PixelForwardLayerPhase1 Class Reference

#include <PixelForwardLayerPhase1.h>

Inheritance diagram for PixelForwardLayerPhase1:

Classes
struct	SubTurbineCrossings

Public Member Functions
virtual const std::vector < const GeomDet * > &	basicComponents () const
virtual const std::vector < const GeometricSearchDet * > &	components () const __attribute__((cold))
	Returns basic components, if any. More...
void	groupedCompatibleDetsV (const TrajectoryStateOnSurface &tsos, const Propagator &prop, const MeasurementEstimator &est, std::vector< DetGroup > &result) const __attribute__((hot))
	PixelForwardLayerPhase1 (std::vector< const Phase1PixelBlade * > &blades)
virtual SubDetector	subDetector () const
	The type of detector (PixelBarrel, PixelEndcap, TIB, TOB, TID, TEC, CSC, DT, RPCBarrel, RPCEndcap) More...
	~PixelForwardLayerPhase1 ()
Public Member Functions inherited from ForwardDetLayer
virtual std::pair< bool, TrajectoryStateOnSurface >	compatible (const TrajectoryStateOnSurface &, const Propagator &, const MeasurementEstimator &) const
bool	contains (const Local3DPoint &p) const
	ForwardDetLayer (bool doHaveGroups)
virtual Location	location () const
	Which part of the detector (barrel, endcap) More...
virtual const BoundDisk &	specificSurface () const
virtual const BoundSurface &	surface () const
	The surface of the GeometricSearchDet. More...
virtual	~ForwardDetLayer ()
Public Member Functions inherited from DetLayer
	DetLayer (bool doHaveGroup, bool ibar)
bool	isBarrel () const
bool	isForward () const
int	seqNum () const
void	setSeqNum (int sq)
virtual	~DetLayer ()
Public Member Functions inherited from GeometricSearchDet
virtual std::vector< DetWithState >	compatibleDets (const TrajectoryStateOnSurface &startingState, const Propagator &prop, const MeasurementEstimator &est) const
virtual void	compatibleDetsV (const TrajectoryStateOnSurface &startingState, const Propagator &prop, const MeasurementEstimator &est, std::vector< DetWithState > &result) const
	GeometricSearchDet (bool doHaveGroups)
virtual std::vector< DetGroup >	groupedCompatibleDets (const TrajectoryStateOnSurface &startingState, const Propagator &prop, const MeasurementEstimator &est) const
bool	hasGroups () const
virtual const Surface::PositionType &	position () const
	Returns position of the surface. More...
virtual	~GeometricSearchDet ()

Private Types
typedef PeriodicBinFinderInPhi < float >	BinFinderType

Private Member Functions
SubTurbineCrossings	computeCrossings (const TrajectoryStateOnSurface &startingState, PropagationDirection propDir, bool innerDisk) const __attribute__((hot))
void	searchNeighbors (const TrajectoryStateOnSurface &tsos, const Propagator &prop, const MeasurementEstimator &est, const SubTurbineCrossings &crossings, float window, std::vector< DetGroup > &result, bool innerDisk) const __attribute__((hot))

Static Private Member Functions
static int	computeHelicity (const GeometricSearchDet *firstBlade, const GeometricSearchDet *secondBlade)
static float	computeWindowSize (const GeomDet *det, const TrajectoryStateOnSurface &tsos, const MeasurementEstimator &est)

Private Attributes
unsigned int	_num_innerpanels
unsigned int	_num_outerpanels
std::vector< const GeomDet * >	theBasicComps
std::vector< float >	theBinFinder_byR
std::vector< unsigned int >	theBinFinder_byR_index
std::vector< unsigned int >	theBinFinder_byR_nextindex
BinFinderType	theBinFinder_inner
BinFinderType	theBinFinder_outer
std::vector< const GeometricSearchDet * >	theComps

Additional Inherited Members
Public Types inherited from DetLayer
typedef GeomDetEnumerators::Location	Location
typedef GeomDetEnumerators::SubDetector	SubDetector
Public Types inherited from GeometricSearchDet
typedef std::pair< const GeomDet *, TrajectoryStateOnSurface >	DetWithState
typedef BoundSurface::PositionType	PositionType
typedef BoundSurface::RotationType	RotationType
typedef TrajectoryStateOnSurface	TrajectoryState
Protected Member Functions inherited from ForwardDetLayer
SimpleDiskBounds const &	bounds () const
virtual BoundDisk *	computeSurface ()
virtual void	initialize ()
float	rmax () const
float	rmin () const
void	setSurface (BoundDisk *cp)
float	zmax () const
float	zmin () const
Protected Attributes inherited from GeometricSearchDet
bool	haveGroups
GeomDetCompatibilityChecker	theCompatibilityChecker

Detailed Description

A concrete implementation for PixelForward layer built out of ForwardPhase1PixelBlade

Definition at line 16 of file PixelForwardLayerPhase1.h.

