/************************************************************************** * 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 VZERO reconstruction // /// // /////////////////////////////////////////////////////////////////////////////// #include #include #include #include "AliRunLoader.h" #include "AliRawReader.h" #include "AliGRPObject.h" #include "AliCDBManager.h" #include "AliCDBStorage.h" #include "AliCDBEntry.h" #include "AliVZEROReconstructor.h" #include "AliVZERORawStream.h" #include "AliVZEROConst.h" #include "AliESDEvent.h" #include "AliVZEROTriggerMask.h" #include "AliESDfriend.h" #include "AliESDVZEROfriend.h" #include "AliVZEROdigit.h" #include "AliVZEROCalibData.h" #include "AliRunInfo.h" #include "AliCTPTimeParams.h" #include "AliLHCClockPhase.h" ClassImp(AliVZEROReconstructor) //_____________________________________________________________________________ AliVZEROReconstructor:: AliVZEROReconstructor(): AliReconstructor(), fESDVZERO(0x0), fESD(0x0), fESDVZEROfriend(0x0), fCalibData(NULL), fTriggerData(NULL), fTimeSlewing(NULL), fSaturationCorr(NULL), fEqFactors(NULL), fCollisionMode(0), fBeamEnergy(0.), fDigitsArray(0) { // Default constructor // Get calibration data fCalibData = GetCalibData(); AliCDBEntry *entry = AliCDBManager::Instance()->Get("GRP/CTP/CTPtiming"); if (!entry) AliFatal("CTP timing parameters are not found in OCDB !"); AliCTPTimeParams *ctpParams = (AliCTPTimeParams*)entry->GetObject(); Float_t l1Delay = (Float_t)ctpParams->GetDelayL1L0()*25.0; AliCDBEntry *entry1 = AliCDBManager::Instance()->Get("GRP/CTP/TimeAlign"); if (!entry1) AliFatal("CTP time-alignment is not found in OCDB !"); AliCTPTimeParams *ctpTimeAlign = (AliCTPTimeParams*)entry1->GetObject(); l1Delay += ((Float_t)ctpTimeAlign->GetDelayL1L0()*25.0); AliCDBEntry *entry2 = AliCDBManager::Instance()->Get("VZERO/Calib/TimeDelays"); if (!entry2) AliFatal("VZERO time delays are not found in OCDB !"); TH1F *delays = (TH1F*)entry2->GetObject(); AliCDBEntry *entry3 = AliCDBManager::Instance()->Get("VZERO/Calib/TimeSlewing"); if (!entry3) AliFatal("VZERO time slewing function is not found in OCDB !"); fTimeSlewing = (TF1*)entry3->GetObject(); AliCDBEntry *entry4 = AliCDBManager::Instance()->Get("GRP/Calib/LHCClockPhase"); if (!entry4) AliFatal("LHC clock-phase shift is not found in OCDB !"); AliLHCClockPhase *phase = (AliLHCClockPhase*)entry4->GetObject(); for(Int_t i = 0 ; i < 64; ++i) { Int_t board = AliVZEROCalibData::GetBoardNumber(i); fTimeOffset[i] = (((Float_t)fCalibData->GetRollOver(board)- (Float_t)fCalibData->GetTriggerCountOffset(board))*25.0+ fCalibData->GetTimeOffset(i)- l1Delay- phase->GetMeanPhase()+ delays->GetBinContent(i+1)+ kV0Offset); } AliCDBEntry *entry5 = AliCDBManager::Instance()->Get("VZERO/Calib/Saturation"); if (!entry5) AliFatal("Saturation entry is not found in OCDB !"); fSaturationCorr = (TObjArray*)entry5->GetObject(); AliCDBEntry *entry6 = AliCDBManager::Instance()->Get("VZERO/Trigger/Data"); if (!entry6) AliFatal("VZERO trigger config data is not found in OCDB !"); fTriggerData = (AliVZEROTriggerData*)entry6->GetObject(); AliCDBEntry *entry7 = AliCDBManager::Instance()->Get("VZERO/Calib/EqualizationFactors"); if (!entry7) AliFatal("VZERO equalization factors are not found in OCDB !"); fEqFactors = (TH1F*)entry7->GetObject(); } //_____________________________________________________________________________ AliVZEROReconstructor& AliVZEROReconstructor::operator = (const AliVZEROReconstructor& /*reconstructor*/) { // assignment operator Fatal("operator =", "assignment operator not implemented"); return *this; } //_____________________________________________________________________________ AliVZEROReconstructor::~AliVZEROReconstructor() { // destructor if(fESDVZERO) delete fESDVZERO; if(fESDVZEROfriend) delete fESDVZEROfriend; if(fDigitsArray) delete fDigitsArray; } //_____________________________________________________________________________ void AliVZEROReconstructor::Init() { // initializer fESDVZERO = new AliESDVZERO; fESDVZEROfriend = new AliESDVZEROfriend; GetCollisionMode(); // fCollisionMode =1 for Pb-Pb simulated data } //______________________________________________________________________ void AliVZEROReconstructor::ConvertDigits(AliRawReader* rawReader, TTree* digitsTree) const { // converts RAW to digits if (!digitsTree) { AliError("No digits tree!"); return; } if (!fDigitsArray) fDigitsArray = new TClonesArray("AliVZEROdigit", 64); digitsTree->Branch("VZERODigit", &fDigitsArray); fESDVZEROfriend->Reset(); rawReader->Reset(); AliVZERORawStream rawStream(rawReader); if (rawStream.Next()) { Int_t aBBflagsV0A = 0; Int_t aBBflagsV0C = 0; Int_t aBGflagsV0A = 0; Int_t aBGflagsV0C = 0; for(Int_t iChannel=0; iChannel < 64; ++iChannel) { Int_t offlineCh = rawStream.GetOfflineChannel(iChannel); // ADC charge samples Short_t chargeADC[AliVZEROdigit::kNClocks]; for(Int_t iClock=0; iClock < AliVZEROdigit::kNClocks; ++iClock) { chargeADC[iClock] = rawStream.GetPedestal(iChannel,iClock); } // Integrator flag Bool_t integrator = rawStream.GetIntegratorFlag(iChannel,AliVZEROdigit::kNClocks/2); // Beam-beam and beam-gas flags if(offlineCh<32) { if (rawStream.GetBBFlag(iChannel,AliVZEROdigit::kNClocks/2)) aBBflagsV0C |= (1 << offlineCh); if (rawStream.GetBGFlag(iChannel,AliVZEROdigit::kNClocks/2)) aBGflagsV0C |= (1 << offlineCh); } else { if (rawStream.GetBBFlag(iChannel,AliVZEROdigit::kNClocks/2)) aBBflagsV0A |= (1 << (offlineCh-32)); if (rawStream.GetBGFlag(iChannel,AliVZEROdigit::kNClocks/2)) aBGflagsV0A |= (1 << (offlineCh-32)); } // HPTDC data (leading time and width) Int_t board = AliVZEROCalibData::GetBoardNumber(offlineCh); Float_t time = rawStream.GetTime(iChannel)*fCalibData->GetTimeResolution(board); Float_t width = rawStream.GetWidth(iChannel)*fCalibData->GetWidthResolution(board); // Add a digit if(!fCalibData->IsChannelDead(iChannel)){ new ((*fDigitsArray)[fDigitsArray->GetEntriesFast()]) AliVZEROdigit(offlineCh, time, width,integrator, chargeADC); } // Filling the part of esd friend object that is available only for raw data