d9/d5d/PrimaryVertexAnalyzer_8cc_source.html

 #include "Validation/RecoVertex/interface/PrimaryVertexAnalyzer.h"


 #include "FWCore/ParameterSet/interface/ParameterSet.h"

 #include "FWCore/MessageLogger/interface/MessageLogger.h"

 #include "FWCore/Version/interface/GetReleaseVersion.h"


 // reco track and vertex

 #include "DataFormats/TrackReco/interface/Track.h"

 #include "DataFormats/VertexReco/interface/Vertex.h"

 #include "RecoVertex/VertexPrimitives/interface/TransientVertex.h"


 // simulated vertices,..., add <use name=SimDataFormats/Vertex> and <../Track>

 #include <SimDataFormats/Vertex/interface/SimVertex.h>

 #include <SimDataFormats/Vertex/interface/SimVertexContainer.h>

 #include <SimDataFormats/Track/interface/SimTrack.h>

 #include <SimDataFormats/Track/interface/SimTrackContainer.h>


 //generator level + CLHEP

 #include "HepMC/GenEvent.h"

 #include "HepMC/GenVertex.h"

 //#include "SimGeneral/HepPDTRecord/interface/ParticleDataTable.h"


 #include "CommonTools/Statistics/interface/ChiSquaredProbability.h"


 // Root

 #include <TH1.h>

 #include <TH2.h>

 #include <TFile.h>

 #include <TProfile.h>


 #include <cmath>

 #include <gsl/gsl_math.h>

 #include <gsl/gsl_eigen.h>


 using namespace edm;

 using namespace reco;

 //

 // constants, enums and typedefs

 //


 //

 // static data member definitions

 //


 //

 // constructors and destructor

 //

 PrimaryVertexAnalyzer::PrimaryVertexAnalyzer(const ParameterSet& iConfig)

 {

    //now do what ever initialization is needed

   simG4_=iConfig.getParameter<edm::InputTag>( "simG4" );

   recoTrackProducer_= iConfig.getUntrackedParameter<std::string>("recoTrackProducer");

   // open output file to store histograms}

   outputFile_  = iConfig.getUntrackedParameter<std::string>("outputFile");

   TString tversion(edm::getReleaseVersion());

   tversion = tversion.Remove(0,1);

   tversion = tversion.Remove(tversion.Length()-1,tversion.Length());

   outputFile_  = std::string(tversion)+"_"+outputFile_;


   vtxSample_   = iConfig.getUntrackedParameter<std::vector< std::string > >("vtxSample");

   for(std::vector<std::string>::iterator isample = vtxSample_.begin(); isample!=vtxSample_.end(); ++isample) {

     if ( *isample == "offlinePrimaryVertices" ) suffixSample_.push_back("AVF");

     if ( *isample == "offlinePrimaryVerticesWithBS" ) suffixSample_.push_back("wBS");

   }

   if ( suffixSample_.size() == 0 ) throw cms::Exception("NoVertexSamples") << " no known vertex samples given";


   rootFile_ = new TFile(outputFile_.c_str(),"RECREATE");

   verbose_= iConfig.getUntrackedParameter<bool>("verbose", false);

   simUnit_= 1.0;  // starting with CMSSW_1_2_x ??

   if ( (edm::getReleaseVersion()).find("CMSSW_1_1_",0)!=std::string::npos){

     simUnit_=0.1;  // for use in  CMSSW_1_1_1 tutorial

   }

 }


 PrimaryVertexAnalyzer::~PrimaryVertexAnalyzer()

 {

     // do anything here that needs to be done at desctruction time

    // (e.g. close files, deallocate resources etc.)

    delete rootFile_;

    /*for(std::map<std::string,TH1*>::const_iterator hist=h.begin(); hist!=h.end(); hist++){

     delete hist->second;

     }*/


 }


 //

 // member functions

 //

 void PrimaryVertexAnalyzer::beginJob(){

   std::cout << " PrimaryVertexAnalyzer::beginJob  conversion from sim units to rec units is " << simUnit_ << std::endl;


   rootFile_->cd();

   // release validation histograms used in DoCompare.C

   for (std::vector<std::string>::iterator isuffix= suffixSample_.begin(); isuffix!=suffixSample_.end(); isuffix++) {


     hdir[*isuffix] = rootFile_->mkdir(TString(*isuffix));

     hdir[*isuffix]->cd();

     h["nbvtx"+ *isuffix]        = new TH1F(TString("nbvtx"+ *isuffix),"Reconstructed Vertices in Event",20,-0.5,19.5);

     h["nbtksinvtx"+ *isuffix]   = new TH1F(TString("nbtksinvtx"+ *isuffix),"Reconstructed Tracks in Vertex",200,-0.5,199.5);

     h["resx"+ *isuffix]         = new TH1F(TString("resx"+ *isuffix),"Residual X",100,-0.04,0.04);

     h["resy"+ *isuffix]         = new TH1F(TString("resy"+ *isuffix),"Residual Y",100,-0.04,0.04);

