␛[1mRooFit v3.60 -- Developed by Wouter Verkerke and David Kirkby␛[0m
Copyright (C) 2000-2013 NIKHEF, University of California & Stanford University
All rights reserved, please read http://roofit.sourceforge.net/license.txt
RooWorkspace(combined) combined contents
variables
---------
(Lumi,SigXsecOverSM,alpha_syst1,alpha_syst2,alpha_syst3,channelCat,gamma_stat_channel1_bin_0,gamma_stat_channel1_bin_1,nom_alpha_syst1,nom_alpha_syst2,nom_alpha_syst3,nom_gamma_stat_channel1_bin_0,nom_gamma_stat_channel1_bin_1,nominalLumi,obs_x_channel1,weightVar)
p.d.f.s
-------
RooGaussian::alpha_syst1Constraint[ x=alpha_syst1 mean=nom_alpha_syst1 sigma=1 ] = 1
RooGaussian::alpha_syst2Constraint[ x=alpha_syst2 mean=nom_alpha_syst2 sigma=1 ] = 1
RooGaussian::alpha_syst3Constraint[ x=alpha_syst3 mean=nom_alpha_syst3 sigma=1 ] = 1
RooRealSumPdf::channel1_model[ signal_channel1_scaleFactors * signal_channel1_shapes + background1_channel1_scaleFactors * background1_channel1_shapes + background2_channel1_scaleFactors * background2_channel1_shapes ] = 220
RooPoisson::gamma_stat_channel1_bin_0_constraint[ x=nom_gamma_stat_channel1_bin_0 mean=gamma_stat_channel1_bin_0_poisMean ] = 0.019943
RooPoisson::gamma_stat_channel1_bin_1_constraint[ x=nom_gamma_stat_channel1_bin_1 mean=gamma_stat_channel1_bin_1_poisMean ] = 0.039861
RooGaussian::lumiConstraint[ x=Lumi mean=nominalLumi sigma=0.1 ] = 1
RooProdPdf::model_channel1[ lumiConstraint * alpha_syst1Constraint * alpha_syst2Constraint * alpha_syst3Constraint * gamma_stat_channel1_bin_0_constraint * gamma_stat_channel1_bin_1_constraint * channel1_model(obs_x_channel1) ] = 0.174888
RooSimultaneous::simPdf[ indexCat=channelCat channel1=model_channel1 ] = 0.174888
functions
--------
RooHistFunc::background1_channel1_Hist_alphanominal[ depList=(obs_x_channel1) depList=(obs_x_channel1) ] = 0
RooStats::HistFactory::FlexibleInterpVar::background1_channel1_epsilon[ paramList=(alpha_syst2) ] = 1
RooProduct::background1_channel1_scaleFactors[ background1_channel1_epsilon * Lumi ] = 1
RooProduct::background1_channel1_shapes[ background1_channel1_Hist_alphanominal * mc_stat_channel1 * channel1_model_binWidth ] = 0
RooHistFunc::background2_channel1_Hist_alphanominal[ depList=(obs_x_channel1) depList=(obs_x_channel1) ] = 100
RooStats::HistFactory::FlexibleInterpVar::background2_channel1_epsilon[ paramList=(alpha_syst3) ] = 1
RooProduct::background2_channel1_scaleFactors[ background2_channel1_epsilon * Lumi ] = 1
RooProduct::background2_channel1_shapes[ background2_channel1_Hist_alphanominal * mc_stat_channel1 * channel1_model_binWidth ] = 200
RooBinWidthFunction::channel1_model_binWidth[ HistFuncForBinWidth=signal_channel1_Hist_alphanominal HistFuncForBinWidth=signal_channel1_Hist_alphanominal ] = 2
RooProduct::gamma_stat_channel1_bin_0_poisMean[ gamma_stat_channel1_bin_0 * gamma_stat_channel1_bin_0_tau ] = 400
RooProduct::gamma_stat_channel1_bin_1_poisMean[ gamma_stat_channel1_bin_1 * gamma_stat_channel1_bin_1_tau ] = 100
ParamHistFunc::mc_stat_channel1[ ] = 1
