#include <Alignment/APEEstimation/src/ApeEstimatorSummary.cc>

Inheritance diagram for ApeEstimatorSummary:

Public Member Functions
	ApeEstimatorSummary (const edm::ParameterSet &)

	~ApeEstimatorSummary () override

Public Member Functions inherited from edm::one::EDAnalyzer<>
	EDAnalyzer ()=default

SerialTaskQueue *	globalLuminosityBlocksQueue () final

SerialTaskQueue *	globalRunsQueue () final

bool	wantsGlobalLuminosityBlocks () const final

bool	wantsGlobalRuns () const final

Public Member Functions inherited from edm::one::EDAnalyzerBase
void	callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)

	EDAnalyzerBase ()

ModuleDescription const &	moduleDescription () const

bool	wantsStreamLuminosityBlocks () const

bool	wantsStreamRuns () const

	~EDAnalyzerBase () override

Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfo >	consumesInfo () const

void	convertCurrentProcessAlias (std::string const &processName)
	Convert "@currentProcess" in InputTag process names to the actual current process name. More...

	EDConsumerBase ()

	EDConsumerBase (EDConsumerBase const &)=delete

	EDConsumerBase (EDConsumerBase &&)=default

ESProxyIndex const *	esGetTokenIndices (edm::Transition iTrans) const

ProductResolverIndexAndSkipBit	indexFrom (EDGetToken, BranchType, TypeID const &) const

void	itemsMayGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const

void	itemsToGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const

std::vector< ProductResolverIndexAndSkipBit > const &	itemsToGetFrom (BranchType iType) const

void	labelsForToken (EDGetToken iToken, Labels &oLabels) const

void	modulesWhoseProductsAreConsumed (std::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const

EDConsumerBase const &	operator= (EDConsumerBase const &)=delete

EDConsumerBase &	operator= (EDConsumerBase &&)=default

bool	registeredToConsume (ProductResolverIndex, bool, BranchType) const

bool	registeredToConsumeMany (TypeID const &, BranchType) const

ProductResolverIndexAndSkipBit	uncheckedIndexFrom (EDGetToken) const

void	updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)

void	updateLookup (eventsetup::ESRecordsToProxyIndices const &)

virtual	~EDConsumerBase () noexcept(false)

Private Types
enum	ApeWeight { wInvalid, wUnity, wEntries, wEntriesOverSigmaX2 }

Private Member Functions
void	analyze (const edm::Event &, const edm::EventSetup &) override

void	beginJob () override

void	bookHists ()

void	calculateApe ()

void	endJob () override

void	getTrackerSectorStructs ()

void	openInputFile ()

std::vector< double >	residualErrorBinning ()

void	writeHists ()

Private Attributes
bool	firstEvent = true

TFile *	inputFile_

std::map< unsigned int, TrackerSectorStruct >	m_tkSector_

unsigned int	noSectors_

const edm::ParameterSet	parameterSet_

Additional Inherited Members
Public Types inherited from edm::one::EDAnalyzerBase
typedef EDAnalyzerBase	ModuleType

Public Types inherited from edm::EDConsumerBase
typedef ProductLabels	Labels

Static Public Member Functions inherited from edm::one::EDAnalyzerBase
static const std::string &	baseType ()

static void	fillDescriptions (ConfigurationDescriptions &descriptions)

static void	prevalidate (ConfigurationDescriptions &descriptions)

Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	consumes (edm::InputTag const &tag)

EDGetToken	consumes (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	consumes (TypeToGet const &id, edm::InputTag const &tag)

ConsumesCollector	consumesCollector ()
	Use a ConsumesCollector to gather consumes information from helper functions. More...

template<typename ProductType , BranchType B = InEvent>
void	consumesMany ()

void	consumesMany (const TypeToGet &id)

template<BranchType B>
void	consumesMany (const TypeToGet &id)

template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes ()

template<typename ESProduct , typename ESRecord , Transition Tr = Transition::Event>
auto	esConsumes (ESInputTag const &tag)

template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType >	mayConsume (edm::InputTag const &tag)

EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

template<BranchType B>
EDGetToken	mayConsume (const TypeToGet &id, edm::InputTag const &tag)

Detailed Description

Description: [one line class summary]

Implementation: [Notes on implementation]

Definition at line 59 of file ApeEstimatorSummary.cc.

Member Enumeration Documentation

enum ApeEstimatorSummary::ApeWeight

private

Enumerator
wInvalid
wUnity
wEntries
wEntriesOverSigmaX2

Definition at line 77 of file ApeEstimatorSummary.cc.

77 { wInvalid, wUnity, wEntries, wEntriesOverSigmaX2 };

ApeEstimatorSummary::wUnity

Definition: ApeEstimatorSummary.cc:77

ApeEstimatorSummary::wEntriesOverSigmaX2

Definition: ApeEstimatorSummary.cc:77

ApeEstimatorSummary::wInvalid

Definition: ApeEstimatorSummary.cc:77

ApeEstimatorSummary::wEntries

Definition: ApeEstimatorSummary.cc:77

Constructor & Destructor Documentation

ApeEstimatorSummary::ApeEstimatorSummary ( const edm::ParameterSet & iConfig )

explicit

Definition at line 101 of file ApeEstimatorSummary.cc.

102 : parameterSet_(iConfig), inputFile_(nullptr) {}

ApeEstimatorSummary::inputFile_

TFile * inputFile_

Definition: ApeEstimatorSummary.cc:84

ApeEstimatorSummary::parameterSet_

const edm::ParameterSet parameterSet_

Definition: ApeEstimatorSummary.cc:80

ApeEstimatorSummary::~ApeEstimatorSummary ( )

override

Definition at line 104 of file ApeEstimatorSummary.cc.

104 {}

Member Function Documentation

void ApeEstimatorSummary::analyze	(	const edm::Event &	iEvent,
		const edm::EventSetup &	iSetup
	)

overrideprivate

Definition at line 890 of file ApeEstimatorSummary.cc.

References firstEvent, edm::EventSetup::get(), edm::ParameterSet::getParameter(), AlignmentErrorsExtended::m_alignError, m_tkSector_, dataset::name, noSectors_, parameterSet_, and AlCaHLTBitMon_QueryRunRegistry::string.

