#include <QuadrupletSeedMerger.h>

Public Member Functions
std::pair< double, double >	calculatePhiEta (SeedingHitSet const &) const

const OrderedSeedingHits &	mergeTriplets (const OrderedSeedingHits &, const edm::EventSetup &)

const TrajectorySeedCollection	mergeTriplets (const TrajectorySeedCollection &, const TrackingRegion &, const edm::EventSetup &)

void	printHit (const TrackingRecHit *) const

void	printNtuplet (const SeedingHitSet &) const

	QuadrupletSeedMerger (const edm::ParameterSet &iConfig, edm::ConsumesCollector &iC)

	QuadrupletSeedMerger (const edm::ParameterSet &iConfig, const edm::ParameterSet &seedCreatorConfig, edm::ConsumesCollector &iC)

void	setAddRemainingTriplets (bool)

void	setMergeTriplets (bool)

void	setTTRHBuilderLabel (std::string)

void	update (const edm::EventSetup &)

	~QuadrupletSeedMerger ()

Private Types
typedef std::array < SeedingHitSet::ConstRecHitPointer, 4 >	QuadrupletHits

Private Member Functions
bool	isValidQuadruplet (const QuadrupletHits &quadruplet, const std::vector< SeedMergerPixelLayer > &layers, const TrackerTopology *tTopo) const

void	mySort (QuadrupletHits &unsortedHits)

	QuadrupletSeedMerger (const edm::ParameterSet &iConfig, SeedCreator *seedCreator, edm::ConsumesCollector &iC)

Private Attributes
bool	isAddRemainingTriplets_

bool	isMergeTriplets_

OrderedHitSeeds	quads_

SeedingLayerSetsBuilder	theLayerBuilder_

ctfseeding::SeedingLayerSets	theLayerSets_

std::unique_ptr< SeedCreator >	theSeedCreator_

edm::ESHandle< TrackerGeometry >	theTrackerGeometry_

edm::ESHandle < TransientTrackingRecHitBuilder >	theTTRHBuilder_

std::string	theTTRHBuilderLabel_

Detailed Description

merge triplets into quadruplets

Definition at line 78 of file QuadrupletSeedMerger.h.

Member Typedef Documentation

typedef std::array<SeedingHitSet::ConstRecHitPointer, 4> QuadrupletSeedMerger::QuadrupletHits

private

Definition at line 98 of file QuadrupletSeedMerger.h.

Constructor & Destructor Documentation

QuadrupletSeedMerger::QuadrupletSeedMerger	(	const edm::ParameterSet &	iConfig,
		edm::ConsumesCollector &	iC
	)

explicit

Definition at line 73 of file QuadrupletSeedMerger.cc.

73 :

74 QuadrupletSeedMerger(iConfig, nullptr, iC) {}

QuadrupletSeedMerger::QuadrupletSeedMerger

QuadrupletSeedMerger(const edm::ParameterSet &iConfig, edm::ConsumesCollector &iC)

Definition: QuadrupletSeedMerger.cc:73

QuadrupletSeedMerger::QuadrupletSeedMerger	(	const edm::ParameterSet &	iConfig,
		const edm::ParameterSet &	seedCreatorConfig,
		edm::ConsumesCollector &	iC
	)

Definition at line 75 of file QuadrupletSeedMerger.cc.

75 :

76 QuadrupletSeedMerger(iConfig, createSeedCreator(seedCreatorConfig), iC) {}

QuadrupletSeedMerger::QuadrupletSeedMerger

QuadrupletSeedMerger(const edm::ParameterSet &iConfig, edm::ConsumesCollector &iC)

Definition: QuadrupletSeedMerger.cc:73

QuadrupletSeedMerger::~QuadrupletSeedMerger ( )

Definition at line 97 of file QuadrupletSeedMerger.cc.

                                             {
 
 }

QuadrupletSeedMerger::QuadrupletSeedMerger	(	const edm::ParameterSet &	iConfig,
		SeedCreator *	seedCreator,
		edm::ConsumesCollector &	iC
	)

private

Definition at line 77 of file QuadrupletSeedMerger.cc.

