#include <DAClusterizerInZ_vect.h>

Inheritance diagram for DAClusterizerInZ_vect:

Classes
struct	track_t

struct	vertex_t

Public Member Functions
double	beta0 (const double betamax, track_t &tks, vertex_t &y) const

std::vector< std::vector < reco::TransientTrack > >	clusterize (const std::vector< reco::TransientTrack > &tracks) const

	DAClusterizerInZ_vect (const edm::ParameterSet &conf)

void	dump (const double beta, const vertex_t &y, const track_t &tks, const int verbosity=0) const

double	Eik (double const &t_z, double const &k_z, double const &t_dz2) const

track_t	fill (const std::vector< reco::TransientTrack > &tracks) const

double	local_exp (double const &inp) const

void	local_exp_list (double arg_inp, double arg_out, const int arg_arr_size) const

bool	merge (vertex_t &) const

bool	merge (vertex_t &y, double &beta) const

bool	purge (vertex_t &, track_t &, double &, const double) const

bool	split (const double beta, track_t &t, vertex_t &y) const

void	splitAll (vertex_t &y) const

double	update (double beta, track_t &gtracks, vertex_t &gvertices, bool useRho0, double &rho0) const

std::vector< TransientVertex >	vertices (const std::vector< reco::TransientTrack > &tracks, const int verbosity=0) const

Public Member Functions inherited from TrackClusterizerInZ
	TrackClusterizerInZ ()

	TrackClusterizerInZ (const edm::ParameterSet &conf)

virtual	~TrackClusterizerInZ ()

Private Attributes
float	betamax_

float	betastop_

double	coolingFactor_

double	d0CutOff_

double	dzCutOff_

int	maxIterations_

bool	use_vdt_

bool	useTc_

bool	verbose_

float	vertexSize_

Detailed Description

Description: separates event tracks into clusters along the beam line

Version which auto-vectorizes with gcc 4.6 or newer

Definition at line 21 of file DAClusterizerInZ_vect.h.

Constructor & Destructor Documentation

DAClusterizerInZ_vect::DAClusterizerInZ_vect ( const edm::ParameterSet & conf )

Definition at line 15 of file DAClusterizerInZ_vect.cc.

References edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), LogDebug, and builder_last_value_cfg::Tmin.

                                                                         {
 
     // some defaults to avoid uninitialized variables
     verbose_ = conf.getUntrackedParameter<bool> ("verbose", false);
     use_vdt_ = conf.getUntrackedParameter<bool> ("use_vdt", false);
 
     betamax_ = 0.1;
     betastop_ = 1.0;
     coolingFactor_ = 0.6;
     maxIterations_ = 100;
     vertexSize_ = 0.01; // 0.1 mm
     dzCutOff_ = 4.0;  
 
     // configure
 
     double Tmin = conf.getParameter<double> ("Tmin");
     vertexSize_ = conf.getParameter<double> ("vertexSize");
     coolingFactor_ = conf.getParameter<double> ("coolingFactor");
     useTc_=true;
     if(coolingFactor_<0){
       coolingFactor_=-coolingFactor_; 
       useTc_=false;
     }
     d0CutOff_ = conf.getParameter<double> ("d0CutOff");
     dzCutOff_ = conf.getParameter<double> ("dzCutOff");
     maxIterations_ = 100;
     if (Tmin == 0) {
         LogDebug("DAClusterizerinZ_vectorized")  << "DAClusterizerInZ: invalid Tmin" << Tmin
                 << "  reset do default " << 1. / betamax_ << endl;
     } else {
         betamax_ = 1. / Tmin;
     }
 
 }

Member Function Documentation

double DAClusterizerInZ_vect::beta0	(	const double	betamax,
		track_t &	tks,
		vertex_t &	y
	)		const

Definition at line 378 of file DAClusterizerInZ_vect.cc.

References DAClusterizerInZ_vect::track_t::_dz2, DAClusterizerInZ_vect::track_t::_pi, DAClusterizerInZ_vect::track_t::_z, DAClusterizerInZ_vect::vertex_t::_z, a, b, DAClusterizerInZ_vect::track_t::GetSize(), DAClusterizerInZ_vect::vertex_t::GetSize(), i, gen::k, fff_deleter::log, nt, funct::pow(), and w.

                                                                                      {
 
     double T0 = 0; // max Tc for beta=0
     // estimate critical temperature from beta=0 (T=inf)
     const unsigned int nt = tks.GetSize();
     const unsigned int nv = y.GetSize();
 
     for (unsigned int k = 0; k < nv; k++) {
 
         // vertex fit at T=inf
         double sumwz = 0;
         double sumw = 0;
         for (unsigned int i = 0; i < nt; i++) {
             double w = tks._pi[i] / tks._dz2[i];
             sumwz += w * tks._z[i];
             sumw += w;
         }
         y._z[k] = sumwz / sumw;
 
         // estimate Tcrit, eventually do this in the same loop
         double a = 0, b = 0;
         for (unsigned int i = 0; i < nt; i++) {
             double dx = tks._z[i] - (y._z[k]);
             double w = tks._pi[i] / tks._dz2[i];
             a += w * pow(dx, 2) / tks._dz2[i];
             b += w;
         }
         double Tc = 2. * a / b; // the critical temperature of this vertex
         if (Tc > T0)
             T0 = Tc;
     }// vertex loop (normally there should be only one vertex at beta=0)
 
     if (T0 > 1. / betamax) {
         return betamax / pow(coolingFactor_, int(log(T0 * betamax) / log(
                 coolingFactor_)) - 1);
     } else {
         // ensure at least one annealing step
         return betamax / coolingFactor_;
     }
 }

vector< vector< reco::TransientTrack > > DAClusterizerInZ_vect::clusterize ( const std::vector< reco::TransientTrack > & tracks ) const

virtual

Implements TrackClusterizerInZ.

