fAli) fileAli =fAli->GetCurrentFile();
fileAli->cd();
} // end if add
}
//______________________________________________________________________
void AliITS::FillModules(TTree *treeH, Int_t mask) {
// fill the modules with the sorted by module hits;
// can be called many times to do a merging
// Inputs:
// TTree *treeH The tree containing the hits to be copied into
// the modules.
// Int_t mask The track number mask to indecate which file
// this hits came from.
// Outputs:
// none.
// Return:
// none.
if (treeH == 0x0)
{
Error("FillModules","Tree is NULL");
}
Int_t lay,lad,det,index;
AliITShit *itsHit=0;
AliITSmodule *mod=0;
char branchname[20];
sprintf(branchname,"%s",GetName());
TBranch *branch = treeH->GetBranch(branchname);
if (!branch) {
Error("FillModules","%s branch in TreeH not found",branchname);
return;
} // end if !branch
branch->SetAddress(&fHits);
Int_t nTracks =(Int_t) treeH->GetEntries();
Int_t iPrimTrack,h;
for(iPrimTrack=0; iPrimTrackGetEvent(iPrimTrack);
if (nBytes <= 0) continue;
Int_t nHits = fHits->GetEntriesFast();
for(h=0; hUncheckedAt(h);
itsHit->GetDetectorID(lay,lad,det);
if (fITSgeom) {
index = fITSgeom->GetModuleIndex(lay,lad,det);
} else {
index=det-1; // This should not be used.
} // end if [You must have fITSgeom for this to work!]
mod = GetModule(index);
itsHit->SetTrack(itsHit->GetTrack()+mask); // Set track mask.
mod->AddHit(itsHit,iPrimTrack,h);
} // end loop over hits
} // end loop over tracks
}
//______________________________________________________________________
void AliITS::ClearModules(){
// Clear the modules TObjArray.
// Inputs:
// none.
// Outputs:
// none.
if(fITSmodules) fITSmodules->Delete();
}
//______________________________________________________________________
void AliITS::MakeBranchS(const char *fl){
// Creates Tree Branch for the ITS summable digits.
// Inputs:
// cont char *fl File name where SDigits branch is to be written
// to. If blank it write the SDigits to the same
// file in which the Hits were found.
// Outputs:
// none.
// Return:
// none.
Int_t buffersize = 4000;
char branchname[30];
// only one branch for SDigits.
sprintf(branchname,"%s",GetName());
if(fLoader->TreeS()){
if (fSDigits == 0x0) fSDigits = new TClonesArray("AliITSpListItem",1000);
MakeBranchInTree(fLoader->TreeS(),branchname,&fSDigits,buffersize,fl);
} // end if
}
//______________________________________________________________________
void AliITS::SetTreeAddressS(TTree *treeS){
// Set branch address for the ITS summable digits Trees.
// Inputs:
// TTree *treeS Tree containing the SDigits.
// Outputs:
// none.
// Return:
// none.
char branchname[30];
if(!treeS) return;
if (fSDigits == 0x0) fSDigits = new TClonesArray("AliITSpListItem",1000);
TBranch *branch;
sprintf(branchname,"%s",GetName());
branch = treeS->GetBranch(branchname);
if (branch) branch->SetAddress(&fSDigits);
}
//______________________________________________________________________
void AliITS::MakeBranchInTreeD(TTree *treeD,const char *file){
// Creates Tree branches for the ITS.
// Inputs:
// TTree *treeD Pointer to the Digits Tree.
// cont char *file File name where Digits branch is to be written
// to. If blank it write the SDigits to the same
// file in which the Hits were found.
// Outputs:
// none.
// Return:
// none.
