1 /**************************************************************************
2 * Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights reserved. *
4 * Author: The ALICE Off-line Project. *
5 * Contributors are mentioned in the code where appropriate. *
7 * Permission to use, copy, modify and distribute this software and its *
8 * documentation strictly for non-commercial purposes is hereby granted *
9 * without fee, provided that the above copyright notice appears in all *
10 * copies and that both the copyright notice and this permission notice *
11 * appear in the supporting documentation. The authors make no claims *
12 * about the suitability of this software for any purpose. It is *
13 * provided "as is" without express or implied warranty. *
14 **************************************************************************/
16 //_________________________________________________________________________
17 // class to extract omega(782)->pi0+gamma->3gamma
18 // Mar. 22, 2011: Additional method, espeically for EMCAL. A high E cluster
19 // is assumpted as pi0 (two photons are overlapped) without unfolding
21 //-- Author: Renzhuo Wan (IOPP-Wuhan, China)
22 //_________________________________________________________________________
29 // --- ROOT system ---
31 #include "TLorentzVector.h"
32 #include "TParticle.h"
35 //---- AliRoot system ----
36 #include "AliAnaOmegaToPi0Gamma.h"
37 #include "AliCaloTrackReader.h"
38 #include "AliCaloPID.h"
40 #include "AliVEvent.h"
41 #include "AliAODEvent.h"
42 #include "AliAODMCParticle.h"
43 ClassImp(AliAnaOmegaToPi0Gamma)
45 //______________________________________________________________________________
46 AliAnaOmegaToPi0Gamma::AliAnaOmegaToPi0Gamma() : AliAnaCaloTrackCorrBaseClass(),
47 fInputAODPi0(0), fInputAODGammaName(""),
48 fEventsList(0x0),fNVtxZBin(0), fNCentBin(0), fNRpBin(0), fNBadChDistBin(0), fNpid(0),
49 fVtxZCut(0), fCent(0), fRp(0),
50 fPi0Mass(0),fPi0MassWindow(0),fPi0OverOmegaPtCut(0),
51 fGammaOverOmegaPtCut(0), fEOverlapCluster(0),
53 fRealOmega0(0), fMixAOmega0(0),
54 fMixBOmega0(0), fMixCOmega0(0),
55 fRealOmega1(0), fMixAOmega1(0),
56 fMixBOmega1(0), fMixCOmega1(0),
57 fRealOmega2(0), fMixAOmega2(0),
58 fMixBOmega2(0), fMixCOmega2(0),
66 //______________________________________________________________________________
67 AliAnaOmegaToPi0Gamma::~AliAnaOmegaToPi0Gamma() {
72 // fInputAODPi0->Clear();
73 // delete fInputAODPi0;
77 for(Int_t i=0;i<fNVtxZBin;i++){
78 for(Int_t j=0;j<fNCentBin;j++){
79 for(Int_t k=0;k<fNRpBin;k++){
80 fEventsList[i*fNCentBin*fNRpBin+j*fNRpBin+k]->Clear();
81 delete fEventsList[i*fNCentBin*fNRpBin+j*fNRpBin+k];
86 delete [] fEventsList;
95 //______________________________________________________________________________
96 void AliAnaOmegaToPi0Gamma::InitParameters()
98 //Init parameters when first called the analysis
99 //Set default parameters
100 fInputAODGammaName="PhotonsDetector";
108 fPi0MassWindow=0.015;
109 fPi0OverOmegaPtCut=0.8;
110 fGammaOverOmegaPtCut=0.2;
116 //______________________________________________________________________________
117 TList * AliAnaOmegaToPi0Gamma::GetCreateOutputObjects()
120 fVtxZCut = new Double_t [fNVtxZBin];
121 for(Int_t i=0;i<fNVtxZBin;i++) fVtxZCut[i]=10*(i+1);
123 fCent=new Double_t[fNCentBin];
124 for(int i = 0;i<fNCentBin;i++)fCent[i]=0;
126 fRp=new Double_t[fNRpBin];
127 for(int i = 0;i<fNRpBin;i++)fRp[i]=0;
129 Int_t nptbins = GetHistogramRanges()->GetHistoPtBins();
130 Float_t ptmax = GetHistogramRanges()->GetHistoPtMax();
