opdet::LEDCalibrationAna Class Reference

Inheritance diagram for opdet::LEDCalibrationAna:

Public Types
using	WorkerType = WorkerT< EDAnalyzer >
using	ModuleType = EDAnalyzer

Public Member Functions
	LEDCalibrationAna (const fhicl::ParameterSet &)
virtual	~LEDCalibrationAna ()
void	beginJob ()
void	endJob ()
void	analyze (const art::Event &)
std::string	workerType () const
bool	modifiesEvent () const
void	registerProducts (MasterProductRegistry &, ProductDescriptions &, ModuleDescription const &)
std::string const &	processName () const
bool	wantAllEvents () const
bool	wantEvent (Event const &e)
fhicl::ParameterSetID	selectorConfig () const
art::Handle< art::TriggerResults >	getTriggerResults (Event const &e) const
template<typename T , BranchType = InEvent>
ProductToken< T >	consumes (InputTag const &)
template<typename T , art::BranchType BT>
art::ProductToken< T >	consumes (InputTag const &it)
template<typename T , BranchType = InEvent>
void	consumesMany ()
template<typename Element , BranchType = InEvent>
ViewToken< Element >	consumesView (InputTag const &)
template<typename T , art::BranchType BT>
art::ViewToken< T >	consumesView (InputTag const &it)
template<typename T , BranchType = InEvent>
ProductToken< T >	mayConsume (InputTag const &)
template<typename T , art::BranchType BT>
art::ProductToken< T >	mayConsume (InputTag const &it)
template<typename T , BranchType = InEvent>
void	mayConsumeMany ()
template<typename Element , BranchType = InEvent>
ViewToken< Element >	mayConsumeView (InputTag const &)
template<typename T , art::BranchType BT>
art::ViewToken< T >	mayConsumeView (InputTag const &it)
base_engine_t &	createEngine (seed_t seed)
base_engine_t &	createEngine (seed_t seed, std::string const &kind_of_engine_to_make)
base_engine_t &	createEngine (seed_t seed, std::string const &kind_of_engine_to_make, label_t const &engine_label)
seed_t	get_seed_value (fhicl::ParameterSet const &pset, char const key[]="seed", seed_t const implicit_seed=-1)

Static Public Member Functions
static cet::exempt_ptr< Consumer >	non_module_context ()

Protected Member Functions
CurrentProcessingContext const *	currentContext () const
detail::CachedProducts &	cachedProducts ()
void	validateConsumedProduct (BranchType const bt, ProductInfo const &pi)
void	prepareForJob (fhicl::ParameterSet const &pset)
void	showMissingConsumes () const

Private Member Functions
uint32_t	ShaperToChannel (uint32_t Shaper)

Private Attributes
std::string	fInputModule
uint32_t	fTriggerChannel
float	fCoincThreshold
float	fMaxTimeMean
float	fMaxTimeThresh
float	fAreaDivs
float	fAreaMin
float	fAreaMax
float	fTriggerDelay
pmtana::PulseRecoManager	fPulseRecoMgr
pmtana::AlgoThreshold	fThreshAlg
pmtana::PedAlgoEdges	fPedAlg
TTree *	fPulseTree
TTree *	fPulseTreeNonCoinc
Float_t	fPeak
Float_t	fPedRMS
Float_t	fPedMean
Float_t	fArea
Float_t	fTBegin
Float_t	fTEnd
Float_t	fTMax
Float_t	fOffset
Int_t	fEventID
Int_t	fRunID
Int_t	fChannel
Int_t	fShaper
bool	fMakeNonCoincTree
std::map< uint32_t, std::vector< double > >	fAreas

Detailed Description

Definition at line 52 of file LEDCalibrationAna_module.cc.

Member Typedef Documentation

using art::EDAnalyzer::ModuleType = EDAnalyzer

inherited

Definition at line 39 of file EDAnalyzer.h.

using art::EDAnalyzer::WorkerType = WorkerT<EDAnalyzer>

inherited

Definition at line 38 of file EDAnalyzer.h.

Constructor & Destructor Documentation

opdet::LEDCalibrationAna::LEDCalibrationAna

(

const fhicl::ParameterSet &

)

Definition at line 116 of file LEDCalibrationAna_module.cc.