Int_t buffersize = 4000;
char branchname[30];
sprintf(branchname,"%s",GetName());
// one branch for digits per type of detector
const char *det[3] = {"SPD","SDD","SSD"};
char digclass[40];
char clclass[40];
Int_t i;
for (i=0; iGetClassNames(digclass,clclass);
// digits
if (fDtype == 0x0) fDtype = new TObjArray(fNDetTypes);
if(!(fDtype->At(i))) fDtype->AddAt(new TClonesArray(digclass,1000),i);
else ResetDigits(i);
} // end for i
for (i=0; iGetClassNames(digclass,clclass);
// digits
if (fDtype == 0x0) fDtype = new TObjArray(fNDetTypes);
if(!(fDtype->At(i))) fDtype->AddAt(new TClonesArray(digclass,1000),i);
else ResetDigits(i);
if (kNTYPES==3) sprintf(branchname,"%sDigits%s",GetName(),det[i]);
else sprintf(branchname,"%sDigits%d",GetName(),i+1);
if (fDtype) {
branch = treeD->GetBranch(branchname);
if (branch) branch->SetAddress(&((*fDtype)[i]));
} // end if fDtype
} // end for i
}
//______________________________________________________________________
void AliITS::Hits2SDigits(){
// Standard Hits to summable Digits function.
// Inputs:
// none.
// Outputs:
// none.
// return; // Using Hits in place of the larger sDigits.
fLoader->LoadHits("read");
fLoader->LoadSDigits("recreate");
AliRunLoader* rl = fLoader->GetRunLoader();
for (Int_t iEvent = 0; iEvent < rl->GetNumberOfEvents(); iEvent++) {
// Do the Hits to Digits operation. Use Standard input values.
// Event number from file, no background hit merging , use size from
// AliITSgeom class, option="All", input from this file only.
rl->GetEvent(iEvent);
if (!fLoader->TreeS()) fLoader->MakeTree("S");
MakeBranch("S");
SetTreeAddress();
HitsToSDigits(iEvent,0,-1," ",fOpt," ");
}
fLoader->UnloadHits();
fLoader->UnloadSDigits();
}
//______________________________________________________________________
void AliITS::Hits2PreDigits(){
// Standard Hits to summable Digits function.
// Inputs:
// none.
// Outputs:
// none.
AliHeader *header=fLoader->GetRunLoader()->GetHeader(); // Get event number from this file.
// Do the Hits to Digits operation. Use Standard input values.
// Event number from file, no background hit merging , use size from
// AliITSgeom class, option="All", input from this file only.
HitsToPreDigits(header->GetEvent(),0,-1," ",fOpt," ");
}
//______________________________________________________________________
AliDigitizer* AliITS::CreateDigitizer(AliRunDigitizer* manager) const
{
return new AliITSDigitizer(manager);
}
//______________________________________________________________________
void AliITS::SDigitsToDigits(Option_t *opt){
// Standard Summable digits to Digits function.
// Inputs:
// none.
// Outputs:
// none.
char name[20] = {0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0};
if(!GetITSgeom()) return; // need transformations to do digitization.
AliITSgeom *geom = GetITSgeom();
const char *all = strstr(opt,"All");
const char *det[3] = {strstr(opt,"SPD"),strstr(opt,"SDD"),
strstr(opt,"SSD")};
if( !det[0] && !det[1] && !det[2] ) all = "All";
else all = 0;
static Bool_t setDef=kTRUE;
if (setDef) SetDefaultSimulation();
setDef=kFALSE;
AliITSsimulation *sim = 0;
AliITSDetType *iDetType = 0;
TTree *trees = fLoader->TreeS();
if( !(trees && this->GetSDigits()) ){
Error("SDigits2Digits","Error: No trees or SDigits. Returning.");
return;
} // end if
sprintf( name, "%s", this->GetName() );
TBranch *brchSDigits = trees->GetBranch( name );
Int_t id,module;
for(module=0;moduleGetIndexMax();module++){
id = geom->GetModuleType(module);
if (!all && !det[id]) continue;
iDetType = DetType(id);
sim = (AliITSsimulation*)iDetType->GetSimulationModel();
if (!sim) {
Error("SDigit2Digits","The simulation class was not "
"instanciated for module %d type %s!",module,
geom->GetModuleTypeName(module));
exit(1);
} // end if !sim
sim->InitSimulationModule(module,gAlice->GetEvNumber());
//
// add summable digits to module
this->GetSDigits()->Clear();
brchSDigits->GetEvent(module);
sim->AddSDigitsToModule(GetSDigits(),0);
//
// Digitise current module sum(SDigits)->Digits
sim->FinishSDigitiseModule();
// fills all branches - wasted disk space
fLoader->TreeD()->Fill();
this->ResetDigits();
} // end for module
fLoader->TreeD()->GetEntries();
fLoader->TreeD()->AutoSave();
// reset tree
fLoader->TreeD()->Reset();
}
//______________________________________________________________________
void AliITS::Hits2Digits(){
// Standard Hits to Digits function.