131 Float_t ptmin = GetHistogramRanges()->GetHistoPtMin();
133 Int_t nmassbins = GetHistogramRanges()->GetHistoMassBins();
134 Float_t massmin = GetHistogramRanges()->GetHistoMassMin();
135 Float_t massmax = GetHistogramRanges()->GetHistoMassMax();
137 fhEtalon = new TH2F("hEtalon","Histo with binning parameters", nptbins,ptmin,ptmax,nmassbins,massmin,massmax) ;
138 fhEtalon->SetXTitle("P_{T} (GeV)") ;
139 fhEtalon->SetYTitle("m_{inv} (GeV)") ;
141 // store them in fOutputContainer
142 fEventsList = new TList*[fNVtxZBin*fNCentBin*fNRpBin];
143 for(Int_t i=0;i<fNVtxZBin;i++){
144 for(Int_t j=0;j<fNCentBin;j++){
145 for(Int_t k=0;k<fNRpBin;k++){
146 fEventsList[i*fNCentBin*fNRpBin+j*fNRpBin+k] = new TList();
147 fEventsList[i*fNCentBin*fNRpBin+j*fNRpBin+k]->SetOwner(kFALSE);
152 TList * outputContainer = new TList() ;
153 outputContainer->SetName(GetName());
154 const Int_t buffersize = 255;
155 char key[buffersize] ;
156 char title[buffersize] ;
157 const char * detector= fInputAODGammaName.Data();
158 Int_t ndim=fNVtxZBin*fNCentBin*fNRpBin*fNBadChDistBin*fNpid;
160 fRealOmega0 =new TH2F*[ndim];
161 fMixAOmega0 =new TH2F*[ndim];
162 fMixBOmega0 =new TH2F*[ndim];
163 fMixCOmega0 =new TH2F*[ndim];
165 fRealOmega1 =new TH2F*[ndim];
166 fMixAOmega1 =new TH2F*[ndim];
167 fMixBOmega1 =new TH2F*[ndim];
168 fMixCOmega1 =new TH2F*[ndim];
170 fRealOmega2 =new TH2F*[ndim];
171 fMixAOmega2 =new TH2F*[ndim];
172 fMixBOmega2 =new TH2F*[ndim];
173 fMixCOmega2 =new TH2F*[ndim];
175 fhFakeOmega = new TH2F*[fNCentBin];
177 for(Int_t i=0;i<fNVtxZBin;i++){
178 for(Int_t j=0;j<fNCentBin;j++){
179 for(Int_t k=0;k<fNRpBin;k++){ //at event level
180 Int_t idim=i*fNCentBin*fNRpBin+j*fNRpBin+k;
181 for(Int_t ipid=0;ipid<fNpid;ipid++){
182 for(Int_t idist=0;idist<fNBadChDistBin;idist++){ //at particle level
184 Int_t index=idim*fNpid*fNBadChDistBin+ipid*fNBadChDistBin+idist;
186 snprintf(key,buffersize,"RealToPi0Gamma_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
187 snprintf(title,buffersize, "%s Real Pi0GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
188 fRealOmega0[index]=(TH2F*)fhEtalon->Clone(key) ;
189 fRealOmega0[index]->SetName(key) ;
190 fRealOmega0[index]->SetTitle(title);
191 outputContainer->Add(fRealOmega0[index]);
193 snprintf(key,buffersize,"MixAToPi0Gamma_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
194 snprintf(title,buffersize, "%s MixA Pi0GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
195 fMixAOmega0[index]=(TH2F*)fhEtalon->Clone(key) ;
196 fMixAOmega0[index]->SetName(key) ;
197 fMixAOmega0[index]->SetTitle(title);
198 outputContainer->Add(fMixAOmega0[index]);
200 snprintf(key,buffersize,"MixBToPi0Gamma_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
201 snprintf(title,buffersize, "%s MixB Pi0GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
202 fMixBOmega0[index]=(TH2F*)fhEtalon->Clone(key) ;
203 fMixBOmega0[index]->SetName(key) ;
204 fMixBOmega0[index]->SetTitle(title);
205 outputContainer->Add(fMixBOmega0[index]);
207 snprintf(key,buffersize,"MixCToPi0Gamma_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
208 snprintf(title,buffersize, "%s MixC Pi0GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
209 fMixCOmega0[index]=(TH2F*)fhEtalon->Clone(key) ;
210 fMixCOmega0[index]->SetName(key) ;
211 fMixCOmega0[index]->SetTitle(title);
212 outputContainer->Add(fMixCOmega0[index]);
214 snprintf(key,buffersize,"RealToPi0Gamma1_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