     h["resz"+ *isuffix]         = new TH1F(TString("resz"+ *isuffix),"Residual Z",100,-0.1,0.1);

     h["pullx"+ *isuffix]        = new TH1F(TString("pullx"+ *isuffix),"Pull X",100,-25.,25.);

     h["pully"+ *isuffix]        = new TH1F(TString("pully"+ *isuffix),"Pull Y",100,-25.,25.);

     h["pullz"+ *isuffix]        = new TH1F(TString("pullz"+ *isuffix),"Pull Z",100,-25.,25.);

     h["vtxchi2"+ *isuffix]      = new TH1F(TString("vtxchi2"+ *isuffix),"#chi^{2}",100,0.,100.);

     h["vtxndf"+ *isuffix]       = new TH1F(TString("vtxndf"+ *isuffix),"ndof",100,0.,100.);

     h["tklinks"+ *isuffix]      = new TH1F(TString("tklinks"+ *isuffix),"Usable track links",2,-0.5,1.5);

     h["nans"+ *isuffix]         = new TH1F(TString("nans"+ *isuffix),"Illegal values for x,y,z,xx,xy,xz,yy,yz,zz",9,0.5,9.5);

     // more histograms

     h["vtxprob"+ *isuffix]      = new TH1F(TString("vtxprob"+ *isuffix),"#chi^{2} probability",100,0.,1.);

     h["eff"+ *isuffix]          = new TH1F(TString("eff"+ *isuffix),"efficiency",2, -0.5, 1.5);

     h["efftag"+ *isuffix]       = new TH1F(TString("efftag"+ *isuffix),"efficiency tagged vertex",2, -0.5, 1.5);

     h["effvseta"+ *isuffix]     = new TProfile(TString("effvseta"+ *isuffix),"efficiency vs eta",20, -2.5, 2.5, 0, 1.);

     h["effvsptsq"+ *isuffix]    = new TProfile(TString("effvsptsq"+ *isuffix),"efficiency vs ptsq",20, 0., 10000., 0, 1.);

     h["effvsntrk"+ *isuffix]    = new TProfile(TString("effvsntrk"+ *isuffix),"efficiency vs # simtracks",200, 0., 200., 0, 1.);

     h["effvsnrectrk"+ *isuffix] = new TProfile(TString("effvsnrectrk"+ *isuffix),"efficiency vs # rectracks",200, 0., 200., 0, 1.);

     h["effvsz"+ *isuffix]       = new TProfile(TString("effvsz"+ *isuffix),"efficiency vs z",40, -20., 20., 0, 1.);

     h["nbsimtksinvtx"+ *isuffix]= new TH1F(TString("nbsimtksinvtx"+ *isuffix),"simulated tracks in vertex",100,-0.5,99.5);

     h["xrec"+ *isuffix]         = new TH1F(TString("xrec"+ *isuffix),"reconstructed x",100,-0.1,0.1);

     h["yrec"+ *isuffix]         = new TH1F(TString("yrec"+ *isuffix),"reconstructed y",100,-0.1,0.1);

     h["zrec"+ *isuffix]         = new TH1F(TString("zrec"+ *isuffix),"reconstructed z",100,-20.,20.);

     h["xsim"+ *isuffix]         = new TH1F(TString("xsim"+ *isuffix),"simulated x",100,-0.1,0.1);

     h["ysim"+ *isuffix]         = new TH1F(TString("ysim"+ *isuffix),"simulated y",100,-0.1,0.1);

     h["zsim"+ *isuffix]         = new TH1F(TString("zsim"+ *isuffix),"simulated z",100,-20.,20.);

     h["nrecvtx"+ *isuffix]      = new TH1F(TString("nrecvtx"+ *isuffix),"# of reconstructed vertices", 50, -0.5, 49.5);

     h["nsimvtx"+ *isuffix]      = new TH1F(TString("nsimvtx"+ *isuffix),"# of simulated vertices", 50, -0.5, 49.5);

     h["nrectrk"+ *isuffix]      = new TH1F(TString("nrectrk"+ *isuffix),"# of reconstructed tracks", 200, -0.5, 199.5);

     h["nsimtrk"+ *isuffix]      = new TH1F(TString("nsimtrk"+ *isuffix),"# of simulated tracks", 200, -0.5, 199.5);

     h["xrectag"+ *isuffix]      = new TH1F(TString("xrectag"+ *isuffix),"reconstructed x, signal vtx",100,-0.1,0.1);

     h["yrectag"+ *isuffix]      = new TH1F(TString("yrectag"+ *isuffix),"reconstructed y, signal vtx",100,-0.1,0.1);

     h["zrectag"+ *isuffix]      = new TH1F(TString("zrectag"+ *isuffix),"reconstructed z, signal vtx",100,-20.,20.);

     h["rapidity"+ *isuffix] = new TH1F(TString("rapidity"+ *isuffix),"rapidity ",100,-10., 10.);

     h["pt"+ *isuffix] = new TH1F(TString("pt"+ *isuffix),"pt ",100,0., 20.);

     h["nrectrk0vtx"+ *isuffix] = new TH1F(TString("nrectrk0vtx"+ *isuffix),"# rec tracks no vertex ",200,0., 200.);

     h["zdistancetag"+ *isuffix] = new TH1F(TString("zdistancetag"+ *isuffix),"z-distance between tagged and generated",100, -0.1, 0.1);

     h["puritytag"+ *isuffix]    = new TH1F(TString("puritytag"+ *isuffix),"purity of primary vertex tags",2, -0.5, 1.5);