References isAddRemainingTriplets_, and isMergeTriplets_.

                                                                                                                             :
   theLayerBuilder_(iConfig, iC),
   theSeedCreator_(seedCreator)
  {
 
   // by default, do not..
   // ..merge triplets
   isMergeTriplets_ = false;
   // ..add remaining triplets
   isAddRemainingTriplets_ = false;
 }

Member Function Documentation

std::pair< double, double > QuadrupletSeedMerger::calculatePhiEta ( SeedingHitSet const & nTuplet ) const

Definition at line 486 of file QuadrupletSeedMerger.cc.

References eta(), p1, p2, phi, funct::sqr(), mathSSE::sqrt(), PV3DBase< T, PVType, FrameType >::x(), PV3DBase< T, PVType, FrameType >::y(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by mergeTriplets().

                                                                                                  {
 
 //   if( nTuplet.size() < 3 ) {
 //     std::cerr << " [QuadrupletSeedMerger::calculatePhiEta] ** ERROR: nTuplet has less than 3 hits" << std::endl;
 //     throw; // tbr.
 //   }
 
   GlobalPoint p1 = nTuplet[0]->globalPosition();
   GlobalPoint p2 = nTuplet[1]->globalPosition();
 
   const double x1 = p1.x();
   const double x2 = p2.x();
   const double y1 = p1.y();
   const double y2 = p2.y();
   const double z1 = p1.z();
   const double z2 = p2.z();
 
   const double phi = atan2( x2 - x1, y2 -y1 );
   const double eta = acos( (z2 - z1) / sqrt( sqr( x2 - x1 ) + sqr( y2 - y1 ) + sqr( z2 - z1 ) ) ); // this is theta angle in reality
 
   std::pair<double,double> retVal;
   retVal=std::make_pair (phi,eta);
   return retVal;
   //return std::make_pair<double,double>( phi, eta );
   
 }

bool QuadrupletSeedMerger::isValidQuadruplet	(	const QuadrupletHits &	quadruplet,
		const std::vector< SeedMergerPixelLayer > &	layers,
		const TrackerTopology *	tTopo
	)		const

private

check for validity of a (radius-) sorted quadruplet:

after sorting, hits must be on layers according to the order given in PixelSeedMergerQuadruplets (from cfg)

Definition at line 607 of file QuadrupletSeedMerger.cc.

References gather_cfg::cout, and cmsHarvester::index.

Referenced by mergeTriplets().

                                                                                                                                                                 {
 
   const unsigned int quadrupletSize = quadruplet.size();
 
   // basic size test..
   if( quadrupletSize != layers.size() ) {
     std::cout << " [QuadrupletSeedMerger::isValidQuadruplet] ** WARNING: size mismatch: "
           << quadrupletSize << "/" << layers.size() << std::endl;
     return false;
   }
 
   // go along layers and check if all (parallel) quadruplet hits match
   for( unsigned int index = 0; index < quadrupletSize; ++index ) {
     if( ! layers[index].isContainsDetector( quadruplet[index]->geographicalId(), tTopo ) ) {
       return false;
     }
   }
 
   return true;
 
 }

const OrderedSeedingHits & QuadrupletSeedMerger::mergeTriplets	(	const OrderedSeedingHits &	inputTriplets,
		const edm::EventSetup &	es
	)

merge triplets into quadruplets INPUT: OrderedSeedingHits OUTPUT: SeedingHitSets

this method is used in RecoPixelVertexing/PixelTrackFitting/src/PixelTrackReconstruction.cc and contains the basic merger functionality

Definition at line 113 of file QuadrupletSeedMerger.cc.

References a, b, KDTreeLinkerAlgo< DATA >::build(), calculatePhiEta(), SeedingLayerSetsBuilder::check(), constexpr, gather_cfg::cout, eta(), edm::EventSetup::get(), i, isAddRemainingTriplets_, isMergeTriplets_, isValidQuadruplet(), j, SeedingLayerSetsBuilder::layers(), bookConverter::max, maxEta, min(), benchmark_cfg::minEta, mySort(), phi, edm::ESHandle< class >::product(), quads_, indexGen::s2, KDTreeLinkerAlgo< DATA >::search(), EgAmbiguityTools::sharedHits(), OrderedSeedingHits::size(), findQualityFiles::size, python.multivaluedict::sort(), theLayerBuilder_, theLayerSets_, and Geom::twoPi().