RooHistFunc::signal_channel1_Hist_alphanominal[ depList=(obs_x_channel1) depList=(obs_x_channel1) ] = 10
RooStats::HistFactory::FlexibleInterpVar::signal_channel1_epsilon[ paramList=(alpha_syst1) ] = 1
RooProduct::signal_channel1_scaleFactors[ signal_channel1_epsilon * SigXsecOverSM * Lumi ] = 1
RooProduct::signal_channel1_shapes[ signal_channel1_Hist_alphanominal * channel1_model_binWidth ] = 20
datasets
--------
RooDataSet::asimovData(obs_x_channel1,weightVar,channelCat)
RooDataSet::obsData(channelCat,obs_x_channel1)
embedded datasets (in pdfs and functions)
-----------------------------------------
RooDataHist::signal_channel1_Hist_alphanominalDHist(obs_x_channel1)
RooDataHist::background1_channel1_Hist_alphanominalDHist(obs_x_channel1)
RooDataHist::background2_channel1_Hist_alphanominalDHist(obs_x_channel1)
parameter snapshots
-------------------
NominalParamValues = (nom_alpha_syst2=0[C],nom_alpha_syst3=0[C],nom_gamma_stat_channel1_bin_0=400[C],nom_gamma_stat_channel1_bin_1=100[C],weightVar=0,obs_x_channel1=1.75,Lumi=1[C],nominalLumi=1[C],alpha_syst1=0[C],nom_alpha_syst1=0[C],alpha_syst2=0,alpha_syst3=0,gamma_stat_channel1_bin_0=1 +/- 0.05,gamma_stat_channel1_bin_1=1 +/- 0.1,SigXsecOverSM=1)
named sets
----------
ModelConfig_GlobalObservables:(nom_alpha_syst2,nom_alpha_syst3,nom_gamma_stat_channel1_bin_0,nom_gamma_stat_channel1_bin_1)
ModelConfig_NuisParams:(alpha_syst2,alpha_syst3,gamma_stat_channel1_bin_0,gamma_stat_channel1_bin_1)
ModelConfig_Observables:(obs_x_channel1,weightVar,channelCat)
ModelConfig_POI:(SigXsecOverSM)
globalObservables:(nom_alpha_syst2,nom_alpha_syst3,nom_gamma_stat_channel1_bin_0,nom_gamma_stat_channel1_bin_1)
observables:(obs_x_channel1,weightVar,channelCat)
generic objects
---------------
RooStats::ModelConfig::ModelConfig
=== Using the following for ModelConfigB_only ===
Observables: RooArgSet:: = (obs_x_channel1,weightVar,channelCat)
Parameters of Interest: RooArgSet:: = (SigXsecOverSM)
Nuisance Parameters: RooArgSet:: = (alpha_syst2,alpha_syst3,gamma_stat_channel1_bin_0,gamma_stat_channel1_bin_1)
Global Observables: RooArgSet:: = (nom_alpha_syst2,nom_alpha_syst3,nom_gamma_stat_channel1_bin_0,nom_gamma_stat_channel1_bin_1)
PDF: RooSimultaneous::simPdf[ indexCat=channelCat channel1=model_channel1 ] = 0.174888
Snapshot:
1) 0x55c6f1760d10 RooRealVar:: SigXsecOverSM = 0 L(0 - 3) "SigXsecOverSM"
=== Using the following for ModelConfig ===
Observables: RooArgSet:: = (obs_x_channel1,weightVar,channelCat)
Parameters of Interest: RooArgSet:: = (SigXsecOverSM)
Nuisance Parameters: RooArgSet:: = (alpha_syst2,alpha_syst3,gamma_stat_channel1_bin_0,gamma_stat_channel1_bin_1)
Global Observables: RooArgSet:: = (nom_alpha_syst2,nom_alpha_syst3,nom_gamma_stat_channel1_bin_0,nom_gamma_stat_channel1_bin_1)
PDF: RooSimultaneous::simPdf[ indexCat=channelCat channel1=model_channel1 ] = 0.174888
Snapshot:
1) 0x55c6f1761340 RooRealVar:: SigXsecOverSM = 1 L(0 - 3) "SigXsecOverSM"
[#0] PROGRESS:Generation -- Test Statistic on data: 1.77404
[#1] INFO:InputArguments -- Profiling conditional MLEs for Null.