   }


 }


 void PrimaryVertexAnalyzer::endJob() {

   rootFile_->cd();

   // save all histograms created in beginJob()

   for (std::map<std::string, TDirectory*>::const_iterator idir=hdir.begin(); idir!=hdir.end(); idir++){

     idir->second->cd();

     for(std::map<std::string,TH1*>::const_iterator hist=h.begin(); hist!=h.end(); hist++){

       if (TString(hist->first).Contains(idir->first)) hist->second->Write();

     }

   }

 }


 // helper functions

 bool PrimaryVertexAnalyzer::matchVertex(const simPrimaryVertex  &vsim,

                        const reco::Vertex       &vrec){

   return (fabs(vsim.z*simUnit_-vrec.z())<0.0500); // =500um

 }


 bool PrimaryVertexAnalyzer::isResonance(const HepMC::GenParticle * p){

   double ctau=(pdt->particle( abs(p->pdg_id()) ))->lifetime();

   if(verbose_) std::cout << "isResonance   " << p->pdg_id() << " " << ctau << std::endl;

   return  ctau >0 && ctau <1e-6;

 }


 bool PrimaryVertexAnalyzer::isFinalstateParticle(const HepMC::GenParticle * p){

   return ( !p->end_vertex() && p->status()==1 );

 }


 bool PrimaryVertexAnalyzer::isCharged(const HepMC::GenParticle * p){

   const ParticleData * part = pdt->particle( p->pdg_id() );

   if (part){

     return part->charge()!=0;

   }else{

     // the new/improved particle table doesn't know anti-particles

     return  pdt->particle( -p->pdg_id() )!=0;

   }

 }


 void PrimaryVertexAnalyzer::printRecVtxs(const Handle<reco::VertexCollection> recVtxs){

     int ivtx=0;

     for(reco::VertexCollection::const_iterator v=recVtxs->begin();

     v!=recVtxs->end(); ++v){

       std::cout << "Recvtx "<< std::setw(3) << std::setfill(' ')<<ivtx++

         << "#trk " << std::setw(3) << v->tracksSize()

         << " chi2 " << std::setw(4) << v->chi2()

         << " ndof " << std::setw(3) << v->ndof() << std::endl

         << " x "  << std::setw(8) <<std::fixed << std::setprecision(4) << v->x()

         << " dx " << std::setw(8) << v->xError()<< std::endl

         << " y "  << std::setw(8) << v->y()

         << " dy " << std::setw(8) << v->yError()<< std::endl

         << " z "  << std::setw(8) << v->z()

         << " dz " << std::setw(8) << v->zError()

         << std::endl;

     }

 }


 void PrimaryVertexAnalyzer::printSimVtxs(const Handle<SimVertexContainer> simVtxs){

     int i=0;

     for(SimVertexContainer::const_iterator vsim=simVtxs->begin();

     vsim!=simVtxs->end(); ++vsim){

       std::cout << i++ << ")" << std::scientific

                 << " evtid=" << vsim->eventId().event()

         << " sim x=" << vsim->position().x()*simUnit_

         << " sim y=" << vsim->position().y()*simUnit_

         << " sim z=" << vsim->position().z()*simUnit_

         << " sim t=" << vsim->position().t()

         << " parent=" << vsim->parentIndex()

         << std::endl;

     }

 }


 void PrimaryVertexAnalyzer::printSimTrks(const Handle<SimTrackContainer> simTrks){

   std::cout <<  " simTrks   type, (momentum), vertIndex, genpartIndex"  << std::endl;

   int i=1;

   for(SimTrackContainer::const_iterator t=simTrks->begin();

       t!=simTrks->end(); ++t){

     //HepMC::GenParticle* gp=evtMC->GetEvent()->particle( (*t).genpartIndex() );

     std::cout << i++ << ")"

           << (*t)

           << " index="

           << (*t).genpartIndex();

     //if (gp) {

     //  HepMC::GenVertex *gv=gp->production_vertex();

     //  std::cout  <<  " genvertex =" << (*gv);

     //}

     std::cout << std::endl;

   }

 }


 std::vector<PrimaryVertexAnalyzer::simPrimaryVertex> PrimaryVertexAnalyzer::getSimPVs(

                       const Handle<HepMCProduct> evtMC, std::string suffix="")

 {

   std::vector<PrimaryVertexAnalyzer::simPrimaryVertex> simpv;

   const HepMC::GenEvent* evt=evtMC->GetEvent();

   if (evt) {

     if(verbose_) std::cout << "process id " <<evt->signal_process_id()<<std::endl;

     if(verbose_) std::cout <<"signal process vertex "<< ( evt->signal_process_vertex() ?

