/************************************************************************** * 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. * **************************************************************************/ /* $Id$ */ //_________________________________________________________________________ // Reconstructed Points for the EMCAL // A RecPoint is a cluster of digits // // //*-- Author: Yves Schutz (SUBATECH) //*-- Author: Dmitri Peressounko (RRC KI & SUBATECH) //*-- Author: Heather Gray (LBL) merged AliEMCALRecPoint and AliEMCALTowerRecPoint 02/04 // --- ROOT system --- #include "TPad.h" #include "TGraph.h" #include "TPaveText.h" #include "TClonesArray.h" #include "TMath.h" #include "TGeoMatrix.h" #include "TGeoManager.h" #include "TGeoPhysicalNode.h" #include "TRandom.h" // --- Standard library --- #include // --- AliRoot header files --- //#include "AliGenerator.h" class AliGenerator; class AliEMCAL; #include "AliLog.h" #include "AliGeomManager.h" #include "AliEMCALGeometry.h" #include "AliEMCALHit.h" #include "AliEMCALDigit.h" #include "AliEMCALRecPoint.h" #include "AliCaloCalibPedestal.h" #include "AliEMCALGeoParams.h" ClassImp(AliEMCALRecPoint) //____________________________________________________________________________ AliEMCALRecPoint::AliEMCALRecPoint() : AliCluster(), fGeomPtr(0), fAmp(0), fIndexInList(-1), //to be set when the point is already stored fGlobPos(0,0,0),fLocPos(0,0,0), fMaxDigit(100), fMulDigit(0), fMaxTrack(200), fMulTrack(0), fDigitsList(0), fTracksList(0), fClusterType(-1), fCoreEnergy(0), fDispersion(0), fEnergyList(0), fAbsIdList(0), fTime(0.), fNExMax(0), fCoreRadius(10), //HG check this fDETracksList(0), fMulParent(0), fMaxParent(0), fParentsList(0), fDEParentsList(0), fSuperModuleNumber(0), fDigitIndMax(-1), fDistToBadTower(-1), fSharedCluster(kFALSE) { // ctor fGeomPtr = AliEMCALGeometry::GetInstance(); fLambda[0] = 0; fLambda[1] = 0; } //____________________________________________________________________________ AliEMCALRecPoint::AliEMCALRecPoint(const char *) : AliCluster(), fGeomPtr(0), fAmp(0), fIndexInList(-1), //to be set when the point is already stored fGlobPos(0,0,0), fLocPos(0,0,0), fMaxDigit(100), fMulDigit(0), fMaxTrack(1000), fMulTrack(0), fDigitsList(new Int_t[fMaxDigit]), fTracksList(new Int_t[fMaxTrack]), fClusterType(-1), fCoreEnergy(0), fDispersion(0), fEnergyList(new Float_t[fMaxDigit]), fAbsIdList(new Int_t[fMaxDigit]), fTime(-1.), fNExMax(0), fCoreRadius(10), fDETracksList(new Float_t[fMaxTrack]), fMulParent(0), fMaxParent(1000), fParentsList(new Int_t[fMaxParent]), fDEParentsList(new Float_t[fMaxParent]), fSuperModuleNumber(0), fDigitIndMax(-1), fDistToBadTower(-1),fSharedCluster(kFALSE) { // ctor for (Int_t i = 0; i < fMaxTrack; i++) fDETracksList[i] = 0; for (Int_t i = 0; i < fMaxParent; i++) { fParentsList[i] = -1; fDEParentsList[i] = 0; } fGeomPtr = AliEMCALGeometry::GetInstance(); fLambda[0] = 0; fLambda[1] = 0; } //____________________________________________________________________________ AliEMCALRecPoint::AliEMCALRecPoint(const AliEMCALRecPoint & rp) : AliCluster(rp), fGeomPtr(rp.fGeomPtr), fAmp(rp.fAmp), fIndexInList(rp.fIndexInList), fGlobPos(rp.fGlobPos),fLocPos(rp.fLocPos), fMaxDigit(rp.fMaxDigit), fMulDigit(rp.fMulDigit), fMaxTrack(rp.fMaxTrack), fMulTrack(rp.fMaxTrack), fDigitsList(new Int_t[rp.fMaxDigit]), fTracksList(new Int_t[rp.fMaxTrack]), fClusterType(rp.fClusterType), fCoreEnergy(rp.fCoreEnergy), fDispersion(rp.fDispersion), fEnergyList(new Float_t[rp.fMaxDigit]), fAbsIdList(new Int_t[rp.fMaxDigit]), fTime(rp.fTime), fNExMax(rp.fNExMax),fCoreRadius(rp.fCoreRadius), fDETracksList(new Float_t[rp.fMaxTrack]), fMulParent(rp.fMulParent), fMaxParent(rp.fMaxParent), fParentsList(new Int_t[rp.fMaxParent]), fDEParentsList(new Float_t[rp.fMaxParent]), fSuperModuleNumber(rp.fSuperModuleNumber), fDigitIndMax(rp.fDigitIndMax), fDistToBadTower(rp.fDistToBadTower), fSharedCluster(rp.fSharedCluster) { //copy ctor fLambda[0] = rp.fLambda[0]; fLambda[1] = rp.fLambda[1]; for(Int_t i = 0; i < rp.fMulDigit; i++) { fEnergyList[i] = rp.fEnergyList[i]; fAbsIdList[i] = rp.fAbsIdList[i]; } for(Int_t i = 0; i < rp.fMulTrack; i++) fDETracksList[i] = rp.fDETracksList[i]; for(Int_t i = 0; i < rp.fMulParent; i++) { fParentsList[i] = rp.fParentsList[i]; fDEParentsList[i] = rp.fDEParentsList[i]; } } //____________________________________________________________________________ AliEMCALRecPoint::~AliEMCALRecPoint() { // dtor if ( fEnergyList ) delete[] fEnergyList ; if ( fAbsIdList ) delete[] fAbsIdList ; if ( fDETracksList) delete[] fDETracksList; if ( fParentsList) delete[] fParentsList; if ( fDEParentsList) delete[] fDEParentsList; delete [] fDigitsList ; delete [] fTracksList ; } //____________________________________________________________________________ AliEMCALRecPoint& AliEMCALRecPoint::operator= (const AliEMCALRecPoint &rp) { // assignment operator if(&rp == this) return *this; fGeomPtr = rp.fGeomPtr; fAmp = rp.fAmp; fIndexInList = rp.fIndexInList; fGlobPos = rp.fGlobPos; fLocPos = rp.fLocPos; fMaxDigit = rp.fMaxDigit; fMulDigit = rp.fMulDigit; fMaxTrack = rp.fMaxTrack; fMulTrack = rp.fMulTrack; if(fDigitsList) delete [] fDigitsList; fDigitsList = new Int_t[rp.fMaxDigit]; if(fTracksList) delete [] fTracksList; fTracksList = new Int_t[rp.fMaxTrack]; for(Int_t i = 0; i= fMaxDigit ) { // increase the size of the lists fMaxDigit*=2 ; Int_t * tempo = new Int_t [fMaxDigit]; Float_t * tempoE = new Float_t[fMaxDigit]; Int_t * tempoId = new Int_t [fMaxDigit]; Int_t index ; for ( index = 0 ; index < fMulDigit ; index++ ){ tempo [index] = fDigitsList[index] ; tempoE [index] = fEnergyList[index] ; tempoId[index] = fAbsIdList [index] ; } delete [] fDigitsList ; delete [] fEnergyList ; delete [] fAbsIdList ; fDigitsList = tempo; fEnergyList = tempoE; fAbsIdList = tempoId; } // if fDigitsList[fMulDigit] = digit.GetIndexInList() ; fEnergyList[fMulDigit] = energy ; fAbsIdList [fMulDigit] = digit.GetId(); fMulDigit++ ; fAmp += energy ; if(shared) fSharedCluster = kTRUE; } //____________________________________________________________________________ Bool_t AliEMCALRecPoint::AreNeighbours(AliEMCALDigit * digit1, AliEMCALDigit * digit2 ) const { // Tells if (true) or not (false) two digits are neighbours // A neighbour is defined as being two digits which share a corner // ONLY USED IN CASE OF UNFOLDING Bool_t areNeighbours = kFALSE ; Int_t nSupMod=0, nModule=0, nIphi=0, nIeta=0; Int_t nSupMod1=0, nModule1=0, nIphi1=0, nIeta1=0; Int_t relid1[2] , relid2[2] ; // ieta, iphi Int_t rowdiff=0, coldiff=0; areNeighbours = kFALSE ; fGeomPtr->GetCellIndex(digit1->GetId(), nSupMod,nModule,nIphi,nIeta); fGeomPtr->GetCellPhiEtaIndexInSModule(nSupMod,nModule,nIphi,nIeta, relid1[0],relid1[1]); fGeomPtr->GetCellIndex(digit2->GetId(), nSupMod1,nModule1,nIphi1,nIeta1); fGeomPtr->GetCellPhiEtaIndexInSModule(nSupMod1,nModule1,nIphi1,nIeta1, relid2[0],relid2[1]); // In case of a shared cluster, index of SM in C side, columns start at 48 and ends at 48*2-1 // C Side impair SM, nSupMod%2=1; A side pair SM nSupMod%2=0 if(fSharedCluster){ //printf("Shared cluster in 2 SMs!\n"); // if(nSupMod1%2) relid1[1]+=AliEMCALGeoParams::fgkEMCALCols;//bad // else relid2[1]+=AliEMCALGeoParams::fgkEMCALCols;//bad if(nSupMod1%2) relid2[1]+=AliEMCALGeoParams::fgkEMCALCols; else relid1[1]+=AliEMCALGeoParams::fgkEMCALCols; } rowdiff = TMath::Abs( relid1[0] - relid2[0] ) ; coldiff = TMath::Abs( relid1[1] - relid2[1] ) ; //if (( coldiff <= 1 ) && ( rowdiff <= 1 ) && (coldiff + rowdiff > 0)) if ((coldiff + rowdiff == 1 )) areNeighbours = kTRUE ; return areNeighbours; } //____________________________________________________________________________ Int_t AliEMCALRecPoint::Compare(const TObject * obj) const { // Compares two RecPoints according to their position in the EMCAL modules Float_t delta = 1 ; //Width of "Sorting row". Int_t rv = 2 ; AliEMCALRecPoint * clu = (AliEMCALRecPoint *)obj ; TVector3 locpos1; GetLocalPosition(locpos1); TVector3 locpos2; clu->GetLocalPosition(locpos2); Int_t rowdif = (Int_t)(TMath::Ceil(locpos1.X()/delta)-TMath::Ceil(locpos2.X()/delta)) ; if (rowdif> 0) rv = 1 ; else if(rowdif < 0) rv = -1 ; else if(locpos1.Y()>locpos2.Y()) rv = -1 ; else rv = 1 ; return rv ; } //___________________________________________________________________________ void AliEMCALRecPoint::Draw(Option_t *option) { // Draw this AliEMCALRecPoint with its current attributes AppendPad(option); } //____________________________________________________________________________ void AliEMCALRecPoint::EvalAll(Float_t logWeight,TClonesArray * digits, const Bool_t justClusters) { // Evaluates cluster parameters // First calculate the index of digit with maximum amplitude and get // the supermodule number where it sits. fDigitIndMax = GetMaximalEnergyIndex(); fSuperModuleNumber = fGeomPtr->GetSuperModuleNumber(GetAbsIdMaxDigit()); //Evaluate global and local position EvalGlobalPosition(logWeight, digits) ; EvalLocalPosition(logWeight, digits) ; //Evaluate shower parameters EvalElipsAxis(logWeight, digits) ; EvalDispersion(logWeight, digits) ; //EvalCoreEnergy(logWeight, digits); EvalTime(digits) ; EvalPrimaries(digits) ; EvalParents(digits); //Called last because it sets the global position of the cluster? //Do not call it when recalculating clusters out of standard reconstruction if(!justClusters){ EvalLocal2TrackingCSTransform(); } } //____________________________________________________________________________ void AliEMCALRecPoint::EvalDispersion(Float_t logWeight, TClonesArray * digits) { // Calculates