/************************************************************************** * 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. * **************************************************************************/ /* $Id$ */ /////////////////////////////////////////////////////////////////////////////// // // // class for ZDC reconstruction // // // /////////////////////////////////////////////////////////////////////////////// #include #include "AliRunLoader.h" #include "AliRawReader.h" #include "AliESDEvent.h" #include "AliESDZDC.h" #include "AliZDCDigit.h" #include "AliZDCRawStream.h" #include "AliZDCReco.h" #include "AliZDCReconstructor.h" #include "AliZDCPedestals.h" #include "AliZDCCalib.h" #include "AliZDCRecoParam.h" #include "AliZDCRecoParampp.h" #include "AliZDCRecoParamPbPb.h" ClassImp(AliZDCReconstructor) AliZDCRecoParam *AliZDCReconstructor::fRecoParam=0; //reconstruction parameters //_____________________________________________________________________________ AliZDCReconstructor:: AliZDCReconstructor() : fPedData(GetPedData()), fECalibData(GetECalibData()) { // **** Default constructor } //_____________________________________________________________________________ AliZDCReconstructor::~AliZDCReconstructor() { // destructor if(fRecoParam) delete fRecoParam; if(fPedData) delete fPedData; if(fECalibData) delete fECalibData; } //_____________________________________________________________________________ void AliZDCReconstructor::Reconstruct(TTree* digitsTree, TTree* clustersTree) const { // *** Local ZDC reconstruction for digits // Works on the current event // Retrieving calibration data Float_t meanPed[48]; for(Int_t jj=0; jj<48; jj++) meanPed[jj] = fPedData->GetMeanPed(jj); // get digits AliZDCDigit digit; AliZDCDigit* pdigit = &digit; digitsTree->SetBranchAddress("ZDC", &pdigit); //printf("\n\t # of digits in tree: %d\n",(Int_t) digitsTree->GetEntries()); // loop over digits Float_t tZN1Corr[10], tZP1Corr[10], tZN2Corr[10], tZP2Corr[10]; Float_t dZEM1Corr[2], dZEM2Corr[2], PMRef1[2], PMRef2[2]; for(Int_t i=0; i<10; i++){ tZN1Corr[i] = tZP1Corr[i] = tZN2Corr[i] = tZP2Corr[i] = 0.; if(i<2) dZEM1Corr[i] = dZEM2Corr[i] = PMRef1[i] = PMRef2[i] = 0.; } // for (Int_t iDigit = 0; iDigit < (digitsTree->GetEntries()/2); iDigit++) { digitsTree->GetEntry(iDigit); if (!pdigit) continue; // Int_t det = digit.GetSector(0); Int_t quad = digit.GetSector(1); Int_t pedindex = -1, kNch = 24; //printf("\n\t Digit #%d det %d quad %d", iDigit, det, quad); // if(quad != 5){ // ZDC (not reference PTMs!) if(det == 1){ // *** ZNC pedindex = quad; tZN1Corr[quad] = (Float_t) (digit.GetADCValue(0)-meanPed[pedindex]); if(tZN1Corr[quad]<0.) tZN1Corr[quad] = 0.; tZN1Corr[quad+5] = (Float_t) (digit.GetADCValue(1)-meanPed[pedindex+kNch]); if(tZN1Corr[quad+5]<0.) tZN1Corr[quad+5] = 0.; //printf("\t pedindex %d tZN1Corr[%d] = %1.0f tZN1Corr[%d] = %1.0f", // pedindex, quad, tZN1Corr[quad], quad+5, tZN1Corr[quad+5]); } else