                          evt->signal_process_vertex()->barcode() : 0 )   <<std::endl;

     if(verbose_) std::cout <<"number of vertices " << evt->vertices_size() << std::endl;


     int idx=0;

     for(HepMC::GenEvent::vertex_const_iterator vitr= evt->vertices_begin();

     vitr != evt->vertices_end(); ++vitr )

       { // loop for vertex ...

     HepMC::FourVector pos = (*vitr)->position();

     //HepLorentzVector pos = (*vitr)->position();


     bool hasMotherVertex=false;

     if(verbose_) std::cout << "mothers of vertex[" << ++idx << "]: " << std::endl;

     for ( HepMC::GenVertex::particle_iterator

           mother  = (*vitr)->particles_begin(HepMC::parents);

           mother != (*vitr)->particles_end(HepMC::parents);

               ++mother ) {

       HepMC::GenVertex * mv=(*mother)->production_vertex();

       if (mv) {

         hasMotherVertex=true;

         if(!verbose_) break; //if verbose_, print all particles of gen vertices

       }

       if(verbose_)std::cout << "\t";

       if(verbose_)(*mother)->print();

     }


     if(hasMotherVertex) {continue;}


     // could be a new vertex, check  all primaries found so far to avoid multiple entries

         const double mm=0.1;

     simPrimaryVertex sv(pos.x()*mm,pos.y()*mm,pos.z()*mm);

     simPrimaryVertex *vp=NULL;  // will become non-NULL if a vertex is found and then point to it

     for(std::vector<simPrimaryVertex>::iterator v0=simpv.begin();

         v0!=simpv.end(); v0++){

       if( (fabs(sv.x-v0->x)<1e-5) && (fabs(sv.y-v0->y)<1e-5) && (fabs(sv.z-v0->z)<1e-5)){

         vp=&(*v0);

         break;

       }

     }


     if(!vp){

       // this is a new vertex

       if(verbose_)std::cout << "this is a new vertex " << sv.x << " " << sv.y << " " << sv.z << std::endl;

       simpv.push_back(sv);

       vp=&simpv.back();

     }else{

       if(verbose_)std::cout << "this is not new vertex " << sv.x << " " << sv.y << " " << sv.z << std::endl;

     }

     vp->genVertex.push_back((*vitr)->barcode());

     // collect final state descendants

     for ( HepMC::GenVertex::particle_iterator

           daughter  = (*vitr)->particles_begin(HepMC::descendants);

           daughter != (*vitr)->particles_end(HepMC::descendants);

               ++daughter ) {

       if (isFinalstateParticle(*daughter)){

         if ( find(vp->finalstateParticles.begin(), vp->finalstateParticles.end(),(*daughter)->barcode())

          == vp->finalstateParticles.end()){

           vp->finalstateParticles.push_back((*daughter)->barcode());

           HepMC::FourVector m=(*daughter)->momentum();

           // the next four lines used to be "vp->ptot+=m;" in the days of CLHEP::HepLorentzVector

           // but adding FourVectors seems not to be foreseen

           vp->ptot.setPx(vp->ptot.px()+m.px());

           vp->ptot.setPy(vp->ptot.py()+m.py());

           vp->ptot.setPz(vp->ptot.pz()+m.pz());

           vp->ptot.setE(vp->ptot.e()+m.e());

           vp->ptsq+=(m.perp())*(m.perp());

           if ( (m.perp()>0.8) && (fabs(m.pseudoRapidity())<2.5) && isCharged( *daughter ) ){

         vp->nGenTrk++;

           }


           h["rapidity"+suffix]->Fill(m.pseudoRapidity());

           h["pt"+suffix]->Fill(m.perp());

         }

       }

     }

       }

   }

   return simpv;

 }


 std::vector<PrimaryVertexAnalyzer::simPrimaryVertex> PrimaryVertexAnalyzer::getSimPVs(

                       const Handle<HepMCProduct> evtMC,

                       const Handle<SimVertexContainer> simVtxs,

                       const Handle<SimTrackContainer> simTrks)

 {

    // simvertices don't have enough information to decide,

    // genVertices don't have the simulated coordinates  ( with VtxSmeared they might)

    // go through simtracks to get the link between simulated and generated vertices

    std::vector<PrimaryVertexAnalyzer::simPrimaryVertex> simpv;

    int idx=0;

    for(SimTrackContainer::const_iterator t=simTrks->begin();

        t!=simTrks->end(); ++t){

      if ( !(t->noVertex()) && !(t->type()==-99) ){

        double ptsq=0;

        bool primary=false;   // something coming directly from the primary vertex

        bool resonance=false; // resonance

        bool track=false;     // undecayed, charged particle

        HepMC::GenParticle* gp=evtMC->GetEvent()->barcode_to_particle( (*t).genpartIndex() );

        if (gp) {

      HepMC::GenVertex * gv=gp->production_vertex();

      if (gv) {

        for ( HepMC::GenVertex::particle_iterator

                  daughter =  gv->particles_begin(HepMC::descendants);

          daughter != gv->particles_end(HepMC::descendants);

