/************************************************************************** * 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. * **************************************************************************/ /* $Id$ */ //--- // Produces the data needed to calculate the quality assurance. // Alla.Maevskaya@cern.ch //--- // --- ROOT system --- #include #include #include #include #include // --- Standard library --- // --- AliRoot header files --- #include "AliESDEvent.h" #include "AliLog.h" #include "AliT0digit.h" #include "AliT0hit.h" #include "AliT0RecPoint.h" #include "AliT0QADataMakerRec.h" #include "AliQAChecker.h" #include "AliT0RawReader.h" #include "AliT0RecoParam.h" #include "THnSparse.h" #include "Riostream.h" ClassImp(AliT0QADataMakerRec) //____________________________________________________________________________ AliT0QADataMakerRec::AliT0QADataMakerRec() : AliQADataMakerRec(AliQAv1::GetDetName(AliQAv1::kT0), "T0 Quality Assurance Data Maker"), fnEventCal(0), fnEventPhys(0) { // ctor for (Int_t i=0; i<6; i++) { fNumTriggers[i]=0; fNumTriggersCal[i]=0; fTrEffCal[i] = 0; fTrEffPhys[i] = 0; } for (Int_t i=0; i<24; i++) { feffC[i]=0; feffA[i]=0; feffqtc[i]=0; feffPhysC[i]=0; } } //____________________________________________________________________________ AliT0QADataMakerRec::AliT0QADataMakerRec(const AliT0QADataMakerRec& qadm) : AliQADataMakerRec(), fnEventCal(0), fnEventPhys(0) { //copy ctor SetName((const char*)qadm.GetName()) ; SetTitle((const char*)qadm.GetTitle()); } //__________________________________________________________________ AliT0QADataMakerRec& AliT0QADataMakerRec::operator = (const AliT0QADataMakerRec& qadm ) { // Equal operator. this->~AliT0QADataMakerRec(); new(this) AliT0QADataMakerRec(qadm); return *this; } //____________________________________________________________________________ void AliT0QADataMakerRec::EndOfDetectorCycle(AliQAv1::TASKINDEX_t task, TObjArray ** list) { //Detector specific actions at end of cycle // do the QA checking AliQAChecker::Instance()->Run(AliQAv1::kT0, task, list) ; for (Int_t specie = 0 ; specie < AliRecoParam::kNSpecies ; specie++) { if (! IsValidEventSpecie(specie, list)) continue ; SetEventSpecie(AliRecoParam::ConvertIndex(specie)) ; if ( task == AliQAv1::kRAWS ) { GetRawsData(0)->SetLabelSize(0.02); const Char_t *triggers[6] = {"mean", "vertex","ORA","ORC","central","semi-central"}; for (Int_t itr=0; itr<6; itr++) { if ( fnEventCal>0) fTrEffCal[itr] = Float_t (fNumTriggersCal[itr])/Float_t (fnEventCal); if ( fnEventPhys>0) fTrEffPhys[itr] = Float_t (fNumTriggers[itr])/Float_t (fnEventPhys); GetRawsData(169+251)->Fill(triggers[itr], fTrEffCal[itr]); GetRawsData(169+251)->SetBinContent(itr+1, fTrEffCal[itr]); GetRawsData(169)->Fill(triggers[itr], fTrEffPhys[itr]); GetRawsData(169)->SetBinContent(itr+1, fTrEffPhys[itr]); } Float_t effic=0; for(Int_t ik=0; ik<24; ik++) { effic=0; if ( fnEventCal>0) effic = Float_t(feffC[ik])/Float_t(fnEventCal); GetRawsData(207+251)->SetBinContent(ik+1,effic) ; effic=0; if ( fnEventCal>0) effic = Float_t(feffA[ik])/Float_t(fnEventCal); GetRawsData(208+251)->SetBinContent(ik+1,effic ); effic=0; if ( fnEventCal>0) effic = Float_t(feffqtc[ik])/Float_t(fnEventCal); GetRawsData(209+251)->SetBinContent(ik+1, effic); effic=0; if ( fnEventPhys>0) effic = Float_t(feffPhysC[ik])/Float_t(fnEventPhys); GetRawsData(207)->SetBinContent(ik+1, effic); } } } } //____________________________________________________________________________ void AliT0QADataMakerRec::StartOfDetectorCycle() { //Detector specific actions at start of cycle for (Int_t i=0; i<500; i++) if(GetRawsData(i)) GetRawsData(i)->Reset(); } //____________________________________________________________________________ void AliT0QADataMakerRec::InitRaws() { // create Raw histograms in Raw subdir const Bool_t expert = kTRUE ; const Bool_t saveCorr = kTRUE ; const Bool_t image = kTRUE ; Float_t low[500]; Float_t high[500]; for (Int_t i=0; i<500; i++){ low[i] = 0; high[i] = 30000; } TString timename, ampname, qtcname, ledname; TString timeCalname, ampCalname, ledCalname, qtcCalname; TString qt1name, qt0name, qt1Calname, qt0Calname; TString nhits; TH1F* fhRefPoint = new TH1F("hRefPoint","Ref Point", 10000, 0 ,50000); Add2RawsList( fhRefPoint,0, expert, !image, !saveCorr); TH1F* fhRefPointcal = new TH1F("hRefPointcal","Ref Point laser", 5000, 0 ,20000); Add2RawsList( fhRefPointcal,250, expert, !image, !saveCorr); TH1F *fhRawCFD[24]; TH1F * fhRawLEDamp[24]; TH1F *fhRawQTC[24]; TH1F * fhRawLED[24]; TH1F *fhRawCFDcal[24]; TH1F * fhRawLEDampcal[24]; TH1F *fhRawQTCcal[24]; TH1F * fhRawLEDcal[24]; TH1F *fhRawQT0cal[24]; TH1F *fhRawQT1cal[24]; TH1F *fhRawQT1[24]; TH1F *fhRawQT0[24]; TH1F* fhRawNhits[24]; for (Int_t i=0; i<24; i++) { timename ="hRawCFD"; ledname = "hRawLED"; qtcname = "hRawQTC"; qt0name = "hRawQT0_"; qt1name = "hRawQT1_"; ampname = "hRawLEDminCFD"; nhits = "hRawNhits"; timename += i+1; ampname += i+1; qtcname += i+1; qt0name += i+1; qt1name += i+1; ledname += i+1; nhits += i+1; fhRawCFD[i] = new TH1F(timename.Data(), Form("%s;CFD [#channels];Counts", timename.Data()),Int_t((high[i+1]-low[i+1])/4),low[i+1],high[i+1]); Add2RawsList( fhRawCFD[i],i+1, expert, !image, !saveCorr); fhRawLED[i] = new TH1F(ledname.Data(), Form("%s;LED[#channels];Counts", ledname.Data()),Int_t((high[i+25]-low[i+25])/4),low[i+25],high[i+25]); Add2RawsList( fhRawLED[i],i+25, expert, !image, !saveCorr); fhRawLEDamp[i] = new TH1F(ampname.Data(), Form("%s;LED-CFD [#channels];Counts", ampname.Data()),1000,0,1000); Add2RawsList( fhRawLEDamp[i],i+49, expert, !image, !saveCorr); fhRawQTC[i] = new TH1F(qtcname.Data(), Form("%s;QTC[#channels];Counts", qtcname.Data()),10000,0,10000); Add2RawsList( fhRawQTC[i],i+73, expert, !image, !saveCorr); fhRawQT1[i] = new TH1F(qt1name.Data(), Form("%s;QT1[#channels];Counts", qt1name.Data()),Int_t((high[97+i]-low[97+i])/4),low[97+i],high[97+i]); Add2RawsList( fhRawQT1[i],97+i, expert, !image, !saveCorr); fhRawQT0[i] = new TH1F(qt0name.Data(), Form("%s;QT0[#channels];Counts", qt0name.Data()),Int_t((high[121+i]-low[121+i])/4),low[121+i],high[121+i]); Add2RawsList( fhRawQT0[i],121+i, expert, !image, !saveCorr); fhRawNhits[i] = new TH1F(nhits.Data(), Form("%s;#Hits;Events", nhits.Data()),20, 0, 20); Add2RawsList( fhRawNhits[i],176+i, expert, !image, !saveCorr); timeCalname ="hRawCFDcal"; ledCalname = "hRawLEDcal"; ampCalname = "hRawLEDminCFDcal"; qtcCalname = "hRawQTCcal"; qt0Calname = "hRawQT0cal"; qt1Calname = "hRawQT1cal"; timeCalname += i+1; ledCalname += i+1; ampCalname += i+1; qtcCalname += i+1; qt0Calname += i+1; qt1Calname += i+1; fhRawCFDcal[i] = new TH1F(timeCalname.Data(), Form("LASER: %s;Time ;Counts", timeCalname.Data()),Int_t((high[251+i]-low[251+i])/4),low[251+i],high[251+i]); Add2RawsList( fhRawCFDcal[i],251+i, expert, !image, !saveCorr); fhRawLEDcal[i] = new TH1F(ledCalname.Data(), Form("LASER: %s;Time ;Counts", ledCalname.Data()),Int_t((high[251+i+24]-low[251+i+24])/4),low[251+i+24],high[251+i+24]); Add2RawsList( fhRawLEDcal[i],251+i+24, expert, !image, !saveCorr); fhRawLEDampcal[i] = new TH1F(ampCalname.Data(), Form("LASER: %s;Amplitude [ADC counts];Counts", ampCalname.Data()),1000,0,1000); Add2RawsList( fhRawLEDampcal[i],251+i+48, expert, !image, !saveCorr); fhRawQTCcal[i] = new TH1F(qtcCalname.Data(), Form("LASER: %s;QTC[#channels]; ;Counts",qtcCalname.Data()),10000,0,10000); Add2RawsList( fhRawQTCcal[i],251+i+72, expert, !image, !saveCorr); fhRawQT0cal[i] = new TH1F(qt0Calname.Data(), Form("LASER: %s;QT0[#channels] ;Counts",qt0Calname.Data()),Int_t((high[251+96+i]-low[251+96+i])/4),low[251+96+i],high[251+96+i]); Add2RawsList( fhRawQT0cal[i],251+96+i, expert, !image, !saveCorr); fhRawQT1cal[i] = new TH1F(qt1Calname.Data(), Form("LASER: %s;QT1[#channels] ;Counts",qt1Calname.Data()),Int_t((high[i+251+120]-low[i+251+120])/4),low[i+251+120],high[i+251+120]); Add2RawsList( fhRawQT1cal[i],i+251+120, expert, !image, !saveCorr); } TH1F* fhRawTrigger = new TH1F("hRawTrigger"," phys triggers;Trigger ;Counts",6,0,6); Add2RawsList(fhRawTrigger ,169, expert, image, !saveCorr); TH1F* fhRawMean = new TH1F("hRawMean","online mean signal, physics event;",Int_t((high[170]-low[170])/4),low[170],high[170]); Add2RawsList( fhRawMean,170, expert, !image, !saveCorr); TH1F* fhRawVertex = new TH1F("hRawVertex","online vertex signal; counts",Int_t((high[171]-low[171])/4),low[171],high[171]); Add2RawsList( fhRawVertex,171, expert, image, !saveCorr); TH1F* fhRawORA = new TH1F("hRawORA","online OR A; counts",Int_t((high[172]-low[172])/4),low[172],high[172]); Add2RawsList( fhRawORA,172, expert, !image, !saveCorr); TH1F* fhRawORC = new TH1F("hRawORC","online OR C;counts",Int_t(( high[173]-low[173])/4),low[173],high[173]); Add2RawsList( fhRawORC,173, expert, !image, !saveCorr); TH1F* fhMultCentr = new TH1F("hMultCentr","online trigger Central;counts ",Int_t(( high[174]-low[174])/4),low[174],high[174]); Add2RawsList( fhMultCentr,174, expert, !image, !saveCorr); TH1F* fhMultSeCentr = new TH1F("hMultSemiCentr","online trigger SemiCentral;counts ",Int_t(( high[175]-low[175])/4),low[175],high[175]); Add2RawsList( fhMultSeCentr,175, expert, !image, !saveCorr); TH1F* fhRawTriggerCal = new TH1F("hRawTriggerCal"," laser triggers",6,0,6); Add2RawsList(fhRawTriggerCal ,169+251 , !expert, image, !saveCorr); TH1F* fhRawMeanCal = new TH1F("hRawMeanCal","online mean signal, calibration event",Int_t((high[170+251]-low[170+251])/4),low[170+251],high[170+251]); Add2RawsList( fhRawMeanCal,170+251, expert, !image, !saveCorr); TH1F* fhRawVertexCal = new TH1F("hRawVertexCal","online vertex signal, calibration event ",Int_t((high[171+251]-low[171+251])/4),low[171+251],high[171+251] ); Add2RawsList( fhRawVertexCal,171+251, expert, !image, !saveCorr); TH1F* fhRawORAcal = new TH1F("hRawORAcal","laser OR