Definition at line 802 of file DAClusterizerInZ_vect.cc.

References gather_cfg::cout, i, gen::k, LogDebug, and position.

                                                          {
                   
     if (verbose_) {
         std::cout  << "###################################################" << endl;
         std::cout  << "# vectorized DAClusterizerInZ_vect::clusterize   nt=" << tracks.size() << endl;
         std::cout  << "###################################################" << endl;
     }
 
     vector<vector<reco::TransientTrack> > clusters;
     vector<TransientVertex> pv = vertices(tracks);
 
     if (verbose_) {
         LogDebug("DAClusterizerinZ_vectorized")  << "# DAClusterizerInZ::clusterize   pv.size=" << pv.size()
                 << endl;
     }
     if (pv.size() == 0) {
         return clusters;
     }
 
     // fill into clusters and merge
     vector<reco::TransientTrack> aCluster = pv.begin()->originalTracks();
 
     for (vector<TransientVertex>::iterator k = pv.begin() + 1; k != pv.end(); k++) {
             if ( fabs(k->position().z() - (k - 1)->position().z()) > (2 * vertexSize_)) {
             // close a cluster
             clusters.push_back(aCluster);
             aCluster.clear();
         }
         for (unsigned int i = 0; i < k->originalTracks().size(); i++) {
             aCluster.push_back(k->originalTracks().at(i));
         }
 
     }
     clusters.push_back(aCluster);
 
     return clusters;
 
 }

void DAClusterizerInZ_vect::dump	(	const double	beta,
		const vertex_t &	y,
		const track_t &	tks,
		const int	verbosity = `0`
	)		const

Definition at line 546 of file DAClusterizerInZ_vect.cc.

                                                   {
 
     const unsigned int nv = y.GetSize();
     const unsigned int nt = tks.GetSize();
 
     LogDebug("DAClusterizerinZ_vectorized")  << "-----DAClusterizerInZ::dump ----" << endl;
     LogDebug("DAClusterizerinZ_vectorized")  << "beta=" << beta << "   betamax= " << betamax_ << endl;
     LogDebug("DAClusterizerinZ_vectorized")  << "                                                               z= ";
     LogDebug("DAClusterizerinZ_vectorized")  << setprecision(4);
     for (unsigned int ivertex = 0; ivertex < nv; ++ ivertex) {
         LogDebug("DAClusterizerinZ_vectorized")  << setw(8) << fixed << y._z[ivertex];
     }
     LogDebug("DAClusterizerinZ_vectorized")  << endl << "T=" << setw(15) << 1. / beta
             << "                                            Tc= ";
     LogDebug("DAClusterizerinZ_vectorized")  << endl
             << "                                                               pk=";
     double sumpk = 0;
     for (unsigned int ivertex = 0; ivertex < nv; ++ ivertex) {
         LogDebug("DAClusterizerinZ_vectorized")  << setw(8) << setprecision(3) << fixed << y._pk[ivertex];
         sumpk += y._pk[ivertex];
     }
     LogDebug("DAClusterizerinZ_vectorized")  << endl;
 
     if (verbosity > 0) {
         double E = 0, F = 0;
         LogDebug("DAClusterizerinZ_vectorized")  << endl;
         LogDebug("DAClusterizerinZ_vectorized") 
         << "----       z +/- dz                ip +/-dip       pt    phi  eta    weights  ----"
         << endl;
         LogDebug("DAClusterizerinZ_vectorized")  << setprecision(4);
         for (unsigned int i = 0; i < nt; i++) {
             if (tks._Z_sum[i] > 0) {
                 F -= log(tks._Z_sum[i]) / beta;
             }
             double tz = tks._z[i];
             LogDebug("DAClusterizerinZ_vectorized")  << setw(3) << i << ")" << setw(8) << fixed << setprecision(4)
              << tz << " +/-" << setw(6) << sqrt(tks._dz2[i]);
 