References pmtana::PulseRecoManager::AddRecoAlgo(), fArea, fAreaDivs, fAreaMax, fAreaMin, fChannel, fCoincThreshold, fEventID, fInputModule, fMakeNonCoincTree, fMaxTimeMean, fMaxTimeThresh, fOffset, fPeak, fPedAlg, fPedMean, fPedRMS, fPulseRecoMgr, fPulseTree, fPulseTreeNonCoinc, fRunID, fShaper, fTBegin, fTEnd, fThreshAlg, fTMax, fTriggerChannel, fTriggerDelay, fhicl::ParameterSet::get(), art::TFileDirectory::make(), and pmtana::PulseRecoManager::SetDefaultPedAlgo().

    : EDAnalyzer(pset),
      fPulseRecoMgr(),
      fThreshAlg(),
      fPedAlg()
  {
    // Indicate that the Input Module comes from .fcl
    fInputModule    = pset.get<std::string>("InputModule");
    fTriggerChannel = pset.get<uint32_t>   ("TriggerChannel");
    fTriggerDelay   = pset.get<uint32_t>   ("TriggerDelay");
    fCoincThreshold = pset.get<float>      ("CoincThreshold");
    fMaxTimeThresh  = pset.get<float>      ("MaxTimeThresh");
    fMaxTimeMean    = pset.get<float>      ("MaxTimeMean");
    fAreaMin        = pset.get<float>      ("AreaMin");
    fAreaMax        = pset.get<float>      ("AreaMax");
    fAreaDivs       = pset.get<float>      ("AreaDivs");
    fMakeNonCoincTree=pset.get<bool>       ("MakeNonCoincTree");
    
    fPulseRecoMgr.AddRecoAlgo(&fThreshAlg);
    fPulseRecoMgr.SetDefaultPedAlgo(&fPedAlg);

    art::ServiceHandle<art::TFileService> tfs;

    fPulseTree = tfs->make<TTree>("fPulseTree","fPulseTree");
    fPulseTree->Branch("Area",     &fArea,     "Area/F");
    fPulseTree->Branch("Peak",     &fPeak,     "Peak/F");
    fPulseTree->Branch("TBegin",   &fTBegin,   "TBegin/F");
    fPulseTree->Branch("TEnd",     &fTEnd,     "TEnd/F");
    fPulseTree->Branch("TMax",     &fTMax,     "TMax/F");
    fPulseTree->Branch("Channel",  &fChannel,  "Channel/I");
    fPulseTree->Branch("Shaper",   &fShaper,   "Shaper/I");
    fPulseTree->Branch("PedMean",  &fPedMean,  "PedMean/F");
    fPulseTree->Branch("PedRMS",   &fPedRMS,   "PedRMS/F");
    fPulseTree->Branch("Offset",   &fOffset,   "Offset/F");
    fPulseTree->Branch("EventID",  &fEventID,  "EventID/I");
    fPulseTree->Branch("RunID",    &fRunID,    "RunID/I");

    fPulseTreeNonCoinc = tfs->make<TTree>("fPulseTreeNonCoinc","fPulseTreeNonCoinc");
    fPulseTreeNonCoinc->Branch("Area",     &fArea,     "Area/F");
    fPulseTreeNonCoinc->Branch("Peak",     &fPeak,     "Peak/F");
    fPulseTreeNonCoinc->Branch("TBegin",   &fTBegin,   "TBegin/F");
    fPulseTreeNonCoinc->Branch("TEnd",     &fTEnd,     "TEnd/F");
    fPulseTreeNonCoinc->Branch("TMax",     &fTMax,     "TMax/F");
    fPulseTreeNonCoinc->Branch("Channel",  &fChannel,  "Channel/I");
    fPulseTreeNonCoinc->Branch("Shaper",   &fShaper,   "Shaper/I");
    fPulseTreeNonCoinc->Branch("PedMean",  &fPedMean,  "PedMean/F");
    fPulseTreeNonCoinc->Branch("PedRMS",   &fPedRMS,   "PedRMS/F");
    fPulseTreeNonCoinc->Branch("EventID",  &fEventID,  "EventID/I");
    fPulseTreeNonCoinc->Branch("RunID",    &fRunID,    "RunID/I");

  }

opdet::LEDCalibrationAna::~LEDCalibrationAna ( )

virtual

Definition at line 170 of file LEDCalibrationAna_module.cc.