          ++daughter ) {

          if (isFinalstateParticle(*daughter)){

            ptsq+=(*daughter)->momentum().perp()*(*daughter)->momentum().perp();

          }

        }

        primary =  ( gv->position().t()==0);

        //resonance= ( gp->mother() && isResonance(gp->mother()));  // in CLHEP/HepMC days

        // no more mother pointer in the improved HepMC GenParticle

        resonance= ( isResonance(*(gp->production_vertex()->particles_in_const_begin())));

        if (gp->status()==1){

          //track=((pdt->particle(gp->pdg_id()))->charge() != 0);

          track=not isCharged(gp);

        }

      }

        }


        const HepMC::FourVector & v=(*simVtxs)[t->vertIndex()].position();

        //const HepLorentzVector & v=(*simVtxs)[t->vertIndex()].position();

        if(primary or resonance){

      {

        // check all primaries found so far to avoid multiple entries

        bool newVertex=true;

        for(std::vector<simPrimaryVertex>::iterator v0=simpv.begin();

            v0!=simpv.end(); v0++){

          if( (fabs(v0->x-v.x())<0.001) && (fabs(v0->y-v.y())<0.001) && (fabs(v0->z-v.z())<0.001) ){

            if (track) {

          v0->simTrackIndex.push_back(idx);

          if (ptsq>(*v0).ptsq){(*v0).ptsq=ptsq;}

            }

            newVertex=false;

          }

        }

        if(newVertex && !resonance){

          simPrimaryVertex anotherVertex(v.x(),v.y(),v.z());

          if (track) anotherVertex.simTrackIndex.push_back(idx);

          anotherVertex.ptsq=ptsq;

          simpv.push_back(anotherVertex);

        }

      }//

        }


      }// simtrack has vertex and valid type

      idx++;

    }//simTrack loop

    return simpv;

 }


 // ------------ method called to produce the data  ------------

 void

 PrimaryVertexAnalyzer::analyze(const Event& iEvent, const EventSetup& iSetup)

 {


   Handle<reco::TrackCollection> recTrks;

   iEvent.getByLabel(recoTrackProducer_, recTrks);


   Handle<SimVertexContainer> simVtxs;

   iEvent.getByLabel( simG4_, simVtxs);


   Handle<SimTrackContainer> simTrks;

   iEvent.getByLabel( simG4_, simTrks);


   for (int ivtxSample=0; ivtxSample!= (int)vtxSample_.size(); ++ivtxSample) {

     std::string isuffix = suffixSample_[ivtxSample];


     Handle<reco::VertexCollection> recVtxs;

     iEvent.getByLabel(vtxSample_[ivtxSample], recVtxs);


     try{

       iSetup.getData(pdt);

     }catch(const Exception&){

       std::cout << "Some problem occurred with the particle data table. This may not work !." <<std::endl;

     }


     bool MC=false;

     Handle<HepMCProduct> evtMC;

     iEvent.getByLabel("generator",evtMC);

     if (!evtMC.isValid()) {

       MC=false;

       if(verbose_){

     std::cout << "no HepMCProduct found"<< std::endl;

       }

     } else {

       if(verbose_){

     std::cout << "generator HepMCProduct found"<< std::endl;

       }

       MC=true;

     }


     if(verbose_){

       //evtMC->GetEvent()->print();

       printRecVtxs(recVtxs);

       //printSimVtxs(simVtxs);

       //printSimTrks(simTrks);

     }


     if(MC){

       // make a list of primary vertices:

       std::vector<simPrimaryVertex> simpv;

       //simpv=getSimPVs(evtMC, simVtxs, simTrks);

       simpv=getSimPVs(evtMC,isuffix);


       // vertex matching and efficiency bookkeeping

       h["nsimvtx"+isuffix]->Fill(simpv.size());

       int nsimtrk=0;

       for(std::vector<simPrimaryVertex>::iterator vsim=simpv.begin();

       vsim!=simpv.end(); vsim++){


     hdir[isuffix]->cd();


     h["nbsimtksinvtx"+isuffix]->Fill(vsim->nGenTrk);

     h["xsim"+isuffix]->Fill(vsim->x*simUnit_);

     h["ysim"+isuffix]->Fill(vsim->y*simUnit_);

     h["zsim"+isuffix]->Fill(vsim->z*simUnit_);

     nsimtrk+=vsim->nGenTrk;

     // look for a matching reconstructed vertex

     vsim->recVtx=NULL;

     for(reco::VertexCollection::const_iterator vrec=recVtxs->begin();

         vrec!=recVtxs->end(); ++vrec){

       if ( matchVertex(*vsim,*vrec) ){

         // if the matching critera are fulfilled, accept the rec-vertex that is closest in z

         if(    ((vsim->recVtx) && (fabs(vsim->recVtx->position().z()-vsim->z)>fabs(vrec->z()-vsim->z)))

            || (!vsim->recVtx) )

