// internal routine to run the inverter HypoTestInverterResult * RunInverter(RooWorkspace * w, const char * modelSBName, const char * modelBName, const char * dataName, int type, int testStatType, int npoints, double poimin, double poimax, int ntoys, bool useCls ) { std::cout << "Running HypoTestInverter on the workspace " << w->GetName() << std::endl; w->Print(); RooAbsData * data = w->data(dataName); if (!data) { Error("RA2bHypoTestDemo","Not existing data %s",dataName); return 0; } else std::cout << "Using data set " << dataName << std::endl; // get models from WS // get the modelConfig out of the file ModelConfig* bModel = (ModelConfig*) w->obj(modelBName); ModelConfig* sbModel = (ModelConfig*) w->obj(modelSBName); if (!sbModel) { Error("RA2bHypoTestDemo","Not existing ModelConfig %s",modelSBName); return 0; } // check the model if (!sbModel->GetPdf()) { Error("RA2bHypoTestDemo","Model %s has no pdf ",modelSBName); return 0; } if (!sbModel->GetParametersOfInterest()) { Error("RA2bHypoTestDemo","Model %s has no poi ",modelSBName); return 0; } if (!sbModel->GetParametersOfInterest()) { Error("RA2bHypoTestInvDemo","Model %s has no poi ",modelSBName); return 0; } if (!sbModel->GetSnapshot() ) { Info("RA2bHypoTestInvDemo","Model %s has no snapshot - make one using model poi",modelSBName); sbModel->SetSnapshot( *sbModel->GetParametersOfInterest() ); } if (!bModel || bModel == sbModel) { Info("RA2bHypoTestInvDemo","The background model %s does not exist",modelBName); Info("RA2bHypoTestInvDemo","Copy it from ModelConfig %s and set POI to zero",modelSBName); bModel = (ModelConfig*) sbModel->Clone(); bModel->SetName(TString(modelSBName)+TString("_with_poi_0")); RooRealVar * var = dynamic_cast<RooRealVar*>(bModel->GetParametersOfInterest()->first()); if (!var) return 0; double oldval = var->getVal(); var->setVal(0); bModel->SetSnapshot( RooArgSet(*var) ); var->setVal(oldval); } else { if (!bModel->GetSnapshot() ) { Info("RA2bHypoTestInvDemo","Model %s has no snapshot - make one using model poi and 0 values ",modelBName); RooRealVar * var = dynamic_cast<RooRealVar*>(bModel->GetParametersOfInterest()->first()); if (var) { double oldval = var->getVal(); var->setVal(0); bModel->SetSnapshot( RooArgSet(*var) ); var->setVal(oldval); } else { Error("RA2bHypoTestInvDemo","Model %s has no valid poi",modelBName); return 0; } } } SimpleLikelihoodRatioTestStat slrts(*sbModel->GetPdf(),*bModel->GetPdf()); if (sbModel->GetSnapshot()) slrts.SetNullParameters(*sbModel->GetSnapshot()); if (bModel->GetSnapshot()) slrts.SetAltParameters(*bModel->GetSnapshot()); // ratio of profile likelihood - need to pass snapshot for the alt RatioOfProfiledLikelihoodsTestStat ropl(*sbModel->GetPdf(), *bModel->GetPdf(), bModel->GetSnapshot()); ropl.SetSubtractMLE(false); //MyProfileLikelihoodTestStat profll(*sbModel->GetPdf()); ProfileLikelihoodTestStat profll(*sbModel->GetPdf()); if (testStatType == 3) profll.SetOneSided(1); if (optimize) profll.SetReuseNLL(true); TestStatistic * testStat = &slrts; if (testStatType == 1) testStat = &ropl; if (testStatType == 2 || testStatType == 3) testStat = &profll; HypoTestCalculatorGeneric * hc = 0; if (type == 0) hc = new FrequentistCalculator(*data, *bModel, *sbModel); else hc = new HybridCalculator(*data, *bModel, *sbModel); ToyMCSampler *toymcs = (ToyMCSampler*)hc->GetTestStatSampler(); //=== DEBUG ///// toymcs->SetWS( w ) ; //=== DEBUG toymcs->SetNEventsPerToy(1); toymcs->SetTestStatistic(testStat); if (optimize) toymcs->SetUseMultiGen(true); if (type == 1) { HybridCalculator *hhc = (HybridCalculator*) hc; hhc->SetToys(ntoys,ntoys); // check for nuisance prior pdf if (bModel->GetPriorPdf() && sbModel->GetPriorPdf() ) { hhc->ForcePriorNuisanceAlt(*bModel->GetPriorPdf()); hhc->ForcePriorNuisanceNull(*sbModel->GetPriorPdf()); } else { if (bModel->GetNuisanceParameters() || sbModel->GetNuisanceParameters() ) { Error("RA2bHypoTestInvDemo","Cannnot run Hybrid calculator because no prior on the nuisance parameter is specified"); return 0; } } } else ((FrequentistCalculator*) hc)->SetToys(ntoys,ntoys); // Get the result RooMsgService::instance().getStream(1).removeTopic(RooFit::NumIntegration); TStopwatch tw; tw.Start(); const RooArgSet * poiSet = sbModel->GetParametersOfInterest(); RooRealVar *poi = (RooRealVar*)poiSet->first(); // fit the data first sbModel->GetPdf()->fitTo(*data); double poihat = poi->getVal(); HypoTestInverter calc(*hc); calc.SetConfidenceLevel(0.95); calc.UseCLs(useCls); calc.SetVerbose(true); // can speed up using proof-lite if (useProof && nworkers > 1) { ProofConfig pc(*w, nworkers, "", kFALSE); toymcs->SetProofConfig(&pc); // enable proof } printf(" npoints = %d, poimin = %7.2f, poimax = %7.2f\n\n", npoints, poimin, poimax ) ; cout << flush ; if ( npoints==1 ) { std::cout << "Evaluating one point : " << poimax << std::endl; calc.RunOnePoint(poimax); } else if (npoints > 0) { if (poimin >= poimax) { // if no min/max given scan between MLE and +4 sigma poimin = int(poihat); poimax = int(poihat + 4 * poi->getError()); } std::cout << "Doing a fixed scan in interval : " << poimin << " , " << poimax << std::endl; calc.SetFixedScan(npoints,poimin,poimax); } else { //poi->setMax(10*int( (poihat+ 10 *poi->getError() )/10 ) ); std::cout << "Doing an automatic scan in interval : " << poi->getMin() << " , " << poi->getMax() << std::endl; } cout << "\n\n right before calc.GetInterval(), ntoys = " << ntoys << " \n\n" << flush ; HypoTestInverterResult * r = calc.GetInterval(); return r; }
// internal routine to run the inverter HypoTestInverterResult * RooStats::HypoTestInvTool::RunInverter(RooWorkspace * w, const char * modelSBName, const char * modelBName, const char * dataName, int type, int testStatType, bool useCLs, int npoints, double poimin, double poimax, int ntoys, bool useNumberCounting, const char * nuisPriorName ){ std::cout << "Running HypoTestInverter on the workspace " << w->GetName() << std::endl; w->Print(); RooAbsData * data = w->data(dataName); if (!data) { Error("StandardHypoTestDemo","Not existing data %s",dataName); return 0; } else std::cout << "Using data set " << dataName << std::endl; if (mUseVectorStore) { RooAbsData::setDefaultStorageType(RooAbsData::Vector); data->convertToVectorStore() ; } // get models from WS // get the modelConfig out of the file ModelConfig* bModel = (ModelConfig*) w->obj(modelBName); ModelConfig* sbModel = (ModelConfig*) w->obj(modelSBName); if (!sbModel) { Error("StandardHypoTestDemo","Not existing ModelConfig %s",modelSBName); return 0; } // check the model if (!sbModel->GetPdf()) { Error("StandardHypoTestDemo","Model %s has no pdf ",modelSBName); return 0; } if (!sbModel->GetParametersOfInterest()) { Error("StandardHypoTestDemo","Model %s has no poi ",modelSBName); return 0; } if (!sbModel->GetObservables()) { Error("StandardHypoTestInvDemo","Model %s has no observables ",modelSBName); return 0; } if (!sbModel->GetSnapshot() ) { Info("StandardHypoTestInvDemo","Model %s has no snapshot - make one using model