A; counts",Int_t((high[172+251]-low[172+251])/4),low[172+251],high[172+251]); Add2RawsList( fhRawORAcal,172+251, expert, !image, !saveCorr ); TH1F* fhRawORCcal = new TH1F("hRawORCcal","laserOR C;counts ",Int_t(( high[173]-low[173])/4),low[173],high[173]); Add2RawsList( fhRawORCcal,173+251, expert, !image, !saveCorr); TH1F* fhMultCentrcal = new TH1F("hMultCentrcal","laser trigger Central;counts ",Int_t(( high[174]-low[174])/4),low[174],high[174]); Add2RawsList( fhMultCentrcal,174+251, expert, !image, !saveCorr); TH1F* fhMultSeCentrcal = new TH1F("hMultSemiCentrcal","laser trigger SemiCentral;counts ",Int_t(( high[175]-low[175])/4),low[175],high[175]); Add2RawsList( fhMultSeCentrcal,175+251, expert, !image, !saveCorr); //multiplicity trigger //side A TH1F* fhMultAcal = new TH1F("hMultAcal","laser: full mulltiplicity;Multiplicity A side;Entries",Int_t((high[201]-low[201])/4),low[201],high[201]); Add2RawsList( fhMultAcal,201+251, expert, !image, !saveCorr ); TH1F* fhMultAScal = new TH1F("hMultASemical","laser:full multiplicity with semi-central trigger A side;Multiplicity;Entries", Int_t((high[202]-low[202])/4),low[202],high[202] ); Add2RawsList( fhMultAScal,202+251, expert, !image, !saveCorr); TH1F* fhMultACcal = new TH1F("hMultACentrcal","laser:full multiplicity with central trigger A side;Multiplicity;Entries", Int_t((high[203]-low[203])/4),low[203],high[203]); Add2RawsList( fhMultACcal,203+251, expert, !image, !saveCorr); TH1F* fhMultA = new TH1F("hMultA","full mulltiplicity A side;Multiplicity;Entries", Int_t((high[201]-low[201])/4) ,low[201],high[201]); Add2RawsList( fhMultA,201, expert, image, !saveCorr ); TH1F* fhMultAS = new TH1F("hMultASemi","full multiplicity with semi-central trigger A side ;Multiplicity;Entries", Int_t((high[202]-low[202])/4),low[202],high[202] ); Add2RawsList( fhMultAS, 202, expert, !image, !saveCorr); TH1F* fhMultAC = new TH1F("hMultACentr","full multiplicity with central trigger;Multiplicity;Entries", Int_t((high[203]-low[203])/4),low[203],high[203]); Add2RawsList( fhMultAC, 203, expert, !image, !saveCorr); //side C TH1F* fhMultCcal = new TH1F("hMultCcal","laser:full mulltiplicity C side;Multiplicity;Entries",Int_t((high[204]-low[204])/4),low[204],high[204]); Add2RawsList( fhMultCcal,204+251, expert, !image, !saveCorr ); TH1F* fhMultCScal = new TH1F("hMultCSemical","laser:full multiplicity with semi-central trigger C side;Multiplicity;Entries", Int_t((high[205]-low[205])/4),low[205],high[205] ); Add2RawsList( fhMultCScal,205+251, expert, !image, !saveCorr); TH1F* fhMultCCcal = new TH1F("hMultCCentrcal","laser:full multiplicity with central trigger C side;Multiplicity;Entries", Int_t((high[206]-low[206])/4),low[206],high[206]); Add2RawsList( fhMultCCcal,206+251, expert, !image, !saveCorr); TH1F* fhMultC = new TH1F("hMultC","full mulltiplicity C side;Multiplicity;Entries", Int_t(high[204]-low[204]/4) ,low[204],high[204]); Add2RawsList( fhMultC,204, expert, image, !saveCorr ); TH1F* fhMultCS = new TH1F("hMultCSemi","full multiplicity with semi-central trigger C side;Multiplicity;Entries", Int_t((high[205]-low[205])/4),low[205],high[205] ); Add2RawsList( fhMultCS,205, expert, !image, !saveCorr); TH1F* fhMultCC = new TH1F("hMultCentr","full multiplicity with central trigger C