[#1] INFO:InputArguments -- Using a ToyMCSampler. Now configuring for Null.
[#0] PROGRESS:Generation -- generated toys: 500 / 5000
[#0] PROGRESS:Generation -- generated toys: 1000 / 5000
[#0] PROGRESS:Generation -- generated toys: 1500 / 5000
[#0] PROGRESS:Generation -- generated toys: 2000 / 5000
[#0] PROGRESS:Generation -- generated toys: 2500 / 5000
[#0] PROGRESS:Generation -- generated toys: 3000 / 5000
[#0] PROGRESS:Generation -- generated toys: 3500 / 5000
[#0] PROGRESS:Generation -- generated toys: 4000 / 5000
[#0] PROGRESS:Generation -- generated toys: 4500 / 5000
[#1] INFO:InputArguments -- Profiling conditional MLEs for Alt.
[#1] INFO:InputArguments -- Using a ToyMCSampler. Now configuring for Alt.
[#0] PROGRESS:Generation -- generated toys: 500 / 1250
[#0] PROGRESS:Generation -- generated toys: 1000 / 1250
Results HypoTestCalculator_result:
- Null p-value = 0.0304 +/- 0.002428
- Significance = 1.87495 +/- 0.0352942 sigma
- Number of Alt toys: 1250
- Number of Null toys: 5000
- Test statistic evaluated on data: 1.77404
- CL_b: 0.0304 +/- 0.002428
- CL_s+b: 0.4328 +/- 0.0140138
- CL_s: 14.2368 +/- 1.22696
Expected p -value and significance at -2 sigma = 0.839 significance -0.990356 sigma
Expected p -value and significance at -1 sigma = 0.2238 significance 0.759422 sigma
Expected p -value and significance at 0 sigma = 0.0434 significance 1.71252 sigma
Expected p -value and significance at 1 sigma = 0.0028 significance 2.77033 sigma
Expected p -value and significance at 2 sigma = 0.0002 significance 3.54008 sigma
#include <cassert>
struct HypoTestOptions {
bool noSystematics = false;
double nToysRatio = 4;
double poiValue = -1;
int printLevel = 0;
bool generateBinned = false;
bool useProof = false;
bool enableDetailedOutput = false;
};
HypoTestOptions optHT;
void StandardHypoTestDemo(const char *infile = "", const char *workspaceName = "combined",
const char *modelSBName = "ModelConfig", const char *modelBName = "",
const char *dataName = "obsData", int calcType = 0,
int testStatType = 3,
int ntoys = 5000, bool useNC = false, const char *nuisPriorName = 0)
{
bool noSystematics = optHT.noSystematics;
double nToysRatio = optHT.nToysRatio;
double poiValue = optHT.poiValue;
int printLevel = optHT.printLevel;
bool generateBinned = optHT.generateBinned;
bool useProof = optHT.useProof;
bool enableDetOutput = optHT.enableDetailedOutput;
SimpleLikelihoodRatioTestStat::SetAlwaysReuseNLL(true);
ProfileLikelihoodTestStat::SetAlwaysReuseNLL(true);
RatioOfProfiledLikelihoodsTestStat::SetAlwaysReuseNLL(true);
const char *filename = "";
if (!strcmp(infile, "")) {
filename = "results/example_combined_GaussExample_model.root";
if (!fileExist) {
#ifdef _WIN32
cout << "HistFactory file cannot be generated on Windows - exit" << endl;
return;
#endif
cout << "will run standard hist2workspace example" << endl;
gROOT->ProcessLine(
".! prepareHistFactory .");
gROOT->ProcessLine(
".! hist2workspace config/example.xml");
cout << "\n\n---------------------" << endl;
cout << "Done creating example input" << endl;
cout << "---------------------\n\n" << endl;
}
} else
filename = infile;
cout << "StandardRooStatsDemoMacro: Input file " << filename << " is not found" << endl;
return;
}
if (!w) {
cout << "workspace not found" << endl;
return;
}
if (!data || !sbModel) {
cout << "data or ModelConfig was not found" << endl;
return;
}
if (noSystematics) {
if (nuisPar && nuisPar->
getSize() > 0) {
std::cout << "StandardHypoTestInvDemo"