if(det == 2){ // *** ZP1 pedindex = quad+5; tZP1Corr[quad] = (Float_t) (digit.GetADCValue(0)-meanPed[pedindex]); if(tZP1Corr[quad]<0.) tZP1Corr[quad] = 0.; tZP1Corr[quad+5] = (Float_t) (digit.GetADCValue(1)-meanPed[pedindex+kNch]); if(tZP1Corr[quad+5]<0.) tZP1Corr[quad+5] = 0.; //printf("\t pedindex %d tZP1Corr[%d] = %1.0f tZP1Corr[%d] = %1.0f", // pedindex, quad, tZP1Corr[quad], quad+5, tZP1Corr[quad+5]); } else if(det == 3){ pedindex = quad+9; if(quad == 1){ // *** ZEM1 dZEM1Corr[0] += (Float_t) (digit.GetADCValue(0)-meanPed[pedindex]); if(dZEM1Corr[0]<0.) dZEM1Corr[0] = 0.; dZEM1Corr[1] += (Float_t) (digit.GetADCValue(1)-meanPed[pedindex+kNch]); if(dZEM1Corr[1]<0.) dZEM1Corr[1] = 0.; //printf("\t pedindex %d tZEM1Corr[%d] = %1.0f tZEM1Corr[%d] = %1.0f", // pedindex, quad, tZEM1Corr[quad], quad+1, tZEM1Corr[quad+1]); } else if(quad == 2){ // *** ZEM2 dZEM2Corr[0] += (Float_t) (digit.GetADCValue(0)-meanPed[pedindex]); if(dZEM2Corr[0]<0.) dZEM2Corr[0] = 0.; dZEM2Corr[1] += (Float_t) (digit.GetADCValue(1)-meanPed[pedindex+kNch]); if(dZEM2Corr[1]<0.) dZEM2Corr[1] = 0.; //printf("\t pedindex %d tZEM2Corr[%d] = %1.0f tZEM2Corr[%d] = %1.0f", // pedindex, quad, tZEM2Corr[quad], quad+1, tZEM2Corr[quad+1]); } } else if(det == 4){ // *** ZN2 pedindex = quad+12; tZN2Corr[quad] = (Float_t) (digit.GetADCValue(0)-meanPed[pedindex]); if(tZN2Corr[quad]<0.) tZN2Corr[quad] = 0.; tZN2Corr[quad+5] = (Float_t) (digit.GetADCValue(1)-meanPed[pedindex+kNch]); if(tZN2Corr[quad+5]<0.) tZN2Corr[quad+5] = 0.; //printf("\t pedindex %d tZN2Corr[%d] = %1.0f tZN2Corr[%d] = %1.0f\n", // pedindex, quad, tZN2Corr[quad], quad+5, tZN2Corr[quad+5]); } else if(det == 5){ // *** ZP2 pedindex = quad+17; tZP2Corr[quad] = (Float_t) (digit.GetADCValue(0)-meanPed[pedindex]); if(tZP2Corr[quad]<0.) tZP2Corr[quad] = 0.; tZP2Corr[quad+5] = (Float_t) (digit.GetADCValue(1)-meanPed[pedindex+kNch]); if(tZP2Corr[quad+5]<0.) tZP2Corr[quad+5] = 0.; //printf("\t pedindex %d tZP2Corr[%d] = %1.0f tZP2Corr[%d] = %1.0f\n", // pedindex, quad, tZP2Corr[quad], quad+5, tZP2Corr[quad+5]); } } else{ // Reference PMs pedindex = (det-1)/3+22; if(det == 1){ PMRef1[0] = (Float_t) (digit.GetADCValue(0)-meanPed[pedindex]); if(PMRef1[0]<0.) PMRef1[0] = 0.; PMRef1[1] = (Float_t) (digit.GetADCValue(1)-meanPed[pedindex+kNch]); if(PMRef2[1]<0.) PMRef1[1] = 0.; } else if(det == 4){ PMRef2[0] = (Float_t) (digit.GetADCValue(0)-meanPed[pedindex]); if(PMRef2[0]<0.) PMRef2[0] = 0.; PMRef2[1] = (Float_t) (digit.GetADCValue(1)-meanPed[pedindex+kNch]); if(PMRef2[1]<0.) PMRef2[1] = 0.; } } } // reconstruct the event ReconstructEventpp(clustersTree, tZN1Corr, tZP1Corr, tZN2Corr, tZP2Corr, dZEM1Corr, dZEM2Corr, PMRef1, PMRef2); } //_____________________________________________________________________________ void AliZDCReconstructor::Reconstruct(AliRawReader* rawReader, TTree* clustersTree) const { // *** ZDC raw data reconstruction // Works on the current event // Retrieving calibration