Referenced by mergeTriplets().

                                                                                                                                 {
 
   //Retrieve tracker topology from geometry
   edm::ESHandle<TrackerTopology> tTopoHand;
   es.get<IdealGeometryRecord>().get(tTopoHand);
   const TrackerTopology *tTopo=tTopoHand.product();
   
   // the list of layers on which quadruplets should be formed
   if(theLayerBuilder_.check(es)) {
     theLayerSets_ = theLayerBuilder_.layers( es ); // this is a vector<vector<SeedingLayer> >
   }
 
   
   // make a working copy of the input triplets
   // to be able to remove merged triplets
 
   std::vector<std::pair<double,double> > phiEtaCache;
   std::vector<SeedingHitSet> tripletCache; //somethings strange about OrderedSeedingHits?
 
   const unsigned int nInputTriplets = inputTriplets.size();
   phiEtaCache.reserve(nInputTriplets);
   tripletCache.reserve(nInputTriplets);
 
   for( unsigned int it = 0; it < nInputTriplets; ++it ) {
     tripletCache.push_back((inputTriplets[it]));
     phiEtaCache.push_back(calculatePhiEta( (tripletCache[it]) ));
 
   }
 
   // the output
   quads_.clear();
 
   // check if the input is all triplets
   // (code is also used for pairs..)
   // if not, copy the input to the output & return
   bool isAllTriplets = true;
   for( unsigned int it = 0; it < nInputTriplets; ++it ) {
     if( tripletCache[it].size() != 3 ) {
       isAllTriplets = false;
       break;
     }
   }
 
   if( !isAllTriplets && isMergeTriplets_ )
     std::cout << "[QuadrupletSeedMerger::mergeTriplets] (in HLT) ** bailing out since non-triplets in input." << std::endl;
 
   if( !isAllTriplets || !isMergeTriplets_ ) {
     quads_.reserve(nInputTriplets);
     for( unsigned int it = 0; it < nInputTriplets; ++it ) {
       quads_.push_back( (tripletCache[it]));
     }
 
     return quads_;
   }
 
 
   quads_.reserve(0.2*nInputTriplets); //rough guess
 
   // loop all possible 4-layer combinations
   // as specified in python/quadrupletseedmerging_cff.py
 
   std::vector<bool> usedTriplets(nInputTriplets,false);
   std::pair<SeedingHitSet::ConstRecHitPointer,SeedingHitSet::ConstRecHitPointer> sharedHits;
   std::pair<SeedingHitSet::ConstRecHitPointer,SeedingHitSet::ConstRecHitPointer> nonSharedHits;
 
   // k-d tree, indices are (th)eta, phi
   // build the tree
   std::vector<KDTreeNodeInfo<unsigned int> > nodes;
   std::vector<unsigned int> foundNodes;
   nodes.reserve(2*nInputTriplets);
   foundNodes.reserve(100);
   KDTreeLinkerAlgo<unsigned int> kdtree;
   double minEta=1e10, maxEta=-1e10;
   for(unsigned int it=0; it < nInputTriplets; ++it) {
     double phi = phiEtaCache[it].first;
     double eta = phiEtaCache[it].second;
     nodes.push_back(KDTreeNodeInfo<unsigned int>(it, eta, phi));
     minEta = std::min(minEta, eta);
     maxEta = std::max(maxEta, eta);
 
     // to wrap all points in phi
     // if(phi < 0) phi += twoPi(); else phi -= twoPi();
     double twoPi = std::copysign(Geom::twoPi(), phi);
     nodes.push_back(KDTreeNodeInfo<unsigned int>(it, eta, phi-twoPi));
   }
   KDTreeBox kdEtaPhi(minEta-0.01, maxEta+0.01, -1*Geom::twoPi(), Geom::twoPi());
   kdtree.build(nodes, kdEtaPhi);
   nodes.clear();
   