side;Multiplicity;Entries", Int_t((high[206]-low[206])/4),low[206],high[206]); Add2RawsList( fhMultCC,206, expert, !image, !saveCorr); //efficiency TH1F* fhEffCFD = new TH1F("hEffCFDcal","CFD efficiecy laser ;#PMT; #CFD counts/nEvents",24, 0 ,24); Add2RawsList( fhEffCFD,207+251, !expert, image, !saveCorr); TH1F* fhCFDeffpsys= new TH1F("fhCFDeffpsys"," CFD efficiency; #PMT; #CFD counts/nEvents",24, 0 ,24); // fhCFDeffpsys->SetMaximum(2); Add2RawsList( fhCFDeffpsys, 207, expert, image, !saveCorr); TH1F* fhEffLED = new TH1F("hEffLEDcal","LEDefficiecy; #PMT; #LED counts/nEvent",24, 0 ,24); Add2RawsList( fhEffLED,208+251, !expert, image, !saveCorr); TH1F* fhEffQTC = new TH1F("hEffQTCcal","QTC efficiecy; #PMT; QTC efficiency%s;",24, 0 ,24); Add2RawsList( fhEffQTC,209+251, !expert, image, !saveCorr); TH2F* fhCFD = new TH2F("hCFD","CFD phys; #PMT; CFD {#channnels}",25, 0 ,25,Int_t((high[210]-low[210])/4),low[210],high[210]); fhCFD->SetOption("COLZ"); Add2RawsList( fhCFD,210, expert, image, !saveCorr); TH2F* fhLED = new TH2F("hLED","LED phys; #PMT; LED [#channnels]",25, 0 ,25,Int_t((high[211]-low[211])/4),low[211],high[211]); fhLED->SetOption("COLZ"); Add2RawsList( fhLED,211, expert, image, !saveCorr); TH2F* fhQTC = new TH2F("hQTC","QTC phys; #PMT; QTC [#channnels]",25, 0 ,25,Int_t( high[212]-low[212]),low[212],high[212]); fhQTC->SetOption("COLZ"); Add2RawsList( fhQTC,212, expert, image, !saveCorr); TH2F* fhCFDcal = new TH2F("hCFDcal","CFD laser; #PMT; CFD {#channnels}",25, 0 ,25,Int_t((high[210]-low[210])/4),low[210],high[210]); fhCFDcal->SetOption("COLZ"); Add2RawsList( fhCFDcal,210+251, expert, image, !saveCorr); TH2F* fhLEDcal = new TH2F("hLEDcal","LED laser; #PMT; LED [#channnels]",25, 0 ,25,Int_t((high[211]-low[211])/4),low[211],high[211]); fhLEDcal->SetOption("COLZ"); Add2RawsList( fhLEDcal,211+251, expert, image, !saveCorr); TH2F* fhQTCcal = new TH2F("hQTCcal","QTC laser; #PMT; QTC [#channnels]",25, 0 ,25,Int_t( high[212]-low[212]),low[212],high[212]); fhQTCcal->SetOption("COLZ"); Add2RawsList( fhQTCcal,212+251, expert, image, !saveCorr); TH1F* fhNumPMTA= new TH1F("hNumPMTA","number of PMT hitted per event",13, 0 ,13); Add2RawsList(fhNumPMTA ,213, expert, image, !saveCorr); TH1F* fhNumPMTC= new TH1F("hNumPMTC","number of PMT hitted per event",13, 0 ,13); Add2RawsList(fhNumPMTC ,214, expert, image, !saveCorr); TH1F* fhHitsOrA= new TH1F("fhHitsOrA","T0_OR A hit multiplicitie",20, 0 ,20); Add2RawsList( fhHitsOrA,215, expert, !image, !saveCorr); TH1F* fhHitsOrC= new TH1F("fhHitsOrC","T0_OR C hit multiplicitie",20, 0 ,20); Add2RawsList(fhHitsOrC ,216, expert, !image, !saveCorr); TH1F* fhOrCminOrA= new TH1F("fhOrCminOrA","T0_OR C - T0_OR A",10000,-5000,5000); Add2RawsList( fhOrCminOrA,219, expert, !image, !saveCorr); TH1F* fhOrCminOrAcal= new TH1F("fhOrCminOrAcal","T0_OR C - T0_OR A",10000,-5000,5000); Add2RawsList( fhOrCminOrAcal,219+251, expert, !image, !saveCorr); TH1F* fhOrCminOrATvdcOn= new TH1F("fhOrCminOrATvdcOn","T0_OR C - T0_OR A TVDC on",10000,-5000,5000); Add2RawsList( fhOrCminOrATvdcOn,217, expert, !image, !saveCorr); TH1F* fhOrCminOrATvdcOncal= new TH1F("fhOrCminOrATvdcOncal","T0_OR C - T0_OR A TVDC on laser",10000,-5000,5000); Add2RawsList( fhOrCminOrATvdcOncal,217+251, expert, !image, !saveCorr); TH1F* fhOrCminOrATvdcOff= new