             if (tks.tt[i]->track().quality(reco::TrackBase::highPurity)) {
                 LogDebug("DAClusterizerinZ_vectorized")  << " *";
             } else {
                 LogDebug("DAClusterizerinZ_vectorized")  << "  ";
             }
             if (tks.tt[i]->track().hitPattern().hasValidHitInFirstPixelBarrel()) {
                 LogDebug("DAClusterizerinZ_vectorized")  << "+";
             } else {
                 LogDebug("DAClusterizerinZ_vectorized")  << "-";
             }
             LogDebug("DAClusterizerinZ_vectorized")  << setw(1)
              << tks.tt[i]->track().hitPattern().pixelBarrelLayersWithMeasurement(); // see DataFormats/TrackReco/interface/HitPattern.h
             LogDebug("DAClusterizerinZ_vectorized")  << setw(1)
              << tks.tt[i]->track().hitPattern().pixelEndcapLayersWithMeasurement();
             LogDebug("DAClusterizerinZ_vectorized")  << setw(1) << hex
                     << tks.tt[i]->track().hitPattern().trackerLayersWithMeasurement()
                     - tks.tt[i]->track().hitPattern().pixelLayersWithMeasurement()
                     << dec;
             LogDebug("DAClusterizerinZ_vectorized")  << "=" << setw(1) << hex
                     << tks.tt[i]->track().trackerExpectedHitsOuter().numberOfHits()
                     << dec;
 
             Measurement1D IP =
                     tks.tt[i]->stateAtBeamLine().transverseImpactParameter();
             LogDebug("DAClusterizerinZ_vectorized")  << setw(8) << IP.value() << "+/-" << setw(6) << IP.error();
             LogDebug("DAClusterizerinZ_vectorized")  << " " << setw(6) << setprecision(2)
              << tks.tt[i]->track().pt() * tks.tt[i]->track().charge();
             LogDebug("DAClusterizerinZ_vectorized")  << " " << setw(5) << setprecision(2)
              << tks.tt[i]->track().phi() << " " << setw(5)
              << setprecision(2) << tks.tt[i]->track().eta();
 
             double sump = 0.;
             for (unsigned int ivertex = 0; ivertex < nv; ++ ivertex) {
                 if ((tks._pi[i] > 0) && (tks._Z_sum[i] > 0)) {
                     //double p=pik(beta,tks[i],*k);
                     double p = y._pk[ivertex]  * exp(-beta * Eik(tks._z[i], y._z[ivertex], tks._dz2[i])) / tks._Z_sum[i];
                     if (p > 0.0001) {
                         LogDebug("DAClusterizerinZ_vectorized")  << setw(8) << setprecision(3) << p;
                     } else {
                         LogDebug("DAClusterizerinZ_vectorized")  << "    .   ";
                     }
                     E += p * Eik(tks._z[i], y._z[ivertex], tks._dz2[i]);
                     sump += p;
                 } else {
                     LogDebug("DAClusterizerinZ_vectorized")  << "        ";
                 }
             }
             LogDebug("DAClusterizerinZ_vectorized")  << endl;
         }
         LogDebug("DAClusterizerinZ_vectorized")  << endl << "T=" << 1 / beta << " E=" << E << " n=" << y.GetSize()
              << "  F= " << F << endl << "----------" << endl;
     }
 }

double DAClusterizerInZ_vect::Eik	(	double const &	t_z,
		double const &	k_z,
		double const &	t_dz2
	)		const

Definition at line 110 of file DAClusterizerInZ_vect.cc.

References funct::pow().

 {
     return pow(t_z - k_z, 2) / t_dz2;
 }

DAClusterizerInZ_vect::track_t DAClusterizerInZ_vect::fill ( const std::vector< reco::TransientTrack > & tracks ) const

Definition at line 70 of file DAClusterizerInZ_vect.cc.

References DAClusterizerInZ_vect::track_t::AddItem(), SiPixelRawToDigiRegional_cfi::beamSpot, funct::cos(), Measurement1D::error(), DAClusterizerInZ_vect::track_t::ExtractRaw(), DAClusterizerInZ_vect::track_t::GetSize(), listHistos::IP, LogDebug, phi, position, funct::pow(), funct::sin(), funct::tan(), testEve_cfg::tracks, and Measurement1D::value().

                                             {
 
     // prepare track data for clustering
     track_t tks;
     for (vector<reco::TransientTrack>::const_iterator it = tracks.begin(); it
             != tracks.end(); it++)
     {
         double t_pi;
         double t_z = ((*it).stateAtBeamLine().trackStateAtPCA()).position().z();
         double phi=((*it).stateAtBeamLine().trackStateAtPCA()).momentum().phi();
         double tantheta = tan(
                 ((*it).stateAtBeamLine().trackStateAtPCA()).momentum().theta());
         //  get the beam-spot
         reco::BeamSpot beamspot = (it->stateAtBeamLine()).beamSpot();
         double t_dz2 = 
               pow((*it).track().dzError(), 2) // track errror
           + (pow(beamspot.BeamWidthX()*cos(phi),2)+pow(beamspot.BeamWidthY()*sin(phi),2))/pow(tantheta,2)  // beam-width
           + pow(vertexSize_, 2); // intrinsic vertex size, safer for outliers and short lived decays
         if (d0CutOff_ > 0) {
             Measurement1D IP =
                     (*it).stateAtBeamLine().transverseImpactParameter();// error constains beamspot
             t_pi = 1. / (1. + local_exp(pow(IP.value() / IP.error(), 2) - pow(
                     d0CutOff_, 2))); // reduce weight for high ip tracks
         } else {
             t_pi = 1.;
         }
 
         tks.AddItem(t_z, t_dz2, &(*it), t_pi);
     }
         tks.ExtractRaw();
 
     if (verbose_) {
         LogDebug("DAClusterizerinZ_vectorized") << "Track count " << tks.GetSize() << std::endl;
     }
 
     return tks;
 }

double DAClusterizerInZ_vect::local_exp ( double const & inp ) const

inline

Definition at line 50 of file DAClusterizerInZ_vect.cc.