                                                                                      {
   // Load APEs from the GT and write them to root files similar to the ones from calculateAPE()
 
   if (firstEvent) {
     // Set baseline or calculate APE value?
     const bool setBaseline(parameterSet_.getParameter<bool>("setBaseline"));
 
     edm::ESHandle<AlignmentErrorsExtended> alignmentErrors;
     iSetup.get<TrackerAlignmentErrorExtendedRcd>().get(alignmentErrors);
 
     // Read in baseline file for calculation of APE value (if not setting baseline)
     // Has same format as iterationFile
     const std::string baselineFileName(parameterSet_.getParameter<std::string>("BaselineFile"));
     TFile* baselineFile(nullptr);
     TTree* sectorNameBaselineTree(nullptr);
     if (!setBaseline) {
       std::ifstream baselineFileStream;
       // Check if baseline file exists
       baselineFileStream.open(baselineFileName.c_str());
       if (baselineFileStream.is_open()) {
         baselineFileStream.close();
         baselineFile = new TFile(baselineFileName.c_str(), "READ");
       }
       if (baselineFile) {
         edm::LogInfo("CalculateAPE") << "Baseline file for APE values sucessfully opened";
         baselineFile->GetObject("nameTree;1", sectorNameBaselineTree);
       } else {
         edm::LogWarning("CalculateAPE") << "There is NO baseline file for APE values, so normalized residual width =1 "
                                            "for ideal conditions is assumed";
       }
     }
 
     // Set up root file for default APE values
     const std::string defaultFileName(parameterSet_.getParameter<std::string>("DefaultFile"));
     TFile* defaultFile = new TFile(defaultFileName.c_str(), "RECREATE");
 
     // Naming in the root files has to be iterTreeX to be consistent for the plotting tool
     TTree* defaultTreeX(nullptr);
     TTree* defaultTreeY(nullptr);
     defaultFile->GetObject("iterTreeX;1", defaultTreeX);
     defaultFile->GetObject("iterTreeY;1", defaultTreeY);
     // The same for TTree containing the names of the sectors (no additional check, since always handled exactly as defaultTree)
     TTree* sectorNameTree(nullptr);
     defaultFile->GetObject("nameTree;1", sectorNameTree);
 
     bool firstIter(false);
     if (!defaultTreeX) {  // should be always true in setBaseline mode, since file is recreated
       firstIter = true;
       defaultTreeX = new TTree("iterTreeX", "Tree for default APE x values from GT");
       defaultTreeY = new TTree("iterTreeY", "Tree for default APE y values from GT");
       edm::LogInfo("CalculateAPE") << "First APE iteration (number 0.), create default file with TTree";
       sectorNameTree = new TTree("nameTree", "Tree with names of sectors");
     } else {
       edm::LogWarning("CalculateAPE") << "NOT the first APE iteration (number 0.), is this wanted or forgot to delete "
                                          "old iteration file with TTree?";
     }
 
     // Assign the information stored in the trees to arrays
     double a_defaultSectorX[noSectors_];
     double a_defaultSectorY[noSectors_];
 
     std::string* a_sectorName[noSectors_];
     std::string* a_sectorBaselineName[noSectors_];
     for (auto const& i_sector : m_tkSector_) {
       const unsigned int iSector(i_sector.first);
       const bool pixelSector(i_sector.second.isPixel);
 
       a_defaultSectorX[iSector] = -99.;
       a_defaultSectorY[iSector] = -99.;
 
       a_sectorName[iSector] = nullptr;
       a_sectorBaselineName[iSector] = nullptr;
       std::stringstream ss_sector, ss_sectorSuffixed;
       ss_sector << "Ape_Sector_" << iSector;
       if (!setBaseline && sectorNameBaselineTree) {
         sectorNameBaselineTree->SetBranchAddress(ss_sector.str().c_str(), &a_sectorBaselineName[iSector]);
         sectorNameBaselineTree->GetEntry(0);
       }
 
       if (firstIter) {  // should be always true in setBaseline mode, since file is recreated
         ss_sectorSuffixed << ss_sector.str() << "/D";
         defaultTreeX->Branch(ss_sector.str().c_str(), &a_defaultSectorX[iSector], ss_sectorSuffixed.str().c_str());
         if (pixelSector) {
           defaultTreeY->Branch(ss_sector.str().c_str(), &a_defaultSectorY[iSector], ss_sectorSuffixed.str().c_str());
         }
         sectorNameTree->Branch(ss_sector.str().c_str(), &a_sectorName[iSector], 32000, 00);
       } else {
         defaultTreeX->SetBranchAddress(ss_sector.str().c_str(), &a_defaultSectorX[iSector]);
         defaultTreeX->GetEntry(0);
         if (pixelSector) {
           defaultTreeY->SetBranchAddress(ss_sector.str().c_str(), &a_defaultSectorY[iSector]);
           defaultTreeY->GetEntry(0);
         }
         sectorNameTree->SetBranchAddress(ss_sector.str().c_str(), &a_sectorName[iSector]);
         sectorNameTree->GetEntry(0);
       }
     }
 
     // Check whether sector definitions are identical with the ones of previous iterations and with the ones in baseline file
     for (auto& i_sector : m_tkSector_) {
       const std::string& name(i_sector.second.name);
       if (!firstIter) {
         const std::string& nameLastIter(*a_sectorName[i_sector.first]);
         if (name != nameLastIter) {
           edm::LogError("CalculateAPE") << "Inconsistent sector definition in iterationFile for sector "
                                         << i_sector.first << ",\n"
                                         << "Recent iteration has name \"" << name << "\", while previous had \""
                                         << nameLastIter << "\"\n"
                                         << "...APE calculation stopped. Please check sector definitions in config!\n";
           return;
         }
       } else
         a_sectorName[i_sector.first] = new std::string(name);
       if (!setBaseline && baselineFile) {
         const std::string& nameBaseline(*a_sectorBaselineName[i_sector.first]);
         if (name != nameBaseline) {
           edm::LogError("CalculateAPE") << "Inconsistent sector definition in baselineFile for sector "
                                         << i_sector.first << ",\n"
                                         << "Recent iteration has name \"" << name << "\", while baseline had \""
                                         << nameBaseline << "\"\n"
                                         << "...APE calculation stopped. Please check sector definitions in config!\n";
           return;
         }
       }
     }
 
     // Loop over sectors for calculating getting default APE
     for (auto& i_sector : m_tkSector_) {
       double defaultApeX(0.);
       double defaultApeY(0.);
       unsigned int nModules(0);
       for (auto const& i_rawId : i_sector.second.v_rawId) {
         std::vector<AlignTransformErrorExtended> alignErrors = alignmentErrors->m_alignError;
         for (std::vector<AlignTransformErrorExtended>::const_iterator i_alignError = alignErrors.begin();
              i_alignError != alignErrors.end();
              ++i_alignError) {
           if (i_rawId == i_alignError->rawId()) {
             CLHEP::HepSymMatrix errMatrix = i_alignError->matrix();
             defaultApeX += errMatrix[0][0];
             defaultApeY += errMatrix[1][1];
             nModules++;
           }
         }
       }
       a_defaultSectorX[i_sector.first] = defaultApeX / nModules;
       a_defaultSectorY[i_sector.first] = defaultApeY / nModules;
     }
     sectorNameTree->Fill();
     sectorNameTree->Write("nameTree");
     defaultTreeX->Fill();
     defaultTreeX->Write("iterTreeX");
     defaultTreeY->Fill();
     defaultTreeY->Write("iterTreeY");
 
     defaultFile->Close();
     delete defaultFile;
 
     if (baselineFile) {
       baselineFile->Close();
       delete baselineFile;
     }
 
     firstEvent = false;
   }
 }

void ApeEstimatorSummary::beginJob ( )

overrideprivatevirtual

Reimplemented from edm::one::EDAnalyzerBase.

Definition at line 1057 of file ApeEstimatorSummary.cc.

References bookHists(), getTrackerSectorStructs(), and openInputFile().

                                    {
   this->openInputFile();
 
   this->getTrackerSectorStructs();
 
   this->bookHists();
 }

void ApeEstimatorSummary::bookHists ( )

private

Definition at line 204 of file ApeEstimatorSummary.cc.