           {

         vsim->recVtx=&(*vrec);

           }

       }

     }

     h["nsimtrk"+isuffix]->Fill(float(nsimtrk));


     // histogram properties of matched vertices

     if (vsim->recVtx){


       if(verbose_){std::cout <<"primary matched " << vsim->x << " " << vsim->y << " " << vsim->z << std:: endl;}


       h["resx"+isuffix]->Fill( vsim->recVtx->x()-vsim->x*simUnit_ );

       h["resy"+isuffix]->Fill( vsim->recVtx->y()-vsim->y*simUnit_ );

       h["resz"+isuffix]->Fill( vsim->recVtx->z()-vsim->z*simUnit_ );

       h["pullx"+isuffix]->Fill( (vsim->recVtx->x()-vsim->x*simUnit_)/vsim->recVtx->xError() );

       h["pully"+isuffix]->Fill( (vsim->recVtx->y()-vsim->y*simUnit_)/vsim->recVtx->yError() );

       h["pullz"+isuffix]->Fill( (vsim->recVtx->z()-vsim->z*simUnit_)/vsim->recVtx->zError() );

       h["eff"+isuffix]->Fill( 1.);

       if(simpv.size()==1){

         if (vsim->recVtx==&(*recVtxs->begin())){

           h["efftag"+isuffix]->Fill( 1.);

         }else{

           h["efftag"+isuffix]->Fill( 0.);

         }

       }

       h["effvseta"+isuffix]->Fill(vsim->ptot.pseudoRapidity(),1.);

       h["effvsptsq"+isuffix]->Fill(vsim->ptsq,1.);

       h["effvsntrk"+isuffix]->Fill(vsim->nGenTrk,1.);

       h["effvsnrectrk"+isuffix]->Fill(recTrks->size(),1.);

       h["effvsz"+isuffix]->Fill(vsim->z*simUnit_,1.);


     }else{  // no rec vertex found for this simvertex


       if(verbose_){std::cout <<"primary not found " << vsim->x << " " << vsim->y << " " << vsim->z << " nGenTrk=" << vsim->nGenTrk << std::endl;}


       h["eff"+isuffix]->Fill( 0.);

       if(simpv.size()==1){ h["efftag"+isuffix]->Fill( 0.); }

       h["effvseta"+isuffix]->Fill(vsim->ptot.pseudoRapidity(),0.);

       h["effvsptsq"+isuffix]->Fill(vsim->ptsq,0.);

       h["effvsntrk"+isuffix]->Fill(float(vsim->nGenTrk),0.);

       h["effvsnrectrk"+isuffix]->Fill(recTrks->size(),0.);

       h["effvsz"+isuffix]->Fill(vsim->z*simUnit_,0.);

     } // no recvertex for this simvertex

       }//found MC event

       // end of sim/rec matching


       // purity of event vertex tags

       if (recVtxs->size()>0 && simpv.size()>0){

     Double_t dz=(*recVtxs->begin()).z() - (*simpv.begin()).z*simUnit_;

     h["zdistancetag"+isuffix]->Fill(dz);

     if( fabs(dz)<0.0500){

       h["puritytag"+isuffix]->Fill(1.);

     }else{

       // bad tag: the true primary was more than 500 um away from the tagged primary

       h["puritytag"+isuffix]->Fill(0.);

     }

       }


     }// MC event


     // test track links, use reconstructed vertices


     h["nrecvtx"+isuffix]->Fill(recVtxs->size());

     h["nrectrk"+isuffix]->Fill(recTrks->size());

     h["nbvtx"+isuffix]->Fill(recVtxs->size()*1.);

     if((recVtxs->size()==0)||recVtxs->begin()->isFake()) {h["nrectrk0vtx"+isuffix]->Fill(recTrks->size());}


     for(reco::VertexCollection::const_iterator v=recVtxs->begin();

     v!=recVtxs->end(); ++v){


       if(v->isFake()) continue;


       try {

     for(reco::Vertex::trackRef_iterator t = v->tracks_begin();

         t!=v->tracks_end(); t++) {

       // illegal charge

       if ( (**t).charge() < -1 || (**t).charge() > 1 ) {

         h["tklinks"+isuffix]->Fill(0.);

       }

       else {

         h["tklinks"+isuffix]->Fill(1.);

       }

     }

       }

       catch (...) {

     // exception thrown when trying to use linked track

     h["tklinks"+isuffix]->Fill(0.);

       }


       h["nbtksinvtx"+isuffix]->Fill(v->tracksSize());

       h["vtxchi2"+isuffix]->Fill(v->chi2());

       h["vtxndf"+isuffix]->Fill(v->ndof());

       h["vtxprob"+isuffix]->Fill(ChiSquaredProbability(v->chi2() ,v->ndof()));

       h["xrec"+isuffix]->Fill(v->position().x());

       h["yrec"+isuffix]->Fill(v->position().y());

       h["zrec"+isuffix]->Fill(v->position().z());

       if (v==recVtxs->begin()){

     h["xrectag"+isuffix]->Fill(v->position().x());

     h["yrectag"+isuffix]->Fill(v->position().y());

     h["zrectag"+isuffix]->Fill(v->position().z());