  {}

Member Function Documentation

void opdet::LEDCalibrationAna::analyze

(

const art::Event &

evt

)

Definition at line 250 of file LEDCalibrationAna_module.cc.

References pmtana::pulse_param::area, art::Event::event(), fArea, fAreas, fChannel, fCoincThreshold, fEventID, fInputModule, fMakeNonCoincTree, fMaxTimeMean, fMaxTimeThresh, fOffset, fPeak, fPedMean, fPedRMS, fPulseRecoMgr, fPulseTree, fPulseTreeNonCoinc, fRunID, fShaper, fTBegin, fTEnd, fThreshAlg, fTMax, fTriggerChannel, fTriggerDelay, art::DataViewImpl::getByLabel(), pmtana::PMTPulseRecoBase::GetNPulse(), pmtana::PMTPulseRecoBase::GetPulse(), pmtana::pulse_param::peak, pmtana::pulse_param::ped_mean, pmtana::pulse_param::ped_sigma, pmtana::PulseRecoManager::Reconstruct(), art::Event::run(), ShaperToChannel(), pmtana::pulse_param::t_end, pmtana::pulse_param::t_max, and pmtana::pulse_param::t_start.

  {

    auto const* ts = lar::providerFrom<detinfo::DetectorClocksService>();


    fRunID=evt.run();
    fEventID=evt.event();

    art::ServiceHandle<art::TFileService> tfs;

    // Create a handle for our vector of pulses
    art::Handle< std::vector< raw::OpDetWaveform > > OpDetWaveformHandle;

    // Read in WaveformHandle
    evt.getByLabel(fInputModule, OpDetWaveformHandle);

    std::map<uint32_t, std::vector<int> > OrgOpDigitByChannel;
    
    for(size_t i=0; i!=OpDetWaveformHandle->size(); ++i)
      {
        OrgOpDigitByChannel[ShaperToChannel(OpDetWaveformHandle->at(i).ChannelNumber())].push_back(i);
      }

    std::vector<uint32_t> FrameNumbersForTrig;
    std::vector<uint32_t> TimeSlicesForTrig;
    
    for(size_t i=0; i!=OrgOpDigitByChannel[fTriggerChannel].size(); ++i)
      {
        double TimeStamp = OpDetWaveformHandle->at(OrgOpDigitByChannel[ fTriggerChannel][i] ).TimeStamp();
        uint32_t Frame     = ts->OpticalClock().Frame(TimeStamp);
        uint32_t TimeSlice = ts->OpticalClock().Sample(TimeStamp);
        FrameNumbersForTrig.push_back(Frame);
        TimeSlicesForTrig.push_back(TimeSlice);
      }

    for(size_t i=0; i!=OpDetWaveformHandle->size(); ++i)
      {
        double TimeStamp = OpDetWaveformHandle->at(i).TimeStamp();
        uint32_t Frame     = ts->OpticalClock().Frame(TimeStamp);
        uint32_t TimeSlice = ts->OpticalClock().Sample(TimeStamp);
        fShaper   = OpDetWaveformHandle->at(i).ChannelNumber();
        fChannel  = ShaperToChannel(fShaper);
        

        if(uint32_t(fChannel) != fTriggerChannel)
          {
            for(size_t j=0; j!=FrameNumbersForTrig.size(); ++j)
              {
                if( (Frame == FrameNumbersForTrig.at(j))
                    && (fabs(TimeSlice - TimeSlicesForTrig.at(j) - fTriggerDelay)<fCoincThreshold))
                  {
                    
                   
                    const raw::OpDetWaveform& wf = OpDetWaveformHandle->at(i);

                    //fPulseRecoMgr.RecoPulse(wf);
                    fPulseRecoMgr.Reconstruct(wf);
                    
                    size_t NPulses = fThreshAlg.GetNPulse();

                    fOffset  = TimeSlice-TimeSlicesForTrig.at(j);
                    //fPedMean = fThreshAlg.PedMean();
                    //fPedRMS  = fThreshAlg.PedRms();
                    
                    for(size_t k=0; k!=NPulses; ++k)
                      {
                        if(fabs(fMaxTimeMean-fThreshAlg.GetPulse(k).t_max)<fMaxTimeThresh)
                          {
                            