poi",modelSBName); sbModel->SetSnapshot( *sbModel->GetParametersOfInterest() ); } // case of no systematics // remove nuisance parameters from model if (noSystematics) { const RooArgSet * nuisPar = sbModel->GetNuisanceParameters(); if (nuisPar && nuisPar->getSize() > 0) { std::cout << "StandardHypoTestInvDemo" << " - Switch off all systematics by setting them constant to their initial values" << std::endl; RooStats::SetAllConstant(*nuisPar); } if (bModel) { const RooArgSet * bnuisPar = bModel->GetNuisanceParameters(); if (bnuisPar) RooStats::SetAllConstant(*bnuisPar); } } if (!bModel || bModel == sbModel) { Info("StandardHypoTestInvDemo","The background model %s does not exist",modelBName); Info("StandardHypoTestInvDemo","Copy it from ModelConfig %s and set POI to zero",modelSBName); bModel = (ModelConfig*) sbModel->Clone(); bModel->SetName(TString(modelSBName)+TString("_with_poi_0")); RooRealVar * var = dynamic_cast<RooRealVar*>(bModel->GetParametersOfInterest()->first()); if (!var) return 0; double oldval = var->getVal(); var->setVal(0); bModel->SetSnapshot( RooArgSet(*var) ); var->setVal(oldval); } else { if (!bModel->GetSnapshot() ) { Info("StandardHypoTestInvDemo","Model %s has no snapshot - make one using model poi and 0 values ",modelBName); RooRealVar * var = dynamic_cast<RooRealVar*>(bModel->GetParametersOfInterest()->first()); if (var) { double oldval = var->getVal(); var->setVal(0); bModel->SetSnapshot( RooArgSet(*var) ); var->setVal(oldval); } else { Error("StandardHypoTestInvDemo","Model %s has no valid poi",modelBName); return 0; } } } // check model has global observables when there are nuisance pdf // for the hybrid case the globobs are not needed if (type != 1 ) { bool hasNuisParam = (sbModel->GetNuisanceParameters() && sbModel->GetNuisanceParameters()->getSize() > 0); bool hasGlobalObs = (sbModel->GetGlobalObservables() && sbModel->GetGlobalObservables()->getSize() > 0); if (hasNuisParam && !hasGlobalObs ) { // try to see if model has nuisance parameters first RooAbsPdf * constrPdf = RooStats::MakeNuisancePdf(*sbModel,"nuisanceConstraintPdf_sbmodel"); if (constrPdf) { Warning("StandardHypoTestInvDemo","Model %s has nuisance parameters but no global observables associated",sbModel->GetName()); Warning("StandardHypoTestInvDemo","\tThe effect of the nuisance parameters will not be treated correctly "); } } } // run first a data fit const RooArgSet * poiSet = sbModel->GetParametersOfInterest(); RooRealVar *poi = (RooRealVar*)poiSet->first(); std::cout << "StandardHypoTestInvDemo : POI initial value: " << poi->GetName() << " = " << poi->getVal() << std::endl; // fit the data first (need to use constraint ) TStopwatch tw; bool doFit = initialFit; if (testStatType == 0 && initialFit == -1) doFit = false; // case of LEP test statistic if (type == 3 && initialFit == -1) doFit = false; // case of Asymptoticcalculator with nominal Asimov double poihat = 0; if (minimizerType.size()==0) minimizerType = ROOT::Math::MinimizerOptions::DefaultMinimizerType(); else ROOT::Math::MinimizerOptions::SetDefaultMinimizer(minimizerType.c_str()); Info("StandardHypoTestInvDemo","Using %s as minimizer for computing the test statistic", ROOT::Math::MinimizerOptions::DefaultMinimizerType().c_str() ); if (doFit) { // do the fit : By doing a fit the POI snapshot (for S+B) is set to the fit value // and the nuisance parameters nominal values will be set to the fit value. // This is relevant when using LEP test statistics Info( "StandardHypoTestInvDemo"," Doing a first