       }


       bool problem = false;

       h["nans"+isuffix]->Fill(1.,isnan(v->position().x())*1.);

       h["nans"+isuffix]->Fill(2.,isnan(v->position().y())*1.);

       h["nans"+isuffix]->Fill(3.,isnan(v->position().z())*1.);


       int index = 3;

       for (int i = 0; i != 3; i++) {

     for (int j = i; j != 3; j++) {

       index++;

       h["nans"+isuffix]->Fill(index*1., isnan(v->covariance(i, j))*1.);

       if (isnan(v->covariance(i, j))) problem = true;

       // in addition, diagonal element must be positive

       if (j == i && v->covariance(i, j) < 0) {

         h["nans"+isuffix]->Fill(index*1., 1.);

         problem = true;

       }

     }

       }


       if (problem) {

     // analyze track parameter covariance definiteness

     double data[25];

     try {

       int itk = 0;

       for(reco::Vertex::trackRef_iterator t = v->tracks_begin();

           t!=v->tracks_end(); t++) {

         std::cout << "Track " << itk++ << std::endl;

         int i2 = 0;

         for (int i = 0; i != 5; i++) {

           for (int j = 0; j != 5; j++) {

         data[i2] = (**t).covariance(i, j);

         std::cout << std:: scientific << data[i2] << " ";

         i2++;

           }

           std::cout << std::endl;

         }

         gsl_matrix_view m

           = gsl_matrix_view_array (data, 5, 5);


         gsl_vector *eval = gsl_vector_alloc (5);

         gsl_matrix *evec = gsl_matrix_alloc (5, 5);


         gsl_eigen_symmv_workspace * w =

           gsl_eigen_symmv_alloc (5);


         gsl_eigen_symmv (&m.matrix, eval, evec, w);


         gsl_eigen_symmv_free (w);


         gsl_eigen_symmv_sort (eval, evec,

                   GSL_EIGEN_SORT_ABS_ASC);


         // print sorted eigenvalues

         {

           int i;

           for (i = 0; i < 5; i++) {

         double eval_i

           = gsl_vector_get (eval, i);

         //gsl_vector_view evec_i

         //  = gsl_matrix_column (evec, i);


         printf ("eigenvalue = %g\n", eval_i);

         //        printf ("eigenvector = \n");

         //        gsl_vector_fprintf (stdout,

         //                &evec_i.vector, "%g");

           }

         }

       }

     }

     catch (...) {

       // exception thrown when trying to use linked track

       break;

     }

       }// if (problem)

     }

   } // for vertex loop

 }

edm::ParameterSet::getParameter
T getParameter(std::string const &) const

edm::ParameterSet::getUntrackedParameter
T getUntrackedParameter(std::string const &, T const &) const

i
int i
Definition: DBlmapReader.cc:9

PrimaryVertexAnalyzer::getSimPVs
std::vector< simPrimaryVertex > getSimPVs(const edm::Handle< edm::HepMCProduct > evtMC, std::string suffix)
Definition: PrimaryVertexAnalyzer.cc:240

MessageLogger.h

parents
TPRegexp parents
Definition: eve_filter.cc:24

pos
Definition: Histograms.cc:19

SimTrack.h

or
The Signals That Services Can Subscribe To This is based on ActivityRegistry and is current per Services can connect to the signals distributed by the ActivityRegistry in order to monitor the activity of the application Each possible callback has some defined which we here list in angle e< void, edm::EventIDconst &, edm::Timestampconst & > We also list in braces which AR_WATCH_USING_METHOD_ is used for those or
Definition: Activities.doc:12

PrimaryVertexAnalyzer::isCharged
bool isCharged(const HepMC::GenParticle *p)
Definition: PrimaryVertexAnalyzer.cc:176

lumiQTWidget.t
tuple t
Definition: lumiQTWidget.py:50

PrimaryVertexAnalyzer::isFinalstateParticle
bool isFinalstateParticle(const HepMC::GenParticle *p)
Definition: PrimaryVertexAnalyzer.cc:172

PrimaryVertexAnalyzer::beginJob
virtual void beginJob()
Definition: PrimaryVertexAnalyzer.cc:93

getHLTprescales.index
tuple index
Definition: getHLTprescales.py:79

PrimaryVertexAnalyzer::printSimTrks
void printSimTrks(const edm::Handle< edm::SimTrackContainer > simVtrks)
Definition: PrimaryVertexAnalyzer.cc:221