215 snprintf(title,buffersize, "%s Real Pi0(A<0.7)GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
216 fRealOmega1[index]=(TH2F*)fhEtalon->Clone(key) ;
217 fRealOmega1[index]->SetName(key) ;
218 fRealOmega1[index]->SetTitle(title);
219 outputContainer->Add(fRealOmega1[index]);
221 snprintf(key,buffersize,"MixAToPi0Gamma1_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
222 snprintf(title,buffersize, "%s MixA Pi0(A<0.7)GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
223 fMixAOmega1[index]=(TH2F*)fhEtalon->Clone(key) ;
224 fMixAOmega1[index]->SetName(key) ;
225 fMixAOmega1[index]->SetTitle(title);
226 outputContainer->Add(fMixAOmega1[index]);
228 snprintf(key,buffersize,"MixBToPi0Gamma1_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
229 snprintf(title,buffersize, "%s MixB Pi0(A<0.7)GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
230 fMixBOmega1[index]=(TH2F*)fhEtalon->Clone(key) ;
231 fMixBOmega1[index]->SetName(key) ;
232 fMixBOmega1[index]->SetTitle(title);
233 outputContainer->Add(fMixBOmega1[index]);
235 snprintf(key,buffersize,"MixCToPi0Gamma1_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
236 snprintf(title,buffersize, "%s MixC Pi0(A<0.7)GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
237 fMixCOmega1[index]=(TH2F*)fhEtalon->Clone(key) ;
238 fMixCOmega1[index]->SetName(key) ;
239 fMixCOmega1[index]->SetTitle(title);
240 outputContainer->Add(fMixCOmega1[index]);
242 snprintf(key,buffersize,"RealToPi0Gamma2_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
243 snprintf(title,buffersize, "%s Real Pi0(A<0.8)GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
244 fRealOmega2[index]=(TH2F*)fhEtalon->Clone(key) ;
245 fRealOmega2[index]->SetName(key) ;
246 fRealOmega2[index]->SetTitle(title);
247 outputContainer->Add(fRealOmega2[index]);
249 snprintf(key,buffersize,"MixAToPi0Gamma2_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
250 snprintf(title,buffersize, "%s MixA Pi0(A<0.8)GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
251 fMixAOmega2[index]=(TH2F*)fhEtalon->Clone(key) ;
252 fMixAOmega2[index]->SetName(key) ;
253 fMixAOmega2[index]->SetTitle(title);
254 outputContainer->Add(fMixAOmega2[index]);
256 snprintf(key,buffersize,"MixBToPi0Gamma2_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
257 snprintf(title,buffersize, "%s MixB Pi0(A<0.8)GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
258 fMixBOmega2[index]=(TH2F*)fhEtalon->Clone(key) ;
259 fMixBOmega2[index]->SetName(key) ;
260 fMixBOmega2[index]->SetTitle(title);
261 outputContainer->Add(fMixBOmega2[index]);
263 snprintf(key,buffersize,"MixCToPi0Gamma2_Vz%dC%dRp%dPid%dDist%d",i,j,k,ipid,idist);
264 snprintf(title,buffersize, "%s MixC Pi0(A<0.8)GammaIVM vz_%2.1f_ct_%2.1f_Rp_%2.1f_pid_%d_dist_%d",detector,fVtxZCut[i],fCent[j],fRp[k],ipid,idist);
265 fMixCOmega2[index]=(TH2F*)fhEtalon->Clone(key) ;
266 fMixCOmega2[index]->SetName(key) ;
267 fMixCOmega2[index]->SetTitle(title);
268 outputContainer->Add(fMixCOmega2[index]);
275 for(Int_t i=0;i<fNCentBin;i++){
276 snprintf(key,buffersize, "fhFakeOmega%d",i);
277 snprintf(title,buffersize,"FakePi0(high pt cluster)+Gamma with Centrality%d",i);
278 fhFakeOmega[i] = (TH2F*)fhEtalon->Clone(key);
279 fhFakeOmega[i]->SetTitle(title);
280 outputContainer->Add(fhFakeOmega[i]);
283 snprintf(key,buffersize, "%sOmegaPri",detector);
284 snprintf(title,buffersize,"primary #omega in %s",detector);
285 fhOmegaPriPt=new TH1F(key, title,nptbins,ptmin,ptmax);
286 fhOmegaPriPt->GetXaxis()->SetTitle("P_{T}");
287 fhOmegaPriPt->GetYaxis()->SetTitle("dN/P_{T}");