References create_public_lumi_plots::exp.

         {
             if ( use_vdt_)
                           return vdt::fast_exp( inp );
 
             return std::exp( inp );
         }

void DAClusterizerInZ_vect::local_exp_list	(	double *	arg_inp,
		double *	arg_out,
		const int	arg_arr_size
	)		const

inline

Definition at line 58 of file DAClusterizerInZ_vect.cc.

References create_public_lumi_plots::exp, and i.

         {
             if ( use_vdt_){
 //                          std::cout << "I use vdt!\n";
                             for(int i=0; i!=arg_arr_size; ++i ) arg_out[i]=vdt::fast_exp(arg_inp[i]);
                    // vdt::fast_expv(arg_arr_size, arg_inp, arg_out);
                         }
                         else
                           for(int i=0; i!=arg_arr_size; ++i ) arg_out[i]=std::exp(arg_inp[i]);
         }

bool DAClusterizerInZ_vect::merge ( vertex_t & y ) const

Definition at line 299 of file DAClusterizerInZ_vect.cc.

References DAClusterizerInZ_vect::vertex_t::_pk, DAClusterizerInZ_vect::vertex_t::_z, DAClusterizerInZ_vect::vertex_t::GetSize(), gen::k, LogDebug, and DAClusterizerInZ_vect::vertex_t::RemoveItem().

                                                     {
     // merge clusters that collapsed or never separated, return true if vertices were merged, false otherwise
 
     const unsigned int nv = y.GetSize();
 
     if (nv < 2)
         return false;
 
     for (unsigned int k = 0; (k + 1) < nv; k++) {
         //if ((k+1)->z - k->z<1.e-2){  // note, no fabs here, maintains z-ordering  (with split()+merge() at every temperature)
         if (fabs(y._z[k + 1] - y._z[k]) < 1.e-2) { // with fabs if only called after freeze-out (splitAll() at highter T)
             y._pk[k] += y._pk[k + 1];
             y._z[k] = 0.5 * (y._z[k] + y._z[k + 1]);
 
             y.RemoveItem(k + 1);
 
             if ( verbose_)
             {
                 LogDebug("DAClusterizerinZ_vectorized") << "Merging vertices k = " << k << std::endl;
             }
 
             return true;
         }
     }
 
     return false;
 }

bool DAClusterizerInZ_vect::merge	(	vertex_t &	y,
		double &	beta
	)		const

Definition at line 261 of file DAClusterizerInZ_vect.cc.

References DAClusterizerInZ_vect::vertex_t::_pk, DAClusterizerInZ_vect::vertex_t::_sw, DAClusterizerInZ_vect::vertex_t::_swE, DAClusterizerInZ_vect::vertex_t::_z, DAClusterizerInZ_vect::vertex_t::GetSize(), gen::k, funct::pow(), DAClusterizerInZ_vect::vertex_t::RemoveItem(), and rho.

                                                                  {
   // merge clusters that collapsed or never separated,
   // only merge if the estimated critical temperature of the merged vertex is below the current temperature
   // return true if vertices were merged, false otherwise
   const unsigned int nv = y.GetSize();
 
   if (nv < 2)
     return false;
 
 
   for (unsigned int k = 0; (k + 1) < nv; k++) {
     if (fabs(y._z[k + 1] - y._z[k]) < 2.e-2) {
       double rho=y._pk[k] + y._pk[k+1];
       double swE=y._swE[k]+y._swE[k+1] - y._pk[k]*y._pk[k+1] /rho *pow(y._z[k+1]-y._z[k],2);
       double Tc=2*swE/(y._sw[k]+y._sw[k+1]);
 
       if(Tc*beta<1){
         if(rho>0){
       y._z[k] = (y._pk[k]*y._z[k] + y._pk[k+1]*y._z[k + 1])/rho;
         }else{
       y._z[k] = 0.5 * (y._z[k] + y._z[k + 1]);
         }
         y._pk[k] = rho;
         y._sw[k]+=y._sw[k+1];
         y._swE[k]=swE;
         y.RemoveItem(k+1);
         return true;
       }
     }
   }
 
   return false;
 }

bool DAClusterizerInZ_vect::purge	(	vertex_t &	y,
		track_t &	tks,
		double &	rho0,
		const double	beta
	)		const

Definition at line 327 of file DAClusterizerInZ_vect.cc.