fit to the observed data "); RooArgSet constrainParams; if (sbModel->GetNuisanceParameters() ) constrainParams.add(*sbModel->GetNuisanceParameters()); RooStats::RemoveConstantParameters(&constrainParams); tw.Start(); RooFitResult * fitres = sbModel->GetPdf()->fitTo(*data,InitialHesse(false), Hesse(false), Minimizer(minimizerType.c_str(),"Migrad"), Strategy(0), PrintLevel(mPrintLevel), Constrain(constrainParams), Save(true) ); if (fitres->status() != 0) { Warning("StandardHypoTestInvDemo","Fit to the model failed - try with strategy 1 and perform first an Hesse computation"); fitres = sbModel->GetPdf()->fitTo(*data,InitialHesse(true), Hesse(false),Minimizer(minimizerType.c_str(),"Migrad"), Strategy(1), PrintLevel(mPrintLevel+1), Constrain(constrainParams), Save(true) ); } if (fitres->status() != 0) Warning("StandardHypoTestInvDemo"," Fit still failed - continue anyway....."); poihat = poi->getVal(); std::cout << "StandardHypoTestInvDemo - Best Fit value : " << poi->GetName() << " = " << poihat << " +/- " << poi->getError() << std::endl; std::cout << "Time for fitting : "; tw.Print(); //save best fit value in the poi snapshot sbModel->SetSnapshot(*sbModel->GetParametersOfInterest()); std::cout << "StandardHypoTestInvo: snapshot of S+B Model " << sbModel->GetName() << " is set to the best fit value" << std::endl; } // print a message in case of LEP test statistics because it affects result by doing or not doing a fit if (testStatType == 0) { if (!doFit) Info("StandardHypoTestInvDemo","Using LEP test statistic - an initial fit is not done and the TS will use the nuisances at the model value"); else Info("StandardHypoTestInvDemo","Using LEP test statistic - an initial fit has been done and the TS will use the nuisances at the best fit value"); } // build test statistics and hypotest calculators for running the inverter SimpleLikelihoodRatioTestStat slrts(*sbModel->GetPdf(),*bModel->GetPdf()); // null parameters must includes snapshot of poi plus the nuisance values RooArgSet nullParams(*sbModel->GetSnapshot()); if (sbModel->GetNuisanceParameters()) nullParams.add(*sbModel->GetNuisanceParameters()); if (sbModel->GetSnapshot()) slrts.SetNullParameters(nullParams); RooArgSet altParams(*bModel->GetSnapshot()); if (bModel->GetNuisanceParameters()) altParams.add(*bModel->GetNuisanceParameters()); if (bModel->GetSnapshot()) slrts.SetAltParameters(altParams); // ratio of profile likelihood - need to pass snapshot for the alt RatioOfProfiledLikelihoodsTestStat ropl(*sbModel->GetPdf(), *bModel->GetPdf(), bModel->GetSnapshot()); ropl.SetSubtractMLE(false); if (testStatType == 11) ropl.SetSubtractMLE(true); ropl.SetPrintLevel(mPrintLevel); ropl.SetMinimizer(minimizerType.c_str()); ProfileLikelihoodTestStat profll(*sbModel->GetPdf()); if (testStatType == 3) profll.SetOneSided(true); if (testStatType == 4) profll.SetSigned(true); profll.SetMinimizer(minimizerType.c_str()); profll.SetPrintLevel(mPrintLevel); profll.SetReuseNLL(mOptimize); slrts.SetReuseNLL(mOptimize); ropl.SetReuseNLL(mOptimize); if (mOptimize) { profll.SetStrategy(0); ropl.SetStrategy(0); ROOT::Math::MinimizerOptions::SetDefaultStrategy(0); } if (mMaxPoi > 0) poi->setMax(mMaxPoi); // increase limit MaxLikelihoodEstimateTestStat maxll(*sbModel->GetPdf(),*poi); NumEventsTestStat nevtts; AsymptoticCalculator::SetPrintLevel(mPrintLevel); // create the HypoTest calculator class HypoTestCalculatorGeneric * hc = 0; if (type == 0) hc = new FrequentistCalculator(*data, *bModel, *sbModel); else if (type == 1) hc = new HybridCalculator(*data, *bModel, *sbModel); // else if (type == 2 ) hc = new AsymptoticCalculator(*data, *bModel, *sbModel, false, mAsimovBins); // else if (type == 3 ) hc = new AsymptoticCalculator(*data, *bModel, *sbModel, true, mAsimovBins); // for using Asimov data generated with nominal values else if (type == 2 ) hc = new AsymptoticCalculator(*data, *bModel, *sbModel, false ); else if (type == 3 ) hc = new AsymptoticCalculator(*data, *bModel, *sbModel, true ); // for using Asimov data generated with nominal values else { Error("StandardHypoTestInvDemo","Invalid - calculator type = %d supported values are only :\n\t\t\t 0 (Frequentist) , 1 (Hybrid) , 2 (Asymptotic) ",type); return 0; } // set the test statistic TestStatistic * testStat = 0; if (testStatType == 0) testStat = &slrts; if (testStatType == 1 || testStatType == 11) testStat = &ropl; if (testStatType == 2 || testStatType == 3 || testStatType == 4) testStat = &profll; if (testStatType == 5) testStat = &maxll; if (testStatType == 6) testStat = &nevtts; if (testStat == 0) { Error("StandardHypoTestInvDemo","Invalid - test statistic type = %d supported values are only :\n\t\t\t 0 (SLR) , 1 (Tevatron) , 2 (PLR), 3 (PLR1), 4(MLE)",testStatType); return 0; } ToyMCSampler *toymcs = (ToyMCSampler*)hc->GetTestStatSampler(); if (toymcs && (type == 0 || type == 1) ) { // look if pdf is number counting or extended if (sbModel->GetPdf()->canBeExtended() ) { if (useNumberCounting) Warning("StandardHypoTestInvDemo","Pdf is extended: but number counting flag is set: ignore it "); } else { // for not extended pdf if (!useNumberCounting ) { int nEvents = data->numEntries(); Info("StandardHypoTestInvDemo","Pdf is not extended: number of events to generate taken from observed data set is %d",nEvents); toymcs->SetNEventsPerToy(nEvents); } else { Info("StandardHypoTestInvDemo","using a number counting pdf"); toymcs->SetNEventsPerToy(1); } } toymcs->SetTestStatistic(testStat); if (data->isWeighted() && !mGenerateBinned) { Info("StandardHypoTestInvDemo","Data set is weighted, nentries = %d and sum of weights = %8.1f but toy generation is unbinned - it would be faster to set mGenerateBinned to true\n",data->numEntries(), data->sumEntries()); } toymcs->SetGenerateBinned(mGenerateBinned); toymcs->SetUseMultiGen(mOptimize); if (mGenerateBinned && sbModel->GetObservables()->getSize() > 2) { Warning("StandardHypoTestInvDemo","generate binned is activated but the number of ovservable is %d. Too much memory could be needed for allocating all the bins",sbModel->GetObservables()->getSize() ); } // set the random seed if needed if (mRandomSeed >= 0) RooRandom::randomGenerator()->SetSeed(mRandomSeed); } // specify if need to re-use same toys if (reuseAltToys) { hc->UseSameAltToys(); } if (type == 1) { HybridCalculator *hhc = dynamic_cast<HybridCalculator*> (hc); assert(hhc); hhc->SetToys(ntoys,ntoys/mNToysRatio); // can use less ntoys for b hypothesis // remove global observables from ModelConfig (this is probably not needed anymore in 5.32) bModel->SetGlobalObservables(RooArgSet() ); sbModel->SetGlobalObservables(RooArgSet() ); // check for nuisance prior pdf in case of nuisance parameters if (bModel->GetNuisanceParameters() || sbModel->GetNuisanceParameters() ) { // fix for using multigen (does not work in this case) toymcs->SetUseMultiGen(false); ToyMCSampler::SetAlwaysUseMultiGen(false); RooAbsPdf * nuisPdf = 0; if (nuisPriorName) nuisPdf = w->pdf(nuisPriorName); // use prior defined first