References m_tkSector_, and residualErrorBinning().

Referenced by beginJob().

                                     {
   const std::vector<double> v_binX(this->residualErrorBinning());
   for (auto& i_sector : m_tkSector_) {
     i_sector.second.WeightX = new TH1F("h_weightX",
                                        "relative weight w_{x}/w_{tot,x};#sigma_{x}  [#mum];w_{x}/w_{tot,x}",
                                        v_binX.size() - 1,
                                        &(v_binX[0]));
     i_sector.second.MeanX = new TH1F("h_meanX",
                                      "residual mean <r_{x}/#sigma_{r,x}>;#sigma_{x}  [#mum];<r_{x}/#sigma_{r,x}>",
                                      v_binX.size() - 1,
                                      &(v_binX[0]));
     i_sector.second.RmsX = new TH1F("h_rmsX",
                                     "residual rms RMS(r_{x}/#sigma_{r,x});#sigma_{x}  [#mum];RMS(r_{x}/#sigma_{r,x})",
                                     v_binX.size() - 1,
                                     &(v_binX[0]));
     i_sector.second.FitMeanX1 = new TH1F(
         "h_fitMeanX1", "fitted residual mean #mu_{x};#sigma_{x}  [#mum];#mu_{x}", v_binX.size() - 1, &(v_binX[0]));
     i_sector.second.ResidualWidthX1 = new TH1F("h_residualWidthX1",
                                                "residual width #Delta_{x};#sigma_{x}  [#mum];#Delta_{x}",
                                                v_binX.size() - 1,
                                                &(v_binX[0]));
     i_sector.second.CorrectionX1 = new TH1F("h_correctionX1",
                                             "correction to APE_{x};#sigma_{x}  [#mum];#Delta#sigma_{align,x}  [#mum]",
                                             v_binX.size() - 1,
                                             &(v_binX[0]));
     i_sector.second.FitMeanX2 = new TH1F(
         "h_fitMeanX2", "fitted residual mean #mu_{x};#sigma_{x}  [#mum];#mu_{x}", v_binX.size() - 1, &(v_binX[0]));
     i_sector.second.ResidualWidthX2 = new TH1F("h_residualWidthX2",
                                                "residual width #Delta_{x};#sigma_{x}  [#mum];#Delta_{x}",
                                                v_binX.size() - 1,
                                                &(v_binX[0]));
     i_sector.second.CorrectionX2 = new TH1F("h_correctionX2",
                                             "correction to APE_{x};#sigma_{x}  [#mum];#Delta#sigma_{align,x}  [#mum]",
                                             v_binX.size() - 1,
                                             &(v_binX[0]));
 
     if (i_sector.second.isPixel) {
       i_sector.second.WeightY = new TH1F("h_weightY",
                                          "relative weight w_{y}/w_{tot,y};#sigma_{y}  [#mum];w_{y}/w_{tot,y}",
                                          v_binX.size() - 1,
                                          &(v_binX[0]));
       i_sector.second.MeanY = new TH1F("h_meanY",
                                        "residual mean <r_{y}/#sigma_{r,y}>;#sigma_{y}  [#mum];<r_{y}/#sigma_{r,y}>",
                                        v_binX.size() - 1,
                                        &(v_binX[0]));
       i_sector.second.RmsY = new TH1F("h_rmsY",
                                       "residual rms RMS(r_{y}/#sigma_{r,y});#sigma_{y}  [#mum];RMS(r_{y}/#sigma_{r,y})",
                                       v_binX.size() - 1,
                                       &(v_binX[0]));
       i_sector.second.FitMeanY1 = new TH1F(
           "h_fitMeanY1", "fitted residual mean #mu_{y};#sigma_{y}  [#mum];#mu_{y}", v_binX.size() - 1, &(v_binX[0]));
       i_sector.second.ResidualWidthY1 = new TH1F("h_residualWidthY1",
                                                  "residual width #Delta_{y};#sigma_{y}  [#mum];#Delta_{y}",
                                                  v_binX.size() - 1,
                                                  &(v_binX[0]));
       i_sector.second.CorrectionY1 = new TH1F("h_correctionY1",
                                               "correction to APE_{y};#sigma_{y}  [#mum];#Delta#sigma_{align,y}  [#mum]",
                                               v_binX.size() - 1,
                                               &(v_binX[0]));
       i_sector.second.FitMeanY2 = new TH1F(
           "h_fitMeanY2", "fitted residual mean #mu_{y};#sigma_{y}  [#mum];#mu_{y}", v_binX.size() - 1, &(v_binX[0]));
       i_sector.second.ResidualWidthY2 = new TH1F("h_residualWidthY2",
                                                  "residual width #Delta_{y};#sigma_{y}  [#mum];#Delta_{y}",
                                                  v_binX.size() - 1,
                                                  &(v_binX[0]));
       i_sector.second.CorrectionY2 = new TH1F("h_correctionY2",
                                               "correction to APE_{y};#sigma_{y}  [#mum];#Delta#sigma_{align,y}  [#mum]",
                                               v_binX.size() - 1,
                                               &(v_binX[0]));
     }
   }
 }

void ApeEstimatorSummary::calculateApe ( )

private

Definition at line 322 of file ApeEstimatorSummary.cc.

References Abs(), alignBH_cfg::fixed, edm::ParameterSet::getParameter(), edm::detail::isnan(), align_cfg::iteration, HIPAlignmentAlgorithm_cfi::iterationFile, LogDebug, m_tkSector_, dataset::name, noSectors_, parameterSet_, mathSSE::sqrt(), AlCaHLTBitMon_QueryRunRegistry::string, wEntries, wEntriesOverSigmaX2, wInvalid, wUnity, anotherprimaryvertexanalyzer_cfi::xMax, anotherprimaryvertexanalyzer_cfi::xMin, CMSBoostedTauSeedingParameters_cfi::yMax, and CMSBoostedTauSeedingParameters_cfi::yMin.

Referenced by endJob().

                                        {
   // Set baseline or calculate APE value?
   const bool setBaseline(parameterSet_.getParameter<bool>("setBaseline"));
 
   // Read in baseline file for calculation of APE value (if not setting baseline)
   // Has same format as iterationFile
   const std::string baselineFileName(parameterSet_.getParameter<std::string>("BaselineFile"));
   TFile* baselineFile(nullptr);
   TTree* baselineTreeX(nullptr);
   TTree* baselineTreeY(nullptr);
   TTree* sectorNameBaselineTree(nullptr);
   if (!setBaseline) {
     std::ifstream baselineFileStream;
     // Check if baseline file exists
     baselineFileStream.open(baselineFileName.c_str());
     if (baselineFileStream.is_open()) {
       baselineFileStream.close();
       baselineFile = new TFile(baselineFileName.c_str(), "READ");
     }
     if (baselineFile) {
       edm::LogInfo("CalculateAPE") << "Baseline file for APE values sucessfully opened";
       baselineFile->GetObject("iterTreeX;1", baselineTreeX);
       baselineFile->GetObject("iterTreeY;1", baselineTreeY);
       baselineFile->GetObject("nameTree;1", sectorNameBaselineTree);
     } else {
       edm::LogWarning("CalculateAPE") << "There is NO baseline file for APE values, so normalized residual width =1 "
                                          "for ideal conditions is assumed";
     }
   }
 