References DAClusterizerInZ_vect::track_t::_dz2, DAClusterizerInZ_vect::track_t::_pi, DAClusterizerInZ_vect::vertex_t::_pk, DAClusterizerInZ_vect::track_t::_z, DAClusterizerInZ_vect::vertex_t::_z, DAClusterizerInZ_vect::track_t::_Z_sum, DAClusterizerInZ_vect::track_t::GetSize(), DAClusterizerInZ_vect::vertex_t::GetSize(), i, gen::k, SiStripMonitorClusterAlca_cfi::k0, LogDebug, nt, AlCaHLTBitMon_ParallelJobs::p, and DAClusterizerInZ_vect::vertex_t::RemoveItem().

                                  {
     // eliminate clusters with only one significant/unique track
     const unsigned int nv = y.GetSize();
     const unsigned int nt = tks.GetSize();
 
     if (nv < 2)
         return false;
 
     double sumpmin = nt;
     unsigned int k0 = nv;
 
     for (unsigned int k = 0; k < nv; k++) {
 
         int nUnique = 0;
         double sump = 0;
         double pmax = y._pk[k] / (y._pk[k] + rho0 * local_exp(-beta * dzCutOff_
                 * dzCutOff_));
 
         for (unsigned int i = 0; i < nt; i++) {
 
             if (tks._Z_sum[i] > 0) {
                 //double p=pik(beta,tks[i],*k);
                 double p = y._pk[k] * local_exp(-beta * Eik(tks._z[i], y._z[k],
                         tks._dz2[i])) / tks._Z_sum[i];
                 sump += p;
                 if ((p > 0.9 * pmax) && (tks._pi[i] > 0)) {
                     nUnique++;
                 }
             }
         }
 
         if ((nUnique < 2) && (sump < sumpmin)) {
             sumpmin = sump;
             k0 = k;
         }
     }
 
     if (k0 != nv) {
         if (verbose_) {
             LogDebug("DAClusterizerinZ_vectorized")  << "eliminating prototype at " << y._z[k0] << " with sump="
                     << sumpmin << endl;
         }
         //rho0+=k0->pk;
         y.RemoveItem(k0);
         return true;
     } else {
         return false;
     }
 }

bool DAClusterizerInZ_vect::split	(	const double	beta,
		track_t &	t,
		vertex_t &	y
	)		const

Definition at line 420 of file DAClusterizerInZ_vect.cc.

                                                                                       {
   // split only critical vertices (Tc >~ T=1/beta   <==>   beta*Tc>~1)
   // an update must have been made just before doing this (same beta, no merging)
   // returns true if at least one cluster was split
 
   double epsilon=1e-3;      // split all single vertices by 10 um
   unsigned int nv = y.GetSize();
 
   // avoid left-right biases by splitting highest Tc first
 
   std::vector<std::pair<double, unsigned int> > critical;
   for(unsigned int k=0; k<nv; k++){
     double Tc= 2*y._swE[k]/y._sw[k];
     if (beta*Tc > 1.){
       critical.push_back( make_pair(Tc, k));
     }
   }
   if (critical.size()==0) return false;
   stable_sort(critical.begin(), critical.end(), std::greater<std::pair<double, unsigned int> >() );
 
 
   bool split=false;
   const unsigned int nt = tks.GetSize();
 
   for(unsigned int ic=0; ic<critical.size(); ic++){
     unsigned int k=critical[ic].second;
     // estimate subcluster positions and weight
     double p1=0, z1=0, w1=0;
     double p2=0, z2=0, w2=0;
     for(unsigned int i=0; i<nt; i++){
       if (tks._Z_sum[i] > 0) {
     double p = y._pk[k] * local_exp(-beta * Eik(tks._z[i], y._z[k],
                             tks._dz2[i])) / tks._Z_sum[i];
 
         double w=p/tks._dz2[i];
         if(tks._z[i]<y._z[k]){
           p1+=p; z1+=w*tks._z[i]; w1+=w;
         }else{
           p2+=p; z2+=w*tks._z[i]; w2+=w;
         }
       }
     }
     if(w1>0){  z1=z1/w1;} else{z1=y._z[k]-epsilon;}
     if(w2>0){  z2=z2/w2;} else{z2=y._z[k]+epsilon;}
 
     // reduce split size if there is not enough room
     if( ( k   > 0 ) && ( y._z[k-1]>=z1 ) ){ z1=0.5*(y._z[k]+y._z[k-1]); }
     if( ( k+1 < nv) && ( y._z[k+1]<=z2 ) ){ z2=0.5*(y._z[k]+y._z[k+1]); }
 
     // split if the new subclusters are significantly separated
     if( (z2-z1)>epsilon){
       split=true;
       double pk1=p1*y._pk[k]/(p1+p2);
       double pk2=p2*y._pk[k]/(p1+p2);
       y._z[k]  =  z2;
       y._pk[k] = pk2;
       y.InsertItem(k, z1, pk1);
       nv++;
 
      // adjust remaining pointers
       for(unsigned int jc=ic; jc<critical.size(); jc++){
         if (critical[jc].second>k) {critical[jc].second++;}
       }
     }
   }
   return split;
 }

void DAClusterizerInZ_vect::splitAll ( vertex_t & y ) const

Definition at line 490 of file DAClusterizerInZ_vect.cc.