// Inputs:
// none.
// Outputs:
// none.
fLoader->LoadHits("read");
fLoader->LoadDigits("recreate");
AliRunLoader* rl = fLoader->GetRunLoader();
for (Int_t iEvent = 0; iEvent < rl->GetNumberOfEvents(); iEvent++) {
// Do the Hits to Digits operation. Use Standard input values.
// Event number from file, no background hit merging , use size from
// AliITSgeom class, option="All", input from this file only.
rl->GetEvent(iEvent);
if (!fLoader->TreeD()) fLoader->MakeTree("D");
MakeBranch("D");
SetTreeAddress();
HitsToDigits(iEvent,0,-1," ",fOpt," ");
}
fLoader->UnloadHits();
fLoader->UnloadDigits();
}
//______________________________________________________________________
void AliITS::HitsToSDigits(Int_t evNumber,Int_t bgrev,Int_t size,
Option_t *option, Option_t *opt, const char *filename){
// keep galice.root for signal and name differently the file for
// background when add! otherwise the track info for signal will be lost !
// the condition below will disappear when the geom class will be
// initialized for all versions - for the moment it is only for v5 !
// 7 is the SDD beam test version. Dummy routine. Hits are ITS's Summable
// Digits.
// Inputs:
// Int_t evnt Event to be processed.
// Int_t bgrev Background Hit tree number.
// Int_t nmodules Not used.
// Option_t *option String indicating if merging hits or not. To
// merge hits set equal to "Add". Otherwise no
// background hits are considered.
// Test_t *filename File name containing the background hits..
// Outputs:
// none.
// Return:
// none.
// return; // using Hits instead of the larger sdigits.
HitsToPreDigits(evNumber,bgrev,size,option,opt,filename);
}
//______________________________________________________________________
void AliITS::HitsToPreDigits(Int_t evNumber,Int_t bgrev,Int_t size,
Option_t *option, Option_t *opt, const char *filename){
// Keep galice.root for signal and name differently the file for
// background when add! otherwise the track info for signal will be lost !
// the condition below will disappear when the geom class will be
// initialized for all versions - for the moment it is only for v5 !
// 7 is the SDD beam test version.
// Inputs:
// Int_t evnt Event to be processed.
// Int_t bgrev Background Hit tree number.
// Int_t nmodules Not used.
// Option_t *option String indicating if merging hits or not. To
// merge hits set equal to "Add". Otherwise no
// background hits are considered.
// Test_t *filename File name containing the background hits..
// Outputs:
// none.
// Return:
// none.
if(!GetITSgeom()) return; // need transformations to do digitization.
AliITSgeom *geom = GetITSgeom();
const char *all = strstr(opt,"All");
const char *det[3] = {strstr(opt,"SPD"),strstr(opt,"SDD"),
strstr(opt,"SSD")};
static Bool_t setDef=kTRUE;
if (setDef) SetDefaultSimulation();
setDef=kFALSE;
Int_t nmodules;
InitModules(size,nmodules);
FillModules(evNumber,bgrev,nmodules,option,filename);
AliITSsimulation *sim = 0;
AliITSDetType *iDetType = 0;
AliITSmodule *mod = 0;
Int_t id,module;
for(module=0;moduleGetIndexMax();module++){
id = geom->GetModuleType(module);
if (!all && !det[id]) continue;
iDetType = DetType(id);
sim = (AliITSsimulation*)iDetType->GetSimulationModel();
if (!sim) {
Error("HitsToSDigits","The simulation class was not "
"instanciated for module %d type %s!",module,
geom->GetModuleTypeName(module));
exit(1);
} // end if !sim
mod = (AliITSmodule *)fITSmodules->At(module);
sim->SDigitiseModule(mod,module,evNumber);
// fills all branches - wasted disk space
fLoader->TreeS()->Fill();
ResetSDigits();
} // end for module
ClearModules();
fLoader->TreeS()->GetEntries();
fLoader->TreeS()->AutoSave();
fLoader->WriteSDigits("OVERWRITE");
// reset tree
fLoader->TreeS()->Reset();
}
//______________________________________________________________________
void AliITS::HitsToDigits(Int_t evNumber,Int_t bgrev,Int_t size,
Option_t *option, Option_t *opt, const char *filename){
// Keep galice.root for signal and name differently the file for
// background when add! otherwise the track info for signal will be lost !