in bModel (then in SbModel) if (!nuisPdf) { Info("StandardHypoTestInvDemo","No nuisance pdf given for the HybridCalculator - try to deduce pdf from the model"); if (bModel->GetPdf() && bModel->GetObservables() ) nuisPdf = RooStats::MakeNuisancePdf(*bModel,"nuisancePdf_bmodel"); else nuisPdf = RooStats::MakeNuisancePdf(*sbModel,"nuisancePdf_sbmodel"); } if (!nuisPdf ) { if (bModel->GetPriorPdf()) { nuisPdf = bModel->GetPriorPdf(); Info("StandardHypoTestInvDemo","No nuisance pdf given - try to use %s that is defined as a prior pdf in the B model",nuisPdf->GetName()); } else { Error("StandardHypoTestInvDemo","Cannnot run Hybrid calculator because no prior on the nuisance parameter is specified or can be derived"); return 0; } } assert(nuisPdf); Info("StandardHypoTestInvDemo","Using as nuisance Pdf ... " ); nuisPdf->Print(); const RooArgSet * nuisParams = (bModel->GetNuisanceParameters() ) ? bModel->GetNuisanceParameters() : sbModel->GetNuisanceParameters(); RooArgSet * np = nuisPdf->getObservables(*nuisParams); if (np->getSize() == 0) { Warning("StandardHypoTestInvDemo","Prior nuisance does not depend on nuisance parameters. They will be smeared in their full range"); } delete np; hhc->ForcePriorNuisanceAlt(*nuisPdf); hhc->ForcePriorNuisanceNull(*nuisPdf); } } else if (type == 2 || type == 3) { if (testStatType == 3) ((AsymptoticCalculator*) hc)->SetOneSided(true); if (testStatType != 2 && testStatType != 3) Warning("StandardHypoTestInvDemo","Only the PL test statistic can be used with AsymptoticCalculator - use by default a two-sided PL"); } else if (type == 0 || type == 1) ((FrequentistCalculator*) hc)->SetToys(ntoys,ntoys/mNToysRatio); // Get the result RooMsgService::instance().getStream(1).removeTopic(RooFit::NumIntegration); HypoTestInverter calc(*hc); calc.SetConfidenceLevel(0.95); calc.UseCLs(useCLs); calc.SetVerbose(true); // can speed up using proof-lite if (mUseProof && mNWorkers > 1) { ProofConfig pc(*w, mNWorkers, "", kFALSE); toymcs->SetProofConfig(&pc); // enable proof } if (npoints > 0) { if (poimin > poimax) { // if no min/max given scan between MLE and +4 sigma poimin = int(poihat); poimax = int(poihat + 4 * poi->getError()); } std::cout << "Doing a fixed scan in interval : " << poimin << " , " << poimax << std::endl; calc.SetFixedScan(npoints,poimin,poimax); } else { //poi->setMax(10*int( (poihat+ 10 *poi->getError() )/10 ) ); std::cout << "Doing an automatic scan in interval : " << poi->getMin() << " , " << poi->getMax() << std::endl; } tw.Start(); HypoTestInverterResult * r = calc.GetInterval(); std::cout << "Time to perform limit scan \n"; tw.Print(); if (mRebuild) { calc.SetCloseProof(1); tw.Start(); SamplingDistribution * limDist = calc.GetUpperLimitDistribution(true,mNToyToRebuild); std::cout << "Time to rebuild distributions " << std::endl; tw.Print(); if (limDist) { std::cout << "expected up limit " << limDist->InverseCDF(0.5) << " +/- " << limDist->InverseCDF(0.16) << " " << limDist->InverseCDF(0.84) << "\n"; //update r to a new updated result object containing the rebuilt expected p-values distributions // (it will not recompute the expected limit) if (r) delete r; // need to delete previous object since GetInterval will return a cloned copy r = calc.GetInterval(); } else std::cout << "ERROR : failed to re-build distributions " << std::endl; } return r; }