TH1F("fhOrCminOrATvdcOff","T0_OR C - T0_OR A TVDC off",10000,-5000,5000); Add2RawsList( fhOrCminOrATvdcOff,218, expert, !image, !saveCorr); TH1F* fhOrCminOrATvdcOffcal= new TH1F("fhOrCminOrATvdcOffcal","T0_OR C - T0_OR ATVDC off laser",10000,-5000,5000); Add2RawsList( fhOrCminOrATvdcOffcal,218+251, expert, !image, !saveCorr); const Char_t *triggers[6] = {"mean", "vertex","ORA","ORC","central","semi-central"}; for (Int_t itr=0; itr<6; itr++) { GetRawsData(169)->Fill(triggers[itr], fNumTriggersCal[itr]); GetRawsData(169)->SetBinContent(itr+1, fNumTriggersCal[itr]); GetRawsData(169+251)->Fill(triggers[itr], fNumTriggers[itr]); GetRawsData(169+251)->SetBinContent(itr+1, fNumTriggers[itr]); } } //____________________________________________________________________________ void AliT0QADataMakerRec::InitDigits() { // create Digits histograms in Digits subdir const Bool_t expert = kTRUE ; const Bool_t image = kTRUE ; TH2F * fhDigCFD = new TH2F("fhDigCFD", " CFD digits; #PMT; CFD digits[#channels]",25,-0.5,24.5,100,0,1000); fhDigCFD->SetOption("COLZ"); Add2DigitsList( fhDigCFD,0, !expert, image); TH2F *fhDigLEDamp = new TH2F("fhDigLEDamp", " LED-CFD digits; #PMT; LED-CFD amplitude ",25,-0.5,24.5,100,100,1000); fhDigLEDamp->SetOption("COLZ"); Add2DigitsList( fhDigLEDamp,1, !expert, !image); TH2F * fhDigQTC = new TH2F("fhDigQTC", " QTC digits; #PMT; QTC amplitude",25,-0.5,24.5,100,100,10000); fhDigQTC->SetOption("COLZ"); Add2DigitsList( fhDigQTC,2, !expert, !image); } //____________________________________________________________________________ void AliT0QADataMakerRec::InitRecPoints() { // create cluster histograms in RecPoint subdir const Bool_t expert = kTRUE ; const Bool_t image = kTRUE ; TH2F* fhRecCFD = new TH2F("hRecCFD"," CFD time;#PMT; CFD Time [ns];",24, 0 ,24, 100,-50,50); fhRecCFD->SetOption("COLZ"); Add2RecPointsList ( fhRecCFD,0, !expert, image); TH2F* fhRecAmpDiff = new TH2F("hRecAmpDiff"," LED-CFD min QTC amplitude;#PMT; difference [MIPs];", 24, 0 ,24, 200,-10,10); fhRecAmpDiff->SetOption("COLZ"); Add2RecPointsList (fhRecAmpDiff, 1, !expert, image); TH1F *fhMean = new TH1F("hMean","online - rec mean;online - rec mean[#channels];",2000, -1000, 1000); Add2RecPointsList ( fhMean,2, !expert, image); } //____________________________________________________________________________ void AliT0QADataMakerRec::InitESDs() { //create ESDs histograms in ESDs subdir const Bool_t expert = kTRUE ; const Bool_t image = kTRUE ; TH1F *fhESDMean = new TH1F("hESDmean"," ESD mean; mean time[%channels]",1000, -5, 5); Add2ESDsList(fhESDMean, 0, expert, !image) ; TH1F * fhESDVertex = new TH1F("hESDvertex","ESDvertex; vertex[cm];",82,-30,30); Add2ESDsList(fhESDVertex, 1, expert, !image) ; TH1F * fhESDResolution = new TH1F("hESDResolution","(T0A-T0C)/2 corrected by SPD vertex; ns",800,-2,2); Add2ESDsList(fhESDResolution, 2, !expert, image) ; } //____________________________________________________________________________ void AliT0QADataMakerRec::MakeRaws( AliRawReader* rawReader) { rawReader->Reset() ; //fills QA histos for RAW Int_t shift=0; // Int_t refPointParam = GetRecoParam()->GetRefPoint(); Int_t refpoint = 0; Int_t refPointParam = 0; AliT0RawReader *start = new AliT0RawReader(rawReader); if (! start->Next()) AliDebug(AliQAv1::GetQADebugLevel(),Form(" no raw data found!!")); else { UInt_t type =rawReader->GetType(); if (type == 8){ shift=251; fnEventCal++;} if (type == 7){ shift=0; fnEventPhys++;} // if (type == 7){ shift=1; fnEventPhys++;} Int_t allData[110][5]; for (Int_t i0=0; i0<110; i0++) { for (Int_t j0=0; j0<5; j0++) allData[i0][j0]=0; } for (Int_t i=0; i<107; i++) for (Int_t iHit=0; iHit<5; iHit++) allData[i][iHit]= start->GetData(i,iHit); if ( allData[0][0] > 0 && (type == 7)) GetRawsData(0) -> Fill( allData[0][0]); if ( allData[0][0] > 0 && (type == 8)) GetRawsData(250) -> Fill( allData[0][0]); refpoint = allData[refPointParam][0]; if (refPointParam < 0 ) refpoint=0; if (refPointParam == 0 ) refpoint = allData[0][0] - 5000; Int_t sideshift, sideshiftqtc; Int_t numPmtC=0; Int_t numPmtA=0; for (Int_t ik = 0; ik<24; ik++) { if(ik<12) { sideshift=1; sideshiftqtc=1; if(allData[ik+sideshift][0]>0 && type == 7 ) numPmtC++; } else { if(allData[ik+45][0]>0 && type == 7 ) numPmtA++; sideshift=45; sideshiftqtc=33; } Int_t nhitsPMT=0; for (Int_t iHt=0; iHt<5; iHt++){ //cfd if(allData[ik+sideshift][iHt]>0) { GetRawsData(shift+ik+1) -> Fill(allData[ik+sideshift][iHt]); GetRawsData(210+shift)->Fill(ik+1, allData[ik+sideshift][iHt]); if(type == 8 ) feffC[ik]++; if(type == 7 ) { nhitsPMT++; feffPhysC[ik]++; } } //led if(allData[ik+12+sideshift][iHt] > 0) { GetRawsData(shift+ik+24+1)-> Fill(allData[ik+12+sideshift][iHt]); GetRawsData(211+shift)->Fill(ik+1, allData[ik+12+sideshift][iHt]); if(type == 8 ) { feffA[ik]++; } } //led -cfd if(allData[ik+12+sideshift][iHt] > 0 && allData[ik+sideshift][iHt] >0 ) GetRawsData(shift+ik+48+1)-> Fill(allData[ik+12+sideshift][iHt]-allData[ik+sideshift][iHt]); //qtc if(allData[2*ik+sideshiftqtc+24][iHt] > 0 && allData[2*ik+sideshiftqtc+25][iHt] > 0) { GetRawsData(shift+ik+72+1)-> Fill(allData[2*ik+sideshiftqtc+24][iHt]-allData[2*ik+sideshiftqtc+25][iHt]); GetRawsData(212+shift)->Fill(ik+1, allData[2*ik+sideshiftqtc+24][iHt]-allData[2*ik+sideshiftqtc+25][iHt]); if(type == 8) feffqtc[ik]++; } if(allData[2*ik+sideshiftqtc+24][iHt] > 0) GetRawsData(shift+ik+96+1)->Fill(allData[2*ik+sideshiftqtc+24][iHt]); if(allData[2*ik+sideshiftqtc+25][iHt] > 0) GetRawsData(shift+ik+120+1)->Fill(allData[2*ik+sideshiftqtc+25][iHt]); } if(type == 7 ) { GetRawsData(ik+176)->Fill(nhitsPMT); GetRawsData(213)->Fill(numPmtC); GetRawsData(214)->Fill(numPmtA); } } Int_t trChannel[6] = {49,50,51,52,55,56}; Float_t ch2cm = 24.4*0.029979; Int_t nhitsOrA=0; Int_t nhitsOrC=0; for (Int_t iHt=0; iHt<5; iHt++) { //orA-orC phys tvdc 1 if((allData[51][iHt]>0 && allData[52][iHt]>0) && allData[50][iHt]>0) { GetRawsData(217+shift)->Fill((allData[52][iHt]-allData[51][iHt])*ch2cm); // GetRawsData(345) ->Fill((allData[51][iHt]+allData[52][iHt])/2.); } //orA-orC phys tvdc 0 if((allData[51][iHt]>0 && allData[52][iHt]>0) && allData[50][iHt]<=0) GetRawsData(218+shift)->Fill((allData[52][iHt]-allData[51][iHt])*ch2cm); if(allData[51][iHt]>0 && allData[52][iHt]>0) GetRawsData(219+shift)->Fill((allData[52][iHt]-allData[51][iHt])*ch2cm); for (Int_t itr=0; itr<6; itr++) { if (allData[trChannel[itr]][iHt] >0) { if(type == 7 )fNumTriggers[itr]++; if(type == 8 )fNumTriggersCal[itr]++; GetRawsData(170+itr+shift)->Fill(allData[trChannel[itr]][iHt]); } } if(type == 7) if(allData[51][iHt] >0) nhitsOrA++; if(type == 7)if(allData[52][iHt] >0) nhitsOrC++; //mult trigger signals phys //C side if(allData[53][iHt]>0 && allData[54][iHt]>0) { GetRawsData(201+shift)->Fill(allData[53][iHt]-allData[54][iHt]); if(allData[56][iHt]>0) GetRawsData(202+shift)->Fill(allData[53][iHt]-allData[54][iHt]); if(allData[55][iHt]>0) GetRawsData(203+shift)->Fill(allData[53][iHt]-allData[54][iHt]); } //A side if(allData[105][iHt]>0 && allData[106][iHt]>0) { GetRawsData(204+shift)->Fill(allData[105][iHt]-allData[106][iHt]); if(allData[56][iHt]>0) GetRawsData(205+shift)->Fill(allData[105][iHt]-allData[106][iHt]); if(allData[55][iHt]>0) GetRawsData(206+shift)->Fill(allData[105][iHt]-allData[106][iHt]); } } GetRawsData(215)->Fill(nhitsOrA); GetRawsData(216)->Fill(nhitsOrC); } delete start; } //____________________________________________________________________________ void AliT0QADataMakerRec::MakeDigits( TTree *digitsTree) { //fills QA histos for Digits TArrayI *digCFD = new TArrayI(24); TArrayI *digLED = new TArrayI(24); TArrayI *digQT0 = new TArrayI(24); TArrayI *digQT1 = new TArrayI(24); Int_t refpoint=0; TBranch *brDigits=digitsTree->GetBranch("T0"); AliT0digit *fDigits = new AliT0digit() ; if (brDigits) { brDigits->SetAddress(&fDigits); }else{ AliError(Form("EXEC Branch T0 digits not found")); return; } digitsTree->GetEvent(0); digitsTree->GetEntry(0); brDigits->GetEntry(0); fDigits->GetTimeCFD(*digCFD); fDigits->GetTimeLED(*digLED); fDigits->GetQT0(*digQT0); fDigits->GetQT1(*digQT1); refpoint = fDigits->RefPoint(); for (Int_t i=0; i<24; i++) { if (digCFD->At(i)>0) { Int_t cfd=digCFD->At(i)- refpoint; GetDigitsData(0) ->Fill(i,cfd); GetDigitsData(1) -> Fill(i, (digLED->At(i) - digCFD->At(i))); GetDigitsData(2) -> Fill(i, (digQT1->At(i) - digQT0->At(i))); } } delete digCFD; delete digLED; delete digQT0; delete digQT1; } //____________________________________________________________________________ void AliT0QADataMakerRec::MakeRecPoints(TTree * clustersTree) { //fills QA histos for clusters AliT0RecPoint* frecpoints= new AliT0RecPoint (); if (!frecpoints) { AliError(":MakeRecPoints >> no recpoints found"); return; } TBranch *brRec =clustersTree ->GetBranch("T0"); if (brRec) { brRec->SetAddress(&frecpoints); }else{ AliError(Form("EXEC Branch T0 rec not found ")); return; } brRec->GetEntry(0); for ( Int_t i=0; i<24; i++) { if(i<12) GetRecPointsData(0) -> Fill(i, frecpoints -> GetTime(i) - frecpoints -> GetTime(0)); if(i>11) GetRecPointsData(0) -> Fill(i, frecpoints -> GetTime(i) - frecpoints -> GetTime(12)); GetRecPointsData(1) -> Fill( i, frecpoints -> GetAmp(i) - frecpoints->AmpLED(i)); } Double_t mmm=frecpoints->GetOnlineMean()- frecpoints->GetMeanTime(); GetRecPointsData(2) ->Fill(mmm); } //____________________________________________________________________________ void AliT0QADataMakerRec::MakeESDs(AliESDEvent * esd) { //fills QA histos for ESD const Double32_t *mean; mean = esd->GetT0TOF(); Double32_t t0time= 0.001*mean[0]; Double32_t orA= 0.001*mean[1]; Double32_t orC=0.001* mean[2]; if (t0time<99) GetESDsData(0) -> Fill(t0time); if( esd->GetT0zVertex() <99) GetESDsData(1)-> Fill(esd->GetT0zVertex()); if( orA<99 && orC<99) GetESDsData(2)-> Fill((orA-orC)/2.); }