// the condition below will disappear when the geom class will be
// initialized for all versions - for the moment it is only for v5 !
// 7 is the SDD beam test version.
// Inputs:
// Int_t evnt Event to be processed.
// Int_t bgrev Background Hit tree number.
// Int_t nmodules Not used.
// Option_t *option String indicating if merging hits or not. To
// merge hits set equal to "Add". Otherwise no
// background hits are considered.
// Test_t *filename File name containing the background hits..
// Outputs:
// none.
// Return:
// none.
if(!GetITSgeom()) return; // need transformations to do digitization.
AliITSgeom *geom = GetITSgeom();
const char *all = strstr(opt,"All");
const char *det[3] = {strstr(opt,"SPD"),strstr(opt,"SDD"),
strstr(opt,"SSD")};
static Bool_t setDef=kTRUE;
if (setDef) SetDefaultSimulation();
setDef=kFALSE;
Int_t nmodules;
InitModules(size,nmodules);
FillModules(evNumber,bgrev,nmodules,option,filename);
AliITSsimulation *sim = 0;
AliITSDetType *iDetType = 0;
AliITSmodule *mod = 0;
Int_t id,module;
for(module=0;moduleGetIndexMax();module++){
id = geom->GetModuleType(module);
if (!all && !det[id]) continue;
iDetType = DetType(id);
sim = (AliITSsimulation*)iDetType->GetSimulationModel();
if (!sim) {
Error("HitsToDigits","The simulation class was not "
"instanciated for module %d type %s!",module,
geom->GetModuleTypeName(module));
exit(1);
} // end if !sim
mod = (AliITSmodule *)fITSmodules->At(module);
sim->DigitiseModule(mod,module,evNumber);
// fills all branches - wasted disk space
fLoader->TreeD()->Fill();
ResetDigits();
} // end for module
ClearModules();
fLoader->TreeD()->GetEntries();
fLoader->TreeD()->AutoSave();
// reset tree
fLoader->TreeD()->Reset();
}
//______________________________________________________________________
void AliITS::ResetSDigits(){
// Reset the Summable Digits array.
// Inputs:
// none.
// Outputs:
// none.
if (fSDigits) fSDigits->Clear();
fNSDigits = 0;
}
//______________________________________________________________________
void AliITS::ResetDigits(){
// Reset number of digits and the digits array for the ITS detector.
// Inputs:
// none.
// Outputs:
// none.
if (!fDtype) return;
Int_t i;
for (i=0;iAt(i)) ((TClonesArray*)fDtype->At(i))->Clear();
if (fNdtype) fNdtype[i]=0;
} // end for i
}
//______________________________________________________________________
void AliITS::ResetDigits(Int_t i){
// Reset number of digits and the digits array for this branch.
// Inputs:
// none.
// Outputs:
// none.
if (fDtype->At(i)) ((TClonesArray*)fDtype->At(i))->Clear();
if (fNdtype) fNdtype[i]=0;
}
//______________________________________________________________________
void AliITS::AddSumDigit(AliITSpListItem &sdig){
// Adds the a module full of summable digits to the summable digits tree.
// Inputs:
// AliITSpListItem &sdig SDigit to be added to SDigits tree.
// Outputs:
// none.
// Return:
// none.
TClonesArray &lsdig = *fSDigits;
new(lsdig[fNSDigits++]) AliITSpListItem(sdig);
}
//______________________________________________________________________
void AliITS::AddRealDigit(Int_t id, Int_t *digits){
// Add a real digit - as coming from data.
// Inputs:
// Int_t id Detector type number.