void HypoTestInvDemo(const char * fileName ="GausModel_b.root", const char * wsName = "w", const char * modelSBName = "model_sb", const char * modelBName = "model_b", const char * dataName = "data_obs", int type = 0, // calculator type int testStatType = 0, // test stat type int npoints = 10, int ntoys=1000, bool useCls = true ) { /* type = 0 Freq calculator type = 1 Hybrid testStatType = 0 LEP = 1 Tevatron = 2 PL */ if (fileName==0) { std::cout << "give input filename " << std::endl; return; } TFile * file = new TFile(fileName); RooWorkspace * w = dynamic_cast<RooWorkspace*>( file->Get(wsName) ); if (!w) { return; } w->Print(); RooAbsData * data = w->data(dataName); if (!data) { Error("HypoTestDemo","Not existing data %s",dataName); } // get models from WS // get the modelConfig out of the file ModelConfig* bModel = (ModelConfig*) w->obj(modelBName); ModelConfig* sbModel = (ModelConfig*) w->obj(modelSBName); SimpleLikelihoodRatioTestStat slrts(*bModel->GetPdf(),*sbModel->GetPdf()); slrts.SetNullParameters(*bModel->GetSnapshot()); slrts.SetAltParameters(*sbModel->GetSnapshot()); RatioOfProfiledLikelihoodsTestStat ropl(*bModel->GetPdf(), *sbModel->GetPdf(), sbModel->GetSnapshot()); ropl.SetSubtractMLE(false); ProfileLikelihoodTestStat profll(*sbModel->GetPdf()); profll.SetOneSided(0); TestStatistic * testStat = &slrts; if (testStatType == 1) testStat = &ropl; if (testStatType == 2) testStat = &profll; HypoTestCalculatorGeneric * hc = 0; if (type == 0) hc = new FrequentistCalculator(*data, *sbModel, *bModel); else new HybridCalculator(*data, *sbModel, *bModel); ToyMCSampler *toymcs = (ToyMCSampler*)hc->GetTestStatSampler(); //toymcs->SetNEventsPerToy(1); toymcs->SetTestStatistic(testStat); if (type == 1) { HybridCalculator *hhc = (HybridCalculator*) hc; hhc->SetToys(ntoys,ntoys); // hhc->ForcePriorNuisanceAlt(*pdfNuis); // hhc->ForcePriorNuisanceNull(*pdfNuis); } else ((FrequentistCalculator*) hc)->SetToys(ntoys,ntoys); // Get the result RooMsgService::instance().getStream(1).removeTopic(RooFit::NumIntegration); TStopwatch tw; tw.Start(); const RooArgSet * poiSet = sbModel->GetParametersOfInterest(); RooRealVar *poi = (RooRealVar*)poiSet->first(); // fit the data first sbModel->GetPdf()->fitTo(*data); double poihat = poi->getVal(); //poi->setVal(30); //poi->setError(10); HypoTestInverter calc(*hc); // GENA: for two-sided interval //calc.SetConfidenceLevel(0.95); // GENA: for 95% upper limit calc.SetConfidenceLevel(0.90); calc.UseCLs(useCls); calc.SetVerbose(true); // can spped up using proof ProofConfig pc(*w, 2, "workers=2", kFALSE); //ProofConfig pc(*w, 30, "localhost", kFALSE); //ToyMCSampler * toymcs = dynamic_cast<ToyMCSampler *> (calc.GetHypoTestCalculator()->GetTestStatSampler() ); // GENA: disable proof for now //toymcs->SetProofConfig(&pc); // enable proof if (npoints > 0) { // GENA double poimin = TMath::Max(poihat - 4 * poi->getError(), 0.0); //poimin = poihat; double poimax = poihat + 4 * poi->getError(); poimin = 0; poimax = 20; //double poimin = poi->getMin(); //double poimax = poi->getMax(); std::cout << "Doing a fixed scan in interval : " << poimin << " , " << poimax << std::endl; calc.SetFixedScan(npoints,poimin,poimax); } HypoTestInverterResult * r = calc.GetInterval(); // write to a file the results TString resultFileName = (useCls) ? "CLs_" : "Cls+b_"; resultFileName += fileName; // GENA //TFile * file = new TFile(resultFileName,"RECREATE"); file = new TFile(resultFileName,"RECREATE"); r->Write(); file->Close(); double ulError = r->UpperLimitEstimatedError(); double upperLimit = r->UpperLimit(); std::cout << "The computed upper limit is: " << upperLimit << std::endl; std::cout << "an estimated error on this upper limit is: " << ulError << std::endl; // check using interpolation // double interpLimit = r->FindInterpolatedLimit(1.