Member Typedef Documentation

typedef PeriodicBinFinderInPhi<float> PixelForwardLayerPhase1::BinFinderType

private

Definition at line 68 of file PixelForwardLayerPhase1.h.

Constructor & Destructor Documentation

PixelForwardLayerPhase1::PixelForwardLayerPhase1

(

std::vector< const Phase1PixelBlade * > &

blades

)

Definition at line 25 of file PixelForwardLayerPhase1.cc.

References _num_innerpanels, _num_outerpanels, ForwardDetLayer::computeSurface(), LogDebug, bookConverter::max, min(), PV3DBase< T, PVType, FrameType >::perp(), phi, PV3DBase< T, PVType, FrameType >::phi(), GeometricSearchDet::position(), GloballyPositioned< T >::position(), ForwardDetLayer::setSurface(), ForwardDetLayer::specificSurface(), ForwardDetLayer::surface(), theBasicComps, theBinFinder_inner, theBinFinder_outer, theComps, and PV3DBase< T, PVType, FrameType >::z().

                                                                                       :
  ForwardDetLayer(true),
    theComps(blades.begin(),blades.end())
{
  // Assumes blades are ordered inner first then outer; and within each by phi
  // where we go 0 -> pi, and then -pi -> 0
  // we also need the number of inner blades for the offset in theComps vector
  //
  // this->specificSurface() not yet available so need to calculate average R
  // we need some way to flag if FPIX is made of an inner and outer disk
  // or probably need to change the way this is done, e.g. a smarter binFinder
  float theRmin = (*(theComps.begin()))->surface().position().perp();
  float theRmax = theRmin;
  for(vector<const GeometricSearchDet*>::const_iterator it=theComps.begin();
      it!=theComps.end(); it++){
    theRmin = std::min( theRmin, (*it)->surface().position().perp());
    theRmax = std::max( theRmax, (*it)->surface().position().perp());
  }
  //float split_inner_outer_radius = 0.5 * (theRmin + theRmax);
  // force the splitting rdius to be 10 cm to cope also with the FPIX disks with only the outer ring 
  float split_inner_outer_radius = 10.;
  _num_innerpanels = 0;
  for(vector<const GeometricSearchDet*>::const_iterator it=theComps.begin();
      it!=theComps.end();it++){
    if((**it).surface().position().perp() <= split_inner_outer_radius) ++_num_innerpanels;
  }
  _num_outerpanels = theComps.size() - _num_innerpanels;
  edm::LogInfo("TkDetLayers") << " Rmin, Rmax, R_average = " << theRmin << ", " << theRmax << ", "
                              << split_inner_outer_radius << std::endl
                              << " num inner, outer disks = "
                              << _num_innerpanels << ", " << _num_outerpanels
                              << std::endl;

  for(vector<const GeometricSearchDet*>::const_iterator it=theComps.begin();
      it!=theComps.end();it++){
    theBasicComps.insert(theBasicComps.end(),
             (**it).basicComponents().begin(),
             (**it).basicComponents().end());
  }

  //They should be already phi-ordered. TO BE CHECKED!!
  //sort( theBlades.begin(), theBlades.end(), PhiLess());
  setSurface( computeSurface() );

  theBinFinder_inner = BinFinderType( theComps.front()->surface().position().phi(),
                                      _num_innerpanels);
  theBinFinder_outer = BinFinderType( theComps[_num_innerpanels]->surface().position().phi(),
                                      _num_outerpanels);