   // loop over triplets, search for close-by triplets by using the k-d tree
   // also identify the hits which are shared by triplet pairs, and
   // store indices to hits which are not shared
   std::vector<unsigned int> t1List;
   std::vector<unsigned int> t2List;
   std::vector<short> t1NonSharedHitList;
   std::vector<short> t2NonSharedHitList;
   constexpr short sharedToNonShared[7] = {-1, -1, -1,
                                           2, // 011=3 shared, not shared = 2
                                           -1,
                                           1, // 101=5 shared, not shared = 1
                                           0}; // 110=6 shared, not shared = 0
   constexpr short nonSharedToShared[3][2] = {
     {1, 2},
     {0, 2},
     {0, 1}
   };
 
   typedef std::tuple<unsigned int, short, short> T2NonSharedTuple;
   std::vector<T2NonSharedTuple> t2Tmp; // temporary to sort t2's before insertion to t2List
   for(unsigned int t1=0; t1<nInputTriplets; ++t1) {
     double phi = phiEtaCache[t1].first;
     double eta = phiEtaCache[t1].second;
 
     KDTreeBox box(eta-0.05, eta+0.05, phi-0.15, phi+0.15);
     foundNodes.clear();
     kdtree.search(box, foundNodes);
     if(foundNodes.empty())
       continue;
 
     const SeedingHitSet& tr1 = tripletCache[t1];
 
     for(unsigned int t2: foundNodes) {
       if(t1 >= t2)
         continue;
 
       // Ensure here that the triplet pairs share two hits.
       const SeedingHitSet& tr2 = tripletCache[t2];
 
       // If neither of first two hits in tr1 are found from tr2, this
       // pair can be skipped
       int equalHits=0;
       // Find the indices of shared hits in both t1 and t2, use them
       // to obtain the index of non-shared hit for both. The index of
       // non-shared hit is then stored for later use (the indices of
       // shared hits can be easily obtained from them).
       unsigned int t1Shared = 0;
       unsigned int t2Shared = 0;
       for(unsigned int i=0; i<2; ++i) {
         for(unsigned int j=0; j<3; ++j) {
           if(areHitsEqual(*tr1[i], *tr2[j])) {
             t1Shared |= (1<<i);
             t2Shared |= (1<<j);
             ++equalHits;
             break;
           }
         }
       }
       if(equalHits == 0)
         continue;
       // If, after including the third hit of tr1, number of equal
       // hits is not 2, this pair can be skipped
       if(equalHits != 2) {
         for(unsigned int j=0; j<3; ++j) {
           if(areHitsEqual(*tr1[2], *tr2[j])) {
             t1Shared |= (1<<2);
             t2Shared |= (1<<j);
             ++equalHits;
             break;
           }
         }
         if(equalHits != 2)
           continue;
       }
       // valid values for the bitfields are 011=3, 101=5, 110=6
       assert(t1Shared <= 6 && t2Shared <= 6); // against out-of-bounds of sharedToNonShared[]
       short t1NonShared = sharedToNonShared[t1Shared];
       short t2NonShared = sharedToNonShared[t2Shared];
       assert(t1NonShared >= 0 && t2NonShared >= 0); // against invalid value from sharedToNonShared[]
 
       t2Tmp.emplace_back(t2, t1NonShared, t2NonShared);
     }
 
     // Sort to increasing order in t2 in order to get exactly same result as before
     std::sort(t2Tmp.begin(), t2Tmp.end(), [](const T2NonSharedTuple& a, const T2NonSharedTuple& b){
         return std::get<0>(a) < std::get<0>(b);
       });
     for(T2NonSharedTuple& t2tpl: t2Tmp) {
       t1List.push_back(t1);
       t2List.push_back(std::get<0>(t2tpl));
       t1NonSharedHitList.push_back(std::get<1>(t2tpl));
       t2NonSharedHitList.push_back(std::get<2>(t2tpl));
     }
     t2Tmp.clear();
   }
   nodes.clear();
 
   for( ctfseeding::SeedingLayerSets::const_iterator lsIt = theLayerSets_.begin(); lsIt < theLayerSets_.end(); ++lsIt ) {
 
     // fill a vector with the layers in this set
     std::vector<SeedMergerPixelLayer> currentLayers;
     currentLayers.reserve(lsIt->size());
     for( ctfseeding::SeedingLayers::const_iterator layIt = lsIt->begin(); layIt < lsIt->end(); ++layIt ) {
       currentLayers.push_back( SeedMergerPixelLayer( layIt->name() ) );
     }
     // loop all pair combinations of these 4 layers;
     // strategy is to look for shared hits on such a pair and
     // then merge the remaining hits in both triplets if feasible
     // (SeedingLayers is a vector<SeedingLayer>)
 
     for( unsigned int s1=0; s1<currentLayers.size()-1; s1++) {
 
       for( unsigned int s2=s1+1; s2<currentLayers.size(); s2++) {
 
     std::vector<unsigned int> nonSharedLayerNums;
     for ( unsigned int us1=0; us1<currentLayers.size(); us1++) {
       if ( s1!=us1 && s2!=us1) nonSharedLayerNums.push_back(us1);
     }
 
     // loop all possible triplet pairs (which come as input)
     for (unsigned int t12=0; t12<t1List.size(); t12++) {
       unsigned int t1=t1List[t12];
       unsigned int t2=t2List[t12];
 
         if (usedTriplets[t1] || usedTriplets[t2] ) continue; 
 
             const SeedingHitSet& firstTriplet = tripletCache[t1];
 
             short t1NonShared = t1NonSharedHitList[t12];
             sharedHits.first = firstTriplet[nonSharedToShared[t1NonShared][0]];
             sharedHits.second = firstTriplet[nonSharedToShared[t1NonShared][1]];
 
             // are the shared hits on these two layers?
             if(areHitsOnLayers(currentLayers[s1], currentLayers[s2], sharedHits, tTopo)) {
               short t2NonShared = t2NonSharedHitList[t12];
               const SeedingHitSet& secondTriplet = tripletCache[t2];
               nonSharedHits.first = firstTriplet[t1NonShared];
               nonSharedHits.second = secondTriplet[t2NonShared];
 
           // are the remaining hits on different layers?
               if(areHitsOnLayers(currentLayers[nonSharedLayerNums[0]], currentLayers[nonSharedLayerNums[1]], nonSharedHits, tTopo)) {
                 QuadrupletHits unsortedHits{ {sharedHits.first, sharedHits.second,
                       nonSharedHits.first, nonSharedHits.second} };
 
                 mySort(unsortedHits);
 
         //start here with old addtoresult
         if( isValidQuadruplet( unsortedHits, currentLayers, tTopo ) ) {
           // and create the quadruplet
           SeedingHitSet quadruplet(unsortedHits[0],unsortedHits[1],unsortedHits[2],unsortedHits[3]);
           
           // insert this quadruplet
           quads_.push_back( quadruplet );
           // remove both triplets from the list,
           // needs this 4-permutation since we're in a double loop
           usedTriplets[t1]=true;
           usedTriplets[t2]=true;
         }
         
           } // isMergeableHitsInTriplets
         } // isTripletsShareHitsOnLayers
         // } // triplet double loop
     }
       } // seeding layers double loop
     }
   
   } // seeding layer sets
   
   // add the remaining triplets
   if( isAddRemainingTriplets_ ) {
     for( unsigned int it = 0; it < nInputTriplets; ++it ) {
       if ( !usedTriplets[it] ) 
     quads_.push_back( tripletCache[it]);
     }
   }
 
   //calc for printout...
 //  unsigned int nLeft=0;
 //  for ( unsigned int i=0; i<nInputTriplets; i++)
 //    if ( !usedTriplets[i] ) nLeft++;
   // some stats
 //  std::cout << " [QuadrupletSeedMerger::mergeTriplets] -- Created: " << theResult.size()
 //      << " quadruplets from: " << nInputTriplets << " input triplets (" << nLeft
 //      << " remaining ";
 //  std::cout << (isAddRemainingTriplets_?"added":"dropped");
 //  std::cout << ")." << std::endl;
 
   return quads_;
 
 }

const TrajectorySeedCollection QuadrupletSeedMerger::mergeTriplets	(	const TrajectorySeedCollection &	seedCollection,
		const TrackingRegion &	region,
		const edm::EventSetup &	es
	)

merge triplets into quadruplets INPUT: TrajectorySeedCollection OUTPUT: TrajectorySeedCollection

this is a wrapper for: vector<SeedingHitSet> mergeTriplets( const OrderedSeedingHits& ) for use in RecoTracker/TkSeedGenerator/plugins/SeedGeneratorFromRegionHitsEDProducer.cc (iterative tracking)

Definition at line 405 of file QuadrupletSeedMerger.cc.

References gather_cfg::cout, edm::EventSetup::get(), i, isMergeTriplets_, mergeTriplets(), OrderedSeedingHits::size(), theSeedCreator_, theTTRHBuilder_, and theTTRHBuilderLabel_.

                                                              {
 
   // ttrh builder for HitSet -> TrajectorySeed conversion;
   // require this to be correctly configured, otherwise -> exception
   es.get<TransientRecHitRecord>().get( theTTRHBuilderLabel_, theTTRHBuilder_ );
 
   // output collection
   TrajectorySeedCollection theResult;
 
   // loop to see if we have triplets ONLY
   // if not, copy input -> output and return
   bool isAllTriplets = true;
   for( TrajectorySeedCollection::const_iterator aTrajectorySeed = seedCollection.begin();
        aTrajectorySeed < seedCollection.end(); ++aTrajectorySeed ) {
     if( 3 != aTrajectorySeed->nHits() ) isAllTriplets = false;
   }
 
   if( !isAllTriplets && isMergeTriplets_ )
     std::cout << " [QuadrupletSeedMerger::mergeTriplets] (in RECO) -- bailing out since non-triplets in input." << std::endl;
 
   if( !isAllTriplets || !isMergeTriplets_ ) {
     for( TrajectorySeedCollection::const_iterator aTrajectorySeed = seedCollection.begin();
        aTrajectorySeed < seedCollection.end(); ++aTrajectorySeed ) {
       theResult.push_back( *aTrajectorySeed );
     }
 
     return theResult;
   }
 
 
   // all this fiddling here is now about converting
   // TrajectorySeedCollection <-> OrderedSeedingHits
 
   // create OrderedSeedingHits first;
   OrderedHitTriplets inputTriplets;
 
   // loop seeds
   for( TrajectorySeedCollection::const_iterator aTrajectorySeed = seedCollection.begin();
        aTrajectorySeed < seedCollection.end(); ++aTrajectorySeed ) {
 
     std::vector<SeedingHitSet::ConstRecHitPointer> recHitPointers;
 
     // loop RecHits
     const TrajectorySeed::range theHitsRange = aTrajectorySeed->recHits();
     for( edm::OwnVector<TrackingRecHit>::const_iterator aHit = theHitsRange.first;
      aHit < theHitsRange.second; ++aHit ) {
       
       // this is a collection of: ReferenceCountingPointer< SeedingHitSet> 
       recHitPointers.push_back( (SeedingHitSet::ConstRecHitPointer)(&*aHit ) );
 
     }
     
     // add to input collection
     inputTriplets.push_back( OrderedHitTriplet( recHitPointers.at( 0 ), recHitPointers.at( 1 ), recHitPointers.at( 2 ) ) );
 
   }
 
   // do the real merging..
   const OrderedSeedingHits &quadrupletHitSets = mergeTriplets( inputTriplets, es );
   
   // convert back to TrajectorySeedCollection
 
   // the idea here is to fetch the same SeedCreator and PSet
   // as those used by the plugin which is calling the merger
   // (at the moment that's SeedGeneratorFromRegionHitsEDProducer)
   theSeedCreator_->init(region, es, 0);
   for ( unsigned int i=0; i< quadrupletHitSets.size(); i++) {
     // add trajectory seed to result collection
     theSeedCreator_->makeSeed( theResult, quadrupletHitSets[i]);
   }
 
   return theResult;
   
 }

void QuadrupletSeedMerger::mySort ( QuadrupletHits & unsortedHits )

private

Definition at line 727 of file QuadrupletSeedMerger.cc.

References p1, PV3DBase< T, PVType, FrameType >::x(), and PV3DBase< T, PVType, FrameType >::y().

Referenced by mergeTriplets().

                                                                                             {
   float radiiSq[4];
   for ( unsigned int iR=0; iR<4; iR++){
     GlobalPoint p1 = unsortedHits[iR]->globalPosition();
     radiiSq[iR]=( p1.x()*p1.x()+p1.y()*p1.y()); // no need to take the sqrt
   }
   SeedingHitSet::ConstRecHitPointer tempRHP;
   float tempFloat=0.;
   for ( unsigned int iR1=0; iR1<3; iR1++) {
     for ( unsigned int iR2=iR1+1; iR2<4; iR2++) {
       if (radiiSq[iR1]>radiiSq[iR2]) {
     tempRHP=unsortedHits[iR1];
     unsortedHits[iR1]=unsortedHits[iR2];
     unsortedHits[iR2]=tempRHP;
     tempFloat=radiiSq[iR1];
     radiiSq[iR1]=radiiSq[iR2];
     radiiSq[iR2]=tempFloat;
       }
     }
   }
 }

void QuadrupletSeedMerger::printHit ( const TrackingRecHit * aHit ) const

Definition at line 519 of file QuadrupletSeedMerger.cc.

References gather_cfg::cout, TrackingRecHit::geographicalId(), TrackingRecHit::localPosition(), PV3DBase< T, PVType, FrameType >::perp(), GloballyPositioned< T >::position(), alignCSCRings::r, GeomDet::surface(), theTrackerGeometry_, GeomDet::toGlobal(), x, detailsBasic3DVector::y, and detailsBasic3DVector::z.

                                                                       {
 
   const GeomDet* geomDet = theTrackerGeometry_->idToDet( aHit->geographicalId() );
   const double r = geomDet->surface().position().perp();
   const double x = geomDet->toGlobal( aHit->localPosition() ).x();
   const double y = geomDet->toGlobal( aHit->localPosition() ).y();
   const double z = geomDet->toGlobal( aHit->localPosition() ).z();
   std::cout << "<RecHit> x: " << x << " y: " << y << " z: " << z << " r: " << r << std::endl;
 
 }

void QuadrupletSeedMerger::printNtuplet ( const SeedingHitSet & aNtuplet ) const

Definition at line 533 of file QuadrupletSeedMerger.cc.

References gather_cfg::cout, PixelEndcapName::diskName(), TrackingRecHit::geographicalId(), PixelBarrelName::layerName(), TrackingRecHit::localPosition(), PixelSubdetector::PixelBarrel, alignCSCRings::r, SeedingHitSet::size(), mathSSE::sqrt(), AlCaHLTBitMon_QueryRunRegistry::string, DetId::subdetId(), theTrackerGeometry_, GeomDet::toGlobal(), x, detailsBasic3DVector::y, and detailsBasic3DVector::z.

                                                                              {
 
   std::cout << "DUMPING NTUPLET OF SIZE:";
   std::cout << aNtuplet.size() << std::endl;
 
   for( unsigned int aHit = 0; aHit < aNtuplet.size(); ++aHit ) {
 
     const TrackingRecHit* theHit = aNtuplet[aHit]->hit();
     const GeomDet* geomDet = theTrackerGeometry_->idToDet( theHit->geographicalId() );
     const double x = geomDet->toGlobal( theHit->localPosition() ).x();
     const double y = geomDet->toGlobal( theHit->localPosition() ).y();
     const double z = geomDet->toGlobal( theHit->localPosition() ).z();
     const double r = sqrt( x*x + y*y );
 
     unsigned int layer;
     std::string detName;
     if( PixelSubdetector::PixelBarrel == theHit->geographicalId().subdetId() ) {
       detName = "BPIX ";
       PixelBarrelName pbn( aNtuplet[aHit]->hit()->geographicalId());
       layer = pbn.layerName();
     }
     else {
       detName = "FPIX";
       if( z > 0 ) detName += "+";
       else detName += "-";
 