   // Set up root file for iterations on APE value (or for setting baseline in setBaseline mode)
   const std::string iterationFileName(setBaseline ? baselineFileName
                                                   : parameterSet_.getParameter<std::string>("IterationFile"));
   // For iterations, updates are needed to not overwrite the iterations before
   TFile* iterationFile = new TFile(iterationFileName.c_str(), setBaseline ? "RECREATE" : "UPDATE");
 
   // Set up TTree for iterative APE values on first pass (first iteration) or read from file (further iterations)
   TTree* iterationTreeX(nullptr);
   TTree* iterationTreeY(nullptr);
   iterationFile->GetObject("iterTreeX;1", iterationTreeX);
   iterationFile->GetObject("iterTreeY;1", iterationTreeY);
   // The same for TTree containing the names of the sectors (no additional check, since always handled exactly as iterationTree)
   TTree* sectorNameTree(nullptr);
   iterationFile->GetObject("nameTree;1", sectorNameTree);
 
   bool firstIter(false);
   if (!iterationTreeX) {  // should be always true in setBaseline mode, since file is recreated
     firstIter = true;
     if (!setBaseline) {
       iterationTreeX = new TTree("iterTreeX", "Tree for APE x values of all iterations");
       iterationTreeY = new TTree("iterTreeY", "Tree for APE y values of all iterations");
       edm::LogInfo("CalculateAPE") << "First APE iteration (number 0.), create iteration file with TTree";
       sectorNameTree = new TTree("nameTree", "Tree with names of sectors");
     } else {
       iterationTreeX = new TTree("iterTreeX", "Tree for baseline x values of normalized residual width");
       iterationTreeY = new TTree("iterTreeY", "Tree for baseline y values of normalized residual width");
       edm::LogInfo("CalculateAPE") << "Set baseline, create baseline file with TTree";
       sectorNameTree = new TTree("nameTree", "Tree with names of sectors");
     }
   } else {
     const unsigned int iteration(iterationTreeX->GetEntries());
     edm::LogWarning("CalculateAPE") << "NOT the first APE iteration (number 0.) but the " << iteration
                                     << ". one, is this wanted or forgot to delete old iteration file with TTree?";
   }
 
   // Assign the information stored in the trees to arrays
   double a_apeSectorX[noSectors_];
   double a_apeSectorY[noSectors_];
   double a_baselineSectorX[noSectors_];
   double a_baselineSectorY[noSectors_];
 
   std::string* a_sectorName[noSectors_];
   std::string* a_sectorBaselineName[noSectors_];
   for (auto const& i_sector : m_tkSector_) {
     const unsigned int iSector(i_sector.first);
     const bool pixelSector(i_sector.second.isPixel);
     a_apeSectorX[iSector] = 99.;
     a_apeSectorY[iSector] = 99.;
     a_baselineSectorX[iSector] = -99.;
     a_baselineSectorY[iSector] = -99.;
 
     a_sectorName[iSector] = nullptr;
     a_sectorBaselineName[iSector] = nullptr;
     std::stringstream ss_sector, ss_sectorSuffixed;
     ss_sector << "Ape_Sector_" << iSector;
     if (!setBaseline && baselineTreeX) {
       baselineTreeX->SetBranchAddress(ss_sector.str().c_str(), &a_baselineSectorX[iSector]);
       baselineTreeX->GetEntry(0);
       if (pixelSector) {
         baselineTreeY->SetBranchAddress(ss_sector.str().c_str(), &a_baselineSectorY[iSector]);
         baselineTreeY->GetEntry(0);
       }
       sectorNameBaselineTree->SetBranchAddress(ss_sector.str().c_str(), &a_sectorBaselineName[iSector]);
       sectorNameBaselineTree->GetEntry(0);
     } else {
       // Set default ideal normalized residual width to 1
       a_baselineSectorX[iSector] = 1.;
       a_baselineSectorY[iSector] = 1.;
     }
     if (firstIter) {  // should be always true in setBaseline mode, since file is recreated
       ss_sectorSuffixed << ss_sector.str() << "/D";
       iterationTreeX->Branch(ss_sector.str().c_str(), &a_apeSectorX[iSector], ss_sectorSuffixed.str().c_str());
       if (pixelSector) {
         iterationTreeY->Branch(ss_sector.str().c_str(), &a_apeSectorY[iSector], ss_sectorSuffixed.str().c_str());
       }
       sectorNameTree->Branch(ss_sector.str().c_str(), &a_sectorName[iSector], 32000, 00);
     } else {
       iterationTreeX->SetBranchAddress(ss_sector.str().c_str(), &a_apeSectorX[iSector]);
       iterationTreeX->GetEntry(iterationTreeX->GetEntries() - 1);
       if (pixelSector) {
         iterationTreeY->SetBranchAddress(ss_sector.str().c_str(), &a_apeSectorY[iSector]);
         iterationTreeY->GetEntry(iterationTreeY->GetEntries() - 1);
       }
       sectorNameTree->SetBranchAddress(ss_sector.str().c_str(), &a_sectorName[iSector]);
       sectorNameTree->GetEntry(0);
     }
   }
 
   // Check whether sector definitions are identical with the ones of previous iterations and with the ones in baseline file
   for (auto& i_sector : m_tkSector_) {
     const std::string& name(i_sector.second.name);
     if (!firstIter) {
       const std::string& nameLastIter(*a_sectorName[i_sector.first]);
       if (name != nameLastIter) {
         edm::LogError("CalculateAPE") << "Inconsistent sector definition in iterationFile for sector " << i_sector.first
                                       << ",\n"
                                       << "Recent iteration has name \"" << name << "\", while previous had \""
                                       << nameLastIter << "\"\n"
                                       << "...APE calculation stopped. Please check sector definitions in config!\n";
         return;
       }
     } else {
       a_sectorName[i_sector.first] = new std::string(name);
     }
     if (!setBaseline && baselineFile) {
       const std::string& nameBaseline(*a_sectorBaselineName[i_sector.first]);
       if (name != nameBaseline) {
         edm::LogError("CalculateAPE") << "Inconsistent sector definition in baselineFile for sector " << i_sector.first
                                       << ",\n"
                                       << "Recent iteration has name \"" << name << "\", while baseline had \""
                                       << nameBaseline << "\"\n"
                                       << "...APE calculation stopped. Please check sector definitions in config!\n";
         return;
       }
     }
   }
 
   // Set up text file for writing out APE values per module
   std::ofstream apeOutputFile;
   if (!setBaseline) {
     const std::string apeOutputFileName(parameterSet_.getParameter<std::string>("ApeOutputFile"));
     apeOutputFile.open(apeOutputFileName.c_str());
     if (apeOutputFile.is_open()) {
       edm::LogInfo("CalculateAPE") << "Text file for writing APE values successfully opened";
     } else {
       edm::LogError("CalculateAPE") << "Text file for writing APE values NOT opened,\n"
                                     << "...APE calculation stopped. Please check path of text file name in config:\n"
                                     << "\t" << apeOutputFileName;
       return;
     }
   }
 