                            fPeak    = fThreshAlg.GetPulse(k).peak;
                            fArea    = fThreshAlg.GetPulse(k).area;
                            fTBegin  = fThreshAlg.GetPulse(k).t_start;
                            fTEnd    = fThreshAlg.GetPulse(k).t_end;
                            fTMax    = fThreshAlg.GetPulse(k).t_max;
                            fPedMean = fThreshAlg.GetPulse(k).ped_mean;
                            fPedRMS  = fThreshAlg.GetPulse(k).ped_sigma;

                            fPulseTree->Fill();
                            
                            fAreas[fChannel].push_back(fArea);
                          }
                        else if(fMakeNonCoincTree)
                          {
                            fPeak    = fThreshAlg.GetPulse(k).peak;
                            fArea    = fThreshAlg.GetPulse(k).area;
                            fTBegin  = fThreshAlg.GetPulse(k).t_start;
                            fTEnd    = fThreshAlg.GetPulse(k).t_end;
                            fTMax    = fThreshAlg.GetPulse(k).t_max;
                            
                            fPulseTreeNonCoinc->Fill();
                          }
                      }
                  }             
              }
          }
      }

  }

void opdet::LEDCalibrationAna::beginJob ( )

virtual

Reimplemented from art::EDAnalyzer.

Definition at line 174 of file LEDCalibrationAna_module.cc.

  {
  }

detail::CachedProducts& art::EventObserverBase::cachedProducts ( )

inlineprotectedinherited

Definition at line 79 of file EventObserverBase.h.

References art::EventObserverBase::selectors_.

Referenced by art::EDAnalyzer::doEvent(), and art::OutputModule::doWriteEvent().

  {
    return selectors_;
  }

template<typename T , BranchType = InEvent>

ProductToken<T> art::Consumer::consumes ( InputTag const &  )

inherited

template<typename T , art::BranchType BT>

art::ProductToken<T> art::Consumer::consumes ( InputTag const &  it )

inherited

Definition at line 147 of file Consumer.h.

References art::InputTag::instance(), art::InputTag::label(), and art::InputTag::process().

{
  if (!moduleContext_)
    return ProductToken<T>::invalid();

  consumables_[BT].emplace_back(ConsumableType::Product,
                                TypeID{typeid(T)},
                                it.label(),
                                it.instance(),
                                it.process());
  return ProductToken<T>{it};
}

template<typename T , art::BranchType BT>

void art::Consumer::consumesMany ( )

inherited

Definition at line 162 of file Consumer.h.

{
  if (!moduleContext_)
    return;

  consumables_[BT].emplace_back(ConsumableType::Many, TypeID{typeid(T)});
}

template<typename Element , BranchType = InEvent>

ViewToken<Element> art::Consumer::consumesView ( InputTag const &  )

inherited

template<typename T , art::BranchType BT>

art::ViewToken<T> art::Consumer::consumesView ( InputTag const &  it )

inherited

Definition at line 172 of file Consumer.h.

References art::InputTag::instance(), art::InputTag::label(), and art::InputTag::process().

{
  if (!moduleContext_)
    return ViewToken<T>::invalid();

  consumables_[BT].emplace_back(ConsumableType::ViewElement,
                                TypeID{typeid(T)},
                                it.label(),
                                it.instance(),
                                it.process());
  return ViewToken<T>{it};
}

EngineCreator::base_engine_t & EngineCreator::createEngine ( seed_t  seed )

inherited

Definition at line 26 of file EngineCreator.cc.

References art::EngineCreator::rng().

Referenced by evgen::CosmicsGen::CosmicsGen(), rndm::NuRandomService::createEngine(), cluster::fuzzyCluster::fuzzyCluster(), cluster::HoughLineFinder::HoughLineFinder(), art::MixFilter< T >::initEngine_(), larg4::LArG4::LArG4(), evgen::LightSource::LightSource(), evgen::NeutronOsc::NeutronOsc(), evgen::NucleonDecay::NucleonDecay(), opdet::OpMCDigi::OpMCDigi(), opdet::OptDetDigitizer::OptDetDigitizer(), phot::PhotonLibraryPropagation::PhotonLibraryPropagation(), detsim::SimDriftElectrons::SimDriftElectrons(), evgen::SingleGen::SingleGen(), evgen::SNNueAr40CCGen::SNNueAr40CCGen(), ToyOneShowerGen::ToyOneShowerGen(), and trkf::Track3DKalman::Track3DKalman().