       PixelEndcapName pen( theHit->geographicalId() );
       layer = pen.diskName();
     }
 
     std::cout << "<NtupletHit> D: " << detName << " L: " << layer << " x: " << x << " y: " << y << " z: " << z << " r: " << r << std::endl;
     
 }
 
   std::cout << "<<<<<<<<<<<<<<<<<<<<<<<<<<<" << std::endl;
 
 }

void QuadrupletSeedMerger::setAddRemainingTriplets ( bool isAddTriplets )

Definition at line 596 of file QuadrupletSeedMerger.cc.

References isAddRemainingTriplets_.

                                                                        {
   isAddRemainingTriplets_ = isAddTriplets;
 }

void QuadrupletSeedMerger::setMergeTriplets ( bool isMergeTriplets )

Definition at line 587 of file QuadrupletSeedMerger.cc.

References isMergeTriplets_.

                                                                   {
   isMergeTriplets_ = isMergeTriplets;
 }

void QuadrupletSeedMerger::setTTRHBuilderLabel ( std::string label )

Definition at line 576 of file QuadrupletSeedMerger.cc.

References diffTwoXMLs::label, and theTTRHBuilderLabel_.

                                                                 {
 
   theTTRHBuilderLabel_ = label;
   
 }

void QuadrupletSeedMerger::update ( const edm::EventSetup & es )

Definition at line 89 of file QuadrupletSeedMerger.cc.

References edm::EventSetup::get(), and theTrackerGeometry_.

                                                          {
   // copy geometry
   es.get<TrackerDigiGeometryRecord>().get( theTrackerGeometry_ );
 }

Member Data Documentation

bool QuadrupletSeedMerger::isAddRemainingTriplets_

private

Definition at line 114 of file QuadrupletSeedMerger.h.

Referenced by mergeTriplets(), QuadrupletSeedMerger(), and setAddRemainingTriplets().

bool QuadrupletSeedMerger::isMergeTriplets_

private

Definition at line 113 of file QuadrupletSeedMerger.h.

Referenced by mergeTriplets(), QuadrupletSeedMerger(), and setMergeTriplets().

OrderedHitSeeds QuadrupletSeedMerger::quads_

private

Definition at line 116 of file QuadrupletSeedMerger.h.

Referenced by mergeTriplets().

SeedingLayerSetsBuilder QuadrupletSeedMerger::theLayerBuilder_

private

Definition at line 108 of file QuadrupletSeedMerger.h.

Referenced by mergeTriplets().

ctfseeding::SeedingLayerSets QuadrupletSeedMerger::theLayerSets_

private

Definition at line 109 of file QuadrupletSeedMerger.h.

Referenced by mergeTriplets().

std::unique_ptr<SeedCreator> QuadrupletSeedMerger::theSeedCreator_

private

Definition at line 112 of file QuadrupletSeedMerger.h.

Referenced by mergeTriplets().

edm::ESHandle<TrackerGeometry> QuadrupletSeedMerger::theTrackerGeometry_

private

Definition at line 110 of file QuadrupletSeedMerger.h.

Referenced by printHit(), printNtuplet(), and update().

edm::ESHandle<TransientTrackingRecHitBuilder> QuadrupletSeedMerger::theTTRHBuilder_

private

Definition at line 111 of file QuadrupletSeedMerger.h.

Referenced by mergeTriplets().

std::string QuadrupletSeedMerger::theTTRHBuilderLabel_

private

Definition at line 115 of file QuadrupletSeedMerger.h.

Referenced by mergeTriplets(), and setTTRHBuilderLabel().

Public Member Functions

Private Types

Private Member Functions

Private Attributes

Detailed Description

Member Typedef Documentation

Constructor & Destructor Documentation

Member Function Documentation

Member Data Documentation