   // Loop over sectors for calculating APE
   const std::string apeWeightName(parameterSet_.getParameter<std::string>("apeWeight"));
   ApeWeight apeWeight(wInvalid);
   if (apeWeightName == "unity")
     apeWeight = wUnity;
   else if (apeWeightName == "entries")
     apeWeight = wEntries;
   else if (apeWeightName == "entriesOverSigmaX2")
     apeWeight = wEntriesOverSigmaX2;
   if (apeWeight == wInvalid) {
     edm::LogError("CalculateAPE") << "Invalid parameter 'apeWeight' in cfg file: \"" << apeWeightName
                                   << "\"\nimplemented apeWeights are \"unity\", \"entries\", \"entriesOverSigmaX2\""
                                   << "\n...APE calculation stopped.";
     return;
   }
   const double minHitsPerInterval(parameterSet_.getParameter<double>("minHitsPerInterval"));
   const double sigmaFactorFit(parameterSet_.getParameter<double>("sigmaFactorFit"));
   const double correctionScaling(parameterSet_.getParameter<double>("correctionScaling"));
   const bool smoothIteration(parameterSet_.getParameter<bool>("smoothIteration"));
   const double smoothFraction(parameterSet_.getParameter<double>("smoothFraction"));
   if (smoothFraction <= 0. || smoothFraction > 1.) {
     edm::LogError("CalculateAPE") << "Incorrect parameter in cfg file,"
                                   << "\nsmoothFraction has to be in [0,1], but is " << smoothFraction
                                   << "\n...APE calculation stopped.";
     return;
   }
   for (auto& i_sector : m_tkSector_) {
     typedef std::pair<double, double> Error2AndResidualWidth2PerBin;
     typedef std::pair<double, Error2AndResidualWidth2PerBin> WeightAndResultsPerBin;
     std::vector<WeightAndResultsPerBin> v_weightAndResultsPerBinX;
     std::vector<WeightAndResultsPerBin> v_weightAndResultsPerBinY;
 
     double baselineWidthX2(a_baselineSectorX[i_sector.first]);
     double baselineWidthY2(a_baselineSectorY[i_sector.first]);
 
     // Loop over residual error bins to calculate APE for every bin
     for (auto const& i_errBins : i_sector.second.m_binnedHists) {
       std::map<std::string, TH1*> mHists = i_errBins.second;
 
       double entriesX = mHists["sigmaX"]->GetEntries();
       double meanSigmaX = mHists["sigmaX"]->GetMean();
 
       // Fitting Parameters
       double xMin = mHists["norResX"]->GetXaxis()->GetXmin();
       double xMax = mHists["norResX"]->GetXaxis()->GetXmax();
       double integralX = mHists["norResX"]->Integral();
       double meanX = mHists["norResX"]->GetMean();
       double rmsX = mHists["norResX"]->GetRMS();
       double maximumX = mHists["norResX"]->GetBinContent(mHists["norResX"]->GetMaximumBin());
 
       // First Gaus Fit
       TF1 funcX_1("mygausX", "gaus", xMin, xMax);
       funcX_1.SetParameters(maximumX, meanX, rmsX);
       TString fitOpt("ILERQ");  //TString fitOpt("IMR"); ("IRLL"); ("IRQ");
       if (integralX > minHitsPerInterval) {
         if (mHists["norResX"]->Fit(&funcX_1, fitOpt)) {
           edm::LogWarning("CalculateAPE") << "Fit1 did not work: " << mHists["norResX"]->Fit(&funcX_1, fitOpt);
           continue;
         }
         LogDebug("CalculateAPE") << "FitResultX1\t" << mHists["norResX"]->Fit(&funcX_1, fitOpt) << "\n";
       }
       double meanX_1 = funcX_1.GetParameter(1);
       double sigmaX_1 = funcX_1.GetParameter(2);
 
       // Second gaus fit
       TF1 funcX_2("mygausX2",
                   "gaus",
                   meanX_1 - sigmaFactorFit * TMath::Abs(sigmaX_1),
                   meanX_1 + sigmaFactorFit * TMath::Abs(sigmaX_1));
       funcX_2.SetParameters(funcX_1.GetParameter(0), meanX_1, sigmaX_1);
       if (integralX > minHitsPerInterval) {
         if (mHists["norResX"]->Fit(&funcX_2, fitOpt)) {
           edm::LogWarning("CalculateAPE") << "Fit2 did not work for x : " << mHists["norResX"]->Fit(&funcX_2, fitOpt);
           continue;
         }
         LogDebug("CalculateAPE") << "FitResultX2\t" << mHists["norResX"]->Fit(&funcX_2, fitOpt) << "\n";
       }
       double meanX_2 = funcX_2.GetParameter(1);
       double sigmaX_2 = funcX_2.GetParameter(2);
 
       // Now the same for y coordinate
       double entriesY(0.);
       double meanSigmaY(0.);
       if (i_sector.second.isPixel) {
         entriesY = mHists["sigmaY"]->GetEntries();
         meanSigmaY = mHists["sigmaY"]->GetMean();
       }
 
       double meanY_1(0.);
       double sigmaY_1(0.);
       double meanY_2(0.);
       double sigmaY_2(0.);
       double meanY(0.);
       double rmsY(0.);
       if (i_sector.second.isPixel) {
         // Fitting Parameters
         double yMin = mHists["norResY"]->GetXaxis()->GetXmin();
         double yMax = mHists["norResY"]->GetXaxis()->GetXmax();
         double integralY = mHists["norResY"]->Integral();
         meanY = mHists["norResY"]->GetMean();
         rmsY = mHists["norResY"]->GetRMS();
         double maximumY = mHists["norResY"]->GetBinContent(mHists["norResY"]->GetMaximumBin());
 
         // First Gaus Fit
         TF1 funcY_1("mygausY", "gaus", yMin, yMax);
         funcY_1.SetParameters(maximumY, meanY, rmsY);
         if (integralY > minHitsPerInterval) {
           if (mHists["norResY"]->Fit(&funcY_1, fitOpt)) {
             edm::LogWarning("CalculateAPE") << "Fit1 did not work: " << mHists["norResY"]->Fit(&funcY_1, fitOpt);
             continue;
           }
           LogDebug("CalculateAPE") << "FitResultY1\t" << mHists["norResY"]->Fit(&funcY_1, fitOpt) << "\n";
         }
         meanY_1 = funcY_1.GetParameter(1);
         sigmaY_1 = funcY_1.GetParameter(2);
 
         // Second gaus fit
         TF1 funcY_2("mygausY2",
                     "gaus",
                     meanY_1 - sigmaFactorFit * TMath::Abs(sigmaY_1),
                     meanY_1 + sigmaFactorFit * TMath::Abs(sigmaY_1));
         funcY_2.SetParameters(funcY_1.GetParameter(0), meanY_1, sigmaY_1);
         if (integralY > minHitsPerInterval) {
           if (mHists["norResY"]->Fit(&funcY_2, fitOpt)) {
             edm::LogWarning("CalculateAPE") << "Fit2 did not work for y : " << mHists["norResY"]->Fit(&funcY_2, fitOpt);
             continue;
           }
           LogDebug("CalculateAPE") << "FitResultY2\t" << mHists["norResY"]->Fit(&funcY_2, fitOpt) << "\n";
         }
         meanY_2 = funcY_2.GetParameter(1);
         sigmaY_2 = funcY_2.GetParameter(2);
       }
 