// Int_t *digits Integer array containing the digits info. See
// AliITSdigit.h
// Outputs:
// none.
// Return:
// none.
TClonesArray &ldigits = *((TClonesArray*)fDtype->At(id));
new(ldigits[fNdtype[id]++]) AliITSdigit(digits);
}
//______________________________________________________________________
void AliITS::AddSimDigit(Int_t id, AliITSdigit *d){
// Add a simulated digit.
// Inputs:
// Int_t id Detector type number.
// AliITSdigit *d Digit to be added to the Digits Tree. See
// AliITSdigit.h
// Outputs:
// none.
// Return:
// none.
TClonesArray &ldigits = *((TClonesArray*)fDtype->At(id));
switch(id){
case 0:
new(ldigits[fNdtype[id]++]) AliITSdigitSPD(*((AliITSdigitSPD*)d));
break;
case 1:
new(ldigits[fNdtype[id]++]) AliITSdigitSDD(*((AliITSdigitSDD*)d));
break;
case 2:
new(ldigits[fNdtype[id]++]) AliITSdigitSSD(*((AliITSdigitSSD*)d));
break;
} // end switch id
}
//______________________________________________________________________
void AliITS::AddSimDigit(Int_t id,Float_t phys,Int_t *digits,Int_t *tracks,
Int_t *hits,Float_t *charges){
// Add a simulated digit to the list.
// Inputs:
// Int_t id Detector type number.
// Float_t phys Physics indicator. See AliITSdigits.h
// Int_t *digits Integer array containing the digits info. See
// AliITSdigit.h
// Int_t *tracks Integer array [AliITSdigitS?D::GetNTracks()]
// containing the track numbers that contributed to
// this digit.
// Int_t *hits Integer array [AliITSdigitS?D::GetNTracks()]
// containing the hit numbers, from AliITSmodule, that
// contributed to this digit.
// Float_t *charge Floating point array of the signals contributed
// to this digit by each track.
// Outputs:
// none.
// Return:
// none.
TClonesArray &ldigits = *((TClonesArray*)fDtype->At(id));
AliITSresponseSDD *resp = 0;
switch(id){
case 0:
new(ldigits[fNdtype[id]++]) AliITSdigitSPD(digits,tracks,hits);
break;
case 1:
resp = (AliITSresponseSDD*)DetType(1)->GetResponseModel();
new(ldigits[fNdtype[id]++]) AliITSdigitSDD(phys,digits,tracks,
hits,charges,resp);
break;
case 2:
new(ldigits[fNdtype[id]++]) AliITSdigitSSD(digits,tracks,hits);
break;
} // end switch id
}
//______________________________________________________________________
void AliITS::Digits2Raw()
{
// convert digits of the current event to raw data
fLoader->LoadDigits();
TTree* digits = fLoader->TreeD();
if (!digits) {
Error("Digits2Raw", "no digits tree");
return;
}
SetTreeAddressD(digits);
AliITSDDLRawData rawWriter;
//Verbose level
// 0: Silent
// 1: cout messages
// 2: txt files with digits
//BE CAREFUL, verbose level 2 MUST be used only for debugging and
//it is highly suggested to use this mode only for debugging digits files
//reasonably small, because otherwise the size of the txt files can reach
//quickly several MB wasting time and disk space.
rawWriter.SetVerbose(0);
//SILICON PIXEL DETECTOR
Info("Digits2Raw", "Formatting raw data for SPD");
rawWriter.RawDataSPD(digits->GetBranch("ITSDigitsSPD"));
//SILICON DRIFT DETECTOR
Info("Digits2Raw", "Formatting raw data for SDD");
rawWriter.RawDataSDD(digits->GetBranch("ITSDigitsSDD"));
//SILICON STRIP DETECTOR
Info("Digits2Raw", "Formatting raw data for SSD");
rawWriter.RawDataSSD(digits->GetBranch("ITSDigitsSSD"));
fLoader->UnloadDigits();
}
//______________________________________________________________________
void AliITS::MakeTreeC(Option_t *option){
// Create a separate tree to store the clusters.
// Inputs:
// Option_t *option string which must contain "C" otherwise
// no Cluster Tree is created.
// Outputs:
// none.