the dispersion of the shower at the origin of the RecPoint // in cell units - Nov 16,2006 Double_t d = 0., wtot = 0., w = 0.; Int_t iDigit=0, nstat=0; AliEMCALDigit * digit=0; // Calculates the dispersion in cell units Double_t etai, phii, etaMean=0.0, phiMean=0.0; int nSupMod=0, nModule=0, nIphi=0, nIeta=0; int iphi=0, ieta=0; // Calculate mean values for(iDigit=0; iDigit < fMulDigit; iDigit++) { digit = (AliEMCALDigit *) digits->At(fDigitsList[iDigit]) ; if (fAmp>0 && fEnergyList[iDigit]>0) { fGeomPtr->GetCellIndex(digit->GetId(), nSupMod,nModule,nIphi,nIeta); fGeomPtr->GetCellPhiEtaIndexInSModule(nSupMod,nModule,nIphi,nIeta, iphi,ieta); // In case of a shared cluster, index of SM in C side, columns start at 48 and ends at 48*2 // C Side impair SM, nSupMod%2=1; A side pair SM nSupMod%2=0 if(fSharedCluster && nSupMod%2) ieta+=AliEMCALGeoParams::fgkEMCALCols; etai=(Double_t)ieta; phii=(Double_t)iphi; w = TMath::Max(0.,logWeight+TMath::Log(fEnergyList[iDigit]/fAmp ) ) ; if(w>0.0) { phiMean += phii*w; etaMean += etai*w; wtot += w; } } } if (wtot>0) { phiMean /= wtot ; etaMean /= wtot ; } else AliError(Form("Wrong weight %f\n", wtot)); // Calculate dispersion for(iDigit=0; iDigit < fMulDigit; iDigit++) { digit = (AliEMCALDigit *) digits->At(fDigitsList[iDigit]) ; if (fAmp>0 && fEnergyList[iDigit]>0) { fGeomPtr->GetCellIndex(digit->GetId(), nSupMod,nModule,nIphi,nIeta); fGeomPtr->GetCellPhiEtaIndexInSModule(nSupMod,nModule,nIphi,nIeta, iphi,ieta); // In case of a shared cluster, index of SM in C side, columns start at 48 and ends at 48*2 // C Side impair SM, nSupMod%2=1; A side pair SM, nSupMod%2=0 if(fSharedCluster && nSupMod%2) ieta+=AliEMCALGeoParams::fgkEMCALCols; etai=(Double_t)ieta; phii=(Double_t)iphi; w = TMath::Max(0.,logWeight+TMath::Log(fEnergyList[iDigit]/fAmp ) ) ; if(w>0.0) { nstat++; d += w*((etai-etaMean)*(etai-etaMean)+(phii-phiMean)*(phii-phiMean)); } } } if ( wtot > 0 && nstat>1) d /= wtot ; else d = 0. ; fDispersion = TMath::Sqrt(d) ; //printf("AliEMCALRecPoint::EvalDispersion() : Dispersion %f \n",fDispersion); } //____________________________________________________________________________ void AliEMCALRecPoint::EvalDistanceToBadChannels(AliCaloCalibPedestal* caloped) { //For each EMC rec. point set the distance to the nearest bad channel. //AliInfo(Form("%d bad channel(s) found.\n", caloped->GetDeadTowerCount())); //It is done in cell units and not in global or local position as before (Sept 2010) if(!caloped->GetDeadTowerCount()) return; //Get channels map of the supermodule where the cluster is. TH2D* hMap = caloped->GetDeadMap(fSuperModuleNumber); Int_t dRrow, dReta; Float_t minDist = 10000.; Float_t dist = 0.; Int_t nSupMod, nModule; Int_t nIphi, nIeta; Int_t iphi, ieta; fDigitIndMax = GetMaximalEnergyIndex(); fGeomPtr->GetCellIndex(fAbsIdList[fDigitIndMax], nSupMod,nModule,nIphi,nIeta); fGeomPtr->GetCellPhiEtaIndexInSModule(nSupMod,nModule,nIphi,nIeta, iphi,ieta); //Loop on tower status map for(Int_t irow = 0; irow < AliEMCALGeoParams::fgkEMCALRows; irow++){ for(Int_t icol = 0; icol < AliEMCALGeoParams::fgkEMCALCols; icol++){ //Check if tower is bad. if(hMap->GetBinContent(icol,irow)==AliCaloCalibPedestal::kAlive) continue; //printf("AliEMCALRecPoint::EvalDistanceToBadChannels() - Bad channel in SM %d, col %d, row %d\n",iSM,icol, irow); dRrow=TMath::Abs(irow-iphi); dReta=TMath::Abs(icol-ieta); dist=TMath::Sqrt(dRrow*dRrow+dReta*dReta); if(dist < minDist) minDist = dist; } } //In case the cluster is shared by 2 SuperModules, need to check the map of the second Super Module if (fSharedCluster) { TH2D* hMap2 = 0; Int_t nSupMod2 = -1; //The only possible combinations are (0,1), (2,3) ... (10,11) if(fSuperModuleNumber%2) nSupMod2 = fSuperModuleNumber-1; else nSupMod2 = fSuperModuleNumber+1; hMap2 = caloped->GetDeadMap(nSupMod2); //Loop on tower status map of second super module for(Int_t irow = 0; irow < AliEMCALGeoParams::fgkEMCALRows; irow++){ for(Int_t icol = 0; icol < AliEMCALGeoParams::fgkEMCALCols; icol++){ //Check if tower is bad. if(hMap2->GetBinContent(icol,irow)==AliCaloCalibPedestal::kAlive) continue; //printf("AliEMCALRecPoint::EvalDistanceToBadChannels() - Bad channel in SM %d, col %d, row %d\n",iSM,icol, irow); dRrow=TMath::Abs(irow-iphi); if(fSuperModuleNumber%2) { dReta=TMath::Abs(icol-(AliEMCALGeoParams::fgkEMCALCols+ieta)); } else { dReta=TMath::Abs(AliEMCALGeoParams::fgkEMCALCols+icol-ieta); } dist=TMath::Sqrt(dRrow*dRrow+dReta*dReta); if(dist < minDist) minDist = dist; } } }// shared cluster in 2 SuperModules fDistToBadTower = minDist; //printf("AliEMCALRecPoint::EvalDistanceToBadChannel() - Distance to Bad is %f cm, shared cluster? %d \n",fDistToBadTower,fSharedCluster); } //____________________________________________________________________________ void AliEMCALRecPoint::EvalLocalPosition(Float_t logWeight, TClonesArray * digits) { // Calculates the center of gravity in the local EMCAL-module coordinates // Info("Print", " logWeight %f : cluster energy %f ", logWeight, fAmp); // for testing AliEMCALDigit * digit=0; Int_t i=0, nstat=0; Double_t dist = TmaxInCm(Double_t(fAmp)); //Int_t idMax = GetAbsIdMaxDigit();// idMax is not used at all in RelPosCellInSModule, why use it? Double_t clXYZ[3]={0.,0.,0.