{
  return rng()->createEngine(placeholder_schedule_id(), seed);
}

EngineCreator::base_engine_t & EngineCreator::createEngine ( seed_t  seed, std::string const &  kind_of_engine_to_make  )

inherited

Definition at line 32 of file EngineCreator.cc.

References art::EngineCreator::rng().

{
  return rng()->createEngine(
    placeholder_schedule_id(), seed, kind_of_engine_to_make);
}

EngineCreator::base_engine_t & EngineCreator::createEngine ( seed_t  seed, std::string const &  kind_of_engine_to_make, label_t const &  engine_label  )

inherited

Definition at line 40 of file EngineCreator.cc.

References art::EngineCreator::rng().

{
  return rng()->createEngine(
    placeholder_schedule_id(), seed, kind_of_engine_to_make, engine_label);
}

CurrentProcessingContext const * art::EDAnalyzer::currentContext ( ) const

protectedinherited

Definition at line 114 of file EDAnalyzer.cc.

References art::EDAnalyzer::current_context_.

Referenced by art::EDAnalyzer::workerType().

  {
    return current_context_.get();
  }

void opdet::LEDCalibrationAna::endJob ( )

virtual

Reimplemented from art::EDAnalyzer.

Definition at line 179 of file LEDCalibrationAna_module.cc.

References fAreaDivs, fAreaMax, fAreaMin, fAreas, and art::TFileDirectory::make().

  { 
    art::ServiceHandle<art::TFileService> tfs;

    for(auto it = fAreas.begin(); it!=fAreas.end(); ++it)
      {
        uint32_t Channel = it->first;
        
        std::stringstream histname;
        histname.flush();
        histname<<"ch"<<Channel<<"area";

        TH1D * HistArea = tfs->make<TH1D>(histname.str().c_str(), histname.str().c_str(), fAreaDivs, fAreaMin, fAreaMax);

        for(size_t j=0; j!=it->second.size(); ++j)
          {
            HistArea->Fill(it->second.at(j));
          }
        
        std::stringstream fitname;
        fitname.flush();
        fitname<<"ch"<<Channel<<"fit";

        double Max = HistArea->GetMaximum();
        double Mid = HistArea->GetBinContent(fAreaDivs/2.);
        
        TF1 * GausFit = new TF1(fitname.str().c_str(),
                            "gaus(0)+gaus(3)+gaus(6)",
                            fAreaMin,
                            fAreaMax);
        
        GausFit->SetParameters(Mid, (fAreaMin+fAreaMax)/2., (fAreaMax-fAreaMin)/2.,
                               Max, 0, (fAreaMin+fAreaMax)/8., 
                               Max/5., 0, (fAreaMin+fAreaMax)/4.);


        GausFit->SetParLimits(0,0,1.1*Max);
        GausFit->SetParLimits(1,0,fAreaMax);
        GausFit->SetParLimits(2,0,fAreaMax);

        GausFit->SetParLimits(3,0,1.1*Max);
        GausFit->FixParameter(4,0);
        GausFit->SetParLimits(5,0,(fAreaMin+fAreaMax)/2.);

        GausFit->SetParLimits(6,0,1.1*Max);
        GausFit->FixParameter(7,0);
        GausFit->SetParLimits(8,0,(fAreaMin+fAreaMax)/2.);


        HistArea->Fit(GausFit);
        
        double Mean     = GausFit->GetParameter(1);
        double Width    = GausFit->GetParameter(2);
        
        double MeanErr  = GausFit->GetParError(1);
        double WidthErr = GausFit->GetParError(2);
        
        double NPE      = pow(Mean,2)/pow(Width,2);
        double SPEScale = Mean / NPE;

        double NPEError = NPE      * pow(2.*(pow(MeanErr/Mean,2) + pow(WidthErr/Width,2)),0.5);
        double SPEError = SPEScale * pow(2.*pow(WidthErr/Width,2) + pow(MeanErr/Mean,2),0.5);
        
        std::cout <<"Channel " << Channel<< ":\tSPE Scale \t"<<SPEScale<<"\t +/- \t" << SPEError<<",\t NPE \t" << NPE<<"\t +/- \t"<< NPEError <<std::endl;
      }
    
  }

EngineCreator::seed_t EngineCreator::get_seed_value ( fhicl::ParameterSet const &  pset, char const  key[] = "seed", seed_t const  implicit_seed = -1  )

inherited

Definition at line 49 of file EngineCreator.cc.