// Return:
// none.
AliITSLoader *pITSLoader = (AliITSLoader*)fLoader;
if (pITSLoader == 0x0) {
Error("MakeTreeC","fLoader == 0x0 option=%s",option);
return;
}
if (pITSLoader->TreeC() == 0x0) pITSLoader->MakeTree("C");
MakeBranchC();
}
void AliITS::MakeBranchC()
{
//Makes barnches in treeC
AliITSLoader *pITSLoader = (AliITSLoader*)fLoader;
if (pITSLoader == 0x0)
{
Error("MakeTreeC","fLoader == 0x0");
return;
}
TTree * lTC = pITSLoader->TreeC();
if (lTC == 0x0)
{
Error("MakeTreeC","Can not get TreeC from Loader");
return;
}
Int_t buffersize = 4000;
char branchname[30];
const char *det[3] = {"SPD","SDD","SSD"};
char digclass[40];
char clclass[40];
// one branch for Clusters per type of detector
Int_t i;
for (i=0; iGetClassNames(digclass,clclass);
// clusters
if (fCtype == 0x0) fCtype = new TObjArray(fNDetTypes);
if(!ClustersAddress(i))
{
fCtype->AddAt(new TClonesArray(clclass,1000),i);
}
if (kNTYPES==3) sprintf(branchname,"%sClusters%s",GetName(),det[i]);
else sprintf(branchname,"%sClusters%d",GetName(),i+1);
if (fCtype && lTC)
{
if (lTC->GetBranch(branchname))
{
Warning("MakeBranchC","Branch %s alread exists in TreeC",branchname);
}
else
{
Info("MakeBranchC","Creating branch %s in TreeC",branchname);
lTC->Branch(branchname,&((*fCtype)[i]), buffersize);
}
} // end if fCtype && lTC
} // end for i
}
//______________________________________________________________________
void AliITS::GetTreeC(Int_t event){
// Get the clusters tree for this event and set the branch address.
// Inputs:
// Int_t event Event number for the cluster tree.
// Outputs:
// none.
// Return:
// none.
char branchname[30];
const char *det[3] = {"SPD","SDD","SSD"};
AliITSLoader *pITSLoader = (AliITSLoader*)fLoader;
TTree * lTC = pITSLoader->TreeC();
ResetClusters();
if (lTC) {
pITSLoader->CleanRawClusters();
} // end if TreeC()
TBranch *branch;
if (lTC) {
Int_t i;
char digclass[40];
char clclass[40];
for (i=0; iGetClassNames(digclass,clclass);
// clusters
if (fCtype == 0x0) fCtype = new TObjArray(fNDetTypes);
if(!fCtype->At(i)) fCtype->AddAt(new TClonesArray(clclass,1000),i);
if(kNTYPES==3) sprintf(branchname,"%sClusters%s",GetName(),det[i]);
else sprintf(branchname,"%sClusters%d",GetName(),i+1);
if (fCtype) {
branch = lTC->GetBranch(branchname);
if (branch) branch->SetAddress(&((*fCtype)[i]));
} // end if fCtype
} // end for i
} else {
Error("GetTreeC","cannot find Clusters Tree for event:%d",event);
} // end if lTC
}
//______________________________________________________________________
void AliITS::AddCluster(Int_t id, AliITSRawCluster *c){
// Add a cluster to the list.
// Inputs:
// Int_t id Detector type number.
// AliITSRawCluster *c Cluster class to be added to the tree of
// clusters.
// Outputs:
// none.
// Return:
// none.
TClonesArray &lc = *((TClonesArray*)fCtype->At(id));
switch(id){
case 0:
new(lc[fNctype[id]++]) AliITSRawClusterSPD(*((AliITSRawClusterSPD*)c));
break;
case 1:
new(lc[fNctype[id]++]) AliITSRawClusterSDD(*((AliITSRawClusterSDD*)c));
break;
case 2:
new(lc[fNctype[id]++]) AliITSRawClusterSSD(*((AliITSRawClusterSSD*)c));
break;
} // end switch id
}
//______________________________________________________________________
void AliITS::ResetClusters(){
// Reset number of clusters and the clusters array for ITS.