data Float_t meanPed[48]; for(Int_t jj=0; jj<48; jj++) meanPed[jj] = fPedData->GetMeanPed(jj); rawReader->Reset(); // loop over raw data Float_t tZN1Corr[10], tZP1Corr[10], tZN2Corr[10], tZP2Corr[10]; Float_t dZEM1Corr[2], dZEM2Corr[2], PMRef1[2], PMRef2[2]; for(Int_t i=0; i<10; i++){ tZN1Corr[i] = tZP1Corr[i] = tZN2Corr[i] = tZP2Corr[i] = 0.; if(i<2) dZEM1Corr[i] = dZEM2Corr[i] = PMRef1[i] = PMRef2[i] = 0.; } // AliZDCRawStream rawData(rawReader); Int_t kNch = 24; while (rawData.Next()) { if(rawData.IsADCDataWord()){ Int_t det = rawData.GetSector(0); Int_t quad = rawData.GetSector(1); Int_t gain = rawData.GetADCGain(); Int_t pedindex=0; // if(quad !=5){ // ZDCs (not reference PTMs) if(det == 1){ pedindex = quad; if(gain == 0) tZN1Corr[quad] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); else tZN1Corr[quad+5] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex+kNch]); } else if(det == 2){ pedindex = quad+5; if(gain == 0) tZP1Corr[quad] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); else tZP1Corr[quad+5] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex+kNch]); } else if(det == 3){ pedindex = quad+9; if(quad==1){ if(gain == 0) dZEM1Corr[0] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); else dZEM1Corr[1] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex+kNch]); } else if(quad==2){ if(gain == 0) dZEM2Corr[0] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); else dZEM2Corr[1] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex+kNch]); } } else if(det == 4){ pedindex = quad+12; if(gain == 0) tZN2Corr[quad] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); else tZN2Corr[quad+5] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex+kNch]); } else if(det == 5){ pedindex = quad+17; if(gain == 0) tZP2Corr[quad] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); else tZP2Corr[quad+5] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex+kNch]); } //printf("\t AliZDCReconstructor - det %d quad %d res %d -> Ped[%d] = %1.0f\n", // det,quad,gain, pedindex, meanPed[pedindex]); } else{ // reference PM pedindex = (det-1)/3 + 22; if(det == 1){ if(gain==0) PMRef1[0] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); else PMRef1[1] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); } else if(det ==4){ if(gain==0) PMRef2[0] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); else PMRef2[1] += (Float_t) (rawData.GetADCValue()-meanPed[pedindex]); } } }//IsADCDataWord } // reconstruct the event ReconstructEventpp(clustersTree, tZN1Corr, tZP1Corr, tZN2Corr, tZP2Corr, dZEM1Corr, dZEM2Corr, PMRef1, PMRef2); } //_____________________________________________________________________________ void AliZDCReconstructor::ReconstructEventpp(TTree *clustersTree, Float_t* ZN1ADCCorr, Float_t* ZP1ADCCorr, Float_t* ZN2ADCCorr, Float_t* ZP2ADCCorr, Float_t* ZEM1ADCCorr, Float_t* ZEM2ADCCorr, Float_t* PMRef1, Float_t* PMRef2) const { // ***** Reconstruct one event // *** RECONSTRUCTION FROM "REAL" DATA // // Retrieving calibration data // --- Equalization coefficients --------------------------------------------- Float_t equalCoeffZN1[5], equalCoeffZP1[5], equalCoeffZN2[5], equalCoeffZP2[5]; for(Int_t ji=0; ji<5; ji++){ equalCoeffZN1[ji] = fECalibData->GetZN1EqualCoeff(ji); equalCoeffZP1[ji] = fECalibData->GetZP1EqualCoeff(ji); equalCoeffZN2[ji] = fECalibData->GetZN2EqualCoeff(ji); equalCoeffZP2[ji] = fECalibData->GetZP2EqualCoeff(ji); } // --- Energy calibration factors ------------------------------------ Float_t calibEne[4]; // ********************************************************************* // **** Until the beam type info isn't known @ reconstruction level **** // **** the energy calibration coefficient are manually set to 1 **** // **** as it will be in real life for pp data taking **** // ********************************************************************* //for(Int_t ij=0; ij<4; ij++) calibEne[ij] = fECalibData->GetEnCalib(ij); for(Int_t ij=0; ij<4; ij++) calibEne[ij] = 1.; // Equalization of detector responses Float_t equalTowZN1[10], equalTowZN2[10], equalTowZP1[10], equalTowZP2[10]; for(Int_t gi=0; gi<5; gi++){ equalTowZN1[gi] = ZN1ADCCorr[gi]*equalCoeffZN1[gi]; equalTowZN1[gi+5] = ZN1ADCCorr[gi+5]*equalCoeffZN1[gi]; equalTowZP1[gi] = ZP1ADCCorr[gi]*equalCoeffZP1[gi]; equalTowZP1[gi+5] = ZP1ADCCorr[gi+5]*equalCoeffZP1[gi]; equalTowZN2[gi] = ZN2ADCCorr[gi]*equalCoeffZN2[gi]; equalTowZN2[gi+5] = ZN2ADCCorr[gi+5]*equalCoeffZN2[gi]; equalTowZP2[gi] = ZP2ADCCorr[gi]*equalCoeffZP2[gi]; equalTowZP2[gi+5] = ZP2ADCCorr[gi+5]*equalCoeffZP2[gi]; } // Energy calibration of detector responses Float_t calibTowZN1[10], calibTowZN2[10], calibTowZP1[10], calibTowZP2[10]; Float_t calibSumZN1[]={0,0}, calibSumZN2[]={0,0}, calibSumZP1[]={0,0}, calibSumZP2[]={0,0}; for(Int_t gi=0; gi<10; gi++){ calibTowZN1[gi] = equalTowZN1[gi]*calibEne[0]; calibTowZP1[gi] = equalTowZP1[gi]*calibEne[1]; calibTowZN2[gi] = equalTowZN2[gi]*calibEne[2]; calibTowZP2[gi] = equalTowZP2[gi]*calibEne[3]; // if(gi<5){ calibSumZN1[0] += calibTowZN1[gi]; calibSumZP1[0] += calibTowZP1[gi]; calibSumZN2[0] += calibTowZN2[gi]; calibSumZP2[0] += calibTowZP2[gi]; } // else{ calibSumZN1[1] += calibTowZN1[gi]; calibSumZP1[1] += calibTowZP1[gi]; calibSumZN2[1] += calibTowZN2[gi]; calibSumZP2[1] += calibTowZP2[gi]; } } // // --- Reconstruction parameters ------------------ if(!fRecoParam) fRecoParam = (AliZDCRecoParampp*) AliZDCRecoParampp::GetppRecoParam(); // --- Number of detected spectator nucleons // *** N.B. -> It works only in Pb-Pb Int_t nDetSpecNLeft, nDetSpecPLeft, nDetSpecNRight, nDetSpecPRight; Float_t beamE = fRecoParam->GetBeamEnergy(); nDetSpecNLeft = (Int_t) (calibSumZN1[0]/beamE); nDetSpecPLeft = (Int_t) (calibSumZP1[0]/beamE); nDetSpecNRight = (Int_t) (calibSumZN2[0]/beamE); nDetSpecPRight = (Int_t) (calibSumZP2[0]/beamE); /*printf("\n\t AliZDCReconstructor -> nDetSpecNLeft %d, nDetSpecPLeft %d," " nDetSpecNRight %d, nDetSpecPRight %d\n",nDetSpecNLeft, nDetSpecPLeft, nDetSpecNRight, nDetSpecPRight);*/ // --- Number of generated spectator nucleons (from HIJING parameterization) Int_t nGenSpecNLeft=0, nGenSpecPLeft=0, nGenSpecLeft=0; Int_t nGenSpecNRight=0, nGenSpecPRight=0, nGenSpecRight=0; Int_t nPartTotLeft=0, nPartTotRight=0; Double_t impPar=0.; // create the output tree AliZDCReco reco(calibSumZN1, calibSumZP1, calibSumZN2, calibSumZP2, calibTowZN1, calibTowZP1, calibTowZN2, calibTowZP2, ZEM1ADCCorr, ZEM2ADCCorr, PMRef1, PMRef2, nDetSpecNLeft, nDetSpecPLeft, nDetSpecNRight, nDetSpecPRight, nGenSpecNLeft, nGenSpecPLeft, nGenSpecLeft, nGenSpecNRight, nGenSpecPRight, nGenSpecRight, nPartTotLeft, nPartTotRight, impPar); AliZDCReco* preco = &reco; const Int_t kBufferSize = 4000; clustersTree->Branch("ZDC", "AliZDCReco", &preco, kBufferSize); // write the output tree clustersTree->Fill(); } //_____________________________________________________________________________ void AliZDCReconstructor::ReconstructEventPbPb(TTree *clustersTree, Float_t* ZN1ADCCorr, Float_t* ZP1ADCCorr, Float_t* ZN2ADCCorr, Float_t* ZP2ADCCorr, Float_t* ZEM1ADCCorr, Float_t* ZEM2ADCCorr, Float_t* PMRef1, Float_t* PMRef2) const { // ***** Reconstruct one event // *** RECONSTRUCTION FROM "REAL" DATA // // Retrieving calibration data // --- Equalization coefficients --------------------------------------------- Float_t equalCoeffZN1[5], equalCoeffZP1[5], equalCoeffZN2[5], equalCoeffZP2[5]; for(Int_t ji=0; ji<5; ji++){ equalCoeffZN1[ji] = fECalibData->GetZN1EqualCoeff(ji); equalCoeffZP1[ji] = fECalibData->GetZP1EqualCoeff(ji); equalCoeffZN2[ji] = fECalibData->GetZN2EqualCoeff(ji); equalCoeffZP2[ji] = fECalibData->GetZP2EqualCoeff(ji); } // --- Energy calibration factors ------------------------------------ Float_t calibEne[4]; for(Int_t ij=0; ij<4; ij++) calibEne[ij] = fECalibData->GetEnCalib(ij); // Equalization of detector responses Float_t equalTowZN1[10], equalTowZN2[10], equalTowZP1[10], equalTowZP2[10]; for(Int_t gi=0; gi<5; gi++){ equalTowZN1[gi] = ZN1ADCCorr[gi]*equalCoeffZN1[gi]; equalTowZN1[gi+5] = ZN1ADCCorr[gi+5]*equalCoeffZN1[gi]; equalTowZP1[gi] = ZP1ADCCorr[gi]*equalCoeffZP1[gi]; equalTowZP1[gi+5] = ZP1ADCCorr[gi+5]*equalCoeffZP1[gi]; equalTowZN2[gi] = ZN2ADCCorr[gi]*equalCoeffZN2[gi]; equalTowZN2[gi+5] = ZN2ADCCorr[gi+5]*equalCoeffZN2[gi]; equalTowZP2[gi] = ZP2ADCCorr[gi]*equalCoeffZP2[gi]; equalTowZP2[gi+5] = ZP2ADCCorr[gi+5]*equalCoeffZP2[gi]; } // Energy calibration of detector responses Float_t calibTowZN1[10], calibTowZN2[10], calibTowZP1[10], calibTowZP2[10]; Float_t calibSumZN1[]={0,0}, calibSumZN2[]={0,0}, calibSumZP1[]={0,0}, calibSumZP2[]={0,0}; for(Int_t gi=0; gi<10; gi++){ calibTowZN1[gi] = equalTowZN1[gi]*calibEne[0]; calibTowZP1[gi] = equalTowZP1[gi]*calibEne[1]; calibTowZN2[gi] = equalTowZN2[gi]*calibEne[2]; calibTowZP2[gi] = equalTowZP2[gi]*calibEne[3]; // if(gi<5){ calibSumZN1[0] += calibTowZN1[gi]; calibSumZP1[0] += calibTowZP1[gi]; calibSumZN2[0] += calibTowZN2[gi]; calibSumZP2[0] += calibTowZP2[gi]; } // else{ calibSumZN1[1] += calibTowZN1[gi]; calibSumZP1[1] += calibTowZP1[gi]; calibSumZN2[1] += calibTowZN2[gi]; calibSumZP2[1] += calibTowZP2[gi]; } } // // --- Reconstruction parameters ------------------ if(!fRecoParam) fRecoParam = (AliZDCRecoParamPbPb*) AliZDCRecoParamPbPb::GetPbPbRecoParam(); // Float_t endPointZEM = fRecoParam->GetZEMEndValue(); Float_t cutFractionZEM = fRecoParam->GetZEMCutFraction(); Float_t dZEMSup = fRecoParam->GetDZEMSup(); Float_t dZEMInf = fRecoParam->GetDZEMInf(); // Float_t cutValueZEM = endPointZEM*cutFractionZEM; Float_t supValueZEM = cutValueZEM+(endPointZEM*dZEMSup); Float_t infValueZEM = cutValueZEM-(endPointZEM*dZEMInf); // Float_t maxValEZN1 = fRecoParam->GetEZN1MaxValue(); Float_t maxValEZP1 = fRecoParam->GetEZP1MaxValue(); Float_t maxValEZDC1 = fRecoParam->GetEZDC1MaxValue(); Float_t maxValEZN2 = fRecoParam->GetEZN2MaxValue(); Float_t maxValEZP2 = fRecoParam->GetEZP2MaxValue(); Float_t maxValEZDC2 = fRecoParam->GetEZDC2MaxValue(); // //printf("\n\t AliZDCReconstructor -> ZEMEndPoint %1.0f, ZEMCutValue %1.0f," // " ZEMSupValue %1.0f, ZEMInfValue %1.0f\n",endPointZEM,cutValueZEM,supValueZEM,infValueZEM); // --- Number of detected spectator nucleons // *** N.B. -> It works only in Pb-Pb Int_t nDetSpecNLeft, nDetSpecPLeft, nDetSpecNRight, nDetSpecPRight; Float_t beamE = fRecoParam->GetBeamEnergy(); nDetSpecNLeft = (Int_t) (calibSumZN1[0]/beamE); nDetSpecPLeft = (Int_t) (calibSumZP1[0]/beamE); nDetSpecNRight = (Int_t) (calibSumZN2[0]/beamE); nDetSpecPRight = (Int_t) (calibSumZP2[0]/beamE); /*printf("\n\t AliZDCReconstructor -> nDetSpecNLeft %d, nDetSpecPLeft %d," " nDetSpecNRight %d, nDetSpecPRight %d\n",nDetSpecNLeft, nDetSpecPLeft, nDetSpecNRight, nDetSpecPRight);*/ // --- Number of generated spectator nucleons (from HIJING parameterization) Int_t nGenSpecNLeft=0, nGenSpecPLeft=0, nGenSpecLeft=0; Int_t nGenSpecNRight=0, nGenSpecPRight=0, nGenSpecRight=0; Double_t impPar=0.; // Float_t corrADCZEMHG = ZEM1ADCCorr[0] + ZEM2ADCCorr[0]; // if(corrADCZEMHG > supValueZEM){ nGenSpecNLeft = (Int_t) ((fRecoParam->GetfZNCen())->Eval(calibSumZN1[0])); nGenSpecPLeft = (Int_t) ((fRecoParam->GetfZPCen())->Eval(calibSumZP1[0])); nGenSpecLeft = (Int_t) ((fRecoParam->GetfZDCCen())->Eval(calibSumZN1[0]+calibSumZP1[0])); nGenSpecNRight = (Int_t) ((fRecoParam->GetfZNCen())->Eval(calibSumZN2[0])); nGenSpecPRight = (Int_t) ((fRecoParam->GetfZNCen())->Eval(calibSumZP2[0])); nGenSpecRight = (Int_t) ((fRecoParam->GetfZNCen())->Eval(calibSumZN2[0]+calibSumZP2[0])); impPar = (fRecoParam->GetfbCen())->Eval(calibSumZN1[0]+calibSumZP1[0]); } else if(corrADCZEMHG < infValueZEM){ nGenSpecNLeft = (Int_t) ((fRecoParam->GetfZNPer())->Eval(calibSumZN1[0])); nGenSpecPLeft = (Int_t) ((fRecoParam->GetfZPPer())->Eval(calibSumZP1[0])); nGenSpecLeft = (Int_t) ((fRecoParam->GetfZDCPer())->Eval(calibSumZN1[0]+calibSumZP1[0])); impPar = (fRecoParam->GetfbPer())->Eval(calibSumZN1[0]+calibSumZP1[0]); } else if(corrADCZEMHG >= infValueZEM && corrADCZEMHG <= supValueZEM){ nGenSpecNLeft = (Int_t) ((fRecoParam->GetfZEMn())->Eval(corrADCZEMHG)); nGenSpecPLeft = (Int_t) ((fRecoParam->GetfZEMp())->Eval(corrADCZEMHG)); nGenSpecLeft = (Int_t)((fRecoParam->GetfZEMsp())->Eval(corrADCZEMHG)); impPar = (fRecoParam->GetfZEMb())->Eval(corrADCZEMHG); } // if(calibSumZN1[0]/maxValEZN1>1.) nGenSpecNLeft = (Int_t) ((fRecoParam->GetfZEMn())->Eval(corrADCZEMHG)); if(calibSumZP1[0]/maxValEZP1>1.) nGenSpecPLeft = (Int_t) ((fRecoParam->GetfZEMp())->Eval(corrADCZEMHG)); if((calibSumZN1[0]+calibSumZP1[0]/maxValEZDC1)>1.){ nGenSpecLeft = (Int_t)((fRecoParam->GetfZEMsp())->Eval(corrADCZEMHG)); impPar = (fRecoParam->GetfZEMb())->Eval(corrADCZEMHG); } if(calibSumZN2[0]/maxValEZN2>1.) nGenSpecNRight = (Int_t) ((fRecoParam->GetfZEMn())->Eval(corrADCZEMHG)); if(calibSumZP2[0]/maxValEZP2>1.) nGenSpecPRight = (Int_t) ((fRecoParam->GetfZEMp())->Eval(corrADCZEMHG)); if((calibSumZN2[0]+calibSumZP2[0]/maxValEZDC2)>1.) nGenSpecRight = (Int_t)((fRecoParam->GetfZEMsp())->Eval(corrADCZEMHG)); // if(nGenSpecNLeft>125) nGenSpecNLeft=125; else if(nGenSpecNLeft<0) nGenSpecNLeft=0; if(nGenSpecPLeft>82) nGenSpecPLeft=82; else if(nGenSpecPLeft<0) nGenSpecPLeft=0; if(nGenSpecLeft>207) nGenSpecLeft=207; else if(nGenSpecLeft<0) nGenSpecLeft=0; // --- Number of generated participants (from HIJING parameterization) Int_t nPart, nPartTotLeft, nPartTotRight; nPart = 207-nGenSpecNLeft-nGenSpecPLeft; nPartTotLeft = 207-nGenSpecLeft; nPartTotRight = 207-nGenSpecRight; if(nPart<0) nPart=0; if(nPartTotLeft<0) nPartTotLeft=0; if(nPartTotRight<0) nPartTotRight=0; // // *** DEBUG *** /*printf("\n\t AliZDCReconstructor -> calibSumZN1[0] %1.0f, calibSumZP1[0] %1.0f," " calibSumZN2[0] %1.0f, calibSumZP2[0] %1.0f, corrADCZEMHG %1.0f\n", calibSumZN1[0],calibSumZP1[0],calibSumZN2[0],calibSumZP2[0],corrADCZEMHG); printf("\t AliZDCReconstructor -> nGenSpecNLeft %d, nGenSpecPLeft %d, nGenSpecLeft %d\n" "\t\t nGenSpecNRight %d, nGenSpecPRight %d, nGenSpecRight %d\n", nGenSpecNLeft, nGenSpecPLeft, nGenSpecLeft, nGenSpecNRight, nGenSpecPRight, nGenSpecRight); printf("\t AliZDCReconstructor -> NpartL %d, NpartR %d, b %1.2f fm\n\n",nPartTotLeft, nPartTotRight, impPar); */ // create the output tree AliZDCReco reco(calibSumZN1, calibSumZP1, calibSumZN2, calibSumZP2, calibTowZN1, calibTowZP1, calibTowZN2, calibTowZP2, ZEM1ADCCorr, ZEM2ADCCorr, PMRef1, PMRef2, nDetSpecNLeft, nDetSpecPLeft, nDetSpecNRight, nDetSpecPRight, nGenSpecNLeft, nGenSpecPLeft, nGenSpecLeft, nGenSpecNRight, nGenSpecPRight, nGenSpecRight, nPartTotLeft, nPartTotRight, impPar); AliZDCReco* preco = &reco; const Int_t kBufferSize = 4000; clustersTree->Branch("ZDC", "AliZDCReco", &preco, kBufferSize); // write the output tree clustersTree->Fill(); } //_____________________________________________________________________________ void AliZDCReconstructor::FillZDCintoESD(TTree *clustersTree, AliESDEvent* esd) const { // fill energies and number of participants to the ESD AliZDCReco reco; AliZDCReco* preco = &reco; clustersTree->SetBranchAddress("ZDC", &preco); clustersTree->GetEntry(0); // AliESDZDC * esdzdc = esd->GetESDZDC(); Float_t tZN1Ene[5], tZN2Ene[5], tZP1Ene[5], tZP2Ene[5]; Float_t tZN1EneLR[5], tZN2EneLR[5], tZP1EneLR[5], tZP2EneLR[5]; for(Int_t i=0; i<5; i++){ tZN1Ene[i] = reco.GetZN1HREnTow(i); tZN2Ene[i] = reco.GetZN2HREnTow(i); tZP1Ene[i] = reco.GetZP1HREnTow(i); tZP2Ene[i] = reco.GetZP2HREnTow(i); // tZN1EneLR[i] = reco.GetZN1LREnTow(i); tZN2EneLR[i] = reco.GetZN2LREnTow(i); tZP1EneLR[i] = reco.GetZP1LREnTow(i); tZP2EneLR[i] = reco.GetZP2LREnTow(i); } esdzdc->SetZN1TowerEnergy(tZN1Ene); esdzdc->SetZN2TowerEnergy(tZN2Ene); esdzdc->SetZP1TowerEnergy(tZP1Ene); esdzdc->SetZP2TowerEnergy(tZP2Ene); esdzdc->SetZN1TowerEnergyLR(tZN1EneLR); esdzdc->SetZN2TowerEnergyLR(tZN2EneLR); esdzdc->SetZP1TowerEnergyLR(tZP1EneLR); esdzdc->SetZP2TowerEnergyLR(tZP2EneLR); // esd->SetZDC(reco.GetZN1HREnergy(), reco.GetZP1HREnergy(), reco.GetZEM1HRsignal(), reco.GetZEM2HRsignal(), reco.GetZN2HREnergy(), reco.GetZP2HREnergy(), reco.GetNPartLeft()); // } //_____________________________________________________________________________ AliCDBStorage* AliZDCReconstructor::SetStorage(const char *uri) { // Setting the storage Bool_t deleteManager = kFALSE; AliCDBManager *manager = AliCDBManager::Instance(); AliCDBStorage *defstorage = manager->GetDefaultStorage(); if(!defstorage || !(defstorage->Contains("ZDC"))){ AliWarning("No default storage set or default storage doesn't contain ZDC!"); manager->SetDefaultStorage(uri); deleteManager = kTRUE; } AliCDBStorage *storage = manager->GetDefaultStorage(); if(deleteManager){ AliCDBManager::Instance()->UnsetDefaultStorage(); defstorage = 0; // the storage is killed by AliCDBManager::Instance()->Destroy() } return storage; } //_____________________________________________________________________________ AliZDCPedestals* AliZDCReconstructor::GetPedData() const { // Getting pedestal calibration object for ZDC set AliCDBEntry *entry = AliCDBManager::Instance()->Get("ZDC/Calib/Pedestals"); if(!entry) AliFatal("No calibration data loaded!"); AliZDCPedestals *calibdata = dynamic_cast (entry->GetObject()); if(!calibdata) AliFatal("Wrong calibration object in calibration file!"); return calibdata; } //_____________________________________________________________________________ AliZDCCalib* AliZDCReconstructor::GetECalibData() const { // Getting energy and equalization calibration object for ZDC set AliCDBEntry *entry = AliCDBManager::Instance()->Get("ZDC/Calib/EMDCalib"); if(!entry) AliFatal("No calibration data loaded!"); AliZDCCalib *calibdata = dynamic_cast (entry->GetObject()); if(!calibdata) AliFatal("Wrong calibration object in calibration file!"); return calibdata; }