       // Fill histograms
       double fitMeanX_1(meanX_1), fitMeanX_2(meanX_2);
       double residualWidthX_1(sigmaX_1), residualWidthX_2(sigmaX_2);
       double fitMeanY_1(meanY_1), fitMeanY_2(meanY_2);
       double residualWidthY_1(sigmaY_1), residualWidthY_2(sigmaY_2);
 
       double correctionX2_1(-0.0010), correctionX2_2(-0.0010);
       double correctionY2_1(-0.0010), correctionY2_2(-0.0010);
       correctionX2_1 = meanSigmaX * meanSigmaX * (residualWidthX_1 * residualWidthX_1 - baselineWidthX2);
       correctionX2_2 = meanSigmaX * meanSigmaX * (residualWidthX_2 * residualWidthX_2 - baselineWidthX2);
       if (i_sector.second.isPixel) {
         correctionY2_1 = meanSigmaY * meanSigmaY * (residualWidthY_1 * residualWidthY_1 - baselineWidthY2);
         correctionY2_2 = meanSigmaY * meanSigmaY * (residualWidthY_2 * residualWidthY_2 - baselineWidthY2);
       }
 
       double correctionX_1 = correctionX2_1 >= 0. ? std::sqrt(correctionX2_1) : -std::sqrt(-correctionX2_1);
       double correctionX_2 = correctionX2_2 >= 0. ? std::sqrt(correctionX2_2) : -std::sqrt(-correctionX2_2);
       double correctionY_1 = correctionY2_1 >= 0. ? std::sqrt(correctionY2_1) : -std::sqrt(-correctionY2_1);
       double correctionY_2 = correctionY2_2 >= 0. ? std::sqrt(correctionY2_2) : -std::sqrt(-correctionY2_2);
       // Meanwhile, this got very bad default values, or? (negative corrections allowed)
       if (isnan(correctionX_1))
         correctionX_1 = -0.0010;
       if (isnan(correctionX_2))
         correctionX_2 = -0.0010;
       if (isnan(correctionY_1))
         correctionY_1 = -0.0010;
       if (isnan(correctionY_2))
         correctionY_2 = -0.0010;
 
       if (entriesX < minHitsPerInterval) {
         meanX = 0.;
         rmsX = -0.0010;
         fitMeanX_1 = 0.;
         correctionX_1 = residualWidthX_1 = -0.0010;
         fitMeanX_2 = 0.;
         correctionX_2 = residualWidthX_2 = -0.0010;
       }
 
       if (entriesY < minHitsPerInterval) {
         meanY = 0.;
         rmsY = -0.0010;
         fitMeanY_1 = 0.;
         correctionY_1 = residualWidthY_1 = -0.0010;
         fitMeanY_2 = 0.;
         correctionY_2 = residualWidthY_2 = -0.0010;
       }
 
       i_sector.second.MeanX->SetBinContent(i_errBins.first, meanX);
       i_sector.second.RmsX->SetBinContent(i_errBins.first, rmsX);
 
       i_sector.second.FitMeanX1->SetBinContent(i_errBins.first, fitMeanX_1);
       i_sector.second.ResidualWidthX1->SetBinContent(i_errBins.first, residualWidthX_1);
       i_sector.second.CorrectionX1->SetBinContent(i_errBins.first, correctionX_1 * 10000.);
 
       i_sector.second.FitMeanX2->SetBinContent(i_errBins.first, fitMeanX_2);
       i_sector.second.ResidualWidthX2->SetBinContent(i_errBins.first, residualWidthX_2);
       i_sector.second.CorrectionX2->SetBinContent(i_errBins.first, correctionX_2 * 10000.);
 
       if (i_sector.second.isPixel) {
         i_sector.second.MeanY->SetBinContent(i_errBins.first, meanY);
         i_sector.second.RmsY->SetBinContent(i_errBins.first, rmsY);
 
         i_sector.second.FitMeanY1->SetBinContent(i_errBins.first, fitMeanY_1);
         i_sector.second.ResidualWidthY1->SetBinContent(i_errBins.first, residualWidthY_1);
         i_sector.second.CorrectionY1->SetBinContent(i_errBins.first, correctionY_1 * 10000.);
 
         i_sector.second.FitMeanY2->SetBinContent(i_errBins.first, fitMeanY_2);
         i_sector.second.ResidualWidthY2->SetBinContent(i_errBins.first, residualWidthY_2);
         i_sector.second.CorrectionY2->SetBinContent(i_errBins.first, correctionY_2 * 10000.);
       }
 
       // Use result for bin only when entries>=minHitsPerInterval
       if (entriesX < minHitsPerInterval && entriesY < minHitsPerInterval)
         continue;
 
       double weightX(0.);
       double weightY(0.);
       if (apeWeight == wUnity) {
         weightX = 1.;
         weightY = 1.;
       } else if (apeWeight == wEntries) {
         weightX = entriesX;
         weightY = entriesY;
       } else if (apeWeight == wEntriesOverSigmaX2) {
         weightX = entriesX / (meanSigmaX * meanSigmaX);
         weightY = entriesY / (meanSigmaY * meanSigmaY);
       }
 
       const Error2AndResidualWidth2PerBin error2AndResidualWidth2PerBinX(meanSigmaX * meanSigmaX,
                                                                          residualWidthX_1 * residualWidthX_1);
       const WeightAndResultsPerBin weightAndResultsPerBinX(weightX, error2AndResidualWidth2PerBinX);
       if (!(entriesX < minHitsPerInterval)) {
         //Fill absolute weights
         i_sector.second.WeightX->SetBinContent(i_errBins.first, weightX);
         v_weightAndResultsPerBinX.push_back(weightAndResultsPerBinX);
       }
 
       const Error2AndResidualWidth2PerBin error2AndResidualWidth2PerBinY(meanSigmaY * meanSigmaY,
                                                                          residualWidthY_1 * residualWidthY_1);
       const WeightAndResultsPerBin weightAndResultsPerBinY(weightY, error2AndResidualWidth2PerBinY);
       if (!(entriesY < minHitsPerInterval)) {
         //Fill absolute weights
         i_sector.second.WeightY->SetBinContent(i_errBins.first, weightY);
         v_weightAndResultsPerBinY.push_back(weightAndResultsPerBinY);
       }
     }
 
     // Do the final calculations
 
     if (v_weightAndResultsPerBinX.empty()) {
       edm::LogError("CalculateAPE") << "NO error interval of sector " << i_sector.first
                                     << " has a valid x APE calculated,\n...so cannot set APE";
       continue;
     }
 
     if (i_sector.second.isPixel && v_weightAndResultsPerBinY.empty()) {
       edm::LogError("CalculateAPE") << "NO error interval of sector " << i_sector.first
                                     << " has a valid y APE calculated,\n...so cannot set APE";
       continue;
     }
 
     double correctionX2(999.);
     double correctionY2(999.);
 