References DAClusterizerInZ_vect::vertex_t::_pk, DAClusterizerInZ_vect::vertex_t::_z, DAClusterizerInZ_vect::vertex_t::AddItem(), DAClusterizerInZ_vect::vertex_t::DebugOut(), alignCSCRings::e, epsilon, DAClusterizerInZ_vect::vertex_t::ExtractRaw(), DAClusterizerInZ_vect::vertex_t::GetSize(), gen::k, LogDebug, DAClusterizerInZ_vect::vertex_t::pk, and DAClusterizerInZ_vect::vertex_t::z.

                                                         {
 
     const unsigned int nv = y.GetSize();
 
     double epsilon = 1e-3; // split all single vertices by 10 um
     double zsep = 2 * epsilon; // split vertices that are isolated by at least zsep (vertices that haven't collapsed)
     vertex_t y1;
 
     if (verbose_)
     {
         LogDebug("DAClusterizerinZ_vectorized") << "Before Split "<< std::endl;
         y.DebugOut();
     }
 
     for (unsigned int k = 0; k < nv; k++) {
 
         if (
                 ( (k == 0)          || ( y._z[k - 1]    < (y._z[k] - zsep)) ) &&
                 ( ((k + 1) == nv)   || ( y._z[k + 1]    > (y._z[k] + zsep)) )   )
         {
             // isolated prototype, split
             double new_z = y.z[k] - epsilon;
             y.z[k] = y.z[k] + epsilon;
 
             double new_pk = 0.5 * y.pk[k];
             y.pk[k] = 0.5 * y.pk[k];
 
             y1.AddItem(new_z, new_pk);
             y1.AddItem(y._z[k], y._pk[k]);
 
         }
         else if ( (y1.GetSize() == 0 ) ||
                 (y1._z[y1.GetSize() - 1] <  (y._z[k] - zsep)  ))
         {
 
             y1.AddItem(y._z[k], y._pk[k]);
         }
         else
         {
             y1._z[y1.GetSize() - 1] = y1._z[y1.GetSize() - 1] - epsilon;
             y._z[k] = y._z[k] + epsilon;
             y1.AddItem( y._z[k] , y._pk[k]);
         }
     }// vertex loop
 
     y = y1;
     y.ExtractRaw();
 
     if (verbose_)
     {
         LogDebug("DAClusterizerinZ_vectorized") << "After split " << std::endl;
         y.DebugOut();
     }
 }

double DAClusterizerInZ_vect::update	(	double	beta,
		track_t &	gtracks,
		vertex_t &	gvertices,
		bool	useRho0,
		double &	rho0
	)		const

Definition at line 116 of file DAClusterizerInZ_vect.cc.

References DAClusterizerInZ_vect::vertex_t::_ei, DAClusterizerInZ_vect::vertex_t::_ei_cache, DAClusterizerInZ_vect::track_t::_pi, DAClusterizerInZ_vect::vertex_t::_se, DAClusterizerInZ_vect::vertex_t::_sw, DAClusterizerInZ_vect::vertex_t::_swE, DAClusterizerInZ_vect::vertex_t::_swz, DAClusterizerInZ_vect::track_t::_Z_sum, beta, delta, DAClusterizerInZ_vect::track_t::GetSize(), DAClusterizerInZ_vect::vertex_t::GetSize(), gen::k, LogDebug, nt, funct::pow(), testEve_cfg::tracks, and w.

                                                                  {
 
     //update weights and vertex positions
     // mass constrained annealing without noise
     // returns the squared sum of changes of vertex positions
 
     const unsigned int nt = gtracks.GetSize();
     const unsigned int nv = gvertices.GetSize();
 
     //initialize sums
     double sumpi = 0;
 
     // to return how much the prototype moved
     double delta = 0;
 
     unsigned int itrack;
     unsigned int ivertex;
 
     // intial value of a sum
     double Z_init = 0;
 
     // define kernels
     auto kernel_calc_exp_arg = [ &beta, nv ] (
             const unsigned int itrack,
             track_t const& tracks,
             vertex_t const& vertices )
     {
         const double track_z = tracks._z[itrack];
         const double track_dz2 = tracks._dz2[itrack];
 
         // auto-vectorized
         for ( unsigned int ivertex = 0; ivertex < nv; ++ivertex)
         {
             double mult_res = ( track_z - vertices._z[ivertex] );
             vertices._ei_cache[ivertex] = -beta *
             ( mult_res * mult_res ) / track_dz2;
         }
     };
 
     // auto kernel_add_Z = [ nv, &Z_init ] (vertex_t const& vertices) raises a warning
     // we declare the return type with " -> double"
     auto kernel_add_Z = [ nv, &Z_init ] (vertex_t const& vertices) -> double
     {
         double ZTemp = Z_init;
  
         for (unsigned int ivertex = 0; ivertex < nv; ++ivertex) {
 
             ZTemp += vertices._pk[ivertex] * vertices._ei[ivertex];
         }
         return ZTemp;
     };
 
     auto kernel_calc_normalization = [ &beta, nv ] (const unsigned int track_num,
             track_t & tks_vec,
             vertex_t & y_vec )
     {
         double w;
 
         const double tmp_trk_pi = tks_vec._pi[track_num];
         const double tmp_trk_Z_sum = tks_vec._Z_sum[track_num];
         const double tmp_trk_dz2 = tks_vec._dz2[track_num];
         const double tmp_trk_z = tks_vec._z[track_num];
 