}, clRmsXYZ[3]={0.,0.,0.}, xyzi[3], wtot=0., w=0.; //printf(" dist : %f e : %f \n", dist, fAmp); for(Int_t iDigit=0; iDigit(digits->At(fDigitsList[iDigit])) ; if(!digit) { AliError("No Digit!!"); continue; } fGeomPtr->RelPosCellInSModule(digit->GetId(), dist, xyzi[0], xyzi[1], xyzi[2]); //Temporal patch, due to mapping problem, need to swap "y" in one of the 2 SM, although no effect in position calculation. GCB 05/2010 if(fSharedCluster && fSuperModuleNumber != fGeomPtr->GetSuperModuleNumber(digit->GetId())) xyzi[1]*=-1; //printf("EvalLocalPosition Cell: Id %i, SM %i : dist %f Local x,y,z %f %f %f \n", // digit->GetId(), fGeomPtr->GetSuperModuleNumber(digit->GetId()), dist, xyzi[0], xyzi[1], xyzi[2]); if(logWeight > 0.0) w = TMath::Max( 0., logWeight + TMath::Log( fEnergyList[iDigit] / fAmp )); else w = fEnergyList[iDigit]; // just energy if(w>0.0) { wtot += w ; nstat++; for(i=0; i<3; i++ ) { clXYZ[i] += (w*xyzi[i]); clRmsXYZ[i] += (w*xyzi[i]*xyzi[i]); } } } // cout << " wtot " << wtot << endl; if ( wtot > 0 ) { // xRMS = TMath::Sqrt(x2m - xMean*xMean); for(i=0; i<3; i++ ) { clXYZ[i] /= wtot; if(nstat>1) { clRmsXYZ[i] /= (wtot*wtot); clRmsXYZ[i] = clRmsXYZ[i] - clXYZ[i]*clXYZ[i]; if(clRmsXYZ[i] > 0.0) { clRmsXYZ[i] = TMath::Sqrt(clRmsXYZ[i]); } else clRmsXYZ[i] = 0; } else clRmsXYZ[i] = 0; } } else { for(i=0; i<3; i++ ) { clXYZ[i] = clRmsXYZ[i] = -1.; } } // // Cluster of one single digit, smear the position to avoid discrete position // // smear x and z with +- 3 cm to uniform (avoid discrete effects). Tower size is approx 6 cm. // // Rndm generates a number in ]0,1] // if (fMulDigit==1) { // clXYZ[0] += fGeomPtr->GetPhiTileSize()*(0.5 - gRandom->Rndm()); // clXYZ[2] += fGeomPtr->GetEtaTileSize()*(0.5 - gRandom->Rndm()); // } //Set position in local vector fLocPos.SetX(clXYZ[0]); fLocPos.SetY(clXYZ[1]); fLocPos.SetZ(clXYZ[2]); if (gDebug==2) printf("EvalLocalPosition Cluster: Local (x,y,z) = (%f,%f,%f) \n", fLocPos.X(), fLocPos.Y(), fLocPos.Z()) ; } //____________________________________________________________________________ void AliEMCALRecPoint::EvalGlobalPosition(Float_t logWeight, TClonesArray * digits) { // Calculates the center of gravity in the global ALICE coordinates // Info("Print", " logWeight %f : cluster energy %f ", logWeight, fAmp); // for testing AliEMCALDigit * digit=0; Int_t i=0, nstat=0; Double_t dist = TmaxInCm(Double_t(fAmp)); //Int_t idMax = GetAbsIdMaxDigit();// idMax is not used at all in RelPosCellInSModule, why use it? Double_t clXYZ[3]={0.,0.,0.}, clRmsXYZ[3]={0.,0.,0.}, lxyzi[3], xyzi[3], wtot=0., w=0.; //printf(" dist : %f e : %f \n", dist, fAmp); for(Int_t iDigit=0; iDigit(digits->At(fDigitsList[iDigit])) ; if(!digit) { AliError("No Digit!!"); continue; } //Get the local coordinates of the cell fGeomPtr->RelPosCellInSModule(digit->GetId(), dist, lxyzi[0], lxyzi[1], lxyzi[2]); //Now get the global coordinate fGeomPtr->GetGlobal(lxyzi,xyzi, fGeomPtr->GetSuperModuleNumber(digit->GetId())); //TVector3 pos(xyzi[0], xyzi[1], xyzi[2]); //printf("EvalGlobalPosition Cell: Id %i, SM %i : dist %f Local (x,y,z) = (%f %f %f), eta %f, phi%f \n", // digit->GetId(), fGeomPtr->GetSuperModuleNumber(digit->GetId()),dist, xyzi[0], xyzi[1], xyzi[2],pos.Eta(),pos.Phi()*TMath::RadToDeg()); if(logWeight > 0.0) w = TMath::Max( 0., logWeight + TMath::Log( fEnergyList[iDigit] / fAmp )); else w = fEnergyList[iDigit]; // just energy if(w>0.0) { wtot += w ; nstat++; for(i=0; i<3; i++ ) { clXYZ[i] += (w*xyzi[i]); clRmsXYZ[i] += (w*xyzi[i]*xyzi[i]); } } } // cout << " wtot " << wtot << endl; if ( wtot > 0 ) { // xRMS = TMath::Sqrt(x2m - xMean*xMean); for(i=0; i<3; i++ ) { clXYZ[i] /= wtot; if(nstat>1) { clRmsXYZ[i] /= (wtot*wtot); clRmsXYZ[i] = clRmsXYZ[i] - clXYZ[i]*clXYZ[i]; if(clRmsXYZ[i] > 0.0) { clRmsXYZ[i] = TMath::Sqrt(clRmsXYZ[i]); } else clRmsXYZ[i] = 0; } else clRmsXYZ[i] = 0; } } else { for(i=0; i<3; i++ ) { clXYZ[i] = clRmsXYZ[i] = -1.; } } // // Cluster of one single digit, smear the position to avoid discrete position // // smear x and z with +- 3 cm to uniform (avoid discrete effects). Tower size is approx 6 cm. // // Rndm generates a number in ]0,1] // if (fMulDigit==1) { // clXYZ[0] += fGeomPtr->GetPhiTileSize()*(0.5 - gRandom->Rndm()); // clXYZ[2] += fGeomPtr->GetEtaTileSize()*(0.5 - gRandom->Rndm()); // } //Set position in global vector fGlobPos.SetX(clXYZ[0]); fGlobPos.SetY(clXYZ[1]); fGlobPos.SetZ(clXYZ[2]); if (gDebug==2) printf("EvalGlobalPosition Cluster: (x ,y ,z) = (%f,%f,%f), eta %f,phi %f\n", fGlobPos.X(), fGlobPos.Y(), fGlobPos.Z(),fGlobPos.Eta(),fGlobPos.Phi()*TMath::RadToDeg()) ; } //____________________________________________________________________________ void AliEMCALRecPoint::EvalLocalPositionFit(Double_t deff, Double_t logWeight, Double_t phiSlope, TClonesArray * digits) { // Evaluates local position of clusters in SM Double_t ycorr=0; AliEMCALDigit *digit=0; Int_t i=0, nstat=0; Double_t clXYZ[3]={0.,0.,0.