     // Get sum of all weights
     double weightSumX(0.);
     for (auto const& i_apeBin : v_weightAndResultsPerBinX) {
       weightSumX += i_apeBin.first;
     }
     i_sector.second.WeightX->Scale(1 / weightSumX);
     double weightSumY(0.);
     if (i_sector.second.isPixel) {
       for (auto const& i_apeBin : v_weightAndResultsPerBinY) {
         weightSumY += i_apeBin.first;
       }
       i_sector.second.WeightY->Scale(1 / weightSumY);
     }
 
     if (!setBaseline) {
       // Calculate weighted mean
       bool firstIntervalX(true);
       for (auto const& i_apeBin : v_weightAndResultsPerBinX) {
         if (firstIntervalX) {
           correctionX2 = i_apeBin.first * i_apeBin.second.first * (i_apeBin.second.second - baselineWidthX2);
           firstIntervalX = false;
         } else {
           correctionX2 += i_apeBin.first * i_apeBin.second.first * (i_apeBin.second.second - baselineWidthX2);
         }
       }
       correctionX2 = correctionX2 / weightSumX;
     } else {
       double numeratorX(0.), denominatorX(0.);
       for (auto const& i_apeBin : v_weightAndResultsPerBinX) {
         numeratorX += i_apeBin.first * i_apeBin.second.first * i_apeBin.second.second;
         denominatorX += i_apeBin.first * i_apeBin.second.first;
       }
       correctionX2 = numeratorX / denominatorX;
     }
 
     if (i_sector.second.isPixel) {
       if (!setBaseline) {
         // Calculate weighted mean
         bool firstIntervalY(true);
         for (auto const& i_apeBin : v_weightAndResultsPerBinY) {
           if (firstIntervalY) {
             correctionY2 = i_apeBin.first * i_apeBin.second.first * (i_apeBin.second.second - baselineWidthY2);
             firstIntervalY = false;
           } else {
             correctionY2 += i_apeBin.first * i_apeBin.second.first * (i_apeBin.second.second - baselineWidthY2);
           }
         }
         correctionY2 = correctionY2 / weightSumY;
       } else {
         double numeratorY(0.), denominatorY(0.);
         for (auto const& i_apeBin : v_weightAndResultsPerBinY) {
           numeratorY += i_apeBin.first * i_apeBin.second.first * i_apeBin.second.second;
           denominatorY += i_apeBin.first * i_apeBin.second.first;
         }
         correctionY2 = numeratorY / denominatorY;
       }
     }
 
     if (!setBaseline) {
       // Calculate updated squared APE of current iteration
       double apeX2(999.);
       double apeY2(999.);
 
       // old APE value from last iteration
       if (firstIter) {
         apeX2 = 0.;
         apeY2 = 0.;
       } else {
         apeX2 = a_apeSectorX[i_sector.first];
         apeY2 = a_apeSectorY[i_sector.first];
       }
       const double apeX2old = apeX2;
       const double apeY2old = apeY2;
 
       // scale APE Correction with value given in cfg (not if smoothed iteration is used)
       edm::LogInfo("CalculateAPE") << "Unscaled correction x for sector " << i_sector.first << " is "
                                    << (correctionX2 > 0. ? +1. : -1.) * std::sqrt(std::fabs(correctionX2));
       if (!smoothIteration || firstIter)
         correctionX2 = correctionX2 * correctionScaling * correctionScaling;
       if (i_sector.second.isPixel) {
         edm::LogInfo("CalculateAPE") << "Unscaled correction y for sector " << i_sector.first << " is "
                                      << (correctionY2 > 0. ? +1. : -1.) * std::sqrt(std::fabs(correctionY2));
         if (!smoothIteration || firstIter)
           correctionY2 = correctionY2 * correctionScaling * correctionScaling;
       }
 
       // new APE value
       // smooth iteration or not?
       if (apeX2 + correctionX2 < 0.)
         correctionX2 = -apeX2;
       if (apeY2 + correctionY2 < 0.)
         correctionY2 = -apeY2;
       const double apeX2new(apeX2old + correctionX2);
       const double apeY2new(apeY2old + correctionY2);
       if (!smoothIteration || firstIter) {
         apeX2 = apeX2new;
         apeY2 = apeY2new;
       } else {
         const double apeXtmp = smoothFraction * std::sqrt(apeX2new) + (1 - smoothFraction) * std::sqrt(apeX2old);
         const double apeYtmp = smoothFraction * std::sqrt(apeY2new) + (1 - smoothFraction) * std::sqrt(apeY2old);
         apeX2 = apeXtmp * apeXtmp;
         apeY2 = apeYtmp * apeYtmp;
       }
       if (apeX2 < 0. || apeY2 < 0.)
         edm::LogError("CalculateAPE") << "\n\n\tBad APE, but why???\n\n\n";
       a_apeSectorX[i_sector.first] = apeX2;
       a_apeSectorY[i_sector.first] = apeY2;
 
       // Set the calculated APE spherical for all modules of strip sectors
       const double apeX(std::sqrt(apeX2));
       const double apeY(std::sqrt(apeY2));
       const double apeZ(std::sqrt(0.5 * (apeX2 + apeY2)));
       for (auto const& i_rawId : i_sector.second.v_rawId) {
         if (i_sector.second.isPixel) {
           apeOutputFile << i_rawId << " " << std::fixed << std::setprecision(5) << apeX << " " << apeY << " " << apeZ
                         << "\n";
         } else {
           apeOutputFile << i_rawId << " " << std::fixed << std::setprecision(5) << apeX << " " << apeX << " " << apeX
                         << "\n";
         }
       }
     } else {  // In setBaseline mode, just fill estimated mean value of residual width
       a_apeSectorX[i_sector.first] = correctionX2;
       a_apeSectorY[i_sector.first] = correctionY2;
     }
   }
   if (!setBaseline)
     apeOutputFile.close();
 
   iterationTreeX->Fill();
   iterationTreeX->Write("iterTreeX",
                         TObject::kOverwrite);  // TObject::kOverwrite needed to not produce another iterTreeX;2
   iterationTreeY->Fill();
   iterationTreeY->Write("iterTreeY",
                         TObject::kOverwrite);  // TObject::kOverwrite needed to not produce another iterTreeY;2
   if (firstIter) {
     sectorNameTree->Fill();
     sectorNameTree->Write("nameTree");
   }
   iterationFile->Close();
   delete iterationFile;
 
   if (baselineFile) {
     baselineFile->Close();
     delete baselineFile;
   }
 }

void ApeEstimatorSummary::endJob ( )

overrideprivatevirtual

Reimplemented from edm::one::EDAnalyzerBase.

Definition at line 1066 of file ApeEstimatorSummary.cc.

References calculateApe(), DEFINE_FWK_MODULE, and writeHists().

Referenced by o2olib.O2ORunMgr::executeJob().

                                  {
   this->calculateApe();
 
   this->writeHists();
 }

void ApeEstimatorSummary::getTrackerSectorStructs ( )

private

Definition at line 128 of file ApeEstimatorSummary.cc.

References TrackerSectorStruct::EntriesX, TrackerSectorStruct::EntriesY, mps_splice::entry, inputFile_, TrackerSectorStruct::isPixel, TrackerSectorStruct::m_binnedHists, m_tkSector_, TrackerSectorStruct::name, TrackerSectorStruct::Name, noSectors_, and TrackerSectorStruct::v_rawId.

Referenced by beginJob().