fESDVZEROfriend->SetBBScalers(offlineCh,rawStream.GetBBScalers(iChannel)); fESDVZEROfriend->SetBGScalers(offlineCh,rawStream.GetBGScalers(iChannel)); for (Int_t iBunch = 0; iBunch < AliESDVZEROfriend::kNBunches; iBunch++) { fESDVZEROfriend->SetChargeMB(offlineCh,iBunch,rawStream.GetChargeMB(iChannel,iBunch)); fESDVZEROfriend->SetIntMBFlag(offlineCh,iBunch,rawStream.GetIntMBFlag(iChannel,iBunch)); fESDVZEROfriend->SetBBMBFlag(offlineCh,iBunch,rawStream.GetBBMBFlag(iChannel,iBunch)); fESDVZEROfriend->SetBGMBFlag(offlineCh,iBunch,rawStream.GetBGMBFlag(iChannel,iBunch)); } for (Int_t iEv = 0; iEv < AliESDVZEROfriend::kNEvOfInt; iEv++) { fESDVZEROfriend->SetBBFlag(offlineCh,iEv,rawStream.GetBBFlag(iChannel,iEv)); fESDVZEROfriend->SetBGFlag(offlineCh,iEv,rawStream.GetBGFlag(iChannel,iEv)); } } // Filling the global part of esd friend object that is available only for raw data rawStream.FillTriggerBits(fTriggerData); fESDVZEROfriend->SetTriggerInputs(rawStream.GetTriggerInputs()); fESDVZEROfriend->SetTriggerInputsMask(rawStream.GetTriggerInputsMask()); for(Int_t iScaler = 0; iScaler < AliESDVZEROfriend::kNScalers; iScaler++) fESDVZEROfriend->SetTriggerScalers(iScaler,rawStream.GetTriggerScalers(iScaler)); for(Int_t iBunch = 0; iBunch < AliESDVZEROfriend::kNBunches; iBunch++) fESDVZEROfriend->SetBunchNumbersMB(iBunch,rawStream.GetBunchNumbersMB(iBunch)); // Store the BB and BG flags in the digits tree (user info) digitsTree->GetUserInfo()->Add(new TParameter("BBflagsV0A",aBBflagsV0A)); digitsTree->GetUserInfo()->Add(new TParameter("BBflagsV0C",aBBflagsV0C)); digitsTree->GetUserInfo()->Add(new TParameter("BGflagsV0A",aBGflagsV0A)); digitsTree->GetUserInfo()->Add(new TParameter("BGflagsV0C",aBGflagsV0C)); UShort_t chargeA,chargeC; rawStream.CalculateChargeForCentrTriggers(fTriggerData,chargeA,chargeC); digitsTree->GetUserInfo()->Add(new TParameter("ChargeA",(Int_t)chargeA)); digitsTree->GetUserInfo()->Add(new TParameter("ChargeC",(Int_t)chargeC)); digitsTree->GetUserInfo()->Add(new TParameter("TriggerInputs",(Int_t)rawStream.GetTriggerInputs())); digitsTree->Fill(); } fDigitsArray->Clear(); } //______________________________________________________________________ void AliVZEROReconstructor::FillESD(TTree* digitsTree, TTree* /*clustersTree*/, AliESDEvent* esd) const { // fills multiplicities to the ESD - pedestal is now subtracted if (!digitsTree) { AliError("No digits tree!"); return; } TBranch* digitBranch = digitsTree->GetBranch("VZERODigit"); digitBranch->SetAddress(&fDigitsArray); Float_t mult[64]; Float_t adc[64]; Float_t time[64]; Float_t width[64]; Bool_t aBBflag[64]; Bool_t aBGflag[64]; for (Int_t i=0; i<64; i++){ adc[i] = 0.0; mult[i] = 0.0; time[i] = kInvalidTime; width[i] = 0.0; aBBflag[i] = kFALSE; aBGflag[i] = kFALSE; } Int_t aBBflagsV0A = 0; Int_t aBBflagsV0C = 0; Int_t aBGflagsV0A = 0; Int_t aBGflagsV0C = 0; if (digitsTree->GetUserInfo()->FindObject("BBflagsV0A")) { aBBflagsV0A = ((TParameter*)digitsTree->GetUserInfo()->FindObject("BBflagsV0A"))->GetVal(); } else { if (esd && (esd->GetEventType() == 7)) AliWarning("V0A beam-beam flags not found in digits tree