288 outputContainer->Add(fhOmegaPriPt);
292 return outputContainer;
295 //______________________________________________________________________________
296 void AliAnaOmegaToPi0Gamma::Print(const Option_t * /*opt*/) const
298 //Print some relevant parameters set in the analysis
299 printf("**** Print %s %s ****\n", GetName(), GetTitle() ) ;
300 AliAnaCaloTrackCorrBaseClass::Print(" ");
301 printf("Omega->pi0+gamma->3gamma\n");
302 printf("Cuts at event level: \n");
303 printf("Bins of vertex Z: %d \n", fNVtxZBin);
304 printf("Bins of centrality: %d \n",fNCentBin);
305 printf("Bins of Reaction plane: %d\n",fNRpBin);
306 printf("Cuts at AOD particle level:\n");
307 printf("Number of PID: %d \n", fNpid);
308 printf("Number of DistToBadChannel cuts: %d\n", fNBadChDistBin);
311 //______________________________________________________________________________
312 void AliAnaOmegaToPi0Gamma::MakeAnalysisFillHistograms()
314 //fill the MC AOD if needed first
316 //need to be further implemented
317 AliStack * stack = 0x0;
318 // TParticle * primary = 0x0;
319 TClonesArray * mcparticles0 = 0x0;
320 //TClonesArray * mcparticles1 = 0x0;
321 AliAODMCParticle * aodprimary = 0x0;
327 if(GetReader()->ReadStack()){
328 stack = GetMCStack() ;
330 printf("AliAnaAcceptance::MakeAnalysisFillHistograms() - There is no stack!\n");
333 for(Int_t i=0 ; i<stack->GetNtrack(); i++){
334 TParticle * prim = stack->Particle(i) ;
335 pdg = prim->GetPdgCode() ;
338 if(TMath::Abs(eta)<0.5) {
339 if(pdg==223) fhOmegaPriPt->Fill(pt);
344 else if(GetReader()->ReadAODMCParticles()){
345 //Get the list of MC particles
346 mcparticles0 = GetReader()->GetAODMCParticles();
349 if(GetDebug() > 0) printf("AliAnaAcceptance::MakeAnalysisFillHistograms() - Standard MCParticles not available!\n");
353 for(Int_t i=0;i<mcparticles0->GetEntries();i++)
355 aodprimary =(AliAODMCParticle*)mcparticles0->At(i);
356 pdg = aodprimary->GetPdgCode() ;
357 eta=aodprimary->Eta();
359 if(TMath::Abs(eta)<0.5)
361 if(pdg==223) fhOmegaPriPt->Fill(pt);
365 }//mcparticles0 exists
370 //process event from AOD brach
371 //extract pi0, eta and omega analysis
372 Int_t iRun=(GetReader()->GetInputEvent())->GetRunNumber() ;
373 if(IsBadRun(iRun)) return ;
376 Double_t vert[]={0,0,0} ;
378 Int_t curEventBin =0;
380 Int_t ivtxzbin=(Int_t)TMath::Abs(vert[2])/10;
381 if(ivtxzbin>=fNVtxZBin)return;
384 Int_t currentCentrality = GetEventCentrality();
385 if(currentCentrality == -1) return;
386 Int_t optCent = GetReader()->GetCentralityOpt();
387 Int_t icentbin=currentCentrality/(optCent/fNCentBin) ; //GetEventCentrality();
389 printf("-------------- %d %d %d ",currentCentrality, optCent, icentbin);
393 if(ivtxzbin==-1) return;
394 curEventBin = ivtxzbin*fNCentBin*fNRpBin + icentbin*fNRpBin + irpbin;
395 TClonesArray *aodGamma = (TClonesArray*) GetAODBranch(fInputAODGammaName); //photon array
396 // TClonesArray *aodGamma = (TClonesArray *) GetReader()->GetOutputEvent()->FindListObject(fInputAODGammaName); //photon array
398 if(aodGamma) nphotons= aodGamma->GetEntries();
401 fInputAODPi0 = (TClonesArray*)GetInputAODBranch(); //pi0 array
403 if(fInputAODPi0) npi0s= fInputAODPi0 ->GetEntries();
406 if(nphotons<3 || npi0s<1)return; //for pi0, eta and omega->pi0+gamma->3gamma reconstruction
408 //reconstruction of omega(782)->pi0+gamma->3gamma
409 //loop for pi0 and photon
410 if(GetDebug() > 0) printf("omega->pi0+gamma->3gamma invariant mass analysis ! This event have %d photons and %d pi0 \n", nphotons, npi0s);
411 for(Int_t i=0;i<npi0s;i++){
412 AliAODPWG4Particle * pi0 = (AliAODPWG4Particle*) (fInputAODPi0->At(i)) ; //pi0
413 TLorentzVector vpi0(pi0->Px(),pi0->Py(),pi0->Pz(),pi0->E());
414 Int_t lab1=pi0->GetCaloLabel(0); // photon1 from pi0 decay
415 Int_t lab2=pi0->GetCaloLabel(1); // photon2 from pi0 decay
416 //for omega->pi0+gamma, it needs at least three photons per event
417 //Get the two decay photons from pi0
418 AliAODPWG4Particle * photon1 =0;
419 AliAODPWG4Particle * photon2 =0;
420 for(Int_t d1=0;d1<nphotons;d1++){
421 for(Int_t d2=0;d2<nphotons;d2++){
422 AliAODPWG4Particle * dp1 = (AliAODPWG4Particle*) (aodGamma->At(d1));
423 AliAODPWG4Particle * dp2 = (AliAODPWG4Particle*) (aodGamma->At(d2));
424 Int_t dlab1=dp1->GetCaloLabel(0);
425 Int_t dlab2=dp2->GetCaloLabel(0);
426 if(dlab1==lab1 && dlab2==lab2){
433 //caculate the asy and dist of the two photon from pi0 decay
434 TLorentzVector dph1(photon1->Px(),photon1->Py(),photon1->Pz(),photon1->E());
435 TLorentzVector dph2(photon2->Px(),photon2->Py(),photon2->Pz(),photon2->E());
437 Double_t pi0asy= TMath::Abs(dph1.E()-dph2.E())/(dph1.E()+dph2.E());
438 // Double_t phi1=dph1.Phi();
439 // Double_t phi2=dph2.Phi();
440 // Double_t eta1=dph1.Eta();
441 // Double_t eta2=dph2.Eta();
442 // Double_t pi0dist=TMath::Sqrt((phi1-phi2)*(phi1-phi2)+(eta1-eta2)*(eta1-eta2));
444 if(pi0->GetIdentifiedParticleType()==111 && nphotons>2 && npi0s
445 && TMath::Abs(vpi0.M()-fPi0Mass)<fPi0MassWindow) { //pi0 candidates
447 //avoid the double counting
448 Int_t * dc1= new Int_t[nphotons];
449 Int_t * dc2= new Int_t[nphotons];
452 for(Int_t k=0;k<i;k++){
453 AliAODPWG4Particle * p3=(AliAODPWG4Particle*)(fInputAODPi0->At(k));
454 Int_t lab4=p3->GetCaloLabel(0);
455 Int_t lab5=p3->GetCaloLabel(1);
456 if(lab1==lab4){ dc1[index1]=lab5; index1++; }
457 if(lab2==lab5){ dc2[index2]=lab4; index2++; }
461 //loop the pi0 with third gamma
462 for(Int_t j=0;j<nphotons;j++){
463 AliAODPWG4Particle *photon3 = (AliAODPWG4Particle*) (aodGamma->At(j));
464 TLorentzVector dph3(photon3->Px(),photon3->Py(),photon3->Pz(),photon3->E());
465 Int_t lab3=photon3->GetCaloLabel(0);
466 Double_t pi0gammapt=(vpi0+dph3).Pt();
467 Double_t pi0gammamass=(vpi0+dph3).M();
468 Double_t pi0OverOmegaPtRatio =vpi0.Pt()/pi0gammapt;
469 Double_t gammaOverOmegaPtRatio= dph3.Pt()/pi0gammapt;
472 if(pi0OverOmegaPtRatio>fPi0OverOmegaPtCut ||
473 gammaOverOmegaPtRatio<fGammaOverOmegaPtCut) continue;
475 for(Int_t l=0;l<index1;l++) if(lab3==dc1[l]) lab3=-1;
476 for(Int_t l=0;l<index2;l++) if(lab3==dc2[l]) lab3=-1;
478 if(lab3>0 && lab3!=lab1 && lab3!=lab2){
479 for(Int_t ipid=0;ipid<fNpid;ipid++){
480 for(Int_t idist=0;idist<fNBadChDistBin;idist++){
481 Int_t index=curEventBin*fNpid*fNBadChDistBin+ipid*fNBadChDistBin+idist;
482 if(photon1->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
483 photon2->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
484 photon3->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
485 photon1->DistToBad()>=idist &&
486 photon2->DistToBad()>=idist &&
487 photon3->DistToBad()>=idist ){
488 //fill the histograms
489 if(GetDebug() > 2) printf("Real: index %d pt %2.3f mass %2.3f \n", index, pi0gammapt, pi0gammamass);
490 fRealOmega0[index]->Fill(pi0gammapt,pi0gammamass);
491 if(pi0asy<0.7) fRealOmega1[index]->Fill(pi0gammapt,pi0gammamass);
492 if(pi0asy<0.8) fRealOmega2[index]->Fill(pi0gammapt,pi0gammamass);
500 if(GetDebug() > 0) printf("MixA: (r1_event1+r2_event1)+r3_event2 \n");
501 //-------------------------
502 //background analysis
504 // --A (r1_event1+r2_event1)+r3_event2
505 Int_t nMixed = fEventsList[curEventBin]->GetSize();
506 for(Int_t im=0;im<nMixed;im++){
507 TClonesArray* ev2= (TClonesArray*) (fEventsList[curEventBin]->At(im));
508 for(Int_t mix1=0;mix1<ev2->GetEntries();mix1++){
509 AliAODPWG4Particle *mix1ph = (AliAODPWG4Particle*) (ev2->At(mix1));
510 TLorentzVector vmixph(mix1ph->Px(),mix1ph->Py(),mix1ph->Pz(),mix1ph->E());
511 Double_t pi0gammapt=(vpi0+vmixph).Pt();
512 Double_t pi0gammamass=(vpi0+vmixph).M();
513 Double_t pi0OverOmegaPtRatio =vpi0.Pt()/pi0gammapt;
514 Double_t gammaOverOmegaPtRatio= vmixph.Pt()/pi0gammapt;
517 if(pi0OverOmegaPtRatio>fPi0OverOmegaPtCut ||
518 gammaOverOmegaPtRatio<fGammaOverOmegaPtCut) continue;
520 for(Int_t ipid=0;ipid<fNpid;ipid++){
521 for(Int_t idist=0;idist<fNBadChDistBin;idist++){
522 Int_t index=curEventBin*fNpid*fNBadChDistBin+ipid*fNBadChDistBin+idist;
523 if(photon1->IsPIDOK(ipid,AliCaloPID::kPhoton)&&
524 photon2->IsPIDOK(ipid,AliCaloPID::kPhoton)&&
525 mix1ph->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
526 photon1->DistToBad()>=idist &&
527 photon2->DistToBad()>=idist &&
528 mix1ph->DistToBad()>=idist ){
529 if(GetDebug() > 2) printf("MixA: index %d pt %2.3f mass %2.3f \n",index, pi0gammapt, pi0gammamass);
530 //fill the histograms
531 fMixAOmega0[index]->Fill(pi0gammapt,pi0gammamass);
532 if(pi0asy<0.7)fMixAOmega1[index]->Fill(pi0gammapt,pi0gammamass);
533 if(pi0asy<0.8)fMixAOmega2[index]->Fill(pi0gammapt,pi0gammamass);
534 //printf("mix A %d %2.2f \n", index, pi0gammamass);
545 // --B (r1_event1+r2_event2)+r3_event2
547 if(GetDebug() >0)printf("MixB: (r1_event1+r2_event2)+r3_event2 \n");
548 for(Int_t i=0;i<nphotons;i++){
549 AliAODPWG4Particle *ph1 = (AliAODPWG4Particle*) (aodGamma->At(i));
550 TLorentzVector vph1(ph1->Px(),ph1->Py(),ph1->Pz(),ph1->E());
551 //interrupt here...................
552 //especially for EMCAL
553 //we suppose the high pt clusters are overlapped pi0
555 for(Int_t j=i+1;j<nphotons;j++){
556 AliAODPWG4Particle *ph2 = (AliAODPWG4Particle*) (aodGamma->At(j));
557 TLorentzVector fakePi0, fakeOmega, vph;
559 if(ph1->E() > fEOverlapCluster && ph1->E() > ph2->E()) {
560 fakePi0.SetPxPyPzE(ph1->Px(),ph1->Py(),ph1->Pz(),TMath::Sqrt(ph1->Px()*ph1->Px()+ph1->Py()*ph1->Py()+ph1->Pz()*ph1->Pz()+0.135*0.135));
561 vph.SetPxPyPzE(ph2->Px(),ph2->Py(),ph2->Pz(),ph2->E());
563 else if(ph2->E() > fEOverlapCluster && ph2->E() > ph1->E()) {
564 fakePi0.SetPxPyPzE(ph2->Px(),ph2->Py(),ph2->Pz(),TMath::Sqrt(ph2->Px()*ph2->Px()+ph2->Py()*ph2->Py()+ph2->Pz()*ph2->Pz()+0.135*0.135));
565 vph.SetPxPyPzE(ph1->Px(), ph1->Py(),ph1->Pz(),ph1->E());
569 fakeOmega=fakePi0+vph;
570 for(Int_t ii=0;ii<fNCentBin;ii++){
571 fhFakeOmega[icentbin]->Fill(fakeOmega.Pt(), fakeOmega.M());
575 //continue ................
576 Int_t nMixed = fEventsList[curEventBin]->GetSize();
577 for(Int_t ie=0;ie<nMixed;ie++){
578 TClonesArray* ev2= (TClonesArray*) (fEventsList[curEventBin]->At(ie));
579 for(Int_t mix1=0;mix1<ev2->GetEntries();mix1++){
580 AliAODPWG4Particle *ph2 = (AliAODPWG4Particle*) (ev2->At(mix1));
581 TLorentzVector vph2(ph2->Px(),ph2->Py(),ph2->Pz(),ph2->E());
582 Double_t pi0asy = TMath::Abs(vph1.E()-vph2.E())/(vph1.E()+vph2.E());
583 Double_t pi0mass=(vph1+vph2).M();
585 if(TMath::Abs(pi0mass-fPi0Mass)<fPi0MassWindow){//for pi0 selection
586 for(Int_t mix2=(mix1+1);mix2<ev2->GetEntries();mix2++){
587 AliAODPWG4Particle *ph3 = (AliAODPWG4Particle*) (ev2->At(mix2));
588 TLorentzVector vph3(ph3->Px(),ph3->Py(),ph3->Pz(),ph3->E());
590 Double_t pi0gammapt=(vph1+vph2+vph3).Pt();
591 Double_t pi0gammamass=(vph1+vph2+vph3).M();
592 Double_t pi0OverOmegaPtRatio =(vph1+vph2).Pt()/pi0gammapt;
593 Double_t gammaOverOmegaPtRatio= vph3.Pt()/pi0gammapt;
595 if(pi0OverOmegaPtRatio>fPi0OverOmegaPtCut ||
596 gammaOverOmegaPtRatio<fGammaOverOmegaPtCut) continue;
598 for(Int_t ipid=0;ipid<fNpid;ipid++){
599 for(Int_t idist=0;idist<fNBadChDistBin;idist++){
600 Int_t index=curEventBin*fNpid*fNBadChDistBin+ipid*fNBadChDistBin+idist;
601 if(ph1->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
602 ph2->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
603 ph3->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
604 ph1->DistToBad()>=idist &&
605 ph2->DistToBad()>=idist &&
606 ph3->DistToBad()>=idist ){
607 if(GetDebug() > 2) printf("MixB: index %d pt %2.3f mass %2.3f \n", index, pi0gammapt, pi0gammamass);
609 fMixBOmega0[index]->Fill(pi0gammapt,pi0gammamass);
610 if(pi0asy<0.7) fMixBOmega1[index]->Fill(pi0gammapt,pi0gammamass);
611 if(pi0asy<0.8) fMixBOmega2[index]->Fill(pi0gammapt,pi0gammamass);
612 //printf("mix B %d %2.2f \n", index, pi0gammamass);
619 // --C (r1_event1+r2_event2)+r3_event3
621 if(GetDebug() >0)printf("MixC: (r1_event1+r2_event2)+r3_event3\n");
622 for(Int_t je=(ie+1);je<nMixed;je++){
623 TClonesArray* ev3= (TClonesArray*) (fEventsList[curEventBin]->At(je));
624 for(Int_t mix3=0;mix3<ev3->GetEntries();mix3++){
625 AliAODPWG4Particle *ph3 = (AliAODPWG4Particle*) (ev3->At(mix3));
626 TLorentzVector vph3(ph3->Px(),ph3->Py(),ph3->Pz(),ph3->E());
628 Double_t pi0gammapt=(vph1+vph2+vph3).Pt();
629 Double_t pi0gammamass=(vph1+vph2+vph3).M();
630 Double_t pi0OverOmegaPtRatio =(vph1+vph2).Pt()/pi0gammapt;
631 Double_t gammaOverOmegaPtRatio= vph3.Pt()/pi0gammapt;
633 if(pi0OverOmegaPtRatio>fPi0OverOmegaPtCut ||
634 gammaOverOmegaPtRatio<fGammaOverOmegaPtCut) continue;
636 for(Int_t ipid=0;ipid<fNpid;ipid++){
637 for(Int_t idist=0;idist<fNBadChDistBin;idist++){
638 Int_t index=curEventBin*fNpid*fNBadChDistBin+ipid*fNBadChDistBin+idist;
639 if(ph1->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
640 ph2->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
641 ph3->IsPIDOK(ipid,AliCaloPID::kPhoton) &&
642 ph1->DistToBad()>=idist &&
643 ph2->DistToBad()>=idist &&
644 ph3->DistToBad()>=idist ){
645 if(GetDebug() > 2) printf("MixC: index %d pt %2.3f mass %2.3f \n", index, pi0gammapt, pi0gammamass);
647 fMixCOmega0[index]->Fill(pi0gammapt,pi0gammamass);
648 if(pi0asy<0.7) fMixCOmega1[index]->Fill(pi0gammapt,pi0gammamass);
649 if(pi0asy<0.8) fMixCOmega2[index]->Fill(pi0gammapt,pi0gammamass);
650 //printf("mix C %d %2.2f \n", index, pi0gammamass);
663 TClonesArray *currentEvent = new TClonesArray(*aodGamma);
664 if(currentEvent->GetEntriesFast()>0){
665 fEventsList[curEventBin]->AddFirst(currentEvent) ;
667 if(fEventsList[curEventBin]->GetSize()>=GetNMaxEvMix()) {
668 TClonesArray * tmp = (TClonesArray*) (fEventsList[curEventBin]->Last()) ;
669 fEventsList[curEventBin]->RemoveLast() ;
674 delete currentEvent ;
680 //______________________________________________________________________________
681 void AliAnaOmegaToPi0Gamma::ReadHistograms(TList * outputList)
683 //read the histograms
684 //for the finalization of the terminate analysis
686 Int_t index = outputList->IndexOf(outputList->FindObject(GetAddedHistogramsStringToName()+"RealToPi0Gamma_Vz0C0Rp0Pid0Dist0"));
688 Int_t ndim=fNVtxZBin*fNCentBin*fNRpBin*fNBadChDistBin*fNpid;
690 if(!fRealOmega0) fRealOmega0 =new TH2F*[ndim];