<< " - Switch off all systematics by setting them constant to their initial values" << std::endl;
}
if (bModel) {
if (bnuisPar)
}
}
if (!bModel) {
Info(
"StandardHypoTestInvDemo",
"The background model %s does not exist", modelBName);
Info(
"StandardHypoTestInvDemo",
"Copy it from ModelConfig %s and set POI to zero", modelSBName);
if (!var)
return;
double oldval = var->
getVal();
}
Info(
"StandardHypoTestDemo",
"Model %s has no snapshot - make one using model poi", modelSBName);
if (!var)
return;
double oldval = var->
getVal();
if (poiValue > 0)
if (poiValue > 0)
}
if (testStatType == 3)
if (enableDetOutput) {
}
AsymptoticCalculator::SetPrintLevel(printLevel);
if (calcType == 0)
else if (calcType == 1)
else if (calcType == 2)
if (calcType == 0) {
if (enableDetOutput)
}
if (calcType == 1) {
}
if (calcType == 2) {
if (testStatType == 3)
if (testStatType != 2 && testStatType != 3)
"Only the PL test statistic can be used with AsymptoticCalculator - use by default a two-sided PL");
}
if (nuisPriorName)
nuisPdf = w->
pdf(nuisPriorName);
if (!nuisPdf) {
Info(
"StandardHypoTestDemo",
"No nuisance pdf given for the HybridCalculator - try to deduce pdf from the model");
else
}
if (!nuisPdf) {
Info(
"StandardHypoTestDemo",
"No nuisance pdf given - try to use %s that is defined as a prior pdf in the B model",
} else {
Error(
"StandardHypoTestDemo",
"Cannot run Hybrid calculator because no prior on the nuisance parameter is "
"specified or can be derived");
return;
}
}
assert(nuisPdf);
Info(
"StandardHypoTestDemo",
"Using as nuisance Pdf ... ");
"Prior nuisance does not depend on nuisance parameters. They will be smeared in their full range");
}
delete np;
}
if (sampler && (calcType == 0 || calcType == 1)) {
if (useNC)
Warning(
"StandardHypoTestDemo",
"Pdf is extended: but number counting flag is set: ignore it ");
} else {
if (!useNC) {
Info(
"StandardHypoTestDemo",
"Pdf is not extended: number of events to generate taken from observed data set is %d", nEvents);
} else {
Info(
"StandardHypoTestDemo",
"using a number counting pdf");
}
}
Info(
"StandardHypoTestDemo",
"Data set is weighted, nentries = %d and sum of weights = %8.1f but toy "
"generation is unbinned - it would be faster to set generateBinned to true\n",
}
if (generateBinned)
if (useProof) {
}
if (testStatType == 0)
if (testStatType == 1)
if (testStatType == 2 || testStatType == 3)
}
delete sampler;
delete slrts;
delete ropl;
delete profll;
if (calcType != 2) {
} else {
std::cout << "Asymptotic results " << std::endl;
}
if (calcType != 2) {
htExp.Append(htr);
double p[5];
for (int i = 0; i < 5; ++i) {
double sig = -2 + i;
}
for (int i = 0; i < 5; ++i) {
htExp.SetTestStatisticData(
q[i]);
double sig = -2 + i;
std::cout << " Expected p -value and significance at " << sig << " sigma = " << htExp.NullPValue()
<< " significance " << htExp.Significance() << " sigma " << std::endl;
}
} else {
for (int i = 0; i < 5; ++i) {
double sig = -2 + i;
std::cout << " Expected p -value and significance at " << sig << " sigma = " << pval << " significance "
}
}
bool writeResult = (calcType != 2);
if (enableDetOutput) {
writeResult = true;
Info(
"StandardHypoTestDemo",
"Detailed output will be written in output result file");
}
if (htr != NULL && writeResult) {
const char *calcTypeName = (calcType == 0) ? "Freq" : (calcType == 1) ? "Hybr" : "Asym";
TFile *fileOut =
new TFile(resultFileName,
"RECREATE");
Info(
"StandardHypoTestDemo",
"HypoTestResult has been written in the file %s", resultFileName.
Data());
}
}
void Info(const char *location, const char *msgfmt,...)
Use this function for informational messages.
void Error(const char *location, const char *msgfmt,...)
Use this function in case an error occurred.
void Warning(const char *location, const char *msgfmt,...)
Use this function in warning situations.
R__EXTERN TSystem * gSystem
RooArgSet * getObservables(const RooArgSet &set, Bool_t valueOnly=kTRUE) const
Given a set of possible observables, return the observables that this PDF depends on.
virtual void Print(Option_t *options=0) const
Print the object to the defaultPrintStream().
RooAbsArg * first() const
RooAbsData is the common abstract base class for binned and unbinned datasets.
virtual Double_t sumEntries() const =0
Return effective number of entries in dataset, i.e., sum all weights.
virtual Bool_t isWeighted() const
virtual Int_t numEntries() const
Return number of entries in dataset, i.e., count unweighted entries.
Bool_t canBeExtended() const
If true, PDF can provide extended likelihood term.
Double_t getVal(const RooArgSet *normalisationSet=nullptr) const
Evaluate object.
RooArgSet is a container object that can hold multiple RooAbsArg objects.
RooRealVar represents a variable that can be changed from the outside.
virtual void setVal(Double_t value)
Set value of variable to 'value'.
Hypothesis Test Calculator based on the asymptotic formulae for the profile likelihood ratio.
Does a frequentist hypothesis test.
Same purpose as HybridCalculatorOriginal, but different implementation.
Common base class for the Hypothesis Test Calculators.
TestStatSampler * GetTestStatSampler(void) const
Returns instance of TestStatSampler.
virtual HypoTestResult * GetHypoTest() const
inherited methods from HypoTestCalculator interface
This class provides the plots for the result of a study performed with any of the HypoTestCalculatorG...
HypoTestResult is a base class for results from hypothesis tests.
void SetBackgroundAsAlt(Bool_t l=kTRUE)
void SetPValueIsRightTail(Bool_t pr)
virtual Double_t AlternatePValue() const
Return p-value for alternate hypothesis.
virtual Double_t NullPValue() const
Return p-value for null hypothesis.
void Print(const Option_t *="") const
Print out some information about the results Note: use Alt/Null labels for the hypotheses here as the...
SamplingDistribution * GetAltDistribution(void) const
ModelConfig is a simple class that holds configuration information specifying how a model should be u...
virtual void SetSnapshot(const RooArgSet &set)
Set parameter values for a particular hypothesis if using a common PDF by saving a snapshot in the wo...
virtual ModelConfig * Clone(const char *name="") const override
clone
const RooArgSet * GetParametersOfInterest() const
get RooArgSet containing the parameter of interest (return NULL if not existing)
const RooArgSet * GetNuisanceParameters() const
get RooArgSet containing the nuisance parameters (return NULL if not existing)
const RooArgSet * GetObservables() const
get RooArgSet for observables (return NULL if not existing)
const RooArgSet * GetSnapshot() const
get RooArgSet for parameters for a particular hypothesis (return NULL if not existing)
RooAbsPdf * GetPdf() const
get model PDF (return NULL if pdf has not been specified or does not exist)
RooAbsPdf * GetPriorPdf() const
get parameters prior pdf (return NULL if not existing)
ProfileLikelihoodTestStat is an implementation of the TestStatistic interface that calculates the pro...
void SetPrintLevel(Int_t printlevel)
virtual void EnableDetailedOutput(bool e=true, bool withErrorsAndPulls=false)
void SetOneSidedDiscovery(Bool_t flag=true)
Holds configuration options for proof and proof-lite.