         // auto-vectorized
         for (unsigned int k = 0; k < nv; ++k) {
             y_vec._se[k] += tmp_trk_pi* y_vec._ei[k] / tmp_trk_Z_sum;
             w = y_vec._pk[k] * tmp_trk_pi * y_vec._ei[k] / tmp_trk_Z_sum / tmp_trk_dz2;
             y_vec._sw[k]  += w;
             y_vec._swz[k] += w * tmp_trk_z;
             y_vec._swE[k] += w * y_vec._ei_cache[k]/(-beta);
         }
     };
 
     // not vectorized
     for (ivertex = 0; ivertex < nv; ++ivertex) {
         gvertices._se[ivertex] = 0.0;
         gvertices._sw[ivertex] = 0.0;
         gvertices._swz[ivertex] = 0.0;
         gvertices._swE[ivertex] = 0.0;
     }
 
 
     // independpent of loop
     if ( useRho0 )
     {
         Z_init = rho0 * local_exp(-beta * dzCutOff_ * dzCutOff_); // cut-off
     }
 
     // loop over tracks
     for (itrack = 0; itrack < nt; ++itrack) {
         kernel_calc_exp_arg(itrack, gtracks, gvertices);
         local_exp_list(gvertices._ei_cache, gvertices._ei, nv);
         //vdt::cephes_single_exp_vect( y_vec._ei, nv );
 
         gtracks._Z_sum[itrack] = kernel_add_Z(gvertices);
 
         // used in the next major loop to follow
         if (!useRho0)
             sumpi += gtracks._pi[itrack];
 
         if (gtracks._Z_sum[itrack] > 0) {
             kernel_calc_normalization(itrack, gtracks, gvertices);
         }
     }
 
     // now update z and pk
     auto kernel_calc_z = [ &delta, &sumpi, nv, this, useRho0 ] (vertex_t & vertices )
     {
         // does not vectorizes
         for (unsigned int ivertex = 0; ivertex < nv; ++ ivertex )
         {
             if (vertices._sw[ivertex] > 0)
             {
                 double znew = vertices._swz[ ivertex ] / vertices._sw[ ivertex ];
 
                 // prevents from vectorizing
                 delta += pow( vertices._z[ ivertex ] - znew, 2 );
                 vertices._z[ ivertex ] = znew;
             }
             else {
                 edm::LogInfo("sumw") << "invalid sum of weights in fit: " << vertices._sw[ivertex]
                 << endl;
                 if (this->verbose_) {
                     LogDebug("DAClusterizerinZ_vectorized")  << " a cluster melted away ?  pk=" << vertices._pk[ ivertex ] << " sumw="
                     << vertices._sw[ivertex] << endl;
                 }
             }
 
             // dont do, if rho cut
             if ( ! useRho0 )
             {
                 vertices._pk[ ivertex ] = vertices._pk[ ivertex ] * vertices._se[ ivertex ] / sumpi;
             }
         }
     };
 
     kernel_calc_z(gvertices);
 
     // return how much the prototypes moved
     return delta;
 }

vector< TransientVertex > DAClusterizerInZ_vect::vertices	(	const std::vector< reco::TransientTrack > &	tracks,
		const int	verbosity = `0`
	)		const

Definition at line 639 of file DAClusterizerInZ_vect.cc.

                                                                  {
 
 
     track_t tks = fill(tracks);
     tks.ExtractRaw();
 
     unsigned int nt = tracks.size();
     double rho0 = 0.0; // start with no outlier rejection
 
     vector<TransientVertex> clusters;
     if (tks.GetSize() == 0)
         return clusters;
 
     vertex_t y; // the vertex prototypes
 
     // initialize:single vertex at infinite temperature
     y.AddItem( 0, 1.0);
 
     int niter = 0; // number of iterations
 
 
     // estimate first critical temperature
     double beta = beta0(betamax_, tks, y);
     if ( verbose_)
     {
         LogDebug("DAClusterizerinZ_vectorized") << "Beta0 is " << beta << std::endl;
     }
 
     niter = 0;
     while ((update(beta, tks, y, false, rho0) > 1.e-6) && (niter++
             < maxIterations_)) {
     }
 
     // annealing loop, stop when T<Tmin  (i.e. beta>1/Tmin)
     while (beta < betamax_) {
 
 
         if(useTc_){
           update(beta, tks,y, false, rho0);
           while(merge(y,beta)){update(beta, tks,y, false, rho0);}
           split(beta, tks,y);
           beta=beta/coolingFactor_;
         }else{
           beta=beta/coolingFactor_;
           splitAll(y);
         }
 
         // make sure we are not too far from equilibrium before cooling further
         niter = 0;
         while ((update(beta, tks, y, false, rho0) > 1.e-6) && (niter++
                 < maxIterations_)) {
         }
 