References fhicl::ParameterSet::get().

Referenced by art::MixFilter< T >::initEngine_().

{
  auto const& explicit_seeds = pset.get<std::vector<int>>(key, {});
  return explicit_seeds.empty() ? implicit_seed : explicit_seeds.front();
}

art::Handle<art::TriggerResults> art::EventObserverBase::getTriggerResults ( Event const &  e ) const

inlineinherited

Definition at line 61 of file EventObserverBase.h.

References art::detail::CachedProducts::getOneTriggerResults(), and art::EventObserverBase::selectors_.

Referenced by art::OutputModule::doWriteEvent().

  {
    return selectors_.getOneTriggerResults(e);
  }

template<typename T , BranchType = InEvent>

ProductToken<T> art::Consumer::mayConsume ( InputTag const &  )

inherited

template<typename T , art::BranchType BT>

art::ProductToken<T> art::Consumer::mayConsume ( InputTag const &  it )

inherited

Definition at line 190 of file Consumer.h.

References art::InputTag::instance(), art::InputTag::label(), and art::InputTag::process().

{
  if (!moduleContext_)
    return ProductToken<T>::invalid();

  consumables_[BT].emplace_back(ConsumableType::Product,
                                TypeID{typeid(T)},
                                it.label(),
                                it.instance(),
                                it.process());
  return ProductToken<T>{it};
}

template<typename T , art::BranchType BT>

void art::Consumer::mayConsumeMany ( )

inherited

Definition at line 205 of file Consumer.h.

{
  if (!moduleContext_)
    return;

  consumables_[BT].emplace_back(ConsumableType::Many, TypeID{typeid(T)});
}

template<typename Element , BranchType = InEvent>

ViewToken<Element> art::Consumer::mayConsumeView ( InputTag const &  )

inherited

template<typename T , art::BranchType BT>

art::ViewToken<T> art::Consumer::mayConsumeView ( InputTag const &  it )

inherited

Definition at line 215 of file Consumer.h.

References art::InputTag::instance(), art::InputTag::label(), and art::InputTag::process().

{
  if (!moduleContext_)
    return ViewToken<T>::invalid();

  consumables_[BT].emplace_back(ConsumableType::ViewElement,
                                TypeID{typeid(T)},
                                it.label(),
                                it.instance(),
                                it.process());
  return ViewToken<T>{it};
}

bool art::EventObserverBase::modifiesEvent ( ) const

inlineinherited

Definition at line 25 of file EventObserverBase.h.

  {
    return false;
  }

cet::exempt_ptr< art::Consumer > art::Consumer::non_module_context ( )

staticinherited

Definition at line 76 of file Consumer.cc.

Referenced by art::RootOutput::beginSubRun(), art::OutputModule::doBeginRun(), art::OutputModule::doBeginSubRun(), art::OutputModule::doEndRun(), art::OutputModule::doEndSubRun(), art::ProducingService::doPostReadEvent(), art::ProducingService::doPostReadRun(), art::ProducingService::doPostReadSubRun(), art::OutputModule::doWriteEvent(), art::ProcessPackage< L >::postScheduleSignal(), art::BeginEndPackage< Level::Run >::Begin::postScheduleSignal(), art::BeginEndPackage< Level::Run >::End::postScheduleSignal(), art::BeginEndPackage< Level::SubRun >::Begin::postScheduleSignal(), art::BeginEndPackage< Level::SubRun >::End::postScheduleSignal(), art::ProcessPackage< L >::preScheduleSignal(), art::BeginEndPackage< Level::Run >::Begin::preScheduleSignal(), art::BeginEndPackage< Level::SubRun >::Begin::preScheduleSignal(), art::EventProcessor::readEvent(), art::EventProcessor::readRun(), art::EmptyEvent::readRun_(), art::EventProcessor::readSubRun(), and art::EmptyEvent::readSubRun_().

{
  static Consumer invalid{InvalidTag{}};
  return &invalid;
}

void art::Consumer::prepareForJob ( fhicl::ParameterSet const &  pset )

protectedinherited

Definition at line 89 of file Consumer.cc.