  //--------- DEBUG INFO --------------
  LogDebug("TkDetLayers") << "DEBUG INFO for PixelForwardLayerPhase1" << "\n"
                          << "Num of inner and outer panels = " << _num_innerpanels << ", " << _num_outerpanels << "\n"
                          << "Based on phi separation for inner: " << theComps.front()->surface().position().phi()
                          << " and on phi separation for outer: "  << theComps[_num_innerpanels]->surface().position().phi()
              << "PixelForwardLayerPhase1.surfcace.phi(): "  << std::endl
              << this->surface().position().phi() << "\n"
              << "PixelForwardLayerPhase1.surfcace.z(): "
              << this->surface().position().z() << "\n"
              << "PixelForwardLayerPhase1.surfcace.innerR(): "
              << this->specificSurface().innerRadius() << "\n"
              << "PixelForwardLayerPhase1.surfcace.outerR(): "
              << this->specificSurface().outerRadius() ;

  for(vector<const GeometricSearchDet*>::const_iterator it=theComps.begin();
      it!=theComps.end(); it++){
    LogDebug("TkDetLayers") << "blades phi,z,r: "
                            << (*it)->surface().position().phi() << " , "
                            << (*it)->surface().position().z() <<   " , "
                            << (*it)->surface().position().perp();
    //for(vector<const GeomDet*>::const_iterator iu=(**it).basicComponents().begin();
    //    iu!=(**it).basicComponents().end();iu++){
    //  std::cout << "   basic component rawId = " << hex << (**iu).geographicalId().rawId() << dec <<std::endl;
    //}
  }
  //-----------------------------------


}

PixelForwardLayerPhase1::~PixelForwardLayerPhase1

(

)

Definition at line 104 of file PixelForwardLayerPhase1.cc.

References i, and theComps.

                                                 {
  vector<const GeometricSearchDet*>::const_iterator i;
  for (i=theComps.begin(); i!=theComps.end(); i++) {
    delete *i;
  }
}

Member Function Documentation

virtual const std::vector<const GeomDet*>& PixelForwardLayerPhase1::basicComponents ( ) const

inlinevirtual

Implements GeometricSearchDet.

Definition at line 23 of file PixelForwardLayerPhase1.h.

References theBasicComps.

{return theBasicComps;}

virtual const std::vector<const GeometricSearchDet*>& PixelForwardLayerPhase1::components ( ) const

inlinevirtual

Returns basic components, if any.

Returns direct components, if any

Implements GeometricSearchDet.

Definition at line 25 of file PixelForwardLayerPhase1.h.

References theComps.

{return theComps;}

PixelForwardLayerPhase1::SubTurbineCrossings PixelForwardLayerPhase1::computeCrossings ( const TrajectoryStateOnSurface &  startingState, PropagationDirection  propDir, bool  innerDisk  ) const

private

Definition at line 296 of file PixelForwardLayerPhase1.cc.

References _num_innerpanels, funct::abs(), PeriodicBinFinderInPhi< T >::binIndex(), HelixArbitraryPlaneCrossing::direction(), TrajectoryStateOnSurface::globalMomentum(), TrajectoryStateOnSurface::globalPosition(), HelixArbitraryPlaneCrossing::pathLength(), HelixArbitraryPlaneCrossing2Order::pathLength(), HelixArbitraryPlaneCrossing::position(), HelixArbitraryPlaneCrossing2Order::position(), rho, ForwardDetLayer::specificSurface(), ForwardDetLayer::surface(), theBinFinder_inner, theBinFinder_outer, theComps, TrajectoryStateOnSurface::transverseCurvature(), and PV3DBase< T, PVType, FrameType >::x().

Referenced by groupedCompatibleDetsV().

{
  typedef MeasurementEstimator::Local2DVector Local2DVector;

  HelixPlaneCrossing::PositionType startPos( startingState.globalPosition());
  HelixPlaneCrossing::DirectionType startDir( startingState.globalMomentum());
  auto rho = startingState.transverseCurvature();

  HelixArbitraryPlaneCrossing turbineCrossing( startPos, startDir, rho,
                           propDir);

  pair<bool,double> thePath = turbineCrossing.pathLength( specificSurface() );

  if (!thePath.first) {
    return SubTurbineCrossings();
  }

  HelixPlaneCrossing::PositionType  turbinePoint( turbineCrossing.position(thePath.second));
  HelixPlaneCrossing::DirectionType turbineDir( turbineCrossing.direction(thePath.second));
  int closestIndex = 0;
  int nextIndex = 0;
  if(innerDisk)
    closestIndex = theBinFinder_inner.binIndex(turbinePoint.barePhi());
  else
    closestIndex = theBinFinder_outer.binIndex(turbinePoint.barePhi());
  
  HelixArbitraryPlaneCrossing2Order theBladeCrossing(turbinePoint, turbineDir, rho);
  
  float closestDist = 0;
  if(innerDisk) {
    const BoundPlane& closestPlane( static_cast<const BoundPlane&>(
                                   theComps[closestIndex]->surface()));
    
    pair<bool,double> theClosestBladePath = theBladeCrossing.pathLength( closestPlane );
    LocalPoint closestPos = closestPlane.toLocal(GlobalPoint(theBladeCrossing.position(theClosestBladePath.second)) );
    closestDist = closestPos.x();
    // use fact that local X perp to global Y
    nextIndex = PhiLess()( closestPlane.phi(), turbinePoint.barePhi()) ?
      closestIndex+1 : closestIndex-1;
  } else {
    const BoundPlane& closestPlane( static_cast<const BoundPlane&>(
                                   theComps[closestIndex + _num_innerpanels]->surface()));
    
    pair<bool,double> theClosestBladePath = theBladeCrossing.pathLength( closestPlane );
    LocalPoint closestPos = closestPlane.toLocal(GlobalPoint(theBladeCrossing.position(theClosestBladePath.second)) );
    closestDist = closestPos.x();
    // use fact that local X perp to global Y
    nextIndex = PhiLess()( closestPlane.phi(), turbinePoint.barePhi()) ?
      closestIndex+1 : closestIndex-1;
  }
  
  float nextDist = 0;
  if(innerDisk) {
    const BoundPlane& nextPlane( static_cast<const BoundPlane&>(
                                theComps[ theBinFinder_inner.binIndex(nextIndex)]->surface()));
    pair<bool,double> theNextBladePath    = theBladeCrossing.pathLength( nextPlane );
    LocalPoint nextPos = nextPlane.toLocal(GlobalPoint(theBladeCrossing.position(theNextBladePath.second)) );
    nextDist = nextPos.x();
  } else {
    const BoundPlane& nextPlane( static_cast<const BoundPlane&>(
                                theComps[ theBinFinder_outer.binIndex(nextIndex) + _num_innerpanels]->surface()));
    pair<bool,double> theNextBladePath    = theBladeCrossing.pathLength( nextPlane );
    LocalPoint nextPos = nextPlane.toLocal(GlobalPoint(theBladeCrossing.position(theNextBladePath.second)) );
    nextDist = nextPos.x();
  }
  if (std::abs(closestDist) < std::abs(nextDist)) {
    return SubTurbineCrossings( closestIndex, nextIndex, nextDist);
  }
  else {
    return SubTurbineCrossings( nextIndex, closestIndex, closestDist);
  }
}

int PixelForwardLayerPhase1::computeHelicity ( const GeometricSearchDet *  firstBlade, const GeometricSearchDet *  secondBlade  )

staticprivate

Definition at line 290 of file PixelForwardLayerPhase1.cc.

References funct::abs(), GeometricSearchDet::position(), and PV3DBase< T, PVType, FrameType >::z().

Referenced by groupedCompatibleDetsV(), and searchNeighbors().

{
  return std::abs(firstBlade->position().z()) < std::abs(secondBlade->position().z()) ? 0 : 1;
}

float PixelForwardLayerPhase1::computeWindowSize ( const GeomDet *  det, const TrajectoryStateOnSurface &  tsos, const MeasurementEstimator &  est  )

staticprivate

Definition at line 371 of file PixelForwardLayerPhase1.cc.

References MeasurementEstimator::maximalLocalDisplacement(), GeomDet::surface(), and x.

Referenced by groupedCompatibleDetsV().

{
  return est.maximalLocalDisplacement(tsos, det->surface()).x();
}

void PixelForwardLayerPhase1::groupedCompatibleDetsV ( const TrajectoryStateOnSurface &  tsos, const Propagator &  prop, const MeasurementEstimator &  est, std::vector< DetGroup > &  result  ) const

virtual

Reimplemented from GeometricSearchDet.

Definition at line 112 of file PixelForwardLayerPhase1.cc.

References _num_innerpanels, Clusterizer1DCommons::add(), PeriodicBinFinderInPhi< T >::binIndex(), PixelForwardLayerPhase1::SubTurbineCrossings::closestIndex, computeCrossings(), computeHelicity(), computeWindowSize(), LayerCrossingSide::endcapSide(), PixelForwardLayerPhase1::SubTurbineCrossings::isValid, PixelForwardLayerPhase1::SubTurbineCrossings::nextIndex, DetGroupMerger::orderAndMergeTwoLevels(), Propagator::propagationDirection(), searchNeighbors(), theBinFinder_inner, theBinFinder_outer, theComps, and svgfig::window().

                                                           {
  std::vector<DetGroup> closestResult_inner;
  std::vector<DetGroup> closestResult_outer;
  std::vector<DetGroup> nextResult_inner;
  std::vector<DetGroup> nextResult_outer;
  std::vector<DetGroup> result_inner;
  std::vector<DetGroup> result_outer;
  int frontindex_inner = 0;
  int frontindex_outer = 0;
  SubTurbineCrossings  crossings_inner;
  SubTurbineCrossings  crossings_outer;

  if(_num_innerpanels > 0) crossings_inner = computeCrossings( tsos, prop.propagationDirection(), true);
  crossings_outer = computeCrossings( tsos, prop.propagationDirection(), false);
  //  if (!crossings_inner.isValid){
  //    edm::LogInfo("TkDetLayers") << "inner computeCrossings returns invalid in PixelForwardLayerPhase1::groupedCompatibleDets:";
  //    return;
  //  }
  if (!crossings_outer.isValid){
    edm::LogInfo("TkDetLayers") << "outer computeCrossings returns invalid in PixelForwardLayerPhase1::groupedCompatibleDets:";
    return;
  }

  typedef CompatibleDetToGroupAdder Adder;
  if(crossings_inner.isValid) {
    Adder::add( *theComps[theBinFinder_inner.binIndex(crossings_inner.closestIndex)],
        tsos, prop, est, closestResult_inner);
    
    if(closestResult_inner.empty()){
      Adder::add( *theComps[theBinFinder_inner.binIndex(crossings_inner.nextIndex)],
          tsos, prop, est, result_inner);
      frontindex_inner = crossings_inner.nextIndex;
    } else {
      if (Adder::add( *theComps[theBinFinder_inner.binIndex(crossings_inner.nextIndex)],
              tsos, prop, est, nextResult_inner)) {
    int crossingSide = LayerCrossingSide().endcapSide( tsos, prop);
    int theHelicity = computeHelicity(theComps[theBinFinder_inner.binIndex(crossings_inner.closestIndex)],
                      theComps[theBinFinder_inner.binIndex(crossings_inner.nextIndex)] );
    std::vector<DetGroup> tmp99 = closestResult_inner;
    DetGroupMerger::orderAndMergeTwoLevels( std::move(tmp99), std::move(nextResult_inner), result_inner,
                        theHelicity, crossingSide);
    if (theHelicity == crossingSide) frontindex_inner = crossings_inner.closestIndex;
    else                             frontindex_inner = crossings_inner.nextIndex;
      } else {
    result_inner.swap(closestResult_inner);
    frontindex_inner = crossings_inner.closestIndex;
      }
    }
  }
  if(!closestResult_inner.empty()){
    DetGroupElement closestGel( closestResult_inner.front().front());
    float window = computeWindowSize( closestGel.det(), closestGel.trajectoryState(), est);
    searchNeighbors( tsos, prop, est, crossings_inner, window, result_inner, true);
  }

  //DetGroupElement closestGel( closestResult.front().front());
  //float window = computeWindowSize( closestGel.det(), closestGel.trajectoryState(), est);
  //float detWidth = closestGel.det()->surface().bounds().width();
  //if (crossings.nextDistance < detWidth + window) {

  Adder::add( *theComps[(theBinFinder_outer.binIndex(crossings_outer.closestIndex)) + _num_innerpanels],
              tsos, prop, est, closestResult_outer);

  if(closestResult_outer.empty()){
    Adder::add( *theComps[theBinFinder_outer.binIndex(crossings_outer.nextIndex) + _num_innerpanels],
                tsos, prop, est, result_outer);
    frontindex_outer = crossings_outer.nextIndex;
  } else {
    if (Adder::add( *theComps[theBinFinder_outer.binIndex(crossings_outer.nextIndex) + _num_innerpanels],
                    tsos, prop, est, nextResult_outer)) {
      int crossingSide = LayerCrossingSide().endcapSide( tsos, prop);
      int theHelicity = computeHelicity(theComps[theBinFinder_outer.binIndex(crossings_outer.closestIndex) + _num_innerpanels],
                    theComps[theBinFinder_outer.binIndex(crossings_outer.nextIndex) + _num_innerpanels] );
      std::vector<DetGroup> tmp99 = closestResult_outer;
      DetGroupMerger::orderAndMergeTwoLevels( std::move(tmp99), std::move(nextResult_outer), result_outer,
                                              theHelicity, crossingSide);
      if (theHelicity == crossingSide) frontindex_outer = crossings_outer.closestIndex;
      else                             frontindex_outer = crossings_outer.nextIndex;
    } else {
      result_outer.swap(closestResult_outer);
      frontindex_outer = crossings_outer.closestIndex;
    }
  }
  if(!closestResult_outer.empty()){
    DetGroupElement closestGel( closestResult_outer.front().front());
    float window = computeWindowSize( closestGel.det(), closestGel.trajectoryState(), est);
    searchNeighbors( tsos, prop, est, crossings_outer, window, result_outer, false);
  }