// Inputs:
// none.
// Outputs:
// none.
Int_t i;
for (i=0;iAt(i)) ((TClonesArray*)fCtype->At(i))->Clear();
if (fNctype) fNctype[i]=0;
}
//______________________________________________________________________
void AliITS::MakeBranchR(const char *file, Option_t *opt){
// Creates Tree branches for the ITS Reconstructed points.
// Inputs:
// cont char *file File name where RecPoints branch is to be written
// to. If blank it write the SDigits to the same
// file in which the Hits were found.
// Outputs:
// none.
// Return:
// none.
Int_t buffsz = 4000;
char branchname[30];
// only one branch for rec points for all detector types
Bool_t oFast= (strstr(opt,"Fast")!=0);
if(oFast){
sprintf(branchname,"%sRecPointsF",GetName());
} else {
sprintf(branchname,"%sRecPoints",GetName());
}
if(!fRecPoints)fRecPoints = new TClonesArray("AliITSRecPoint",1000);
if (fLoader->TreeR()) {
if (fRecPoints == 0x0) fRecPoints = new TClonesArray("AliITSRecPoint",1000);
MakeBranchInTree(fLoader->TreeR(),branchname,&fRecPoints,buffsz,file);
} // end if
}
//______________________________________________________________________
void AliITS::SetTreeAddressR(TTree *treeR){
// Set branch address for the Reconstructed points Trees.
// Inputs:
// TTree *treeR Tree containing the RecPoints.
// Outputs:
// none.
// Return:
// none.
char branchname[30];
if(!treeR) return;
if (fRecPoints == 0x0) fRecPoints = new TClonesArray("AliITSRecPoint",1000);
TBranch *branch;
sprintf(branchname,"%sRecPoints",GetName());
branch = treeR->GetBranch(branchname);
if (branch) {
branch->SetAddress(&fRecPoints);
}
else {
sprintf(branchname,"%sRecPointsF",GetName());
branch = treeR->GetBranch(branchname);
if (branch) {
branch->SetAddress(&fRecPoints);
}
}
}
//______________________________________________________________________
void AliITS::AddRecPoint(const AliITSRecPoint &r){
// Add a reconstructed space point to the list
// Inputs:
// const AliITSRecPoint &r RecPoint class to be added to the tree
// of reconstructed points TreeR.
// Outputs:
// none.
// Return:
// none.
TClonesArray &lrecp = *fRecPoints;
new(lrecp[fNRecPoints++]) AliITSRecPoint(r);
}
//______________________________________________________________________
void AliITS::HitsToFastRecPoints(Int_t evNumber,Int_t bgrev,Int_t size,
Option_t *opt0,Option_t *opt1, const char *flnm){
// keep galice.root for signal and name differently the file for
// background when add! otherwise the track info for signal will be lost !
// the condition below will disappear when the geom class will be
// initialized for all versions - for the moment it is only for v5 !
// Inputs:
// Int_t evnt Event to be processed.
// Int_t bgrev Background Hit tree number.
// Int_t size Size used by InitModules. See InitModules.
// Option_t *opt0 Option passed to FillModules. See FillModules.
// Option_t *opt1 String indicating if merging hits or not. To
// merge hits set equal to "Add". Otherwise no
// background hits are considered.
// Test_t *flnm File name containing the background hits..
// Outputs:
// none.
// Return:
// none.
if(!GetITSgeom()) return;
AliITSLoader *pITSloader = (AliITSLoader*)fLoader;
AliITSgeom *geom = GetITSgeom();
const char *all = strstr(opt1,"All");
const char *det[3] ={strstr(opt1,"SPD"),strstr(opt1,"SDD"),
strstr(opt1,"SSD")};
Int_t nmodules;
InitModules(size,nmodules);
FillModules(evNumber,bgrev,nmodules,opt0,flnm);
AliITSsimulation *sim = 0;
AliITSDetType *iDetType = 0;
AliITSmodule *mod = 0;
Int_t id,module;
//m.b. : this change is nothing but a nice way to make sure
//the CPU goes up !
