BoostedDoubleSVProducer.cc

Go to the documentation of this file.

// -*- C++ -*-
//
// Package:    ​RecoBTag/​SecondaryVertex
// Class:      BoostedDoubleSVProducer
//
//
// Original Author:  Dinko Ferencek
//         Created:  Thu, 06 Oct 2016 14:02:30 GMT
//
//


// system include files
#include <memory>

// user include files
#include "FWCore/Framework/interface/Frameworkfwd.h"
#include "FWCore/Framework/interface/stream/EDProducer.h"

#include "FWCore/Framework/interface/Event.h"
#include "FWCore/Framework/interface/MakerMacros.h"

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

#include "DataFormats/BTauReco/interface/CandIPTagInfo.h"
#include "DataFormats/BTauReco/interface/CandSecondaryVertexTagInfo.h"
#include "DataFormats/BTauReco/interface/BoostedDoubleSVTagInfo.h"
#include "DataFormats/BTauReco/interface/TaggingVariable.h"
#include "DataFormats/ParticleFlowCandidate/interface/PFCandidate.h"
#include "DataFormats/PatCandidates/interface/PackedCandidate.h"
#include "DataFormats/VertexReco/interface/Vertex.h"
#include "DataFormats/VertexReco/interface/VertexFwd.h"
#include "DataFormats/Candidate/interface/VertexCompositePtrCandidate.h"

#include "RecoBTag/SecondaryVertex/interface/TrackKinematics.h"
#include "RecoBTag/SecondaryVertex/interface/V0Filter.h"
#include "RecoBTag/SecondaryVertex/interface/TrackSelector.h"
#include "RecoVertex/VertexPrimitives/interface/ConvertToFromReco.h"
#include "TrackingTools/Records/interface/TransientTrackRecord.h"
#include "TrackingTools/IPTools/interface/IPTools.h"
#include "TrackingTools/TransientTrack/interface/TransientTrackBuilder.h"

#include "fastjet/PseudoJet.hh"
#include "fastjet/contrib/Njettiness.hh"

#include <map>

//
// class declaration
//

class BoostedDoubleSVProducer : public edm::stream::EDProducer<> {
   public:
      explicit BoostedDoubleSVProducer(const edm::ParameterSet&);
      ~BoostedDoubleSVProducer();

      static void fillDescriptions(edm::ConfigurationDescriptions& descriptions);

   private:
      virtual void beginStream(edm::StreamID) override;
      virtual void produce(edm::Event&, const edm::EventSetup&) override;
      virtual void endStream() override;

      void calcNsubjettiness(const reco::JetBaseRef & jet, float & tau1, float & tau2, std::vector<fastjet::PseudoJet> & currentAxes) const;
      void setTracksPVBase(const reco::TrackRef & trackRef, const reco::VertexRef & vertexRef, float & PVweight) const;
      void setTracksPV(const reco::CandidatePtr & trackRef, const reco::VertexRef & vertexRef, float & PVweight) const;
      void etaRelToTauAxis(const reco::VertexCompositePtrCandidate & vertex, const fastjet::PseudoJet & tauAxis, std::vector<float> & tau_trackEtaRel) const;

      // ----------member data ---------------------------
      const edm::EDGetTokenT<std::vector<reco::CandSecondaryVertexTagInfo> > svTagInfos_;

      const double beta_;
      const double R0_;

      const double maxSVDeltaRToJet_;
      const double maxDistToAxis_;
      const double maxDecayLen_;
      reco::V0Filter trackPairV0Filter;
      reco::TrackSelector trackSelector;

      // static variables
      static constexpr float dummyZ_ratio             = -3.0f;
      static constexpr float dummyTrackSip3dSig       = -50.0f;
      static constexpr float dummyTrackSip2dSigAbove  = -19.0f;
      static constexpr float dummyTrackEtaRel         = -1.0f;
      static constexpr float dummyVertexMass          = -1.0f;
      static constexpr float dummyVertexEnergyRatio   = -1.0f;
      static constexpr float dummyVertexDeltaR        = -1.0f;
      static constexpr float dummyFlightDistance2dSig = -1.0f;

      static constexpr float charmThreshold  = 1.5f;
      static constexpr float bottomThreshold = 5.2f;
};