     }
 
 
     if(useTc_){
       // last round of splitting, make sure no critical clusters are left
       update(beta, tks,y, false, rho0);// make sure Tc is up-to-date
       while(merge(y,beta)){update(beta, tks,y, false, rho0);}
       unsigned int ntry=0;
       while( split(beta, tks,y) && (ntry++<10) ){
         niter=0; 
         while((update(beta, tks,y, false, rho0)>1.e-6)  && (niter++ < maxIterations_)){}
         merge(y,beta);
         update(beta, tks,y, false, rho0);
       }
     }else{
       // merge collapsed clusters 
       while(merge(y,beta)){update(beta, tks,y, false, rho0);}  
       //while(merge(y)){}   original code
     }
  
     if (verbose_) {
         LogDebug("DAClusterizerinZ_vectorized")  << "dump after 1st merging " << endl;
         dump(beta, y, tks, 2);
     }
 
     // switch on outlier rejection
     rho0 = 1. / nt;
     
     // auto-vectorized
     for (unsigned int k = 0; k < y.GetSize(); k++) {
         y._pk[k] = 1.;
     } // democratic
     niter = 0;
     while ((update(beta, tks, y, true, rho0) > 1.e-8) && (niter++
             < maxIterations_)) {
     }
     if (verbose_) {
         LogDebug("DAClusterizerinZ_vectorized")  << "rho0=" << rho0 << " niter=" << niter << endl;
         dump(beta, y, tks, 2);
     }
 
     // merge again  (some cluster split by outliers collapse here)
     while (merge(y)) {
     }
     if (verbose_) {
         LogDebug("DAClusterizerinZ_vectorized")  << "dump after 2nd merging " << endl;
         dump(beta, y, tks, 2);
     }
 
     // continue from freeze-out to Tstop (=1) without splitting, eliminate insignificant vertices
     while (beta <= betastop_) {
         while (purge(y, tks, rho0, beta)) {
             niter = 0;
             while ((update(beta, tks, y, true, rho0) > 1.e-6) && (niter++
                     < maxIterations_)) {
             }
         }
         beta /= coolingFactor_;
         niter = 0;
         while ((update(beta, tks, y, true, rho0) > 1.e-6) && (niter++
                 < maxIterations_)) {
         }
     }
 
     if (verbose_) {
         LogDebug("DAClusterizerinZ_vectorized")  << "Final result, rho0=" << rho0 << endl;
         dump(beta, y, tks, 2);
     }
 
     // select significant tracks and use a TransientVertex as a container
     GlobalError dummyError;
 
     // ensure correct normalization of probabilities, should makes double assginment reasonably impossible
     const unsigned int nv = y.GetSize();
 
     for (unsigned int i = 0; i < nt; i++) {
         tks._Z_sum[i] = rho0 * local_exp(-beta * dzCutOff_ * dzCutOff_);
 
         for (unsigned int k = 0; k < nv; k++) {
             tks._Z_sum[i] += y._pk[k] * local_exp(-beta * Eik(tks._z[i], y._z[k],
                     tks._dz2[i]));
         }
     }
 
     for (unsigned int k = 0; k < nv; k++) {
 
         GlobalPoint pos(0, 0, y._z[k]);
 
         vector<reco::TransientTrack> vertexTracks;
         for (unsigned int i = 0; i < nt; i++) {
             if (tks._Z_sum[i] > 0) {
 
                 double p = y._pk[k] * local_exp(-beta * Eik(tks._z[i], y._z[k],
                         tks._dz2[i])) / tks._Z_sum[i];
                 if ((tks._pi[i] > 0) && (p > 0.5)) {
 
                     vertexTracks.push_back(*(tks.tt[i]));
                     tks._Z_sum[i] = 0;
                 } // setting Z=0 excludes double assignment
             }
         }
         TransientVertex v(pos, dummyError, vertexTracks, 0);
         clusters.push_back(v);
     }
 
     return clusters;
 
 }

Member Data Documentation

float DAClusterizerInZ_vect::betamax_

private

Definition at line 206 of file DAClusterizerInZ_vect.h.

float DAClusterizerInZ_vect::betastop_

private

Definition at line 207 of file DAClusterizerInZ_vect.h.

double DAClusterizerInZ_vect::coolingFactor_

private

Definition at line 205 of file DAClusterizerInZ_vect.h.

double DAClusterizerInZ_vect::d0CutOff_

private

Definition at line 209 of file DAClusterizerInZ_vect.h.

double DAClusterizerInZ_vect::dzCutOff_

private

Definition at line 208 of file DAClusterizerInZ_vect.h.

int DAClusterizerInZ_vect::maxIterations_

private

Definition at line 204 of file DAClusterizerInZ_vect.h.

bool DAClusterizerInZ_vect::use_vdt_

private

Definition at line 210 of file DAClusterizerInZ_vect.h.

bool DAClusterizerInZ_vect::useTc_

private

Definition at line 211 of file DAClusterizerInZ_vect.h.

bool DAClusterizerInZ_vect::verbose_

private

Definition at line 202 of file DAClusterizerInZ_vect.h.

float DAClusterizerInZ_vect::vertexSize_

private

Definition at line 203 of file DAClusterizerInZ_vect.h.

Classes

Public Member Functions

Private Attributes

Detailed Description

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation