Int_t AddRsnDaughterCutsRhoNsigma(AliPID::EParticleType type1,AliPID::EParticleType type2,TString opt,Bool_t isRsnMini=kFALSE,AliRsnInputHandler *rsnIH=0,AliAnalysisTaskSE *task=0) { if (!rsnIH) return 0; Bool_t valid = kTRUE; Int_t isPP = AliAnalysisManager::GetGlobalInt("rsnIsPP",valid); Bool_t usePPCut = kFALSE; if (isPP && (opt.Contains("usePP"))) usePPCut = kTRUE; // === USER HAS TO SET CORRECT NUMBER OF CUTS SETS ===== Int_t numberOfCuts = 1; //--------------------------------------------- // Define single cuts //--------------------------------------------- Printf("AddRsnDaughterCutsRho Option : %s",opt.Data()); Double_t nSigmaTPC=3.0; Double_t nSigmaTOF=3.0; Double_t etaRange=0.8; Bool_t useTPC_Pi=kFALSE; Bool_t useTOF_Pi=kFALSE; if (opt.Contains("qualityonly")) { useTPC_Pi=kFALSE; useTOF_Pi=kFALSE; } else if (!opt.Contains("nsig")) { useTPC_Pi=kTRUE; useTOF_Pi=kTRUE; } if (opt.Contains("PiTPCnsig")) useTPC_Pi=kTRUE; if (opt.Contains("PiTOFnsig")) useTOF_Pi=kTRUE; if (opt.Contains("PiTPCnsig10")) nSigmaTPC = 1.0; if (opt.Contains("PiTPCnsig15")) nSigmaTPC = 1.5; if (opt.Contains("PiTPCnsig20")) nSigmaTPC = 2.0; if (opt.Contains("PiTPCnsig25")) nSigmaTPC = 2.5; if (opt.Contains("PiTPCnsig30")) nSigmaTPC = 3.0; if (opt.Contains("PiTOFnsig10")) nSigmaTOF = 1.0; if (opt.Contains("PiTOFnsig15")) nSigmaTOF = 1.5; if (opt.Contains("PiTOFnsig20")) nSigmaTOF = 2.0; if (opt.Contains("PiTOFnsig25")) nSigmaTOF = 2.5; if (opt.Contains("PiTOFnsig30")) nSigmaTOF = 3.0; Bool_t usePDG=kFALSE; if (opt.Contains("pdg")) { Printf("Using PDG"); usePDG = kTRUE; } Bool_t useEta = kFALSE; if (opt.Contains("eta")) { Printf("Using ETA range (%.2f,%.2f)",-etaRange,etaRange); useEta = kTRUE; } //--------------------------------------------- // Combine cuts //--------------------------------------------- TString cutname = "Pi_Rho"; if (!opt.IsNull()) cutname += Form("_%s",opt.Data()); AliRsnCutSet *cuts = new AliRsnCutSet(cutname.Data(), AliRsnTarget::kDaughter); TString scheme=""; AliRsnCutTrackQuality *qualityCut = new AliRsnCutTrackQuality("cutQuatityPi"); qualityCut->SetDefaults2010(); cuts->AddCut(qualityCut); if (!scheme.IsNull()) scheme += "&"; scheme += qualityCut->GetName(); if (useTPC_Pi) { AliRsnCutPIDNSigma *cutPiTPC = new AliRsnCutPIDNSigma("cutPIDNSigmaTPCPi",AliPID::kPion,AliRsnCutPIDNSigma::kTPC); cutPiTPC->SinglePIDRange(nSigmaTPC); cuts->AddCut(cutPiTPC); if (!scheme.IsNull()) scheme += "&"; scheme += cutPiTPC->GetName(); } if (useTOF_Pi) { AliRsnCutPIDNSigma *cutPiTOF = new AliRsnCutPIDNSigma("cutPIDNSigmaTOFPi",AliPID::kPion,AliRsnCutPIDNSigma::kTOF); cutPiTOF->SinglePIDRange(nSigmaTOF); cuts->AddCut(cutPiTOF); if (!scheme.IsNull()) scheme += "&"; scheme += cutPiTOF->GetName(); } if (useEta) { Printf("Adding ETA ..."); AliRsnValueDaughter *valEta = new AliRsnValueDaughter(Form("val%sETA%s",AliPID::ParticleName(type1),opt.Data()),AliRsnValueDaughter::kEta); AliRsnCutValue *cutEta = new AliRsnCutValue(Form("cut%sETA%s",AliPID::ParticleName(type1),opt.Data()),-etaRange,etaRange); cutEta->SetTargetType(AliRsnTarget::kDaughter); cutEta->SetValueObj(valEta); cuts->AddCut(cutEta); if (!scheme.IsNull()) scheme += "&"; scheme += cutEta->GetName(); } if (usePDG) { Printf("Adding PDG ..."); AliRsnCutPID *cutPDG = new AliRsnCutPID(Form("cut%sPDG%s",AliPID::ParticleName(type1),opt.Data()),type1,0.0,kTRUE); cuts->AddCut(cutPDG); if (!scheme.IsNull()) scheme += "&"; scheme += cutPDG->GetName(); } Printf ("CUT Scheme is '%s'",scheme.Data()); cuts->SetCutScheme(scheme.Data()); if (opt.Contains("mon")) { AddMonitorOutput(cuts->GetMonitorOutput(),opt); } if (isRsnMini) { AliRsnMiniAnalysisTask *taskRsnMini = dynamic_cast<AliRsnMiniAnalysisTask *>(task); if (taskRsnMini) { taskRsnMini->AddTrackCuts(cuts); } } else { AliRsnDaughterSelector *sel = rsnIH->GetSelector(); // sel->SetLabelCheck(kFALSE); sel->Add(cuts, kTRUE); } return numberOfCuts; }
Int_t AddRsnDaughterCutsKStarTOFanalysis(AliPID::EParticleType type1,AliPID::EParticleType type2,TString opt,AliRsnInputHandler *rsnIH=0,AliAnalysisTaskSE *task=0) { if (!rsnIH) return 0; Bool_t valid; Int_t isRsnMini = AliRsnTrainManager::GetGlobalInt("IsRsnMini",valid); // === USER HAS TO SET CORRECT NUMBER OF CUTS SETS ===== Int_t numberOfCuts = 2; //--------------------------------------------- // Define single cutsP //--------------------------------------------- Printf("AddRsnDaughterCutsKStarTOFanalysis Option : %s",opt.Data()); // default values Double_t nSigmaTPC_Pi=3.0; Double_t nSigmaTPC_K=3.0; Double_t nSigmaTOF_Pi=3.0; Double_t nSigmaTOF_K=3.0; Double_t nSigmaTPCveto_Pi=5.0; Double_t nSigmaTPCveto_K=5.0; Double_t etaRange=0.8; Bool_t useTPC_Pi=kFALSE; Bool_t useTOF_Pi=kFALSE; Bool_t useTPC_K=kFALSE; Bool_t useTOF_K=kFALSE; Bool_t useTPCveto_Pi = kFALSE; Bool_t useTPCveto_K = kFALSE; Bool_t useCombined_Pi = kFALSE; Bool_t useCombined_K = kFALSE; if (opt.Contains("qualityonly")) { useTPC_Pi=kFALSE; useTOF_Pi=kFALSE; useTPC_K=kFALSE; useTOF_K=kFALSE; useTPCveto_Pi = kFALSE; useTPCveto_K = kFALSE; useCombined_Pi = kFALSE; useCombined_K = kFALSE; } else { if (opt.Contains("combined")) { useCombined_Pi = kTRUE; useCombined_K = kTRUE; } else { if (opt.Contains("PiTPCnsig")) useTPC_Pi=kTRUE; if (opt.Contains("PiTOFnsig")) useTOF_Pi=kTRUE; if (opt.Contains("KTPCnsig")) useTPC_K=kTRUE; if (opt.Contains("KTOFnsig")) useTOF_K=kTRUE; if(opt.Contains("TPCveto")) { useTPCveto_Pi = kTRUE; useTPCveto_K = kTRUE; nSigmaTPCveto_Pi = 5.0; nSigmaTPCveto_K = 5.0; } } } if (opt.Contains("PiTPCnsig10")) nSigmaTPC_Pi = 1.0; if (opt.Contains("PiTPCnsig15")) nSigmaTPC_Pi = 1.5; if (opt.Contains("PiTPCnsig20")) nSigmaTPC_Pi = 2.0; if (opt.Contains("PiTPCnsig25")) nSigmaTPC_Pi = 2.5; if (opt.Contains("PiTPCnsig30")) nSigmaTPC_Pi = 3.0; if (opt.Contains("KTPCnsig10")) nSigmaTPC_K = 1.0; if (opt.Contains("KTPCnsig15")) nSigmaTPC_K = 1.5; if (opt.Contains("KTPCnsig20")) nSigmaTPC_K = 2.0; if (opt.Contains("KTPCnsig25")) nSigmaTPC_K = 2.5; if (opt.Contains("KTPCnsig30")) nSigmaTPC_K = 3.0; if (opt.Contains("PiTOFnsig10")) nSigmaTOF_Pi = 1.0; if (opt.Contains("PiTOFnsig15")) nSigmaTOF_Pi = 1.5; if (opt.Contains("PiTOFnsig20")) nSigmaTOF_Pi = 2.0; if (opt.Contains("PiTOFnsig25")) nSigmaTOF_Pi = 2.5; if (opt.Contains("PiTOFnsig30")) nSigmaTOF_Pi = 3.0; if (opt.Contains("KTOFnsig10")) nSigmaTOF_K = 1.0; if (opt.Contains("KTOFnsig15")) nSigmaTOF_K = 1.5; if (opt.Contains("KTOFnsig20")) nSigmaTOF_K = 2.0; if (opt.Contains("KTOFnsig25")) nSigmaTOF_K = 2.5; if (opt.Contains("KTOFnsig30")) nSigmaTOF_K = 3.0; Bool_t usePDG=kFALSE; if (opt.Contains("pdg")) { Printf("Using PDG"); usePDG = kTRUE; } Bool_t useEta = kFALSE; if (opt.Contains("eta")) { Printf("Using ETA range (%.2f,%.2f)",-etaRange,etaRange); useEta = kTRUE; } // KAON SETTINGS ======================================= TString scheme=""; TString cutname = "K_Kstar"; if (!opt.IsNull()) cutname += Form("_%s",opt.Data()); AliRsnCutSet *cutsK; if (useCombined_K) { cutsK = new AliRsnCutSetDaughterParticle(cutname.Data(), AliRsnCutSetDaughterParticle::kTPCTOFpidKstarPP2010, AliPID::kKaon, nSigmaTOF_K, 5); if (!scheme.IsNull()) scheme += "&"; scheme += cutsK->GetCutScheme(); } else { if (useTPCveto_K) { cutsK = new AliRsnCutSetDaughterParticle(cutname.Data(), AliRsnCutSetDaughterParticle::kTOFpidKstarPbPb2010, AliPID::kKaon, nSigmaTOF_K, 5); if (!scheme.IsNull()) scheme += "&"; scheme += cutsK->GetCutScheme(); } else { cutsK = new AliRsnCutSet(cutname.Data(), AliRsnTarget::kDaughter); AliRsnCutTrackQuality *qualityCutK = new AliRsnCutTrackQuality("cutQuatityK"); qualityCutK->SetDefaults2010(); cutsK->AddCut(qualityCutK); if (!scheme.IsNull()) scheme += "&"; scheme += qualityCutK->GetName(); if (useTPC_K) { AliRsnCutPIDNSigma *cutKTPC = new AliRsnCutPIDNSigma("cutNSigmaTPCK",AliPID::kKaon,AliRsnCutPIDNSigma::kTPC); cutKTPC->SinglePIDRange(nSigmaTPC_K); cutsK->AddCut(cutKTPC); if (!scheme.IsNull()) scheme += "&"; scheme += cutKTPC->GetName(); } if (useTOF_K) { AliRsnCutPIDNSigma *cutKTOF = new AliRsnCutPIDNSigma("cutNSigmaTOFK",AliPID::kKaon,AliRsnCutPIDNSigma::kTOF); cutKTOF->SinglePIDRange(nSigmaTOF_K); cutsK->AddCut(cutKTOF); if (!scheme.IsNull()) scheme += "&"; scheme += cutKTOF->GetName(); } } } if (useEta) { AliRsnValueDaughter *valEtaK = new AliRsnValueDaughter(Form("val%sETA%s",AliPID::ParticleName(type2),opt.Data()),AliRsnValueDaughter::kEta); AliRsnCutValue *cutEtaK = new AliRsnCutValue(Form("cut%sETA%s",AliPID::ParticleName(type2),opt.Data()),-etaRange,etaRange); cutEtaK->SetTargetType(AliRsnTarget::kDaughter); cutEtaK->SetValueObj(valEtaK); cutsK->AddCut(cutEtaK); if (!scheme.IsNull()) scheme += "&"; scheme += cutEtaK->GetName(); } if (usePDG) { AliRsnCutPID *cutPDGK = new AliRsnCutPID(Form("cut%sPDG%s",AliPID::ParticleName(type2),opt.Data()),type2,0.0,kTRUE); cutsK->AddCut(cutPDGK); if (!scheme.IsNull()) scheme += "&"; scheme += cutPDGK->GetName(); } Printf ("CUT Scheme for KAON is '%s'",scheme.Data()); cutsK->SetCutScheme(scheme.Data()); // END KAON ======================================= // Pion SETTINGS =========================================== scheme=""; cutname = "Pi_Kstar"; if (!opt.IsNull()) cutname += Form("_%s",opt.Data()); AliRsnCutSet *cutsPi; if (useCombined_Pi) { cutsPi = new AliRsnCutSetDaughterParticle(cutname.Data(), AliRsnCutSetDaughterParticle::kTPCTOFpidKstarPP2010, AliPID::kPion, nSigmaTOF_Pi, 5); if (!scheme.IsNull()) scheme += "&"; scheme += cutsPi->GetCutScheme(); } else { if (useTPCveto_Pi) { cutsPi = new AliRsnCutSetDaughterParticle(cutname.Data(), AliRsnCutSetDaughterParticle::kTOFpidKstarPbPb2010, AliPID::kPion, nSigmaTOF_Pi, 5); if (!scheme.IsNull()) scheme += "&"; scheme += cutsPi->GetCutScheme(); } else { cutsPi = new AliRsnCutSet(cutname.Data(), AliRsnTarget::kDaughter); AliRsnCutTrackQuality *qualityCutPi = new AliRsnCutTrackQuality("cutQuatityPi"); qualityCutPi->SetDefaults2010(); cutsPi->AddCut(qualityCutPi); if (!scheme.IsNull()) scheme += "&"; scheme += qualityCutPi->GetName(); if (useTPC_Pi) { AliRsnCutPIDNSigma *cutPiTPC = new AliRsnCutPIDNSigma("cutNSigmaTPCPi",AliPID::kPion,AliRsnCutPIDNSigma::kTPC); cutPiTPC->SinglePIDRange(nSigmaTPC_Pi); cutsPi->AddCut(cutPiTPC); if (!scheme.IsNull()) scheme += "&"; scheme += cutPiTPC->GetName(); } if (useTOF_Pi) { AliRsnCutPIDNSigma *cutPiTOF = new AliRsnCutPIDNSigma("cutNSigmaTOFPi",AliPID::kPion,AliRsnCutPIDNSigma::kTOF); cutPiTOF->SinglePIDRange(nSigmaTOF_Pi); cutsPi->AddCut(cutPiTOF); if (!scheme.IsNull()) scheme += "&"; scheme += cutPiTOF->GetName(); } } } if (useEta) { AliRsnValueDaughter *valEtaP = new AliRsnValueDaughter(Form("val%sETA%s",AliPID::ParticleName(type1),opt.Data()),AliRsnValueDaughter::kEta); AliRsnCutValue *cutEtaP = new AliRsnCutValue(Form("cut%sETA%s",AliPID::ParticleName(type1),opt.Data()),-etaRange,etaRange); cutEtaP->SetTargetType(AliRsnTarget::kDaughter); cutEtaP->SetValueObj(valEtaP); cutsPi->AddCut(cutEtaP); if (!scheme.IsNull()) scheme += "&"; scheme += cutEtaP->GetName(); } if (usePDG) { AliRsnCutPID *cutPDGP = new AliRsnCutPID(Form("cut%sPDG%s",AliPID::ParticleName(type1),opt.Data()),type1,0.0,kTRUE); cutsPi->AddCut(cutPDGP); if (!scheme.IsNull()) scheme += "&"; scheme += cutPDGP->GetName(); } Printf ("CUT Scheme for PROTON is '%s'",scheme.Data()); cutsPi->SetCutScheme(scheme.Data()); // END PION ======================================= if (opt.Contains("mon")) { AddMonitorOutput(cutsPi->GetMonitorOutput(),opt); AddMonitorOutput(cutsK->GetMonitorOutput(),opt); } if (isRsnMini) { AliRsnMiniAnalysisTask *taskRsnMini = dynamic_cast<AliRsnMiniAnalysisTask *>(task); if (taskRsnMini) { taskRsnMini->AddTrackCuts(cutsK); taskRsnMini->AddTrackCuts(cutsPi); } } else { AliRsnDaughterSelector *sel = rsnIH->GetSelector(); // sel->SetLabelCheck(kFALSE); sel->Add(cutsPi, kTRUE); sel->Add(cutsK, kTRUE); } return numberOfCuts; }
Int_t AddRsnDaughterCutsLambdaNsigma(AliPID::EParticleType type1,AliPID::EParticleType type2,TString opt,AliRsnInputHandler *rsnIH=0,AliAnalysisTaskSE *task=0) { if (!rsnIH) return 0; Bool_t valid = kTRUE; // Int_t collisionType = AliRsnTrainManager::GetGlobalInt("IsCollisionType",valid); Int_t useCommonQualityCut = AliRsnTrainManager::GetGlobalInt("RsnCommonQualityCut",valid); TString rsnQualityCut = AliRsnTrainManager::GetGlobalStr("RsnQualityCut",valid); Int_t isMC = AliRsnTrainManager::GetGlobalInt("IsMC",valid); Int_t isRsnMini = AliRsnTrainManager::GetGlobalInt("IsRsnMini",valid); Int_t isMixing = AliRsnTrainManager::GetGlobalInt("IsMixing",valid); // === USER HAS TO SET CORRECT NUMBER OF CUTS SETS ===== Int_t numberOfCuts = 2; //--------------------------------------------- // Define single cutsP //--------------------------------------------- Printf("AddRsnDaughterCutsLambda Option : %s",opt.Data()); Double_t nSigmaTPC_P=3.0; Double_t nSigmaTPC_K=3.0; Double_t nSigmaTOF_P=3.0; Double_t nSigmaTOF_K=3.0; Double_t etaRange=0.8; Double_t PtMin_P=0.15; Double_t PtMax_P=1.e10; Double_t PtMin_K=0.15; Double_t PtMax_K=1.e10; Double_t PMax_P=1.1; Double_t PMax_K=0.6; Bool_t useTPC_P=kFALSE; Bool_t useTOF_P=kFALSE; Bool_t rejectUnmatchedTOF_P=kTRUE; Bool_t useTPC_K=kFALSE; Bool_t useTOF_K=kFALSE; Bool_t rejectUnmatchedTOF_K=kTRUE; if (opt.Contains("qualityonly")) { useTPC_P=kFALSE; useTOF_P=kFALSE; useTPC_K=kFALSE; useTOF_K=kFALSE; } else if (!opt.Contains("nsig")) { useTPC_P=kTRUE; useTOF_P=kTRUE; useTPC_K=kTRUE; useTOF_K=kTRUE; } if (opt.Contains("PTPCnsig")) useTPC_P=kTRUE; if (opt.Contains("PTPCnsig10")) nSigmaTPC_P = 1.0; if (opt.Contains("PTPCnsig15")) nSigmaTPC_P = 1.5; if (opt.Contains("PTPCnsig20")) nSigmaTPC_P = 2.0; if (opt.Contains("PTPCnsig25")) nSigmaTPC_P = 2.5; if (opt.Contains("PTPCnsig30")) nSigmaTPC_P = 3.0; if (opt.Contains("PTPCnsig40")) nSigmaTPC_P = 4.0; if (opt.Contains("PTPCnsig50")) nSigmaTPC_P = 5.0; if (opt.Contains("PTPCnsig1000")) nSigmaTPC_P = 100.0; if (opt.Contains("KTPCnsig")) useTPC_K=kTRUE; if (opt.Contains("KTPCnsig10")) nSigmaTPC_K = 1.0; if (opt.Contains("KTPCnsig15")) nSigmaTPC_K = 1.5; if (opt.Contains("KTPCnsig20")) nSigmaTPC_K = 2.0; if (opt.Contains("KTPCnsig25")) nSigmaTPC_K = 2.5; if (opt.Contains("KTPCnsig30")) nSigmaTPC_K = 3.0; if (opt.Contains("KTPCnsig40")) nSigmaTPC_K = 4.0; if (opt.Contains("KTPCnsig50")) nSigmaTPC_K = 5.0; if (opt.Contains("KTPCnsig1000")) nSigmaTPC_K = 100.0; if (opt.Contains("PTOFnsig")) useTOF_P=kTRUE; if (opt.Contains("PTOFacceptUnmatched")) rejectUnmatchedTOF_P=kFALSE; if (opt.Contains("PTOFnsig10")) nSigmaTOF_P = 1.0; if (opt.Contains("PTOFnsig15")) nSigmaTOF_P = 1.5; if (opt.Contains("PTOFnsig20")) nSigmaTOF_P = 2.0; if (opt.Contains("PTOFnsig25")) nSigmaTOF_P = 2.5; if (opt.Contains("PTOFnsig30")) nSigmaTOF_P = 3.0; if (opt.Contains("PTOFnsig40")) nSigmaTOF_P = 4.0; if (opt.Contains("PTOFnsig50")) nSigmaTOF_P = 5.0; if (opt.Contains("PTOFnsig1000")) nSigmaTOF_P = 100.0; if (opt.Contains("KTOFnsig")) useTOF_K=kTRUE; if (opt.Contains("KTOFacceptUnmatched")) rejectUnmatchedTOF_K=kFALSE; if (opt.Contains("KTOFnsig10")) nSigmaTOF_K = 1.0; if (opt.Contains("KTOFnsig15")) nSigmaTOF_K = 1.5; if (opt.Contains("KTOFnsig20")) nSigmaTOF_K = 2.0; if (opt.Contains("KTOFnsig25")) nSigmaTOF_K = 2.5; if (opt.Contains("KTOFnsig30")) nSigmaTOF_K = 3.0; if (opt.Contains("KTOFnsig40")) nSigmaTOF_K = 4.0; if (opt.Contains("KTOFnsig50")) nSigmaTOF_K = 5.0; if (opt.Contains("KTOFnsig1000")) nSigmaTOF_K = 100.0; Bool_t usePDG=kFALSE; if (opt.Contains("pdg")) { Printf("Using PDG"); usePDG = kTRUE; } Bool_t useEta = kFALSE; if (opt.Contains("eta")) { for(int j=1;j<=9;j++) if(opt.Contains(Form("eta0%i",j))) etaRange=0.1*j; Printf("Using ETA range (%.2f,%.2f)",-etaRange,etaRange); useEta = kTRUE; } Bool_t usePPt=kFALSE; if(opt.Contains("PPt")){ Printf("Using Proton pT range (%.2f,%.2f)",PtMin_P,PtMax_P); usePPt=kTRUE; } Bool_t useKPt=kFALSE; if(opt.Contains("KPt")){ Printf("Using Kaon pT range (%.2f,%.2f)",PtMin_K,PtMax_K); useKPt=kTRUE; } Bool_t usePMax_P=kFALSE; if(opt.Contains("PPMax")){ for(int j=1;j<=9;j++) if(opt.Contains(Form("PPMax0%i",j))) PMax_P=0.1*j; for(int j=10;j<=30;j++) if(opt.Contains(Form("PPMax%i",j))) PMax_P=0.1*j; Printf("Using Proton momentum range (0,%.2f)",PMax_P); usePMax_P=kTRUE; } Bool_t usePMax_K=kFALSE; if(opt.Contains("KPMax")){ for(int j=1;j<=9;j++) if(opt.Contains(Form("KPMax0%i",j))) PMax_K=0.1*j; for(int j=10;j<=30;j++) if(opt.Contains(Form("KPMax%i",j))) PMax_K=0.1*j; Printf("Using Kaon momentum range (0,%.2f)",PMax_K); usePMax_K=kTRUE; } // PROTON SETTINGS =========================================== TString scheme=""; TString cutname = "p_Lambda"; if (!opt.IsNull()) cutname += Form("_%s",opt.Data()); AliRsnCutSet *cutsP = new AliRsnCutSet(cutname.Data(), AliRsnTarget::kDaughter); AliRsnCutTrackQuality *qualityCutP = new AliRsnCutTrackQuality("cutQualityP"); if (useCommonQualityCut>=0) { qualityCutP->SetAODTestFilterBit(useCommonQualityCut); } else { qualityCutP->SetDefaults2010(); } cutsP->AddCut(qualityCutP); if (!scheme.IsNull()) scheme += "&"; scheme += qualityCutP->GetName(); if (useTPC_P) { AliRsnCutPIDNSigma *cutPTPC = new AliRsnCutPIDNSigma("cutNSigmaTPCP",AliPID::kProton,AliRsnCutPIDNSigma::kTPC); cutPTPC->SinglePIDRange(nSigmaTPC_P); cutsP->AddCut(cutPTPC); if (!scheme.IsNull()) scheme += "&"; scheme += cutPTPC->GetName(); } if (useTOF_P) { AliRsnCutPIDNSigma *cutPTOF = new AliRsnCutPIDNSigma("cutNSigmaTOFP",AliPID::kProton,AliRsnCutPIDNSigma::kTOF); cutPTOF->SinglePIDRange(nSigmaTOF_P); cutsP->AddCut(cutPTOF); if(rejectUnmatchedTOF_P){ if (!scheme.IsNull()) scheme += "&"; scheme += cutPTOF->GetName(); }else{ AliRsnCutTOFMatch *cutPTOFMatch = new AliRsnCutTOFMatch("cutPTOFMatch"); cutsP->AddCut(cutPTOFMatch); if (!scheme.IsNull()) scheme += "&"; scheme += Form("(%s|(!%s))",cutPTOF->GetName(),cutPTOFMatch->GetName()); } } if (useEta) { AliRsnValueDaughter *valEtaP = new AliRsnValueDaughter(Form("val%sETA%s",AliPID::ParticleName(type1),opt.Data()),AliRsnValueDaughter::kEta); AliRsnCutValue *cutEtaP = new AliRsnCutValue(Form("cut%sETA%s",AliPID::ParticleName(type1),opt.Data()),-etaRange,etaRange); cutEtaP->SetTargetType(AliRsnTarget::kDaughter); cutEtaP->SetValueObj(valEtaP); cutsP->AddCut(cutEtaP); if (!scheme.IsNull()) scheme += "&"; scheme += cutEtaP->GetName(); } if (usePDG) { AliRsnCutPID *cutPDGP = new AliRsnCutPID(Form("cut%sPDG%s",AliPID::ParticleName(type1),opt.Data()),type1,0.0,kTRUE); cutsP->AddCut(cutPDGP); if (!scheme.IsNull()) scheme += "&"; scheme += cutPDGP->GetName(); } if(usePPt){ AliRsnValueDaughter *valPtP = new AliRsnValueDaughter(Form("val%sPt%s",AliPID::ParticleName(type1),opt.Data()),AliRsnValueDaughter::kPt); AliRsnCutValue *cutPtP = new AliRsnCutValue(Form("cut%sPt%s",AliPID::ParticleName(type1),opt.Data()),PtMin_P,PtMax_P); cutPtP->SetTargetType(AliRsnTarget::kDaughter); cutPtP->SetValueObj(valPtP); cutsP->AddCut(cutPtP); if (!scheme.IsNull()) scheme += "&"; scheme += cutPtP->GetName(); } if(usePMax_P){ AliRsnValueDaughter *valPP = new AliRsnValueDaughter(Form("val%sP%s",AliPID::ParticleName(type1),opt.Data()),AliRsnValueDaughter::kP); AliRsnCutValue *cutPP = new AliRsnCutValue(Form("cut%sP%s",AliPID::ParticleName(type1),opt.Data()),0.,PMax_P); cutPP->SetTargetType(AliRsnTarget::kDaughter); cutPP->SetValueObj(valPP); cutsP->AddCut(cutPP); if (!scheme.IsNull()) scheme += "&"; scheme += cutPP->GetName(); } Printf ("CUT Scheme for PROTON is '%s'",scheme.Data()); cutsP->SetCutScheme(scheme.Data()); // END PROTON ======================================= // KAON SETTINGS ======================================= scheme=""; cutname = "K_Lambda"; if (!opt.IsNull()) cutname += Form("_%s",opt.Data()); AliRsnCutSet *cutsK = new AliRsnCutSet(cutname.Data(), AliRsnTarget::kDaughter); AliRsnCutTrackQuality *qualityCutK = new AliRsnCutTrackQuality("cutQualityK"); if (useCommonQualityCut>=0) { qualityCutK->SetAODTestFilterBit(useCommonQualityCut); } else { qualityCutK->SetDefaults2010(); } cutsK->AddCut(qualityCutK); if (!scheme.IsNull()) scheme += "&"; scheme += qualityCutK->GetName(); if (useTPC_K) { AliRsnCutPIDNSigma *cutKTPC = new AliRsnCutPIDNSigma("cutNSigmaTPCK",AliPID::kKaon,AliRsnCutPIDNSigma::kTPC); cutKTPC->SinglePIDRange(nSigmaTPC_K); cutsK->AddCut(cutKTPC); if (!scheme.IsNull()) scheme += "&"; scheme += cutKTPC->GetName(); } if (useTOF_K) { AliRsnCutPIDNSigma *cutKTOF = new AliRsnCutPIDNSigma("cutNSigmaTOFK",AliPID::kKaon,AliRsnCutPIDNSigma::kTOF); cutKTOF->SinglePIDRange(nSigmaTOF_K); cutsK->AddCut(cutKTOF); if(rejectUnmatchedTOF_K){ if (!scheme.IsNull()) scheme += "&"; scheme += cutKTOF->GetName(); }else{ AliRsnCutTOFMatch *cutKTOFMatch = new AliRsnCutTOFMatch("cutKTOFMatch"); cutsK->AddCut(cutKTOFMatch); if (!scheme.IsNull()) scheme += "&"; scheme += Form("(%s|(!%s))",cutKTOF->GetName(),cutKTOFMatch->GetName()); } } if (useEta) { AliRsnValueDaughter *valEtaK = new AliRsnValueDaughter(Form("val%sETA%s",AliPID::ParticleName(type2),opt.Data()),AliRsnValueDaughter::kEta); AliRsnCutValue *cutEtaK = new AliRsnCutValue(Form("cut%sETA%s",AliPID::ParticleName(type2),opt.Data()),-etaRange,etaRange); cutEtaK->SetTargetType(AliRsnTarget::kDaughter); cutEtaK->SetValueObj(valEtaK); cutsK->AddCut(cutEtaK); if (!scheme.IsNull()) scheme += "&"; scheme += cutEtaK->GetName(); } if (usePDG) { AliRsnCutPID *cutPDGK = new AliRsnCutPID(Form("cut%sPDG%s",AliPID::ParticleName(type2),opt.Data()),type2,0.0,kTRUE); cutsK->AddCut(cutPDGK); if (!scheme.IsNull()) scheme += "&"; scheme += cutPDGK->GetName(); } if(useKPt){ AliRsnValueDaughter *valPtK = new AliRsnValueDaughter(Form("val%sPt%s",AliPID::ParticleName(type2),opt.Data()),AliRsnValueDaughter::kPt); AliRsnCutValue *cutPtK = new AliRsnCutValue(Form("cut%sPt%s",AliPID::ParticleName(type2),opt.Data()),PtMin_K,PtMax_K); cutPtK->SetTargetType(AliRsnTarget::kDaughter); cutPtK->SetValueObj(valPtK); cutsK->AddCut(cutPtK); if (!scheme.IsNull()) scheme += "&"; scheme += cutPtK->GetName(); } if(usePMax_K){ AliRsnValueDaughter *valPK = new AliRsnValueDaughter(Form("val%sP%s",AliPID::ParticleName(type2),opt.Data()),AliRsnValueDaughter::kP); AliRsnCutValue *cutPK = new AliRsnCutValue(Form("cut%sP%s",AliPID::ParticleName(type2),opt.Data()),0.,PMax_K); cutPK->SetTargetType(AliRsnTarget::kDaughter); cutPK->SetValueObj(valPK); cutsK->AddCut(cutPK); if (!scheme.IsNull()) scheme += "&"; scheme += cutPK->GetName(); } Printf ("CUT Scheme for KAON is '%s'",scheme.Data()); cutsK->SetCutScheme(scheme.Data()); // END KAON ======================================= if (opt.Contains("mon")) { AddMonitorOutput(cutsP->GetMonitorOutput(),opt); AddMonitorOutput(cutsK->GetMonitorOutput(),opt); } if (isRsnMini) { AliRsnMiniAnalysisTask *taskRsnMini = dynamic_cast<AliRsnMiniAnalysisTask *>(task); if (taskRsnMini) { taskRsnMini->AddTrackCuts(cutsP); taskRsnMini->AddTrackCuts(cutsK); } } else { AliRsnDaughterSelector *sel = rsnIH->GetSelector(); // sel->SetLabelCheck(kFALSE); sel->Add(cutsP, kTRUE); sel->Add(cutsK, kTRUE); } return numberOfCuts; }
// // *** Configuration script for K*+-->K0Short-Pi analysis *** // // A configuration script for RSN package needs to define the followings: // // (1) decay tree of each resonance to be studied, which is needed to select // true pairs and to assign the right mass to all candidate daughters // (2) cuts at all levels: single daughters, tracks, events // (3) output objects: histograms or trees // Bool_t ConfigKStarPlusMinus ( AliRsnMiniAnalysisTask *task, Int_t collSyst, Bool_t isMC, Float_t piPIDCut, Float_t pPIDCut, Int_t aodFilterBit, Float_t trackDCAcut, Float_t massTol, Float_t lambdaDCA, Float_t lambdaCosPoinAn, Float_t lambdaDaughDCA, Int_t NTPCcluster, const char *suffix, AliRsnCutSet *cutsPair ) { // manage suffix if (strlen(suffix) > 0) suffix = Form("_%s", suffix); ///////////////////////////////////////////////////// // selections for the pion from the decay of KStarPlusMinus* ///////////////////////////////////////////////////// // AliRsnCutDaughterSigmaStar2010PP *cutPi = new AliRsnCutDaughterSigmaStar2010PP("cutPionForKStarPlusMinus", AliPID::kPion); cutPi->SetPIDCut(piPIDCut); // fPIDCut used in IsSelected() after the call to cutQuality AliRsnCutTrackQuality *cutQuality = (AliRsnCutTrackQuality*) cutPi->CutQuality(); //cutQuality->SetDefaults2011(); cutQuality->SetDefaults2010(0,1); // 1st par. not default (0 -> use TPC clusters). 2nd par. default (-> standard Pt and eta range) // SetDefaults2010 contains the following selections: // SetPtRange(0.15, 1E+20); // SetEtaRange(-0.8, 0.8); // and from aliroot/master/src/ANALYSIS/ANALYSISalice/AliESDtrackCuts.cxx // AliESDtrackCuts::GetStandardITSTPCTrackCuts2010(1,0) // esdTrackCuts->SetMinNClustersTPC(70); // esdTrackCuts->SetMaxChi2PerClusterTPC(4); // esdTrackCuts->SetAcceptKinkDaughters(kFALSE); // esdTrackCuts->SetRequireTPCRefit(kTRUE); // esdTrackCuts->SetRequireITSRefit(kTRUE); // esdTrackCuts->SetClusterRequirementITS(AliESDtrackCuts::kSPD,AliESDtrackCuts::kAny); // esdTrackCuts->SetMaxDCAToVertexXYPtDep("0.0182+0.0350/pt^1.01"); // NB. With pt_min=0.15 (see above) -> DCAxy_max = 0.2560 // esdTrackCuts->SetMaxChi2TPCConstrainedGlobal(36); // esdTrackCuts->SetMaxDCAToVertexZ(2); // esdTrackCuts->SetDCAToVertex2D(kFALSE); // esdTrackCuts->SetRequireSigmaToVertex(kFALSE); // esdTrackCuts->SetMaxChi2PerClusterITS(36); // AliRsnCutSet *cutSetPi = new AliRsnCutSet("setPionForKStarPlusMinus", AliRsnTarget::kDaughter); cutSetPi->AddCut(cutPi); cutSetPi->SetCutScheme(cutPi->GetName()); Int_t iCutPi = task->AddTrackCuts(cutSetPi); // ///////////////////////////////////////////////////////////// // selections for Lambda and for the daughters of Lambda ///////////////////////////////////////////////////////////// // // selections for the proton and pion daugthers of Lambda and AntiLambda AliESDtrackCuts *esdTrackCuts = new AliESDtrackCuts("qualityDaughterLambda"); esdTrackCuts->SetPtRange(0.15,1.E10); esdTrackCuts->SetEtaRange(-0.8,0.8); esdTrackCuts->SetRequireTPCRefit(); esdTrackCuts->SetAcceptKinkDaughters(0); // esdTrackCuts->SetMinNClustersTPC(NTPCcluster); esdTrackCuts->SetMaxChi2PerClusterTPC(4); esdTrackCuts->SetMinDCAToVertexXY(0.15); // ///////////////////////////////////////////////// // selections for Lambda AliRsnCutV0 *cutLambda = new AliRsnCutV0("cutLambda", kK0Short, AliPID::kPion, AliPID::kPion); cutLambda->SetPIDCutProton(pPIDCut); // PID for the proton daughter of Lambda cutLambda->SetPIDCutPion(piPIDCut); // PID for the pion daughter of Lambda cutLambda->SetESDtrackCuts(esdTrackCuts); // all the other selections (defined above) for proton and pion daughters of Lambda cutLambda->SetMaxDaughtersDCA(lambdaDaughDCA); cutLambda->SetMaxDCAVertex(lambdaDCA); cutLambda->SetMinCosPointingAngle(lambdaCosPoinAn); cutLambda->SetTolerance(massTol); cutLambda->SetMaxRapidity(0.5); // AliRsnCutSet *cutSetLambda = new AliRsnCutSet("setLambda", AliRsnTarget::kDaughter); cutSetLambda->AddCut(cutLambda); cutSetLambda->SetCutScheme(cutLambda->GetName()); Int_t iCutLambda = task->AddTrackCuts(cutSetLambda); // //###################################################################################################### // // -- Values ------------------------------------------------------------------------------------ // /* invariant mass */ Int_t imID = task->CreateValue(AliRsnMiniValue::kInvMass, kFALSE); /* transv. momentum */ Int_t ptID = task->CreateValue(AliRsnMiniValue::kPt, kFALSE); /* centrality */ Int_t centID = task->CreateValue(AliRsnMiniValue::kMult, kFALSE); // // -- Create all needed outputs ----------------------------------------------------------------- // // use an array for more compact writing, which are different on mixing and charges // [0] = unlike // [1] = mixing // [2] = like ++ // [3] = like -- Bool_t use [6] = {1 ,1 ,1 ,1 ,1 ,1 }; Bool_t useIM [6] = {1 ,1 ,1 ,1 ,1 ,1 }; TString name [6] = {"KStarPlusMinus","AKStarPlusMinus","KStarPlusMinusmix","AKStarPlusMinusmix","KStarPlusMinust","AKStarPlusMinust"}; TString comp [6] = {"PAIR" ,"PAIR" ,"MIX" ,"MIX" ,"TRUE" ,"TRUE" }; TString output [6] = {"HIST" ,"HIST" ,"HIST" ,"HIST" ,"HIST" ,"HIST" }; Char_t charge1 [6] = {'0' ,'0' ,'0' ,'0' ,'0' ,'0' }; Char_t charge2 [6] = {'+' ,'-' ,'+' ,'-' ,'+' ,'-' }; Int_t cutID1 [6] = { iCutLambda ,iCutLambda ,iCutLambda ,iCutLambda ,iCutLambda ,iCutLambda }; Int_t cutID2 [6] = { iCutPi ,iCutPi ,iCutPi ,iCutPi ,iCutPi ,iCutPi }; Int_t ipdg [6] = {323 ,-323 ,323 ,-323 ,323 ,-323 }; Double_t mass [6] = { 0.89166 ,0.89166 ,0.89166 ,0.89166 ,0.89166 ,0.89166 }; for (Int_t i = 0; i < 6; i++) { if (!use[i]) continue; if (collSyst) output[i] = "SPARSE"; // create output AliRsnMiniOutput *out = task->CreateOutput(Form("sigmastar_%s%s", name[i].Data(), suffix), output[i].Data(), comp[i].Data()); // selection settings out->SetCutID(0, cutID1[i]); out->SetCutID(1, cutID2[i]); out->SetDaughter(0, AliRsnDaughter::kKaon0); out->SetDaughter(1, AliRsnDaughter::kPion); out->SetCharge(0, charge1[i]); out->SetCharge(1, charge2[i]); out->SetMotherPDG(ipdg[i]); out->SetMotherMass(mass[i]); // pair cuts out->SetPairCuts(cutsPair); // axis X: invmass if (useIM[i]) out->AddAxis(imID, 2000, 0, 2.0); // out->AddAxis(imID, 700, 1.2, 4.0); // axis Y: transverse momentum out->AddAxis(ptID, 100, 0.0, 10.0); //out->AddAxis(lambdaDCA, 10, 0.0, 1.0); if (collSyst) out->AddAxis(centID, 10, 0.0, 100.0); } AddMonitorOutput_PionPt(cutSetPi->GetMonitorOutput()); AddMonitorOutput_PionEta(cutSetPi->GetMonitorOutput()); AddMonitorOutput_PionDCAxy(cutSetPi->GetMonitorOutput()); AddMonitorOutput_PionDCAz(cutSetPi->GetMonitorOutput()); AddMonitorOutput_PionPIDCut(cutSetPi->GetMonitorOutput()); AddMonitorOutput_PionNTPC(cutSetPi->GetMonitorOutput()); AddMonitorOutput_PionTPCchi2(cutSetPi->GetMonitorOutput()); // AddMonitorOutput_LambdaP(cutSetLambda->GetMonitorOutput()); AddMonitorOutput_LambdaPt(cutSetLambda->GetMonitorOutput()); AddMonitorOutput_LambdaNegDaughPt(cutSetLambda->GetMonitorOutput()); AddMonitorOutput_LambdaPosDaughPt(cutSetLambda->GetMonitorOutput()); AddMonitorOutput_LambdaMass(cutSetLambda->GetMonitorOutput()); AddMonitorOutput_LambdaDCA(cutSetLambda->GetMonitorOutput()); AddMonitorOutput_LambdaRadius(cutSetLambda->GetMonitorOutput()); AddMonitorOutput_LambdaDaughterDCA(cutSetLambda->GetMonitorOutput()); AddMonitorOutput_LambdaCosPointAngle(cutSetLambda->GetMonitorOutput()); // AddMonitorOutput_LambdaProtonPID(cutSetLambda->GetMonitorOutput()); AddMonitorOutput_LambdaPionPID(cutSetLambda->GetMonitorOutput()); if (isMC) { TString mode = "HIST"; if (collSyst) mode = "SPARSE"; // create output AliRsnMiniOutput *out = task->CreateOutput(Form("KStarPlusMinus_TrueMC%s", suffix), mode.Data(), "MOTHER"); // selection settings out->SetDaughter(0, AliRsnDaughter::kKaon0); out->SetDaughter(1, AliRsnDaughter::kPion); out->SetMotherPDG(323); out->SetMotherMass(0.89166); // pair cuts out->SetPairCuts(cutsPair); // binnings out->AddAxis(imID, 2000, 0.0, 2.0); out->AddAxis(ptID, 100, 0.0, 10.0); //out->AddAxis(lambdaDCA, 10, 0.0, 1.0); if (collSyst) out->AddAxis(centID, 10, 0.0, 100.0); // create output AliRsnMiniOutput *out = task->CreateOutput(Form("AKStarPlusMinus_TrueMC%s", suffix), mode.Data(), "MOTHER"); // selection settings out->SetDaughter(0, AliRsnDaughter::kKaon0); out->SetDaughter(1, AliRsnDaughter::kPion); out->SetMotherPDG(-323); out->SetMotherMass(0.89166); // pair cuts out->SetPairCuts(cutsPair); // binnings out->AddAxis(imID, 2000, 0.0, 2.0); out->AddAxis(ptID, 100, 0.0, 10.0); //out->AddAxis(lambdaDCA, 10, 0.0, 1.0); if (collSyst) out->AddAxis(centID, 10, 0.0, 100.0); } return kTRUE; }
Int_t AddRsnDaughterCutsPhiNsigma(AliPID::EParticleType type1,AliPID::EParticleType type2,TString opt,AliRsnInputHandler *rsnIH=0,AliAnalysisTaskSE *task=0) { if (!rsnIH) return 0; Bool_t valid = kTRUE; // Int_t collisionType = AliRsnTrainManager::GetGlobalInt("IsCollisionType",valid); Int_t useCommonQualityCut = AliRsnTrainManager::GetGlobalInt("RsnCommonQualityCut",valid); TString rsnQualityCut = AliRsnTrainManager::GetGlobalStr("RsnQualityCut",valid); Int_t isMC = AliRsnTrainManager::GetGlobalInt("IsMC",valid); Int_t isRsnMini = AliRsnTrainManager::GetGlobalInt("IsRsnMini",valid); Int_t isMixing = AliRsnTrainManager::GetGlobalInt("IsMixing",valid); // experts only (don't touch) Int_t isRsnDev = AliAnalysisManager::GetGlobalInt("rsnUseRSNParDev",valid); // === USER HAS TO SET CORRECT NUMBER OF CUTS SETS ===== Int_t numberOfCuts = 1; //--------------------------------------------- // Define single cuts //--------------------------------------------- Printf("AliRsnCutPIDNSigma Option : %s",opt.Data()); Double_t nSigmaTPC=3.0; Double_t nSigmaTOF=3.0; Double_t etaMin=-0.8; Double_t etaMax=0.8; Double_t trackPtMin=0.; Double_t trackPtMax=1.e10; Int_t NclTPC=70; Char_t DCAxyFormula[100]="0.0182+0.035/pt^1.01"; Bool_t useTPC_K=kFALSE; Bool_t useTOF_K=kFALSE; Bool_t rejectUnmatchedTOF_K=kTRUE; Bool_t useTrackPtCut=kFALSE; if (opt.Contains("qualityonly")) { useTPC_K=kFALSE; useTOF_K=kFALSE; } if (opt.Contains("KTPCnsig")) useTPC_K=kTRUE; if (opt.Contains("KTOFnsig")) useTOF_K=kTRUE; if (opt.Contains("KTOFacceptUnmatched")) rejectUnmatchedTOF_K=kFALSE; if (opt.Contains("KTPCnsig05")) nSigmaTPC = 0.5; if (opt.Contains("KTPCnsig08")) nSigmaTPC = 0.8; if (opt.Contains("KTPCnsig10")) nSigmaTPC = 1.0; if (opt.Contains("KTPCnsig15")) nSigmaTPC = 1.5; if (opt.Contains("KTPCnsig20")) nSigmaTPC = 2.0; if (opt.Contains("KTPCnsig25")) nSigmaTPC = 2.5; if (opt.Contains("KTPCnsig30")) nSigmaTPC = 3.0; if (opt.Contains("KTPCnsig40")) nSigmaTPC = 4.0; if (opt.Contains("KTPCnsig50")) nSigmaTPC = 5.0; if (opt.Contains("KTPCnsig1000")) nSigmaTPC = 100.0; if (opt.Contains("KTOFnsig10")) nSigmaTOF = 1.0; if (opt.Contains("KTOFnsig15")) nSigmaTOF = 1.5; if (opt.Contains("KTOFnsig20")) nSigmaTOF = 2.0; if (opt.Contains("KTOFnsig25")) nSigmaTOF = 2.5; if (opt.Contains("KTOFnsig30")) nSigmaTOF = 3.0; if (opt.Contains("KTOFnsig40")) nSigmaTOF = 4.0; if (opt.Contains("KTOFnsig50")) nSigmaTOF = 5.0; if (opt.Contains("KTOFnsig1000")) nSigmaTOF = 100.0; if (opt.Contains("trackPt")) { useTrackPtCut = kTRUE; if (opt.Contains("trackPtMin015")) trackPtMin = 0.15; if (opt.Contains("trackPtMin02")) trackPtMin = 0.2; if (opt.Contains("trackPtMin05")) trackPtMin = 0.5; if (opt.Contains("trackPtMin06")) trackPtMin = 0.6; if (opt.Contains("trackPtMax18")) trackPtMax = 1.8; if (opt.Contains("trackPtMax20")) trackPtMax = 2.0; if (opt.Contains("trackPtMax25")) trackPtMax = 2.5; } Bool_t usePDG=kFALSE; if (opt.Contains("pdg")) { Printf("Using PDG"); usePDG = kTRUE; } Bool_t useEta = kFALSE; if (opt.Contains("eta")) { for(int j=1;j<=9;j++) if(opt.Contains(Form("eta0%i",j))){etaMin=-0.1*j; etaMax=0.1*j;} for(int j=1;j<=9;j++) if(opt.Contains(Form("etaMinMinus0%i",j))) etaMin=-0.1*j; if(opt.Contains("etaMin00")) etaMin=0.; for(int j=1;j<=9;j++) if(opt.Contains(Form("etaMinPlus0%i",j))) etaMin=0.1*j; for(int j=1;j<=9;j++) if(opt.Contains(Form("etaMaxMinus0%i",j))) etaMax=-0.1*j; if(opt.Contains("etaMax00")) etaMax=0.; for(int j=1;j<=9;j++) if(opt.Contains(Form("etaMaxPlus0%i",j))) etaMax=0.1*j; Printf("Using ETA range (%.2f,%.2f)",etaMin,etaMax); useEta = kTRUE; } Bool_t useNclTPC = kFALSE; if (opt.Contains("NclTPC")) { if (opt.Contains("NclTPC70")) NclTPC=70; if (opt.Contains("NclTPC75")) NclTPC=75; if (opt.Contains("NclTPC80")) NclTPC=80; if (opt.Contains("NclTPC85")) NclTPC=85; if (opt.Contains("NclTPC90")) NclTPC=90; useNclTPC = kTRUE; } Bool_t useDCAxy = kFALSE; if (opt.Contains("DCAxy")) { if (opt.Contains("DCAxyFormula7s")) sprintf(DCAxyFormula,"0.0182+0.035/pt^1.01"); if (opt.Contains("DCAxyFormula6s")) sprintf(DCAxyFormula,"0.0156+0.03/pt^1.01"); if (opt.Contains("DCAxyFormula5s")) sprintf(DCAxyFormula,"0.013+0.025/pt^1.01"); useDCAxy = kTRUE; } //--------------------------------------------- // Combine cuts //--------------------------------------------- TString cutname = "K_Phi"; if (!opt.IsNull()) cutname += Form("_%s",opt.Data()); AliRsnCutSet *cuts = new AliRsnCutSet(cutname.Data(), AliRsnTarget::kDaughter); TString scheme=""; AliRsnCutTrackQuality *qualityCut = new AliRsnCutTrackQuality("cutQualityK"); if (!rsnQualityCut.IsNull()) { AliESDtrackCuts *esdTK = RsnQualityCut(rsnQualityCut.Data()); if(useDCAxy) esdTK->SetMaxDCAToVertexXYPtDep(DCAxyFormula); qualityCut->SetESDtrackCuts(esdTK); } else { if (useCommonQualityCut>=0) { qualityCut->SetAODTestFilterBit(useCommonQualityCut); if(useDCAxy) {qualityCut->SetCheckOnlyFilterBit(kFALSE); qualityCut->SetDCARPtFormula(DCAxyFormula);} } else { qualityCut->SetDefaults2010(); if(useDCAxy) qualityCut->SetDCARPtFormula(DCAxyFormula); } } cuts->AddCut(qualityCut); if (!scheme.IsNull()) scheme += "&"; scheme += qualityCut->GetName(); if (useTPC_K) { AliRsnCutPIDNSigma *cutKTPC = new AliRsnCutPIDNSigma("cutPIDNSigmaTPCK",AliPID::kKaon,AliRsnCutPIDNSigma::kTPC); cutKTPC->SinglePIDRange(nSigmaTPC); cuts->AddCut(cutKTPC); if (!scheme.IsNull()) scheme += "&"; scheme += cutKTPC->GetName(); } if (useTOF_K) { AliRsnCutPIDNSigma *cutKTOF = new AliRsnCutPIDNSigma("cutPIDNSigmaTOFK",AliPID::kKaon,AliRsnCutPIDNSigma::kTOF); cutKTOF->SinglePIDRange(nSigmaTOF); cuts->AddCut(cutKTOF); if(rejectUnmatchedTOF_K){ if (!scheme.IsNull()) scheme += "&"; scheme += cutKTOF->GetName(); }else{ AliRsnCutTOFMatch *cutKTOFMatch = new AliRsnCutTOFMatch("cutKTOFMatch"); cuts->AddCut(cutKTOFMatch); if (!scheme.IsNull()) scheme += "&"; scheme += Form("(%s|(!%s))",cutKTOF->GetName(),cutKTOFMatch->GetName()); } } if (useEta) { Printf("Adding ETA ..."); AliRsnValueDaughter *valEta = new AliRsnValueDaughter(Form("val%sETA%s",AliPID::ParticleName(type1),opt.Data()),AliRsnValueDaughter::kEta); AliRsnCutValue *cutEta = new AliRsnCutValue(Form("cut%sETA%s",AliPID::ParticleName(type1),opt.Data()),etaMin,etaMax); cutEta->SetTargetType(AliRsnTarget::kDaughter); cutEta->SetValueObj(valEta); cuts->AddCut(cutEta); if (!scheme.IsNull()) scheme += "&"; scheme += cutEta->GetName(); } if (useTrackPtCut) { Printf("Adding Pt min=%.3f max=%.3f ...",trackPtMin,trackPtMax); AliRsnValueDaughter *valTrackPt = new AliRsnValueDaughter(Form("val%sTrackPt%s",AliPID::ParticleName(type1),opt.Data()),AliRsnValueDaughter::kPt); AliRsnCutValue *cutTrackPt = new AliRsnCutValue(Form("cut%sTrackPt%s",AliPID::ParticleName(type1),opt.Data()),trackPtMin,trackPtMax); cutTrackPt->SetTargetType(AliRsnTarget::kDaughter); cutTrackPt->SetValueObj(valTrackPt); cuts->AddCut(cutTrackPt); if (!scheme.IsNull()) scheme += "&"; scheme += cutTrackPt->GetName(); } if (useNclTPC) { Printf("Adding NclTPC >= %i",NclTPC); AliRsnValueDaughter *valNclTPC = new AliRsnValueDaughter(Form("val%sNclTPC%s",AliPID::ParticleName(type1),opt.Data()),AliRsnValueDaughter::kNTPCclusters); AliRsnCutValue *cutNclTPC = new AliRsnCutValue(Form("cut%sNclTPC%s",AliPID::ParticleName(type1),opt.Data()),NclTPC-0.1,1000.); cutNclTPC->SetTargetType(AliRsnTarget::kDaughter); cutNclTPC->SetValueObj(valNclTPC); cuts->AddCut(cutNclTPC); if (!scheme.IsNull()) scheme += "&"; scheme += cutNclTPC->GetName(); } if (usePDG) { Printf("Adding PDG ..."); AliRsnCutPID *cutPDG = new AliRsnCutPID(Form("cut%sPDG%s",AliPID::ParticleName(type1),opt.Data()),type1,0.0,kTRUE); cuts->AddCut(cutPDG); if (!scheme.IsNull()) scheme += "&"; scheme += cutPDG->GetName(); } Printf ("CUT Scheme is '%s'",scheme.Data()); cuts->SetCutScheme(scheme.Data()); if (opt.Contains("mon")) { AddMonitorOutput(cuts->GetMonitorOutput(),opt); } if (isRsnMini) { AliRsnMiniAnalysisTask *taskRsnMini = (AliRsnMiniAnalysisTask *)task; if (taskRsnMini) { taskRsnMini->AddTrackCuts(cuts); } } else { AliRsnDaughterSelector *sel = rsnIH->GetSelector(); // sel->SetLabelCheck(kFALSE); sel->Add(cuts, kTRUE); if (isRsnDev>=0 && opt.Contains("pairPID")) { AliRsnActPostDaughterSelection *pairPID = new AliRsnActPostDaughterSelection(); pairPID->SetID(0); const char *fn="rsnRange.txt"; if (!gSystem->AccessPathName(fn)) { TString minStr = gSystem->GetFromPipe(TString::Format("head -n 1 %s").Data()); TString maxStr = gSystem->GetFromPipe(TString::Format("tail -n 1 %s").Data()); pairPID->SetMass(minStr.Atof(),maxStr.Atof()); } else { // pairPID->SetMass(1.01,1.03); pairPID->SetMass(1.015,1.025); pairPID->SetMass(1.019,1.021); pairPID->SetMass(1.0195,1.0205); pairPID->SetMass(1.1000,1.1005); // pairPID->SetMass(1.1005,1.1010); } sel->AddAction(pairPID); } } return numberOfCuts; }
Bool_t ConfigTPCanalysisKStarTest ( AliRsnMiniAnalysisTask *task, Bool_t isMC, Bool_t isPP, const char *suffix, AliRsnCutSet *cutsPair, Float_t nsigmaPi = 2.0, Float_t nsigmaKa = 2.0, Bool_t enableMonitor = kTRUE, Bool_t IsMcTrueOnly = kFALSE, Int_t Pdg = 313, TString optSys = "Default" ) { // manage suffix if (strlen(suffix) > 0) suffix = Form("_%s", suffix); TString opt = "PbPb"; TString schemePi=""; TString schemeK=""; TString cutnameK = "K_KS"; TString cutnamePi = "Pi_KS"; if (!opt.IsNull()) cutnameK += Form("_%s",opt.Data()); if (!opt.IsNull()) cutnamePi += Form("_%s",opt.Data()); AliRsnCutSet * cutSetKaon = new AliRsnCutSet(cutnameK.Data(), AliRsnTarget::kDaughter); AliRsnCutSet * cutSetPion = new AliRsnCutSet(cutnamePi.Data(), AliRsnTarget::kDaughter); AliRsnCutTrackQuality *fQualityTrackCut = new AliRsnCutTrackQuality("AliRsnCutTrackQuality"); //Analysis Track cuts are implemented here AliESDtrackCuts * esdTrackCuts = MyTrackCuts(1, kTRUE,optSys.Data()); fQualityTrackCut->SetESDtrackCuts(esdTrackCuts); fQualityTrackCut->SetPtRange(0.15,30); fQualityTrackCut->SetEtaRange(-0.8,0.8); //PID selection cutSetKaon->AddCut(fQualityTrackCut); if (!schemeK.IsNull()) schemeK += "&"; schemeK += fQualityTrackCut->GetName(); cutSetPion->AddCut(fQualityTrackCut); if (!schemePi.IsNull()) schemePi += "&"; schemePi += fQualityTrackCut->GetName(); AliRsnCutPIDNSigma *cutPiTPC = new AliRsnCutPIDNSigma("cutNSigmaTPCPi",AliPID::kPion,AliRsnCutPIDNSigma::kTPC); cutPiTPC->SinglePIDRange(nsigmaPi); cutSetPion->AddCut(cutPiTPC); if (!schemePi.IsNull()) schemePi += "&"; schemePi += cutPiTPC->GetName(); AliRsnCutPIDNSigma *cutKTPC = new AliRsnCutPIDNSigma("cutNSigmaTPCK",AliPID::kKaon,AliRsnCutPIDNSigma::kTPC); cutKTPC->SinglePIDRange(nsigmaKa); cutSetKaon->AddCut(cutKTPC); if (!schemeK.IsNull()) schemeK += "&"; schemeK += cutKTPC->GetName(); Printf ("CUT Scheme for KAON is '%s'",schemeK.Data()); Printf ("CUT Scheme for PION is '%s'",schemePi.Data()); cutSetPion->SetCutScheme(schemePi.Data()); cutSetKaon->SetCutScheme(schemeK.Data()); Int_t iCutPi = task->AddTrackCuts(cutSetPion); Int_t iCutK = task->AddTrackCuts(cutSetKaon); if(enableMonitor){ Printf("======== Monitoring cut AliRsnCutSetDaughterParticle enabled"); //gROOT->LoadMacro("$ALICE_ROOT/PWGLF/RESONANCES/macros/mini/AddMonitorOutput.C"); gROOT->LoadMacro("$ALICE_PHYSICS/PWGLF/RESONANCES/macros/mini/AddMonitorOutput.C"); AddMonitorOutput(isMC, cutSetPion->GetMonitorOutput()); AddMonitorOutput(isMC, cutSetKaon->GetMonitorOutput()); } // -- Values ------------------------------------------------------------------------------------ /* invariant mass */ Int_t imID = task->CreateValue(AliRsnMiniValue::kInvMass, kFALSE); /* IM resolution */ Int_t resID = task->CreateValue(AliRsnMiniValue::kInvMassRes, kTRUE); /* transv. momentum */ Int_t ptID = task->CreateValue(AliRsnMiniValue::kPt, kFALSE); /* centrality */ Int_t centID = task->CreateValue(AliRsnMiniValue::kMult, kFALSE); /* pseudorapidity */ Int_t etaID = task->CreateValue(AliRsnMiniValue::kEta, kFALSE); /* rapidity */ Int_t yID = task->CreateValue(AliRsnMiniValue::kY, kFALSE); // -- Create all needed outputs ----------------------------------------------------------------- // use an array for more compact writing, which are different on mixing and charges // [0] = unlike // [1] = mixing // [2] = like ++ // [3] = like -- Bool_t use [10] = { !IsMcTrueOnly, !IsMcTrueOnly, !IsMcTrueOnly, !IsMcTrueOnly , !IsMcTrueOnly, !IsMcTrueOnly, isMC , isMC , isMC , isMC }; Bool_t useIM [10] = { 1 , 1 , 1 , 1 , 1 , 1 , 1 , 1 , 0 , 0 }; TString name [10] = {"UnlikePM", "UnlikeMP", "MixingPM", "MixingMP", "LikePP", "LikeMM", "TruesPM", "TruesMP", "ResPM" , "ResMP" }; TString comp [10] = {"PAIR" , "PAIR" , "MIX" , "MIX" , "PAIR" , "PAIR" , "TRUE" , "TRUE" , "TRUE" , "TRUE" }; //TString output [10] = {"HIST" , "HIST" , "HIST" , "HIST" , "HIST" , "HIST" , "HIST" , "HIST" , "HIST" , "HIST" }; TString output [10] = {"SPARSE" , "SPARSE" , "SPARSE" , "SPARSE" , "SPARSE" , "SPARSE" , "SPARSE" , "SPARSE" , "SPARSE" , "SPARSE" }; Char_t charge1 [10] = {'+' , '-' , '+' , '-' , '+' , '-' , '+' , '-' , '+' , '-' }; Char_t charge2 [10] = {'-' , '+' , '-' , '+' , '+' , '-' , '-' , '+' , '-' , '+' }; Int_t cutID1 [10] = { iCutK , iCutK , iCutK , iCutK , iCutK , iCutK , iCutK , iCutK , iCutK , iCutK }; Int_t cutID2 [10] = { iCutPi , iCutPi , iCutPi , iCutPi , iCutPi , iCutPi , iCutPi , iCutPi , iCutPi , iCutPi }; for (Int_t i = 0; i < 10; i++) { if (!use[i]) continue; if(Pdg > 0) AliRsnMiniOutput *out = task->CreateOutput(Form("kstar1_%s%s", name[i].Data(), suffix), output[i].Data(), comp[i].Data()); if(Pdg < 0) AliRsnMiniOutput *out = task->CreateOutput(Form("kstar2_%s%s", name[i].Data(), suffix), output[i].Data(), comp[i].Data()); out->SetCutID(0, cutID1[i]); out->SetCutID(1, cutID2[i]); out->SetDaughter(0, AliRsnDaughter::kKaon); out->SetDaughter(1, AliRsnDaughter::kPion); out->SetCharge(0, charge1[i]); out->SetCharge(1, charge2[i]); out->SetMotherPDG(Pdg);//313 out->SetMotherMass(0.89594); out->SetPairCuts(cutsPair); // axis X: invmass (or resolution) if (useIM[i]) out->AddAxis(imID, 90, 0.6, 1.5); //else //out->AddAxis(resID, 200, -0.02, 0.02); // axis Y: transverse momentum out->AddAxis(ptID, 300, 0.0, 30.0); // axis Z: centrality-multiplicity if (!isPP) out->AddAxis(centID, 100, 0.0, 100.0); else out->AddAxis(centID, 400, 0.0, 400.0); // axis W: pseudorapidity // out->AddAxis(etaID, 20, -1.0, 1.0); // axis J: rapidity //out->AddAxis(yID, 32, -0.8, 0.8); } if (isMC){ // create output if(Pdg > 0) {AliRsnMiniOutput *outm = task->CreateOutput(Form("kstar_Mother1%s", suffix), "SPARSE", "MOTHER");} if(Pdg < 0) {AliRsnMiniOutput *outm = task->CreateOutput(Form("kstar_Mother2%s", suffix), "SPARSE", "MOTHER");} outm->SetDaughter(0, AliRsnDaughter::kKaon); outm->SetDaughter(1, AliRsnDaughter::kPion); outm->SetMotherPDG(Pdg);//313 outm->SetMotherMass(0.89594); // pair cuts outm->SetPairCuts(cutsPair); // binnings outm->AddAxis(imID, 90, 0.6, 1.5); outm->AddAxis(ptID, 300, 0.0, 30.0); if (!isPP){ outm->AddAxis(centID, 100, 0.0, 100.0); } else { outm->AddAxis(centID, 400, 0.0, 400.0); } //outm->AddAxis(yID, 32, -0.8, 0.8); } return kTRUE; }