UserInfo!"); } if (digitsTree->GetUserInfo()->FindObject("BBflagsV0C")) { aBBflagsV0C = ((TParameter*)digitsTree->GetUserInfo()->FindObject("BBflagsV0C"))->GetVal(); } else { if (esd && (esd->GetEventType() == 7)) AliWarning("V0C beam-beam flags not found in digits tree UserInfo!"); } if (digitsTree->GetUserInfo()->FindObject("BGflagsV0A")) { aBGflagsV0A = ((TParameter*)digitsTree->GetUserInfo()->FindObject("BGflagsV0A"))->GetVal(); } else { if (esd && (esd->GetEventType() == 7)) AliWarning("V0A beam-gas flags not found in digits tree UserInfo!"); } if (digitsTree->GetUserInfo()->FindObject("BGflagsV0C")) { aBGflagsV0C = ((TParameter*)digitsTree->GetUserInfo()->FindObject("BGflagsV0C"))->GetVal(); } else { if (esd && (esd->GetEventType() == 7)) AliWarning("V0C beam-gas flags not found in digits tree UserInfo!"); } // Beam-beam and beam-gas flags (hardware) for (Int_t iChannel = 0; iChannel < 64; ++iChannel) { if(iChannel < 32) { aBBflag[iChannel] = (aBBflagsV0C >> iChannel) & 0x1; aBGflag[iChannel] = (aBGflagsV0C >> iChannel) & 0x1; } else { aBBflag[iChannel] = (aBBflagsV0A >> (iChannel-32)) & 0x1; aBGflag[iChannel] = (aBGflagsV0A >> (iChannel-32)) & 0x1; } } // Fill the trigger charges and bits UShort_t chargeA = 0; UShort_t chargeC = 0; UShort_t triggerInputs = 0; if (digitsTree->GetUserInfo()->FindObject("ChargeA")) { chargeA = (UShort_t)(((TParameter*)digitsTree->GetUserInfo()->FindObject("ChargeA"))->GetVal()); } else { if (esd && (esd->GetEventType() == 7)) AliWarning("V0A trigger charge not found in digits tree UserInfo!"); } if (digitsTree->GetUserInfo()->FindObject("ChargeC")) { chargeC = (UShort_t)(((TParameter*)digitsTree->GetUserInfo()->FindObject("ChargeC"))->GetVal()); } else { if (esd && (esd->GetEventType() == 7)) AliWarning("V0C trigger charge not found in digits tree UserInfo!"); } if (digitsTree->GetUserInfo()->FindObject("TriggerInputs")) { triggerInputs = (UShort_t)(((TParameter*)digitsTree->GetUserInfo()->FindObject("TriggerInputs"))->GetVal()); } else { if (esd && (esd->GetEventType() == 7)) AliWarning("V0C trigger charge not found in digits tree UserInfo!"); } fESDVZERO->SetTriggerChargeA(chargeA); fESDVZERO->SetTriggerChargeC(chargeC); fESDVZERO->SetTriggerBits(triggerInputs); fESDVZERO->SetBit(AliESDVZERO::kTriggerChargeBitsFilled,kTRUE); Int_t nEntries = (Int_t)digitsTree->GetEntries(); for (Int_t e=0; eGetEvent(e); Int_t nDigits = fDigitsArray->GetEntriesFast(); for (Int_t d=0; dAt(d); Int_t pmNumber = digit->PMNumber(); // Pedestal retrieval and suppression Bool_t integrator = digit->Integrator(); Float_t maxadc = 0; Int_t imax = -1; Float_t adcPedSub[AliVZEROdigit::kNClocks]; for(Int_t iClock=0; iClock < AliVZEROdigit::kNClocks; ++iClock) { Short_t charge = digit->ChargeADC(iClock); Bool_t iIntegrator = (iClock%2 == 0) ? integrator : !integrator; Int_t k = pmNumber + 64*iIntegrator; adcPedSub[iClock] = (Float_t)charge - fCalibData->GetPedestal(k); if(adcPedSub[iClock] <= GetRecoParam()->GetNSigmaPed()*fCalibData->GetSigma(k)) { adcPedSub[iClock] = 0; continue; } if(iClock < GetRecoParam()->GetStartClock() || iClock > GetRecoParam()->GetEndClock()) continue; if(adcPedSub[iClock] > maxadc) { maxadc = adcPedSub[iClock]; imax = iClock; } } if (imax != -1) { Int_t start = imax - GetRecoParam()->GetNPreClocks(); if (start < 0) start = 0; Int_t end = imax + GetRecoParam()->GetNPostClocks(); if (end > 20) end = 20; for(Int_t iClock = start; iClock <= end; iClock++) { adc[pmNumber] += adcPedSub[iClock]; } } // HPTDC leading time and width // Correction for slewing and various time delays time[pmNumber] = CorrectLeadingTime(pmNumber,digit->Time(),adc[pmNumber]); width[pmNumber] = digit->Width(); if (adc[pmNumber] > 0) { AliDebug(1,Form("PM = %d ADC = %.2f (%.2f) TDC %.2f (%.2f) Int %d (%d %d %d %d %d %d %d %d %d %d %d %d %d %d %d %d %d %d %d %d %d) %.2f %.2f %.2f %.2f %d %d",pmNumber, adc[pmNumber], digit->ChargeADC(11)+digit->ChargeADC(10)+digit->ChargeADC(9)+digit->ChargeADC(8)+ digit->ChargeADC(7)+digit->ChargeADC(6)+digit->ChargeADC(5)+digit->ChargeADC(4)- 4.*fCalibData->GetPedestal(pmNumber)-4.*fCalibData->GetPedestal(pmNumber+64), digit->Time(),time[pmNumber], integrator, digit->ChargeADC(0),digit->ChargeADC(1),digit->ChargeADC(2),digit->ChargeADC(3),digit->ChargeADC(4),digit->ChargeADC(5),digit->ChargeADC(6),digit->ChargeADC(7), digit->ChargeADC(8),digit->ChargeADC(9),digit->ChargeADC(10), digit->ChargeADC(11),digit->ChargeADC(12), digit->ChargeADC(13),digit->ChargeADC(14),digit->ChargeADC(15),digit->ChargeADC(16),digit->ChargeADC(17),digit->ChargeADC(18),digit->ChargeADC(19),digit->ChargeADC(20), fCalibData->GetPedestal(pmNumber),fCalibData->GetSigma(pmNumber), fCalibData->GetPedestal(pmNumber+64),fCalibData->GetSigma(pmNumber+64), aBBflag[pmNumber],aBGflag[pmNumber])); }; TF1 *saturationFunc = (TF1*)fSaturationCorr->UncheckedAt(pmNumber); if (!saturationFunc) AliFatal(Form("Saturation correction for channel %d is not found!",pmNumber)); AliDebug(1,Form("Saturation PM=%d %f %f",pmNumber,adc[pmNumber],saturationFunc->Eval(adc[pmNumber]))); mult[pmNumber] = saturationFunc->Eval(adc[pmNumber])*fCalibData->GetMIPperADC(pmNumber); // Fill ESD friend object for (Int_t iEv = 0; iEv < AliESDVZEROfriend::kNEvOfInt; iEv++) { fESDVZEROfriend->SetPedestal(pmNumber,iEv,(Float_t)digit->ChargeADC(iEv)); fESDVZEROfriend->SetIntegratorFlag(pmNumber,iEv,(iEv%2 == 0) ? integrator : !integrator); } fESDVZEROfriend->SetTime(pmNumber,digit->Time()); fESDVZEROfriend->SetWidth(pmNumber,digit->Width()); } // end of loop over digits } // end of loop over events in digits tree fESDVZERO->SetBit(AliESDVZERO::kCorrectedLeadingTime,kTRUE); fESDVZERO->SetMultiplicity(mult); fESDVZERO->SetADC(adc); fESDVZERO->SetTime(time); fESDVZERO->SetWidth(width); fESDVZERO->SetBit(AliESDVZERO::kOnlineBitsFilled,kTRUE); fESDVZERO->SetBBFlag(aBBflag); fESDVZERO->SetBGFlag(aBGflag); fESDVZERO->SetBit(AliESDVZERO::kCorrectedForSaturation,kTRUE); // now fill the V0 decision and channel flags { AliVZEROTriggerMask triggerMask; triggerMask.SetRecoParam(GetRecoParam()); triggerMask.FillMasks(fESDVZERO, fCalibData, fTimeSlewing); } if (esd) { AliDebug(1, Form("Writing VZERO data to ESD tree")); esd->SetVZEROData(fESDVZERO); const AliESDRun *esdRun = esd->GetESDRun(); if (esdRun) { Float_t factors[64]; Float_t factorSum = 0; for(Int_t i = 0; i < 64; ++i) { factors[i] = fEqFactors->GetBinContent(i+1)*fCalibData->GetMIPperADC(i); factorSum += factors[i]; } for(Int_t i = 0; i < 64; ++i) factors[i] *= (64./factorSum); esd->SetVZEROEqFactors(factors); } else AliError("AliESDRun object is not available! Cannot write the equalization factors!"); } if (esd) { AliESDfriend *fr = (AliESDfriend*)esd->FindListObject("AliESDfriend"); if (fr) { AliDebug(1, Form("Writing VZERO friend data to ESD tree")); fr->SetVZEROfriend(fESDVZEROfriend); } } fDigitsArray->Clear(); } //_____________________________________________________________________________ AliCDBStorage* AliVZEROReconstructor::SetStorage(const char *uri) { // Sets the storage Bool_t deleteManager = kFALSE; AliCDBManager *manager = AliCDBManager::Instance(); AliCDBStorage *defstorage = manager->GetDefaultStorage(); if(!defstorage || !(defstorage->Contains("VZERO"))){ AliWarning("No default storage set or default storage doesn't contain VZERO!"); 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; } //____________________________________________________________________________ void AliVZEROReconstructor::GetCollisionMode() { // Retrieval of collision mode TString beamType = GetRunInfo()->GetBeamType(); if(beamType==AliGRPObject::GetInvalidString()){ AliError("VZERO cannot retrieve beam type"); return; } if( (beamType.CompareTo("P-P") ==0) || (beamType.CompareTo("p-p") ==0) ){ fCollisionMode=0; } else if( (beamType.CompareTo("Pb-Pb") ==0) || (beamType.CompareTo("A-A") ==0) ){ fCollisionMode=1; } fBeamEnergy = GetRunInfo()->GetBeamEnergy(); if(fBeamEnergy==AliGRPObject::GetInvalidFloat()) { AliError("Missing value for the beam energy ! Using 0"); fBeamEnergy = 0.; } AliDebug(1,Form("\n ++++++ Beam type and collision mode retrieved as %s %d @ %1.3f GeV ++++++\n\n",beamType.Data(), fCollisionMode, fBeamEnergy)); } //_____________________________________________________________________________ AliVZEROCalibData* AliVZEROReconstructor::GetCalibData() const { // Gets calibration object for VZERO set AliCDBManager *man = AliCDBManager::Instance(); AliCDBEntry *entry=0; entry = man->Get("VZERO/Calib/Data"); AliVZEROCalibData *calibdata = 0; if (entry) calibdata = (AliVZEROCalibData*) entry->GetObject(); if (!calibdata) AliFatal("No calibration data from calibration database !"); return calibdata; } Float_t AliVZEROReconstructor::CorrectLeadingTime(Int_t i, Float_t time, Float_t adc) const { // Correct the leading time // for slewing effect and // misalignment of the channels if (time < 1e-6) return kInvalidTime; // Channel alignment and general offset subtraction if (i < 32) time -= kV0CDelayCables; time -= fTimeOffset[i]; // In case of pathological signals if (adc < 1e-6) return time; // Slewing correction Float_t thr = fCalibData->GetCalibDiscriThr(i,kTRUE); time -= fTimeSlewing->Eval(adc/thr); return time; }