References fhicl::ParameterSet::get_if_present().

Referenced by art::EDProducer::doBeginJob(), art::EDFilter::doBeginJob(), and art::EDAnalyzer::doBeginJob().

{
  if (!moduleContext_)
    return;

  pset.get_if_present("errorOnMissingConsumes", requireConsumes_);
  for (auto& consumablesPerBranch : consumables_) {
    cet::sort_all(consumablesPerBranch);
  }
}

std::string const& art::EventObserverBase::processName ( ) const

inlineinherited

Definition at line 41 of file EventObserverBase.h.

References art::EventObserverBase::process_name_.

Referenced by art::FileDumperOutput::printPrincipal(), and art::RootOutput::RootOutput().

  {
    return process_name_;
  }

void art::EventObserverBase::registerProducts ( MasterProductRegistry &  , ProductDescriptions &  , ModuleDescription const &    )

inlineinherited

Definition at line 33 of file EventObserverBase.h.

  {}

fhicl::ParameterSetID art::EventObserverBase::selectorConfig ( ) const

inlineinherited

Definition at line 56 of file EventObserverBase.h.

References art::EventObserverBase::selector_config_id_.

Referenced by art::RootOutputFile::writeOne().

  {
    return selector_config_id_;
  }

uint32_t opdet::LEDCalibrationAna::ShaperToChannel ( uint32_t  Shaper )

private

Definition at line 351 of file LEDCalibrationAna_module.cc.

References DEFINE_ART_MODULE.

Referenced by analyze().

  {
    static std::map<uint32_t, uint32_t> ShaperToChannelMap;
    if(ShaperToChannelMap.size()==0)
      {
        
        // temporary
        for(size_t i=0; i!=40; ++i)
          {
            ShaperToChannelMap[i]=i;
          }
      }
    
    return ShaperToChannelMap[Shaper];
  }

void art::Consumer::showMissingConsumes ( ) const

protectedinherited

Definition at line 125 of file Consumer.cc.

Referenced by art::EDProducer::doEndJob(), art::EDFilter::doEndJob(), art::EDAnalyzer::doEndJob(), and art::RootOutput::endJob().

{
  if (!moduleContext_)
    return;

  // If none of the branches have missing consumes statements, exit early.
  if (std::all_of(cbegin(missingConsumes_),
                  cend(missingConsumes_),
                  [](auto const& perBranch) { return perBranch.empty(); }))
    return;

  constexpr cet::HorizontalRule rule{60};
  mf::LogPrint log{"MTdiagnostics"};
  log << '\n'
      << rule('=') << '\n'
      << "The following consumes (or mayConsume) statements are missing from\n"
      << module_context(moduleDescription_) << '\n'
      << rule('-') << '\n';

  cet::for_all_with_index(
    missingConsumes_, [&log](std::size_t const i, auto const& perBranch) {
      for (auto const& pi : perBranch) {
        log << "  "
            << assemble_consumes_statement(static_cast<BranchType>(i), pi)
            << '\n';
      }
    });
  log << rule('=');
}

void art::Consumer::validateConsumedProduct ( BranchType const  bt, ProductInfo const &  pi  )

protectedinherited

Definition at line 101 of file Consumer.cc.

References art::errors::ProductRegistrationFailure.

{
  // Early exits if consumes tracking has been disabled or if the
  // consumed product is an allowed consumable.
  if (!moduleContext_)
    return;

  if (cet::binary_search_all(consumables_[bt], pi))
    return;

  if (requireConsumes_) {
    throw Exception(errors::ProductRegistrationFailure,
                    "Consumer: an error occurred during validation of a "
                    "retrieved product\n\n")
      << "The following consumes (or mayConsume) statement is missing from\n"
      << module_context(moduleDescription_) << ":\n\n"
      << "  " << assemble_consumes_statement(bt, pi) << "\n\n";
  }

  missingConsumes_[bt].insert(pi);
}

bool art::EventObserverBase::wantAllEvents ( ) const

inlineinherited

Definition at line 46 of file EventObserverBase.h.

References art::EventObserverBase::wantAllEvents_.

Referenced by art::EDAnalyzer::doEvent(), art::OutputModule::doEvent(), art::OutputModule::doWriteEvent(), art::RootOutput::RootOutput(), and art::OutputWorker::wantAllEvents().