-r->ConfidenceLevel() ); // cout << "The computer interpolated limits is " << interpLimit << endl; const int nEntries = r->ArraySize(); std::vector<Double_t> xArray(nEntries); std::vector<Double_t> yArray(nEntries); std::vector<Double_t> yErrArray(nEntries); for (int i=0; i<nEntries; i++) { xArray[i] = r->GetXValue(i); yArray[i] = r->GetYValue(i); yErrArray[i] = r->GetYError(i); std::cout << xArray[i] << " , " << yArray[i] << " err = " << yErrArray[i] << std::endl; } // see expected result (bands) TGraph * g0 = new TGraph(nEntries); TGraphAsymmErrors * g1 = new TGraphAsymmErrors(nEntries); TGraphAsymmErrors * g2l = new TGraphAsymmErrors(nEntries); TGraphAsymmErrors * g2u = new TGraphAsymmErrors(nEntries); double p[7]; double q[7]; p[0] = ROOT::Math::normal_cdf(-2); p[1] = ROOT::Math::normal_cdf(-1.5); p[2] = ROOT::Math::normal_cdf(-1); p[3] = 0.5; p[4] = ROOT::Math::normal_cdf(1); p[5] = ROOT::Math::normal_cdf(1.5); p[6] = ROOT::Math::normal_cdf(2); for (int i=0; i<nEntries; i++) { SamplingDistribution * s = r->GetExpectedDistribution(i); // GENA //const std::vector<double> & values = s->GetSamplingDistribution(); const std::vector<Double_t> & cValues = s->GetSamplingDistribution(); std::vector<Double_t> values; for (std::vector<Double_t>::const_iterator val = cValues.begin(); val != cValues.end(); ++val) values.push_back(*val); TMath::Quantiles(values.size(), 7, &values[0],q,p,false); double p0 = q[3]; double p2l = q[1]; double p2u = q[5]; g0->SetPoint(i, r->GetXValue(i), p0 ) ; g1->SetPoint(i, r->GetXValue(i), p0); g2l->SetPoint(i, r->GetXValue(i), p2l); g2u->SetPoint(i, r->GetXValue(i), p2u); //g2->SetPoint(i, r->GetXValue(i), s->InverseCDF(0.50)); g1->SetPointEYlow(i, q[3] - q[2]); // -1 sigma errorr g1->SetPointEYhigh(i, q[4] - q[3]);//+1 sigma error g2l->SetPointEYlow(i, q[1]-q[0]); // -2 -- -1 sigma error g2l->SetPointEYhigh(i, q[2]-q[1]); g2u->SetPointEYlow(i, q[5]-q[4]); g2u->SetPointEYhigh(i, q[6]-q[5]); if (plotHypoTestResult) { HypoTestResult * hr = new HypoTestResult(); hr->SetNullDistribution( r->GetBackgroundDistribution() ); hr->SetAltDistribution( r->GetSignalAndBackgroundDistribution(i) ); new TCanvas(); HypoTestPlot * pl = new HypoTestPlot(*hr); pl->Draw(); } } HypoTestInverterPlot *plot = new HypoTestInverterPlot("result","",r); TGraphErrors * g = plot->MakePlot(); g->Draw("APL"); g2l->SetFillColor(kYellow); g2l->Draw("3"); g2u->SetFillColor(kYellow); g2u->Draw("3"); g1->SetFillColor(kGreen); g1->Draw("3"); g0->SetLineColor(kBlue); g0->SetLineStyle(2); g0->SetLineWidth(2); g0->Draw("L"); //g1->Draw("P"); //g2->Draw("P"); g->SetLineWidth(2); g->Draw("PL"); // GENA: two-sided interval //double alpha = 1.-r->ConfidenceLevel(); // GENA: upper limit double alpha = (1.-r->ConfidenceLevel())/2.0; double x1 = g->GetXaxis()->GetXmin(); double x2 = g->GetXaxis()->GetXmax(); TLine * line = new TLine(x1, alpha, x2,alpha); line->SetLineColor(kRed); line->Draw(); // see the expected limit and -1 +1 sigma bands // SamplingDistribution * limits = r->GetUpperLimitDistribution(); // std::cout << " expected limit (median) " << limits->InverseCDF(0.50) << std::endl; // std::cout << " expected limit (-1 sig) " << limits->InverseCDF((ROOT::Math::normal_cdf(-1))) << std::endl; // std::cout << " expected limit (+1 sig) " << limits->InverseCDF((ROOT::Math::normal_cdf(+1))) << std::endl; tw.Print(); }