cout<<"HitsToFastRecPoints: N mod = "<GetIndexMax()<GetIndexMax();module++){
id = geom->GetModuleType(module);
if (!all && !det[id]) continue;
iDetType = DetType(id);
sim = (AliITSsimulation*)iDetType->GetSimulationModel();
if (!sim)
{
Error("HitsToFastPoints","The simulation class was not "
"instanciated for module %d type %x!",module,
geom->GetModuleTypeName(module));
exit(1);
} // end if !sim
mod = (AliITSmodule *)fITSmodules->At(module);
sim->CreateFastRecPoints(mod,module,gRandom);
cout<TreeR()->Fill();
TTree *lTR = pITSloader->TreeR();
TBranch *br=lTR->GetBranch("ITSRecPointsF");
br->Fill();
ResetRecPoints();
} // end for module
ClearModules();
fLoader->WriteRecPoints("OVERWRITE");
}
//______________________________________________________________________
void AliITS::Digits2Reco(){
// Find clusters and reconstruct space points.
// Inputs:
// none.
// Outputs:
// none.
AliHeader *header=fLoader->GetRunLoader()->GetHeader();
// to Digits to RecPoints for event in file, all digits in file, and
// all ITS detectors.
DigitsToRecPoints(header->GetEvent(),0,fOpt);
}
//______________________________________________________________________
void AliITS::DigitsToRecPoints(Int_t evNumber,Int_t lastentry,Option_t *opt){
// cluster finding and reconstruction of space points
// the condition below will disappear when the geom class will be
// initialized for all versions - for the moment it is only for v5 !
// 7 is the SDD beam test version
// Inputs:
// Int_t evNumber Event number to be processed.
// Int_t lastentry Offset for module when not all of the modules
// are processed.
// Option_t *opt String indicating which ITS sub-detectors should
// be processed. If ="All" then all of the ITS
// sub detectors are processed.
// Outputs:
// none.
// Return:
// none.
if(!GetITSgeom()) return;
AliITSgeom *geom = GetITSgeom();
const char *all = strstr(opt,"All");
const char *det[3] = {strstr(opt,"SPD"),strstr(opt,"SDD"),
strstr(opt,"SSD")};
static Bool_t setRec=kTRUE;
if (setRec) SetDefaultClusterFinders();
setRec=kFALSE;
AliITSLoader *pITSloader = (AliITSLoader*)fLoader;
TTree *treeC=pITSloader->TreeC();
AliITSClusterFinder *rec = 0;
AliITSDetType *iDetType = 0;
Int_t id,module,first=0;
for(module=0;moduleGetIndexMax();module++){
id = geom->GetModuleType(module);
if (!all && !det[id]) continue;
if(det[id]) first = geom->GetStartDet(id);
iDetType = DetType(id);
rec = (AliITSClusterFinder*)iDetType->GetReconstructionModel();
TClonesArray *itsDigits = this->DigitsAddress(id);
if (!rec) {
Error("DigitsToRecPoints",
"The reconstruction class was not instanciated! event=%d",
evNumber);
exit(1);
} // end if !rec
this->ResetDigits();
TTree *lTD = pITSloader->TreeD();
if (all) {
lTD->GetEvent(lastentry+module);
}else {
lTD->GetEvent(lastentry+(module-first));
}
Int_t ndigits = itsDigits->GetEntriesFast();
if (ndigits) rec->FindRawClusters(module);
pITSloader->TreeR()->Fill();
ResetRecPoints();
treeC->Fill();
ResetClusters();
} // end for module
pITSloader->WriteRecPoints("OVERWRITE");
pITSloader->WriteRawClusters("OVERWRITE");
}
//______________________________________________________________________
void AliITS::ResetRecPoints(){
// Reset number of rec points and the rec points array.
// Inputs:
// none.
// Outputs:
// none.
if (fRecPoints) fRecPoints->Clear();
fNRecPoints = 0;
}
//______________________________________________________________________
AliLoader* AliITS::MakeLoader(const char* topfoldername)
{
//builds ITSgetter (AliLoader type)
//if detector wants to use castomized getter, it must overload this method
Info("MakeLoader","Creating AliITSLoader. Top folder is %s.",topfoldername);
fLoader = new AliITSLoader(GetName(),topfoldername);
return fLoader;
}