TestStatistic that returns the ratio of profiled likelihoods.
void SetSubtractMLE(bool subtract)
virtual void EnableDetailedOutput(bool e=true)
void SetLogYaxis(Bool_t ly)
changes plot to log scale on y axis
void Draw(Option_t *options=0)
Draw this plot and all of the elements it contains.
This class simply holds a sampling distribution of some test statistic.
const std::vector< Double_t > & GetSamplingDistribution() const
Get test statistics values.
TestStatistic class that returns -log(L[null] / L[alt]) where L is the likelihood.
virtual void EnableDetailedOutput(bool e=true)
void SetNullParameters(const RooArgSet &nullParameters)
void SetAltParameters(const RooArgSet &altParameters)
ToyMCSampler is an implementation of the TestStatSampler interface.
void SetProofConfig(ProofConfig *pc=NULL)
virtual void SetTestStatistic(TestStatistic *testStatistic, unsigned int i)
void SetGenerateBinned(bool binned=true)
virtual void SetNEventsPerToy(const Int_t nevents)
Forces the generation of exactly n events even for extended PDFs.
The RooWorkspace is a persistable container for RooFit projects.
RooAbsData * data(const char *name) const
Retrieve dataset (binned or unbinned) with given name. A null pointer is returned if not found.
void Print(Option_t *opts=0) const
Print contents of the workspace.
TObject * obj(const char *name) const
Return any type of object (RooAbsArg, RooAbsData or generic object) with given name)
RooAbsPdf * pdf(const char *name) const
Retrieve p.d.f (RooAbsPdf) with given name. A null pointer is returned if not found.
A ROOT file is a suite of consecutive data records (TKey instances) with a well defined format.
static TFile * Open(const char *name, Option_t *option="", const char *ftitle="", Int_t compress=ROOT::RCompressionSetting::EDefaults::kUseCompiledDefault, Int_t netopt=0)
Create / open a file.
void Close(Option_t *option="") override
Close a file.
virtual void SetName(const char *name)
Set the name of the TNamed.
virtual const char * GetName() const
Returns name of object.
virtual Int_t Write(const char *name=0, Int_t option=0, Int_t bufsize=0)
Write this object to the current directory.
TString & Replace(Ssiz_t pos, Ssiz_t n, const char *s)
const char * Data() const
static TString Format(const char *fmt,...)
Static method which formats a string using a printf style format descriptor and return a TString.
virtual Bool_t AccessPathName(const char *path, EAccessMode mode=kFileExists)
Returns FALSE if one can access a file using the specified access mode.
double normal_cdf(double x, double sigma=1, double x0=0)
Cumulative distribution function of the normal (Gaussian) distribution (lower tail).
double normal_quantile_c(double z, double sigma)
Inverse ( ) of the cumulative distribution function of the upper tail of the normal (Gaussian) distri...
The namespace RooFit contains mostly switches that change the behaviour of functions of PDFs (or othe...
Namespace for the RooStats classes.
bool SetAllConstant(const RooAbsCollection &coll, bool constant=true)
RooAbsPdf * MakeNuisancePdf(RooAbsPdf &pdf, const RooArgSet &observables, const char *name)
void Quantiles(Int_t n, Int_t nprob, Double_t *x, Double_t *quantiles, Double_t *prob, Bool_t isSorted=kTRUE, Int_t *index=0, Int_t type=7)
Computes sample quantiles, corresponding to the given probabilities.