//
// constants, enums and typedefs
//


//
// static data member definitions
//

//
// constructors and destructor
//
BoostedDoubleSVProducer::BoostedDoubleSVProducer(const edm::ParameterSet& iConfig) :
  svTagInfos_( consumes<std::vector<reco::CandSecondaryVertexTagInfo> >(iConfig.getParameter<edm::InputTag>("svTagInfos")) ),
  beta_(iConfig.getParameter<double>("beta")),
  R0_(iConfig.getParameter<double>("R0")),
  maxSVDeltaRToJet_(iConfig.getParameter<double>("maxSVDeltaRToJet")),
  maxDistToAxis_(iConfig.getParameter<edm::ParameterSet>("trackSelection").getParameter<double>("maxDistToAxis")),
  maxDecayLen_(iConfig.getParameter<edm::ParameterSet>("trackSelection").getParameter<double>("maxDecayLen")),
  trackPairV0Filter(iConfig.getParameter<edm::ParameterSet>("trackPairV0Filter")),
  trackSelector(iConfig.getParameter<edm::ParameterSet>("trackSelection"))
{
    produces<std::vector<reco::BoostedDoubleSVTagInfo> >();
}


BoostedDoubleSVProducer::~BoostedDoubleSVProducer()
{

   // do anything here that needs to be done at destruction time
   // (e.g. close files, deallocate resources etc.)

}


//
// member functions
//

// ------------ method called to produce the data  ------------
void
BoostedDoubleSVProducer::produce(edm::Event& iEvent, const edm::EventSetup& iSetup)
{
   // get the track builder
   edm::ESHandle<TransientTrackBuilder> trackBuilder;
   iSetup.get<TransientTrackRecord>().get("TransientTrackBuilder",trackBuilder);

   // get input secondary vertex TagInfos
   edm::Handle<std::vector<reco::CandSecondaryVertexTagInfo> > svTagInfos;
   iEvent.getByToken(svTagInfos_, svTagInfos);

   // create the output collection
   auto tagInfos = std::make_unique<std::vector<reco::BoostedDoubleSVTagInfo> >();

   // loop over TagInfos
   for(std::vector<reco::CandSecondaryVertexTagInfo>::const_iterator iterTI = svTagInfos->begin(); iterTI != svTagInfos->end(); ++iterTI)
   {
     // get TagInfos
     const reco::CandIPTagInfo              & ipTagInfo = *(iterTI->trackIPTagInfoRef().get());
     const reco::CandSecondaryVertexTagInfo & svTagInfo = *(iterTI);

     // default variable values
     float z_ratio = dummyZ_ratio;
     float trackSip3dSig_3 = dummyTrackSip3dSig, trackSip3dSig_2 = dummyTrackSip3dSig, trackSip3dSig_1 = dummyTrackSip3dSig, trackSip3dSig_0 = dummyTrackSip3dSig;
     float tau2_trackSip3dSig_0 = dummyTrackSip3dSig, tau1_trackSip3dSig_0 = dummyTrackSip3dSig, tau2_trackSip3dSig_1 = dummyTrackSip3dSig, tau1_trackSip3dSig_1 = dummyTrackSip3dSig;
     float trackSip2dSigAboveCharm_0 = dummyTrackSip2dSigAbove, trackSip2dSigAboveBottom_0 = dummyTrackSip2dSigAbove, trackSip2dSigAboveBottom_1 = dummyTrackSip2dSigAbove;
     float tau1_trackEtaRel_0 = dummyTrackEtaRel, tau1_trackEtaRel_1 = dummyTrackEtaRel, tau1_trackEtaRel_2 = dummyTrackEtaRel;
     float tau2_trackEtaRel_0 = dummyTrackEtaRel, tau2_trackEtaRel_1 = dummyTrackEtaRel, tau2_trackEtaRel_2 = dummyTrackEtaRel;
     float tau1_vertexMass = dummyVertexMass, tau1_vertexEnergyRatio = dummyVertexEnergyRatio, tau1_vertexDeltaR = dummyVertexDeltaR, tau1_flightDistance2dSig = dummyFlightDistance2dSig;
     float tau2_vertexMass = dummyVertexMass, tau2_vertexEnergyRatio = dummyVertexEnergyRatio, tau2_vertexDeltaR = dummyVertexDeltaR, tau2_flightDistance2dSig = dummyFlightDistance2dSig;
     float jetNTracks = 0, nSV = 0, tau1_nSecondaryVertices = 0, tau2_nSecondaryVertices = 0;

     // get the jet reference
     const reco::JetBaseRef jet = svTagInfo.jet();

     std::vector<fastjet::PseudoJet> currentAxes;
     float tau2, tau1;
     // calculate N-subjettiness
     calcNsubjettiness(jet, tau1, tau2, currentAxes);

     const reco::VertexRef & vertexRef = ipTagInfo.primaryVertex();
     GlobalPoint pv(0.,0.,0.);
     if ( ipTagInfo.primaryVertex().isNonnull() )
       pv = GlobalPoint(vertexRef->x(),vertexRef->y(),vertexRef->z());

     const std::vector<reco::CandidatePtr> & selectedTracks = ipTagInfo.selectedTracks();
     const std::vector<reco::btag::TrackIPData> & ipData = ipTagInfo.impactParameterData();
     size_t trackSize = selectedTracks.size();


     reco::TrackKinematics allKinematics;
     std::vector<float> IP3Ds, IP3Ds_1, IP3Ds_2;
     int contTrk=0;

     // loop over tracks associated to the jet
     for (size_t itt=0; itt < trackSize; ++itt)
     {
       const reco::CandidatePtr trackRef = selectedTracks[itt];

       float track_PVweight = 0.;
       setTracksPV(trackRef, vertexRef, track_PVweight);
       if (track_PVweight>0.5) allKinematics.add(trackRef);

       const reco::btag::TrackIPData &data = ipData[itt];
       bool isSelected = false;
       if (trackSelector(trackRef, data, *jet, pv)) isSelected = true;

       // check if the track is from V0
       bool isfromV0 = false, isfromV0Tight = false;
       std::vector<reco::CandidatePtr> trackPairV0Test(2);

       trackPairV0Test[0] = trackRef;

       for (size_t jtt=0; jtt < trackSize; ++jtt)
       {
         if (itt == jtt) continue;

         const reco::btag::TrackIPData & pairTrackData = ipData[jtt];
         const reco::CandidatePtr pairTrackRef = selectedTracks[jtt];

         trackPairV0Test[1] = pairTrackRef;

         if (!trackPairV0Filter(trackPairV0Test))
         {
           isfromV0 = true;

           if ( trackSelector(pairTrackRef, pairTrackData, *jet, pv) )
             isfromV0Tight = true;
         }

         if (isfromV0 && isfromV0Tight)
           break;
       }

       if( isSelected && !isfromV0Tight ) jetNTracks += 1.;

       reco::TransientTrack transientTrack = trackBuilder->build(trackRef);
       GlobalVector direction(jet->px(), jet->py(), jet->pz());

       int index = 0;
       if (currentAxes.size() > 1 && reco::deltaR2(trackRef->momentum(),currentAxes[1]) < reco::deltaR2(trackRef->momentum(),currentAxes[0]))
           index = 1;
       direction = GlobalVector(currentAxes[index].px(), currentAxes[index].py(), currentAxes[index].pz());

       // decay distance and track distance wrt to the closest tau axis
       float decayLengthTau=-1;
       float distTauAxis=-1;

       TrajectoryStateOnSurface closest = IPTools::closestApproachToJet(transientTrack.impactPointState(), *vertexRef , direction, transientTrack.field());
       if (closest.isValid())
         decayLengthTau =  (closest.globalPosition() - RecoVertex::convertPos(vertexRef->position())).mag();

       distTauAxis = std::abs(IPTools::jetTrackDistance(transientTrack, direction, *vertexRef ).second.value());

       float IP3Dsig = ipTagInfo.impactParameterData()[itt].ip3d.significance();

       if( !isfromV0 && decayLengthTau<maxDecayLen_ && distTauAxis<maxDistToAxis_ )
       {
         IP3Ds.push_back( IP3Dsig<-50. ? -50. : IP3Dsig );
         ++contTrk;
         if (currentAxes.size() > 1)
         {
           if (reco::deltaR2(trackRef->momentum(),currentAxes[0]) < reco::deltaR2(trackRef->momentum(),currentAxes[1]))
             IP3Ds_1.push_back( IP3Dsig<-50. ? -50. : IP3Dsig );
           else
             IP3Ds_2.push_back( IP3Dsig<-50. ? -50. : IP3Dsig );
         }
         else
           IP3Ds_1.push_back( IP3Dsig<-50. ? -50. : IP3Dsig );
       }
     }

     std::vector<size_t> indices = ipTagInfo.sortedIndexes(reco::btag::IP2DSig);
     bool charmThreshSet = false;

     reco::TrackKinematics kin;
     for (size_t i=0; i<indices.size(); ++i)
     {
       size_t idx = indices[i];
       const reco::btag::TrackIPData & data = ipData[idx];
       const reco::CandidatePtr trackRef = selectedTracks[idx];

       kin.add(trackRef);

       if ( kin.vectorSum().M() > charmThreshold // charm cut
            && !charmThreshSet )
       {
         trackSip2dSigAboveCharm_0 = data.ip2d.significance();

         charmThreshSet = true;
       }

       if ( kin.vectorSum().M() > bottomThreshold ) // bottom cut
       {
         trackSip2dSigAboveBottom_0 = data.ip2d.significance();
         if ( (i+1)<indices.size() ) trackSip2dSigAboveBottom_1 = (ipData[indices[i+1]]).ip2d.significance();

         break;
       }
     }

     float dummyTrack = -50.;

     std::sort( IP3Ds.begin(),IP3Ds.end(),std::greater<float>() );
     std::sort( IP3Ds_1.begin(),IP3Ds_1.end(),std::greater<float>() );
     std::sort( IP3Ds_2.begin(),IP3Ds_2.end(),std::greater<float>() );
     int num_1 = IP3Ds_1.size();
     int num_2 = IP3Ds_2.size();

     switch(contTrk){
             case 0:

                     trackSip3dSig_0 = dummyTrack;
                     trackSip3dSig_1 = dummyTrack;
                     trackSip3dSig_2 = dummyTrack;
                     trackSip3dSig_3 = dummyTrack;

                     break;

             case 1:

                     trackSip3dSig_0 = IP3Ds.at(0);
                     trackSip3dSig_1 = dummyTrack;
                     trackSip3dSig_2 = dummyTrack;
                     trackSip3dSig_3 = dummyTrack;

                     break;

             case 2:

                     trackSip3dSig_0 = IP3Ds.at(0);
                     trackSip3dSig_1 = IP3Ds.at(1);
                     trackSip3dSig_2 = dummyTrack;
                     trackSip3dSig_3 = dummyTrack;

                     break;

             case 3:

                     trackSip3dSig_0 = IP3Ds.at(0);
                     trackSip3dSig_1 = IP3Ds.at(1);
                     trackSip3dSig_2 = IP3Ds.at(2);
                     trackSip3dSig_3 = dummyTrack;

                     break;

             default:

                     trackSip3dSig_0 = IP3Ds.at(0);
                     trackSip3dSig_1 = IP3Ds.at(1);
                     trackSip3dSig_2 = IP3Ds.at(2);
                     trackSip3dSig_3 = IP3Ds.at(3);

     }

     switch(num_1){
             case 0:

                     tau1_trackSip3dSig_0 = dummyTrack;
                     tau1_trackSip3dSig_1 = dummyTrack;

                     break;

             case 1:

                     tau1_trackSip3dSig_0 = IP3Ds_1.at(0);
                     tau1_trackSip3dSig_1 = dummyTrack;

                     break;

             default:

                     tau1_trackSip3dSig_0 = IP3Ds_1.at(0);
                     tau1_trackSip3dSig_1 = IP3Ds_1.at(1);

     }

     switch(num_2){
             case 0:

                      tau2_trackSip3dSig_0 = dummyTrack;
                      tau2_trackSip3dSig_1 = dummyTrack;

                      break;

             case 1:
                      tau2_trackSip3dSig_0 = IP3Ds_2.at(0);
                      tau2_trackSip3dSig_1 = dummyTrack;

                      break;

             default:

                      tau2_trackSip3dSig_0 = IP3Ds_2.at(0);
                      tau2_trackSip3dSig_1 = IP3Ds_2.at(1);

     }

     math::XYZVector jetDir = jet->momentum().Unit();
     reco::TrackKinematics tau1Kinematics;
     reco::TrackKinematics tau2Kinematics;
     std::vector<float> tau1_trackEtaRels, tau2_trackEtaRels;

     std::map<double, size_t> VTXmap;
     for (size_t vtx = 0; vtx < svTagInfo.nVertices(); ++vtx)
     {
       const reco::VertexCompositePtrCandidate vertex = svTagInfo.secondaryVertex(vtx);
       // get the vertex kinematics
       reco::TrackKinematics vertexKinematic(vertex);

       if (currentAxes.size() > 1)
       {
               if (reco::deltaR2(svTagInfo.flightDirection(vtx),currentAxes[1]) < reco::deltaR2(svTagInfo.flightDirection(vtx),currentAxes[0]))
               {
                       tau2Kinematics = tau2Kinematics + vertexKinematic;
                       if( tau2_flightDistance2dSig < 0 )
                       {
                         tau2_flightDistance2dSig = svTagInfo.flightDistance(vtx,true).significance();
                         tau2_vertexDeltaR = reco::deltaR(svTagInfo.flightDirection(vtx),currentAxes[1]);
                       }
                       etaRelToTauAxis(vertex, currentAxes[1], tau2_trackEtaRels);
                       tau2_nSecondaryVertices += 1.;
               }
               else
               {
                       tau1Kinematics = tau1Kinematics + vertexKinematic;
                       if( tau1_flightDistance2dSig < 0 )
                       {
                         tau1_flightDistance2dSig =svTagInfo.flightDistance(vtx,true).significance();
                         tau1_vertexDeltaR = reco::deltaR(svTagInfo.flightDirection(vtx),currentAxes[0]);
                       }
                       etaRelToTauAxis(vertex, currentAxes[0], tau1_trackEtaRels);
                       tau1_nSecondaryVertices += 1.;
               }

       }
       else if (currentAxes.size() > 0)
       {
               tau1Kinematics = tau1Kinematics + vertexKinematic;
               if( tau1_flightDistance2dSig < 0 )
               {
                 tau1_flightDistance2dSig =svTagInfo.flightDistance(vtx,true).significance();
                 tau1_vertexDeltaR = reco::deltaR(svTagInfo.flightDirection(vtx),currentAxes[0]);
               }
               etaRelToTauAxis(vertex, currentAxes[0], tau1_trackEtaRels);
               tau1_nSecondaryVertices += 1.;
       }

       GlobalVector flightDir = svTagInfo.flightDirection(vtx);
       if (reco::deltaR2(flightDir, jetDir)<(maxSVDeltaRToJet_*maxSVDeltaRToJet_))
         VTXmap[svTagInfo.flightDistance(vtx).error()]=vtx;
     }
     nSV = VTXmap.size();


     math::XYZTLorentzVector allSum = allKinematics.weightedVectorSum() ;
     if ( tau1_nSecondaryVertices > 0. )
     {
       math::XYZTLorentzVector tau1_vertexSum = tau1Kinematics.weightedVectorSum();
       if ( allSum.E() > 0. ) tau1_vertexEnergyRatio = tau1_vertexSum.E() / allSum.E();
       if ( tau1_vertexEnergyRatio > 50. ) tau1_vertexEnergyRatio = 50.;

       tau1_vertexMass = tau1_vertexSum.M();
     }

     if ( tau2_nSecondaryVertices > 0. )
     {
       math::XYZTLorentzVector tau2_vertexSum = tau2Kinematics.weightedVectorSum();
       if ( allSum.E() > 0. ) tau2_vertexEnergyRatio = tau2_vertexSum.E() / allSum.E();
       if ( tau2_vertexEnergyRatio > 50. ) tau2_vertexEnergyRatio = 50.;

       tau2_vertexMass= tau2_vertexSum.M();
     }


     float dummyEtaRel = -1.;

     std::sort( tau1_trackEtaRels.begin(),tau1_trackEtaRels.end() );
     std::sort( tau2_trackEtaRels.begin(),tau2_trackEtaRels.end() );

     switch(tau2_trackEtaRels.size()){
             case 0:

                     tau2_trackEtaRel_0 = dummyEtaRel;
                     tau2_trackEtaRel_1 = dummyEtaRel;
                     tau2_trackEtaRel_2 = dummyEtaRel;

                     break;

             case 1:

                     tau2_trackEtaRel_0 = tau2_trackEtaRels.at(0);
                     tau2_trackEtaRel_1 = dummyEtaRel;
                     tau2_trackEtaRel_2 = dummyEtaRel;

                     break;

             case 2:

                     tau2_trackEtaRel_0 = tau2_trackEtaRels.at(0);
                     tau2_trackEtaRel_1 = tau2_trackEtaRels.at(1);
                     tau2_trackEtaRel_2 = dummyEtaRel;

                     break;

             default:

                     tau2_trackEtaRel_0 = tau2_trackEtaRels.at(0);
                     tau2_trackEtaRel_1 = tau2_trackEtaRels.at(1);
                     tau2_trackEtaRel_2 = tau2_trackEtaRels.at(2);

     }

     switch(tau1_trackEtaRels.size()){
             case 0:

                     tau1_trackEtaRel_0 = dummyEtaRel;
                     tau1_trackEtaRel_1 = dummyEtaRel;
                     tau1_trackEtaRel_2 = dummyEtaRel;

                     break;

             case 1:

                     tau1_trackEtaRel_0 = tau1_trackEtaRels.at(0);
                     tau1_trackEtaRel_1 = dummyEtaRel;
                     tau1_trackEtaRel_2 = dummyEtaRel;

                     break;

             case 2:

                     tau1_trackEtaRel_0 = tau1_trackEtaRels.at(0);
                     tau1_trackEtaRel_1 = tau1_trackEtaRels.at(1);
                     tau1_trackEtaRel_2 = dummyEtaRel;

                     break;

             default:

                     tau1_trackEtaRel_0 = tau1_trackEtaRels.at(0);
                     tau1_trackEtaRel_1 = tau1_trackEtaRels.at(1);
                     tau1_trackEtaRel_2 = tau1_trackEtaRels.at(2);

     }

     int cont=0;
     GlobalVector flightDir_0, flightDir_1;
     reco::Candidate::LorentzVector SV_p4_0 , SV_p4_1;
     double vtxMass = 0.;

     for ( std::map<double, size_t>::iterator iVtx=VTXmap.begin(); iVtx!=VTXmap.end(); ++iVtx)
     {
       ++cont;
       const reco::VertexCompositePtrCandidate &vertex = svTagInfo.secondaryVertex(iVtx->second);
       if (cont==1)
       {
         flightDir_0 = svTagInfo.flightDirection(iVtx->second);
         SV_p4_0 = vertex.p4();
         vtxMass = SV_p4_0.mass();

         if(vtxMass > 0.)
           z_ratio = reco::deltaR(currentAxes[1],currentAxes[0])*SV_p4_0.pt()/vtxMass;
       }
       if (cont==2)
       {
         flightDir_1 = svTagInfo.flightDirection(iVtx->second);
         SV_p4_1 = vertex.p4();
         vtxMass = (SV_p4_1+SV_p4_0).mass();

         if(vtxMass > 0.)
           z_ratio = reco::deltaR(flightDir_0,flightDir_1)*SV_p4_1.pt()/vtxMass;

         break;
       }
     }

     // when only one tau axis has SVs assigned, they are all assigned to the 1st tau axis
     // in the special case below need to swap values
     if( (tau1_vertexMass<0 && tau2_vertexMass>0) )
     {
       float temp = tau1_trackEtaRel_0;
       tau1_trackEtaRel_0= tau2_trackEtaRel_0;
       tau2_trackEtaRel_0= temp;

       temp = tau1_trackEtaRel_1;
       tau1_trackEtaRel_1= tau2_trackEtaRel_1;
       tau2_trackEtaRel_1= temp;

       temp = tau1_trackEtaRel_2;
       tau1_trackEtaRel_2= tau2_trackEtaRel_2;
       tau2_trackEtaRel_2= temp;

       temp = tau1_flightDistance2dSig;
       tau1_flightDistance2dSig= tau2_flightDistance2dSig;
       tau2_flightDistance2dSig= temp;

       tau1_vertexDeltaR= tau2_vertexDeltaR;

       temp = tau1_vertexEnergyRatio;
       tau1_vertexEnergyRatio= tau2_vertexEnergyRatio;
       tau2_vertexEnergyRatio= temp;

       temp = tau1_vertexMass;
       tau1_vertexMass= tau2_vertexMass;
       tau2_vertexMass= temp;
     }

     reco::TaggingVariableList vars;

     vars.insert(reco::btau::jetNTracks, jetNTracks, true);
     vars.insert(reco::btau::jetNSecondaryVertices, nSV, true);
     vars.insert(reco::btau::trackSip3dSig_0, trackSip3dSig_0, true);
     vars.insert(reco::btau::trackSip3dSig_1, trackSip3dSig_1, true);
     vars.insert(reco::btau::trackSip3dSig_2, trackSip3dSig_2, true);
     vars.insert(reco::btau::trackSip3dSig_3, trackSip3dSig_3, true);
     vars.insert(reco::btau::tau1_trackSip3dSig_0, tau1_trackSip3dSig_0, true);
     vars.insert(reco::btau::tau1_trackSip3dSig_1, tau1_trackSip3dSig_1, true);
     vars.insert(reco::btau::tau2_trackSip3dSig_0, tau2_trackSip3dSig_0, true);
     vars.insert(reco::btau::tau2_trackSip3dSig_1, tau2_trackSip3dSig_1, true);
     vars.insert(reco::btau::trackSip2dSigAboveCharm, trackSip2dSigAboveCharm_0, true);
     vars.insert(reco::btau::trackSip2dSigAboveBottom_0, trackSip2dSigAboveBottom_0, true);
     vars.insert(reco::btau::trackSip2dSigAboveBottom_1, trackSip2dSigAboveBottom_1, true);
     vars.insert(reco::btau::tau1_trackEtaRel_0, tau1_trackEtaRel_0, true);
     vars.insert(reco::btau::tau1_trackEtaRel_1, tau1_trackEtaRel_1, true);
     vars.insert(reco::btau::tau1_trackEtaRel_2, tau1_trackEtaRel_2, true);
     vars.insert(reco::btau::tau2_trackEtaRel_0, tau2_trackEtaRel_0, true);
     vars.insert(reco::btau::tau2_trackEtaRel_1, tau2_trackEtaRel_1, true);
     vars.insert(reco::btau::tau2_trackEtaRel_2, tau2_trackEtaRel_2, true);
     vars.insert(reco::btau::tau1_vertexMass, tau1_vertexMass, true);
     vars.insert(reco::btau::tau1_vertexEnergyRatio, tau1_vertexEnergyRatio, true);
     vars.insert(reco::btau::tau1_flightDistance2dSig, tau1_flightDistance2dSig, true);
     vars.insert(reco::btau::tau1_vertexDeltaR, tau1_vertexDeltaR, true);
     vars.insert(reco::btau::tau2_vertexMass, tau2_vertexMass, true);
     vars.insert(reco::btau::tau2_vertexEnergyRatio, tau2_vertexEnergyRatio, true);
     vars.insert(reco::btau::tau2_flightDistance2dSig, tau2_flightDistance2dSig, true);
     vars.insert(reco::btau::z_ratio, z_ratio, true);

     vars.finalize();

     tagInfos->push_back( reco::BoostedDoubleSVTagInfo(vars, edm::Ref<std::vector<reco::CandSecondaryVertexTagInfo> >(svTagInfos, iterTI - svTagInfos->begin())) );
   }

   // put the output in the event
   iEvent.put( std::move(tagInfos) );
}


void
BoostedDoubleSVProducer::calcNsubjettiness(const reco::JetBaseRef & jet, float & tau1, float & tau2, std::vector<fastjet::PseudoJet> & currentAxes) const
{
  std::vector<fastjet::PseudoJet> fjParticles;

  // loop over jet constituents and push them in the vector of FastJet constituents
  for(const reco::CandidatePtr & daughter : jet->daughterPtrVector())
  {
    if ( daughter.isNonnull() && daughter.isAvailable() )
    {
      const reco::Jet * subjet = dynamic_cast<const reco::Jet *>(daughter.get());
      // if the daughter is actually a subjet
      if( subjet && daughter->numberOfDaughters() > 1 )
      {
        // loop over subjet constituents and push them in the vector of FastJet constituents
        for(size_t i=0; i<daughter->numberOfDaughters(); ++i)
        {
          const reco::Candidate * constit = daughter->daughter(i);

          if ( constit )
            fjParticles.push_back( fastjet::PseudoJet( constit->px(), constit->py(), constit->pz(), constit->energy() ) );
          else
            edm::LogWarning("MissingJetConstituent") << "Jet constituent required for N-subjettiness computation is missing!";
        }
      }
      else
        fjParticles.push_back( fastjet::PseudoJet( daughter->px(), daughter->py(), daughter->pz(), daughter->energy() ) );
    }
    else
      edm::LogWarning("MissingJetConstituent") << "Jet constituent required for N-subjettiness computation is missing!";
  }

  // N-subjettiness calculator
  fastjet::contrib::Njettiness njettiness(fastjet::contrib::OnePass_KT_Axes(), fastjet::contrib::NormalizedMeasure(beta_,R0_));

  // calculate N-subjettiness
  tau1 = njettiness.getTau(1, fjParticles);
  tau2 = njettiness.getTau(2, fjParticles);
  currentAxes = njettiness.currentAxes();
}


void
BoostedDoubleSVProducer::setTracksPVBase(const reco::TrackRef & trackRef, const reco::VertexRef & vertexRef, float & PVweight) const
{
  PVweight = 0.;

  const reco::TrackBaseRef trackBaseRef( trackRef );

  typedef reco::Vertex::trackRef_iterator IT;

  const reco::Vertex & vtx = *(vertexRef);
  // loop over tracks in vertices
  for(IT it=vtx.tracks_begin(); it!=vtx.tracks_end(); ++it)
  {
    const reco::TrackBaseRef & baseRef = *it;
    // one of the tracks in the vertex is the same as the track considered in the function
    if( baseRef == trackBaseRef )
    {
      PVweight = vtx.trackWeight(baseRef);
      break;
    }
  }
}


void
BoostedDoubleSVProducer::setTracksPV(const reco::CandidatePtr & trackRef, const reco::VertexRef & vertexRef, float & PVweight) const
{
  PVweight = 0.;

  const pat::PackedCandidate * pcand = dynamic_cast<const pat::PackedCandidate *>(trackRef.get());

  if(pcand) // MiniAOD case
  {
    if( pcand->fromPV() == pat::PackedCandidate::PVUsedInFit )
    {
      PVweight = 1.;
    }
  }
  else
  {
    const reco::PFCandidate * pfcand = dynamic_cast<const reco::PFCandidate *>(trackRef.get());

    setTracksPVBase(pfcand->trackRef(), vertexRef, PVweight);
  }
}


void
BoostedDoubleSVProducer::etaRelToTauAxis(const reco::VertexCompositePtrCandidate & vertex, const fastjet::PseudoJet & tauAxis, std::vector<float> & tau_trackEtaRel) const
{
  math::XYZVector direction(tauAxis.px(), tauAxis.py(), tauAxis.pz());
  const std::vector<reco::CandidatePtr> & tracks = vertex.daughterPtrVector();

  for(std::vector<reco::CandidatePtr>::const_iterator track = tracks.begin(); track != tracks.end(); ++track)
    tau_trackEtaRel.push_back(std::abs(reco::btau::etaRel(direction.Unit(), (*track)->momentum())));
}

// ------------ method called once each stream before processing any runs, lumis or events  ------------
void
BoostedDoubleSVProducer::beginStream(edm::StreamID)
{
}

// ------------ method called once each stream after processing all runs, lumis and events  ------------
void
BoostedDoubleSVProducer::endStream() {
}

// ------------ method fills 'descriptions' with the allowed parameters for the module  ------------
void
BoostedDoubleSVProducer::fillDescriptions(edm::ConfigurationDescriptions& descriptions) {
  //The following says we do not know what parameters are allowed so do no validation
  // Please change this to state exactly what you do use, even if it is no parameters
  edm::ParameterSetDescription desc;
  desc.setUnknown();
  descriptions.addDefault(desc);
}

//define this as a plug-in
DEFINE_FWK_MODULE(BoostedDoubleSVProducer);