}, clRmsXYZ[3]={0.,0.,0.}, xyzi[3], wtot=0., w=0.; Double_t dist = TmaxInCm(Double_t(fAmp)); //Int_t idMax = GetAbsIdMaxDigit();// idMax is not used at all in RelPosCellInSModule, why use it? for(Int_t iDigit=0; iDigitGetEntries(); iDigit++) { digit = dynamic_cast(digits->At(fDigitsList[iDigit])) ; if(digit){ dist = deff; //fGeomPtr->RelPosCellInSModule(digit->GetId(), idMax, dist, xyzi[0], xyzi[1], xyzi[2]); fGeomPtr->RelPosCellInSModule(digit->GetId(), dist, xyzi[0], xyzi[1], xyzi[2]); if(logWeight > 0.0) w = TMath::Max( 0., logWeight + TMath::Log( fEnergyList[iDigit] / fAmp )); else w = fEnergyList[iDigit]; // just energy if(w>0.0) { wtot += w ; nstat++; for(i=0; i<3; i++ ) { clXYZ[i] += (w*xyzi[i]); clRmsXYZ[i] += (w*xyzi[i]*xyzi[i]); } } }else AliError("Digit null"); }//loop // cout << " wtot " << wtot << endl; if ( wtot > 0 ) { // xRMS = TMath::Sqrt(x2m - xMean*xMean); for(i=0; i<3; i++ ) { clXYZ[i] /= wtot; if(nstat>1) { clRmsXYZ[i] /= (wtot*wtot); clRmsXYZ[i] = clRmsXYZ[i] - clXYZ[i]*clXYZ[i]; if(clRmsXYZ[i] > 0.0) { clRmsXYZ[i] = TMath::Sqrt(clRmsXYZ[i]); } else clRmsXYZ[i] = 0; } else clRmsXYZ[i] = 0; } } else { for(i=0; i<3; i++ ) { clXYZ[i] = clRmsXYZ[i] = -1.; } } // clRmsXYZ[i] ?? if(phiSlope != 0.0 && logWeight > 0.0 && wtot) { // Correction in phi direction (y - coords here); Aug 16; // May be put to global level or seperate method ycorr = clXYZ[1] * (1. + phiSlope); //printf(" y %f : ycorr %f : slope %f \n", clXYZ[1], ycorr, phiSlope); clXYZ[1] = ycorr; } fLocPos.SetX(clXYZ[0]); fLocPos.SetY(clXYZ[1]); fLocPos.SetZ(clXYZ[2]); // if (gDebug==2) // printf("EvalLocalPosition: eta,phi,r = %f,%f,%f", fLocPos.X(), fLocPos.Y(), fLocPos.Z()) ; } //_____________________________________________________________________________ Bool_t AliEMCALRecPoint::EvalLocalPosition2(TClonesArray * digits, TArrayD &ed) { // Evaluated local position of rec.point using digits // and parametrisation of w0 and deff //printf(" AliEMCALRecPoint::EvalLocalPosition2() \n"); return AliEMCALRecPoint::EvalLocalPositionFromDigits(digits, ed, fLocPos); } //_____________________________________________________________________________ Bool_t AliEMCALRecPoint::EvalLocalPositionFromDigits(TClonesArray *digits, TArrayD &ed, TVector3 &locPos) { // Used when digits should be recalibrated Double_t deff=0, w0=0, esum=0; Int_t iDigit=0; // AliEMCALDigit *digit; if(ed.GetSize() && (digits->GetEntries()!=ed.GetSize())) return kFALSE; // Calculate sum energy of digits esum = 0.0; for(iDigit=0; iDigitGetEntries(); iDigit++) { digit = dynamic_cast(digits->At(iDigit)); if(digit){ //geo->RelPosCellInSModule(digit->GetId(), idMax, deff, xyzi[0], xyzi[1], xyzi[2]); geo->RelPosCellInSModule(digit->GetId(), deff, xyzi[0], xyzi[1], xyzi[2]); if(w0 > 0.0) w = TMath::Max( 0., w0 + TMath::Log(ed[iDigit] / esum)); else w = ed[iDigit]; // just energy if(w>0.0) { wtot += w ; nstat++; for(i=0; i<3; i++ ) { clXYZ[i] += (w*xyzi[i]); } } }else AliError("Digit null"); }//loop // cout << " wtot " << wtot << endl; if (wtot > 0) { for(i=0; i<3; i++ ) { clXYZ[i] /= wtot; } locPos.SetX(clXYZ[0]); locPos.SetY(clXYZ[1]); locPos.SetZ(clXYZ[2]); return kTRUE; } else { return kFALSE; } } //_____________________________________________________________________________ void AliEMCALRecPoint::GetDeffW0(const Double_t esum , Double_t &deff, Double_t &w0) { // // Aug 31, 2001 // Applied for simulation data with threshold 3 adc // Calculate efective distance (deff) and weigh parameter (w0) // for coordinate calculation; 0.5 GeV < esum <100 GeV. // Look to: http://rhic.physics.wayne.edu/~pavlinov/ALICE/SHISHKEBAB/RES/CALIB/GEOMCORR/deffandW0VaEgamma_2.gif // Double_t e=0.0; const Double_t kdp0=9.25147, kdp1=1.16700; // Hard coded now const Double_t kwp0=4.83713, kwp1=-2.77970e-01, kwp2 = 4.41116; // No extrapolation here e = esum<0.5?0.5:esum; e = e>100.?100.:e; deff = kdp0 + kdp1*TMath::Log(e); w0 = kwp0 / (1. + TMath::Exp(kwp1*(e+kwp2))); //printf(" AliEMCALRecPoint::GetDeffW0 esum %5.2f : deff %5.2f : w0 %5.2f \n", esum, deff, w0); } //______________________________________________________________________________ void AliEMCALRecPoint::EvalCoreEnergy(Float_t logWeight, TClonesArray * digits) { // This function calculates energy in the core, // i.e. within a radius rad = fCoreEnergy around the center. Beyond this radius // in accordance with shower profile the energy deposition // should be less than 2% // Unfinished - Nov 15,2006 // Distance is calculate in (phi,eta) units AliEMCALDigit * digit = 0 ; Int_t iDigit=0; if (!fLocPos.Mag()) { EvalLocalPosition(logWeight, digits); } Double_t phiPoint = fLocPos.Phi(), etaPoint = fLocPos.Eta(); Double_t eta, phi, distance; for(iDigit=0; iDigit < fMulDigit; iDigit++) { digit = (AliEMCALDigit *) ( digits->At(fDigitsList[iDigit]) ) ; eta = phi = 0.0; fGeomPtr->EtaPhiFromIndex(digit->GetId(),eta, phi) ; phi = phi * TMath::DegToRad(); distance = TMath::Sqrt((eta-etaPoint)*(eta-etaPoint)+(phi-phiPoint)*(phi-phiPoint)); if(distance < fCoreRadius) fCoreEnergy += fEnergyList[iDigit] ; } } //____________________________________________________________________________ void AliEMCALRecPoint::EvalElipsAxis(Float_t logWeight,TClonesArray * digits) { // Calculates the axis of the shower ellipsoid in eta and phi // in cell units TString gn(fGeomPtr->GetName()); Double_t wtot = 0.; Double_t x = 0.; Double_t z = 0.; Double_t dxx = 0.; Double_t dzz = 0.; Double_t dxz = 0.; AliEMCALDigit * digit = 0; Double_t etai =0, phii=0, w=0; int nSupMod=0, nModule=0, nIphi=0, nIeta=0; int iphi=0, ieta=0; for(Int_t iDigit=0; iDigitAt(fDigitsList[iDigit]) ; etai = phii = 0.; // Nov 15,2006 - use cell numbers as coordinates // Copied for shish-kebab geometry, ieta,iphi is cast as double as eta,phi // We can use the eta,phi(or coordinates) of cell nSupMod = nModule = nIphi = nIeta = iphi = ieta = 0; fGeomPtr->GetCellIndex(digit->GetId(), nSupMod,nModule,nIphi,nIeta); fGeomPtr->GetCellPhiEtaIndexInSModule(nSupMod,nModule,nIphi,nIeta, iphi,ieta); // In case of a shared cluster, index of SM in C side, columns start at 48 and ends at 48*2 // C Side impair SM, nSupMod%2=1; A side pair SM, nSupMod%2=0 if(fSharedCluster && nSupMod%2) ieta+=AliEMCALGeoParams::fgkEMCALCols; etai=(Double_t)ieta; phii=(Double_t)iphi; w = TMath::Max(0.,logWeight+TMath::Log(fEnergyList[iDigit]/fAmp ) ) ; // fAmp summed amplitude of digits, i.e. energy of recpoint // Gives smaller value of lambda than log weight // w = fEnergyList[iDigit] / fAmp; // Nov 16, 2006 - try just energy dxx += w * etai * etai ; x += w * etai ; dzz += w * phii * phii ; z += w * phii ; dxz += w * etai * phii ; wtot += w ; } if ( wtot > 0 ) { dxx /= wtot ; x /= wtot ; dxx -= x * x ; dzz /= wtot ; z /= wtot ; dzz -= z * z ; dxz /= wtot ; dxz -= x * z ; fLambda[0] = 0.5 * (dxx + dzz) + TMath::Sqrt( 0.25 * (dxx - dzz) * (dxx - dzz) + dxz * dxz ) ; if(fLambda[0] > 0) fLambda[0] = TMath::Sqrt(fLambda[0]) ; else fLambda[0] = 0; fLambda[1] = 0.5 * (dxx + dzz) - TMath::Sqrt( 0.25 * (dxx - dzz) * (dxx - dzz) + dxz * dxz ) ; if(fLambda[1] > 0) //To avoid exception if numerical errors lead to negative lambda. fLambda[1] = TMath::Sqrt(fLambda[1]) ; else fLambda[1]= 0. ; } else { fLambda[0]= 0. ; fLambda[1]= 0. ; } //printf("AliEMCALRecPoint::EvalElipsAxis() lambdas = %f,%f \n", fLambda[0],fLambda[1]) ; } //______________________________________________________________________________ void AliEMCALRecPoint::EvalPrimaries(TClonesArray * digits) { // Constructs the list of primary particles (tracks) which // have contributed to this RecPoint and calculate deposited energy // for each track AliEMCALDigit * digit =0; Int_t * primArray = new Int_t[fMaxTrack] ; memset(primArray,-1,sizeof(Int_t)*fMaxTrack); Float_t * dEPrimArray = new Float_t[fMaxTrack] ; memset(dEPrimArray,-1,sizeof(Int_t)*fMaxTrack); Int_t index ; for ( index = 0 ; index < GetDigitsMultiplicity() ; index++ ) { // all digits digit = dynamic_cast(digits->At( fDigitsList[index] )) ; if(!digit) { AliError("No Digit!!"); continue; } Int_t nprimaries = digit->GetNprimary() ; if ( nprimaries == 0 ) continue ; Int_t jndex ; for ( jndex = 0 ; jndex < nprimaries ; jndex++ ) { // all primaries in digit if ( fMulTrack > fMaxTrack ) { fMulTrack = fMaxTrack ; Error("EvalPrimaries", "increase fMaxTrack ") ; break ; } Int_t newPrimary = digit->GetPrimary(jndex+1); Float_t dEPrimary = digit->GetDEPrimary(jndex+1); Int_t kndex ; Bool_t already = kFALSE ; for ( kndex = 0 ; kndex < fMulTrack ; kndex++ ) { //check if not already stored if ( newPrimary == primArray[kndex] ){ already = kTRUE ; dEPrimArray[kndex] += dEPrimary; break ; } } // end of check if ( !already && (fMulTrack < fMaxTrack)) { // store it primArray[fMulTrack] = newPrimary ; dEPrimArray[fMulTrack] = dEPrimary ; fMulTrack++ ; } // store it } // all primaries in digit } // all digits Int_t *sortIdx = new Int_t[fMulTrack]; TMath::Sort(fMulTrack,dEPrimArray,sortIdx); for(index = 0; index < fMulTrack; index++) { fTracksList[index] = primArray[sortIdx[index]] ; fDETracksList[index] = dEPrimArray[sortIdx[index]] ; } delete [] sortIdx; delete [] primArray ; delete [] dEPrimArray ; } //______________________________________________________________________________ void AliEMCALRecPoint::EvalParents(TClonesArray * digits) { // Constructs the list of parent particles (tracks) which have contributed to this RecPoint AliEMCALDigit * digit=0 ; Int_t * parentArray = new Int_t[fMaxTrack] ; memset(parentArray,-1,sizeof(Int_t)*fMaxTrack); Float_t * dEParentArray = new Float_t[fMaxTrack] ; memset(dEParentArray,-1,sizeof(Int_t)*fMaxTrack); Int_t index ; for ( index = 0 ; index < GetDigitsMultiplicity() ; index++ ) { // all digits if (fDigitsList[index] >= digits->GetEntries() || fDigitsList[index] < 0) AliError(Form("Trying to get invalid digit %d (idx in WriteRecPoint %d)",fDigitsList[index],index)); digit = dynamic_cast(digits->At( fDigitsList[index] )) ; if(!digit) { AliError("No Digit!!"); continue; } Int_t nparents = digit->GetNiparent() ; if ( nparents == 0 ) continue ; Int_t jndex ; for ( jndex = 0 ; jndex < nparents ; jndex++ ) { // all primaries in digit if ( fMulParent > fMaxParent ) { fMulTrack = - 1 ; Error("EvalParents", "increase fMaxParent") ; break ; } Int_t newParent = digit->GetIparent(jndex+1) ; Float_t newdEParent = digit->GetDEParent(jndex+1) ; Int_t kndex ; Bool_t already = kFALSE ; for ( kndex = 0 ; kndex < fMulParent ; kndex++ ) { //check if not already stored if ( newParent == parentArray[kndex] ){ dEParentArray[kndex] += newdEParent; already = kTRUE ; break ; } } // end of check if ( !already && (fMulParent < fMaxParent)) { // store it parentArray[fMulParent] = newParent ; dEParentArray[fMulParent] = newdEParent ; fMulParent++ ; } // store it } // all parents in digit } // all digits if (fMulParent>0) { Int_t *sortIdx = new Int_t[fMulParent]; TMath::Sort(fMulParent,dEParentArray,sortIdx); for(index = 0; index < fMulParent; index++) { fParentsList[index] = parentArray[sortIdx[index]] ; fDEParentsList[index] = dEParentArray[sortIdx[index]] ; } delete [] sortIdx; } delete [] parentArray; delete [] dEParentArray; } //____________________________________________________________________________ void AliEMCALRecPoint::GetLocalPosition(TVector3 & lpos) const { // returns the position of the cluster in the local reference system // of the sub-detector lpos = fLocPos; } //____________________________________________________________________________ void AliEMCALRecPoint::GetGlobalPosition(TVector3 & gpos) const { // returns the position of the cluster in the global reference system of ALICE // These are now the Cartesian X, Y and Z // cout<<" geom "<GetGlobal(fLocPos, gpos, fSuperModuleNumber); gpos = fGlobPos; } //____________________________________________________________________________ //void AliEMCALRecPoint::GetGlobalPosition(TVector3 & gpos, TMatrixF & gmat) const //{ // // returns the position of the cluster in the global reference system of ALICE // // These are now the Cartesian X, Y and Z // // cout<<" geom "<GetGlobalEMCAL(this, gpos, gmat); // //} //_____________________________________________________________________________ void AliEMCALRecPoint::EvalLocal2TrackingCSTransform() { //Evaluates local to "tracking" c.s. transformation (B.P.). //All evaluations should be completed before calling for this //function. //See ALICE PPR Chapter 5 p.18 for "tracking" c.s. definition, //or just ask Jouri Belikov. :) SetVolumeId(AliGeomManager::LayerToVolUID(AliGeomManager::kEMCAL,GetSuperModuleNumber())); const TGeoHMatrix* tr2loc = GetTracking2LocalMatrix(); if(!tr2loc) AliFatal(Form("No Tracking2LocalMatrix found.")); Double_t lxyz[3] = {fLocPos.X(),fLocPos.Y(),fLocPos.Z()}; Double_t txyz[3] = {0,0,0}; tr2loc->MasterToLocal(lxyz,txyz); SetX(txyz[0]); SetY(txyz[1]); SetZ(txyz[2]); if(AliLog::GetGlobalDebugLevel()>0) { TVector3 gpos; //TMatrixF gmat; //GetGlobalPosition(gpos,gmat); //Not doing anythin special, replace by next line. fGeomPtr->GetGlobal(fLocPos, gpos, GetSuperModuleNumber()); Float_t gxyz[3]; GetGlobalXYZ(gxyz); AliInfo(Form("lCS-->(%.3f,%.3f,%.3f), tCS-->(%.3f,%.3f,%.3f), gCS-->(%.3f,%.3f,%.3f), gCScalc-\ ->(%.3f,%.3f,%.3f), supermodule %d", fLocPos.X(),fLocPos.Y(),fLocPos.Z(), GetX(),GetY(),GetZ(), gpos.X(),gpos.Y(),gpos.Z(), gxyz[0],gxyz[1],gxyz[2],GetSuperModuleNumber())); } } //____________________________________________________________________________ Float_t AliEMCALRecPoint::GetMaximalEnergy(void) const { // Finds the maximum energy in the cluster Float_t menergy = 0. ; Int_t iDigit; for(iDigit=0; iDigit menergy) menergy = fEnergyList[iDigit] ; } return menergy ; } //____________________________________________________________________________ Int_t AliEMCALRecPoint::GetMaximalEnergyIndex(void) const { // Finds the maximum energy in the cluster Float_t menergy = 0. ; Int_t mid = 0 ; Int_t iDigit; for(iDigit=0; iDigit menergy){ menergy = fEnergyList[iDigit] ; mid = iDigit ; } }//loop on cluster digits return mid ; } //____________________________________________________________________________ Int_t AliEMCALRecPoint::GetMultiplicityAtLevel(Float_t H) const { // Calculates the multiplicity of digits with energy larger than H*energy Int_t multipl = 0 ; Int_t iDigit ; for(iDigit=0; iDigit H * fAmp) multipl++ ; } return multipl ; } //____________________________________________________________________________ Int_t AliEMCALRecPoint::GetNumberOfLocalMax(AliEMCALDigit ** maxAt, Float_t * maxAtEnergy, Float_t locMaxCut,TClonesArray * digits) const { // Calculates the number of local maxima in the cluster using fLocalMaxCut as the minimum // energy difference between two local maxima AliEMCALDigit * digit = 0; AliEMCALDigit * digitN = 0; Int_t iDigitN = 0 ; Int_t iDigit = 0 ; for(iDigit = 0; iDigit < fMulDigit; iDigit++) maxAt[iDigit] = (AliEMCALDigit*) digits->At(fDigitsList[iDigit]) ; for(iDigit = 0 ; iDigit < fMulDigit; iDigit++) { if(maxAt[iDigit]) { digit = maxAt[iDigit] ; for(iDigitN = 0; iDigitN < fMulDigit; iDigitN++) { if(iDigitN == iDigit) continue;//the same digit digitN = (AliEMCALDigit *) digits->At(fDigitsList[iDigitN]) ; if ( AreNeighbours(digit, digitN) ) { if (fEnergyList[iDigit] > fEnergyList[iDigitN] ) { maxAt[iDigitN] = 0 ; // but may be digit too is not local max ? if(fEnergyList[iDigit] < fEnergyList[iDigitN] + locMaxCut) maxAt[iDigit] = 0 ; } else { maxAt[iDigit] = 0 ; // but may be digitN too is not local max ? if(fEnergyList[iDigit] > fEnergyList[iDigitN] - locMaxCut) maxAt[iDigitN] = 0 ; } } // if Areneighbours } // while digitN } // slot not empty } // while digit iDigitN = 0 ; for(iDigit = 0; iDigit < fMulDigit; iDigit++) { if(maxAt[iDigit] ){ maxAt[iDigitN] = maxAt[iDigit] ; maxAtEnergy[iDigitN] = fEnergyList[iDigit] ; iDigitN++ ; } } return iDigitN ; } //____________________________________________________________________________ Int_t AliEMCALRecPoint::GetPrimaryIndex() const { // Get the primary track index in TreeK which deposits the most energy // in Digits which forms RecPoint. if (fMulTrack) return fTracksList[0]; return -12345; } //____________________________________________________________________________ void AliEMCALRecPoint::EvalTime(TClonesArray * digits){ // time is set to the time of the digit with the maximum energy Float_t maxE = 0; Int_t maxAt = 0; for(Int_t idig=0; idig < fMulDigit; idig++){ if(fEnergyList[idig] > maxE){ maxE = fEnergyList[idig] ; maxAt = idig; } } fTime = ((AliEMCALDigit*) digits->At(fDigitsList[maxAt]))->GetTime() ; } //______________________________________________________________________________ void AliEMCALRecPoint::Paint(Option_t *) { // Paint this ALiRecPoint as a TMarker with its current attributes TVector3 pos(0.,0.,0.) ; GetLocalPosition(pos) ; Coord_t x = pos.X() ; Coord_t y = pos.Z() ; Color_t markercolor = 1 ; Size_t markersize = 1.; Style_t markerstyle = 5 ; if (!gPad->IsBatch()) { gVirtualX->SetMarkerColor(markercolor) ; gVirtualX->SetMarkerSize (markersize) ; gVirtualX->SetMarkerStyle(markerstyle) ; } gPad->SetAttMarkerPS(markercolor,markerstyle,markersize) ; gPad->PaintPolyMarker(1,&x,&y,"") ; } //_____________________________________________________________________ Double_t AliEMCALRecPoint::TmaxInCm(const Double_t e , const Int_t key) { // e energy in GeV) // key = 0(gamma, default) // != 0(electron) const Double_t ca = 4.82; // shower max parameter - first guess; ca=TMath::Log(1000./8.07) Double_t tmax = 0.; // position of electromagnetic shower max in cm Double_t x0 = 1.31; // radiation lenght (cm) //If old geometry in use if(!((fGeomPtr->GetEMCGeometry()->GetGeoName()).Contains("V1"))) x0 = 1.28; if(e>0.1) { tmax = TMath::Log(e) + ca; if (key==0) tmax += 0.5; else tmax -= 0.5; tmax *= x0; // convert to cm } return tmax; } //______________________________________________________________________________ Float_t AliEMCALRecPoint::EtaToTheta(Float_t arg) const { //Converts Theta (Radians) to Eta(Radians) return (2.*TMath::ATan(TMath::Exp(-arg))); } //______________________________________________________________________________ Float_t AliEMCALRecPoint::ThetaToEta(Float_t arg) const { //Converts Eta (Radians) to Theta(Radians) return (-1 * TMath::Log(TMath::Tan(0.5 * arg))); } //____________________________________________________________________________ void AliEMCALRecPoint::Print(Option_t *opt) const { // Print the list of digits belonging to the cluster if(strlen(opt)==0) return; TString message ; message = "AliEMCALRecPoint:\n" ; message += " digits # = " ; AliInfo(message.Data()) ; Int_t iDigit; for(iDigit=0; iDigit