PrimaryVertexAnalyzer::simPrimaryVertex
Definition: PrimaryVertexAnalyzer.h:65

abs
#define abs(x)
Definition: mlp_lapack.h:159

NULL
#define NULL
Definition: scimark2.h:8

edm::Handle< reco::VertexCollection >

dt_dqm_sourceclient_common_cff.reco
tuple reco
Definition: dt_dqm_sourceclient_common_cff.py:105

spr::find
void find(edm::Handle< EcalRecHitCollection > &hits, DetId thisDet, std::vector< EcalRecHitCollection::const_iterator > &hit, bool debug=false)
Definition: FindCaloHit.cc:7

detailsBasic3DVector::z
double double double z
Definition: newBasic3DVector.h:17

edm::EventSetup::getData
void getData(T &iHolder) const
Definition: EventSetup.h:67

PrimaryVertexAnalyzer::simPrimaryVertex::simTrackIndex
std::vector< int > simTrackIndex
Definition: PrimaryVertexAnalyzer.h:74

resonance
const std::pair< int, int > resonance[nResonances]
Definition: Histograms.cc:75

ParameterSet.h

estimatePileup.hist
tuple hist
Definition: estimatePileup.py:215

iEvent
int iEvent
Definition: GenABIO.cc:243

reco::Vertex
Definition: Vertex.h:35

TransientVertex.h

PrimaryVertexAnalyzer::~PrimaryVertexAnalyzer
~PrimaryVertexAnalyzer()
Definition: PrimaryVertexAnalyzer.cc:77

edm::isnan
bool isnan(float f)
Definition: math.h:69

edm::Exception
Definition: EDMException.h:74

PrimaryVertexAnalyzer::analyze
virtual void analyze(const edm::Event &, const edm::EventSetup &)
Definition: PrimaryVertexAnalyzer.cc:406

PrimaryVertexAnalyzer::simPrimaryVertex::z
double z
Definition: PrimaryVertexAnalyzer.h:67

j
int j
Definition: DBlmapReader.cc:9

reco::Vertex::z
double z() const
y coordinate
Definition: Vertex.h:99

SimVertex.h

ChiSquaredProbability
float ChiSquaredProbability(double chiSquared, double nrDOF)
Definition: ChiSquaredProbability.cc:13

edm::EventSetup
Definition: EventSetup.h:44

PrimaryVertexAnalyzer::endJob
virtual void endJob()
Definition: PrimaryVertexAnalyzer.cc:148

ChiSquaredProbability.h

edm::HandleBase::isValid
bool isValid() const
Definition: HandleBase.h:76

ParticleData
HepPDT::ParticleData ParticleData
Definition: ParticleDataTable.h:10

edm::Event::getByLabel
bool getByLabel(InputTag const &tag, Handle< PROD > &result) const
Definition: Event.h:356

Vertex.h

edm::getReleaseVersion
std::string getReleaseVersion()
Definition: GetReleaseVersion.cc:7

m
int m
Definition: DTDataIntegrityTask.cc:33

PrimaryVertexAnalyzer::isResonance
bool isResonance(const HepMC::GenParticle *p)
Definition: PrimaryVertexAnalyzer.cc:166

h
The Signals That Services Can Subscribe To This is based on ActivityRegistry h
Helper function to determine trigger accepts.
Definition: Activities.doc:4

GetReleaseVersion.h

part
part
Definition: HCALResponse.h:21

cms::Exception
Definition: Exception.h:66

createPayload.suffix
string suffix
Definition: createPayload.py:280

configurableAnalysis::GenParticle
char GenParticle[]
Definition: modules.cc:23

PrimaryVertexAnalyzer::printRecVtxs
void printRecVtxs(const edm::Handle< reco::VertexCollection > recVtxs)
Definition: PrimaryVertexAnalyzer.cc:186

alignCSCRings.e
list e
Definition: alignCSCRings.py:90

AlCaHLTBitMon_ParallelJobs.p
tuple p
Definition: AlCaHLTBitMon_ParallelJobs.py:152

SimTrackContainer.h

data
char data[epos_bytes_allocation]
Definition: EPOS_Wrapper.h:82

edm::InputTag
Definition: InputTag.h:12

PrimaryVertexAnalyzer::PrimaryVertexAnalyzer
PrimaryVertexAnalyzer(const edm::ParameterSet &)
Definition: PrimaryVertexAnalyzer.cc:49

reco::Vertex::trackRef_iterator
std::vector< TrackBaseRef >::const_iterator trackRef_iterator
The iteratator for the vector&lt;TrackRef&gt;
Definition: Vertex.h:38

edm::ParameterSet
Definition: ParameterSet.h:35

gather_cfg.cout
tuple cout
Definition: gather_cfg.py:121

PrimaryVertexAnalyzer.h

edm::Event
Definition: Event.h:50

Track.h

PrimaryVertexAnalyzer::matchVertex
bool matchVertex(const simPrimaryVertex &vsim, const reco::Vertex &vrec)
Definition: PrimaryVertexAnalyzer.cc:161

v
mathSSE::Vec4< T > v
Definition: newBasic3DVector.h:354

w
T w() const
Definition: newBasic3DVector.h:234

SimVertexContainer.h

PrimaryVertexAnalyzer::printSimVtxs
void printSimVtxs(const edm::Handle< edm::SimVertexContainer > simVtxs)
Definition: PrimaryVertexAnalyzer.cc:205