  {
    return wantAllEvents_;
  }

bool art::EventObserverBase::wantEvent ( Event const &  e )

inlineinherited

Definition at line 51 of file EventObserverBase.h.

References art::EventObserverBase::selectors_, and art::detail::CachedProducts::wantEvent().

Referenced by art::EDAnalyzer::doEvent(), art::OutputModule::doEvent(), and art::OutputModule::doWriteEvent().

  {
    return selectors_.wantEvent(e);
  }

std::string art::EDAnalyzer::workerType ( ) const

inlineinherited

Definition at line 109 of file EDAnalyzer.h.

References art::EDAnalyzer::currentContext().

    {
      return "WorkerT<EDAnalyzer>";
    }

Member Data Documentation

Float_t opdet::LEDCalibrationAna::fArea

private

Definition at line 87 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

float opdet::LEDCalibrationAna::fAreaDivs

private

Definition at line 74 of file LEDCalibrationAna_module.cc.

Referenced by endJob(), and LEDCalibrationAna().

float opdet::LEDCalibrationAna::fAreaMax

private

Definition at line 76 of file LEDCalibrationAna_module.cc.

Referenced by endJob(), and LEDCalibrationAna().

float opdet::LEDCalibrationAna::fAreaMin

private

Definition at line 75 of file LEDCalibrationAna_module.cc.

Referenced by endJob(), and LEDCalibrationAna().

std::map<uint32_t, std::vector<double> > opdet::LEDCalibrationAna::fAreas

private

Definition at line 101 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and endJob().

Int_t opdet::LEDCalibrationAna::fChannel

private

Definition at line 94 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

float opdet::LEDCalibrationAna::fCoincThreshold

private

Definition at line 71 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

Int_t opdet::LEDCalibrationAna::fEventID

private

Definition at line 92 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

std::string opdet::LEDCalibrationAna::fInputModule

private

Definition at line 69 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

bool opdet::LEDCalibrationAna::fMakeNonCoincTree

private

Definition at line 99 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

float opdet::LEDCalibrationAna::fMaxTimeMean

private

Definition at line 72 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

float opdet::LEDCalibrationAna::fMaxTimeThresh

private

Definition at line 73 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

Float_t opdet::LEDCalibrationAna::fOffset

private

Definition at line 91 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

Float_t opdet::LEDCalibrationAna::fPeak

private

Definition at line 84 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

pmtana::PedAlgoEdges opdet::LEDCalibrationAna::fPedAlg

private

Definition at line 81 of file LEDCalibrationAna_module.cc.

Referenced by LEDCalibrationAna().

Float_t opdet::LEDCalibrationAna::fPedMean

private

Definition at line 86 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

Float_t opdet::LEDCalibrationAna::fPedRMS

private

Definition at line 85 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

pmtana::PulseRecoManager opdet::LEDCalibrationAna::fPulseRecoMgr

private

Definition at line 79 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

TTree* opdet::LEDCalibrationAna::fPulseTree

private

Definition at line 82 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

TTree* opdet::LEDCalibrationAna::fPulseTreeNonCoinc

private

Definition at line 83 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

Int_t opdet::LEDCalibrationAna::fRunID

private

Definition at line 93 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

Int_t opdet::LEDCalibrationAna::fShaper

private

Definition at line 95 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

Float_t opdet::LEDCalibrationAna::fTBegin

private

Definition at line 88 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

Float_t opdet::LEDCalibrationAna::fTEnd

private

Definition at line 89 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

pmtana::AlgoThreshold opdet::LEDCalibrationAna::fThreshAlg

private

Definition at line 80 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

Float_t opdet::LEDCalibrationAna::fTMax

private

Definition at line 90 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

uint32_t opdet::LEDCalibrationAna::fTriggerChannel

private

Definition at line 70 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

float opdet::LEDCalibrationAna::fTriggerDelay

private

Definition at line 77 of file LEDCalibrationAna_module.cc.

Referenced by analyze(), and LEDCalibrationAna().

---

The documentation for this class was generated from the following file:

• /cvmfs/larsoft.opensciencegrid.org/products/larana/v07_04_02/source/larana/OpticalDetector/LEDCalibrationAna_module.cc