                                                   {
   // At present first of the plugins registered in TFileService needs to be the one containing the normalized residual histos per sector per error bin
   TString pluginName(inputFile_->GetListOfKeys()->At(0)->GetName());
 
   pluginName += "/";
   TDirectory *sectorDir(nullptr), *intervalDir(nullptr);
   bool sectorBool(true);
   unsigned int iSector(1);
   for (; sectorBool; ++iSector) {
     std::stringstream sectorName, fullSectorName;
     sectorName << "Sector_" << iSector << "/";
     fullSectorName << pluginName << sectorName.str();
     TString fullName(fullSectorName.str().c_str());
     inputFile_->cd();
     sectorDir = (TDirectory*)inputFile_->TDirectory::GetDirectory(fullName);
     if (sectorDir) {
       TrackerSectorStruct tkSector;
       sectorDir->GetObject("z_name;1", tkSector.Name);
       tkSector.name = tkSector.Name->GetTitle();
       bool intervalBool(true);
       for (unsigned int iInterval(1); intervalBool; ++iInterval) {
         std::stringstream intervalName, fullIntervalName;
         intervalName << "Interval_" << iInterval << "/";
         fullIntervalName << fullSectorName.str() << intervalName.str();
         fullName = fullIntervalName.str().c_str();
         intervalDir = (TDirectory*)inputFile_->TDirectory::GetDirectory(fullName);
         if (intervalDir) {
           intervalDir->GetObject("h_sigmaX;1", tkSector.m_binnedHists[iInterval]["sigmaX"]);
           intervalDir->GetObject("h_norResX;1", tkSector.m_binnedHists[iInterval]["norResX"]);
           intervalDir->GetObject("h_sigmaY;1", tkSector.m_binnedHists[iInterval]["sigmaY"]);
           intervalDir->GetObject("h_norResY;1", tkSector.m_binnedHists[iInterval]["norResY"]);
           if (tkSector.m_binnedHists[iInterval]["sigmaY"] && tkSector.m_binnedHists[iInterval]["norResY"]) {
             tkSector.isPixel = true;
           }
         } else {
           intervalBool = false;
           if (iSector == 1)
             edm::LogInfo("CalculateAPE") << "There are " << iInterval - 1
                                          << " intervals per sector defined in input file";
         }
       }
       TDirectory* resultsDir(nullptr);
       std::stringstream fullResultName;
       fullResultName << fullSectorName.str() << "Results/";
       fullName = fullResultName.str().c_str();
       resultsDir = (TDirectory*)inputFile_->TDirectory::GetDirectory(fullName);
       if (resultsDir) {
         resultsDir->GetObject("h_entriesX;1", tkSector.EntriesX);
         if (tkSector.isPixel)
           resultsDir->GetObject("h_entriesY;1", tkSector.EntriesY);
         TTree* rawIdTree(nullptr);
         resultsDir->GetObject("rawIdTree", rawIdTree);
         unsigned int rawId(0);
         rawIdTree->SetBranchAddress("RawId", &rawId);
         for (int entry = 0; entry < rawIdTree->GetEntries(); ++entry) {
           rawIdTree->GetEntry(entry);
           // command "hadd" adds entries in TTree, so rawId are existing as often as number of files are added
           bool alreadyAdded(false);
           for (auto const& i_rawId : tkSector.v_rawId) {
             if (rawId == i_rawId)
               alreadyAdded = true;
           }
           if (alreadyAdded)
             break;
           tkSector.v_rawId.push_back(rawId);
         }
       }
       m_tkSector_[iSector] = tkSector;
     } else {
       sectorBool = false;
       edm::LogInfo("CalculateAPE") << "There are " << iSector - 1 << " sectors defined in input file";
     }
   }
   noSectors_ = iSector + 1;
 }

void ApeEstimatorSummary::openInputFile ( )

private

Definition at line 110 of file ApeEstimatorSummary.cc.

References edm::errors::Configuration, Exception, edm::ParameterSet::getParameter(), inputFile_, PATTauDiscriminantCutMultiplexer_cfi::inputFileName, parameterSet_, and AlCaHLTBitMon_QueryRunRegistry::string.

Referenced by beginJob().

                                         {
   const std::string inputFileName(parameterSet_.getParameter<std::string>("InputFile"));
   std::ifstream inputFileStream;
   // Check if baseline file exists
   inputFileStream.open(inputFileName.c_str());
   if (inputFileStream.is_open()) {
     inputFile_ = new TFile(inputFileName.c_str(), "READ");
   }
   if (inputFile_) {
     edm::LogInfo("CalculateAPE") << "Input file from loop over tracks and corresponding hits sucessfully opened";
   } else {
     edm::LogError("CalculateAPE") << "There is NO input file\n"
                                   << "...APE calculation stopped. Please check path of input file name in config:\n"
                                   << "\t" << inputFileName;
     throw edm::Exception(edm::errors::Configuration, "Bad input file name");
   }
 }

std::vector< double > ApeEstimatorSummary::residualErrorBinning ( )

private

Definition at line 277 of file ApeEstimatorSummary.cc.

References m_tkSector_.

Referenced by bookHists().

                                                             {
   std::vector<double> v_binX;
   TH1* EntriesX(m_tkSector_[1].EntriesX);
   for (int iBin = 1; iBin <= EntriesX->GetNbinsX() + 1; ++iBin) {
     v_binX.push_back(EntriesX->GetBinLowEdge(iBin));
   }
   return v_binX;
 }

void ApeEstimatorSummary::writeHists ( )

private

Definition at line 286 of file ApeEstimatorSummary.cc.

References dir, TrackerOfflineValidation_Dqm_cff::dirName, edm::ParameterSet::getParameter(), m_tkSector_, parameterSet_, and AlCaHLTBitMon_QueryRunRegistry::string.

Referenced by endJob().

                                      {
   TFile* resultsFile = new TFile(parameterSet_.getParameter<std::string>("ResultsFile").c_str(), "RECREATE");
   TDirectory* baseDir = resultsFile->mkdir("ApeEstimatorSummary");
   for (auto const& i_sector : m_tkSector_) {
     std::stringstream dirName;
     dirName << "Sector_" << i_sector.first;
     TDirectory* dir = baseDir->mkdir(dirName.str().c_str());
     dir->cd();
 
     i_sector.second.Name->Write();
 
     i_sector.second.WeightX->Write();
     i_sector.second.MeanX->Write();
     i_sector.second.RmsX->Write();
     i_sector.second.FitMeanX1->Write();
     i_sector.second.ResidualWidthX1->Write();
     i_sector.second.CorrectionX1->Write();
     i_sector.second.FitMeanX2->Write();
     i_sector.second.ResidualWidthX2->Write();
     i_sector.second.CorrectionX2->Write();
 
     if (i_sector.second.isPixel) {
       i_sector.second.WeightY->Write();
       i_sector.second.MeanY->Write();
       i_sector.second.RmsY->Write();
       i_sector.second.FitMeanY1->Write();
       i_sector.second.ResidualWidthY1->Write();
       i_sector.second.CorrectionY1->Write();
       i_sector.second.FitMeanY2->Write();
       i_sector.second.ResidualWidthY2->Write();
       i_sector.second.CorrectionY2->Write();
     }
   }
   resultsFile->Close();
 }