691 if(!fMixAOmega0) fMixAOmega0 =new TH2F*[ndim];
692 if(!fMixBOmega0) fMixBOmega0 =new TH2F*[ndim];
693 if(!fMixCOmega0) fMixCOmega0 =new TH2F*[ndim];
695 if(!fRealOmega1) fRealOmega1 =new TH2F*[ndim];
696 if(!fMixAOmega1) fMixAOmega1 =new TH2F*[ndim];
697 if(!fMixBOmega1) fMixBOmega1 =new TH2F*[ndim];
698 if(!fMixCOmega1) fMixCOmega1 =new TH2F*[ndim];
700 if(!fRealOmega2) fRealOmega2 =new TH2F*[ndim];
701 if(!fMixAOmega2) fMixAOmega2 =new TH2F*[ndim];
702 if(!fMixBOmega2) fMixBOmega2 =new TH2F*[ndim];
703 if(!fMixCOmega2) fMixCOmega2 =new TH2F*[ndim];
705 for(Int_t i=0;i<fNVtxZBin;i++){
706 for(Int_t j=0;j<fNCentBin;j++){
707 for(Int_t k=0;k<fNRpBin;k++){ //at event level
708 Int_t idim=i*fNCentBin*fNRpBin+j*fNRpBin+k;
709 for(Int_t ipid=0;ipid<fNpid;ipid++){
710 for(Int_t idist=0;idist<fNBadChDistBin;idist++){ //at particle
711 Int_t ind=idim*fNpid*fNBadChDistBin+ipid*fNBadChDistBin+idist;
712 fRealOmega0[ind]= (TH2F*) outputList->At(index++);
713 fMixAOmega0[ind]= (TH2F*) outputList->At(index++);
714 fMixBOmega0[ind]= (TH2F*) outputList->At(index++);
715 fMixCOmega0[ind]= (TH2F*) outputList->At(index++);
717 fRealOmega1[ind]= (TH2F*) outputList->At(index++);
718 fMixAOmega1[ind]= (TH2F*) outputList->At(index++);
719 fMixBOmega1[ind]= (TH2F*) outputList->At(index++);
720 fMixCOmega1[ind]= (TH2F*) outputList->At(index++);
722 fRealOmega2[ind]= (TH2F*) outputList->At(index++);
723 fMixAOmega2[ind]= (TH2F*) outputList->At(index++);
724 fMixBOmega2[ind]= (TH2F*) outputList->At(index++);
725 fMixCOmega2[ind]= (TH2F*) outputList->At(index++);
735 fhOmegaPriPt = (TH1F*) outputList->At(index++);
740 //______________________________________________________________________________
741 void AliAnaOmegaToPi0Gamma::Terminate(TList * outputList)
743 // //Do some calculations and plots from the final histograms.
744 if(GetDebug() >= 0) printf("AliAnaOmegaToPi0Gamma::Terminate() \n");
745 ReadHistograms(outputList);
746 const Int_t buffersize = 255;
747 char cvs1[buffersize];
748 snprintf(cvs1, buffersize, "Neutral_%s_IVM",fInputAODGammaName.Data());
750 TCanvas * cvsIVM = new TCanvas(cvs1, cvs1, 400, 10, 600, 700) ;
751 cvsIVM->Divide(2, 2);
754 char dec[buffersize];
755 snprintf(dec,buffersize,"h2Real_%s",fInputAODGammaName.Data());
756 TH2F * h2Real= (TH2F*)fRealOmega0[0]->Clone(dec);
757 h2Real->GetXaxis()->SetRangeUser(4,6);
758 TH1F * hRealOmega = (TH1F*) h2Real->ProjectionY();
759 hRealOmega->SetTitle("RealPi0Gamma 4<pt<6");
760 hRealOmega->SetLineColor(2);
764 snprintf(dec,buffersize,"hMixA_%s",fInputAODGammaName.Data());
765 TH2F *h2MixA= (TH2F*)fMixAOmega0[0]->Clone(dec);
766 h2MixA->GetXaxis()->SetRangeUser(4,6);
767 TH1F * hMixAOmega = (TH1F*) h2MixA->ProjectionY();
768 hMixAOmega->SetTitle("MixA 4<pt<6");
769 hMixAOmega->SetLineColor(2);
773 snprintf(dec,buffersize,"hMixB_%s",fInputAODGammaName.Data());
774 TH2F * h2MixB= (TH2F*)fMixBOmega0[0]->Clone(dec);
775 h2MixB->GetXaxis()->SetRangeUser(4,6);
776 TH1F * hMixBOmega = (TH1F*) h2MixB->ProjectionY();
777 hMixBOmega->SetTitle("MixB 4<pt<6");
778 hMixBOmega->SetLineColor(2);
782 snprintf(dec,buffersize,"hMixC_%s",fInputAODGammaName.Data());
783 TH2F *h2MixC= (TH2F*)fMixCOmega0[0]->Clone(dec);
784 h2MixC->GetXaxis()->SetRangeUser(4,6);
785 TH1F * hMixCOmega = (TH1F*) h2MixC->ProjectionY();
786 hMixCOmega->SetTitle("MixC 4<pt<6");
787 hMixCOmega->SetLineColor(2);
790 char eps[buffersize];
791 snprintf(eps,buffersize,"CVS_%s_IVM.eps",fInputAODGammaName.Data());
git://git.uio.no / u / mrichter / AliRoot.git / blob