  if(result_inner.empty() && result_outer.empty() ) return;
  if(result_inner.empty()) result.swap(result_outer);
  else if(result_outer.empty()) result.swap(result_inner);
  else {
    int crossingSide = LayerCrossingSide().endcapSide( tsos, prop);
    int theHelicity = computeHelicity(theComps[theBinFinder_inner.binIndex(frontindex_inner)],
                                      theComps[theBinFinder_outer.binIndex(frontindex_outer) + _num_innerpanels] );
    DetGroupMerger::orderAndMergeTwoLevels( std::move(result_inner), std::move(result_outer), result,
                        theHelicity, crossingSide);
  }

}

void PixelForwardLayerPhase1::searchNeighbors ( const TrajectoryStateOnSurface &  tsos, const Propagator &  prop, const MeasurementEstimator &  est, const SubTurbineCrossings &  crossings, float  window, std::vector< DetGroup > &  result, bool  innerDisk  ) const

private

Definition at line 220 of file PixelForwardLayerPhase1.cc.

References _num_innerpanels, _num_outerpanels, Clusterizer1DCommons::add(), PeriodicBinFinderInPhi< T >::binIndex(), PixelForwardLayerPhase1::SubTurbineCrossings::closestIndex, computeHelicity(), LayerCrossingSide::endcapSide(), bookConverter::max, HLT_25ns14e33_v1_cff::Merger, min(), PixelForwardLayerPhase1::SubTurbineCrossings::nextIndex, theBinFinder_inner, theBinFinder_outer, and theComps.

Referenced by groupedCompatibleDetsV().

{
  typedef CompatibleDetToGroupAdder Adder;
  int crossingSide = LayerCrossingSide().endcapSide( tsos, prop);
  typedef DetGroupMerger Merger;

  int negStart = min( crossings.closestIndex, crossings.nextIndex) - 1;
  int posStart = max( crossings.closestIndex, crossings.nextIndex) + 1;

  int quarter = theComps.size()/4;
  if(innerDisk) quarter = _num_innerpanels/4;
  else quarter = _num_outerpanels/4;

  for (int idet=negStart; idet >= negStart - quarter+1; idet--) {
    std::vector<DetGroup> tmp1;
    std::vector<DetGroup> newResult;
    if(innerDisk) {
      const GeometricSearchDet* neighbor = theComps[theBinFinder_inner.binIndex(idet)];
      // if (!overlap( gCrossingPos, *neighbor, window)) break; // mybe not needed?
      // maybe also add shallow crossing angle test here???
      if (!Adder::add( *neighbor, tsos, prop, est, tmp1)) break;
      int theHelicity = computeHelicity(theComps[theBinFinder_inner.binIndex(idet)],
                                        theComps[theBinFinder_inner.binIndex(idet+1)] );
      std::vector<DetGroup> tmp2; tmp2.swap(result);
      Merger::orderAndMergeTwoLevels( std::move(tmp1), std::move(tmp2), newResult, theHelicity, crossingSide);
    } else {
      const GeometricSearchDet* neighbor = theComps[(theBinFinder_outer.binIndex(idet)) + _num_innerpanels];
      // if (!overlap( gCrossingPos, *neighbor, window)) break; // mybe not needed?
      // maybe also add shallow crossing angle test here???
      if (!Adder::add( *neighbor, tsos, prop, est, tmp1)) break;
      int theHelicity = computeHelicity(theComps[(theBinFinder_outer.binIndex(idet)) + _num_innerpanels],
                                        theComps[(theBinFinder_outer.binIndex(idet+1)) + _num_innerpanels] );
      std::vector<DetGroup> tmp2; tmp2.swap(result);
      Merger::orderAndMergeTwoLevels( std::move(tmp1), std::move(tmp2), newResult, theHelicity, crossingSide);
    }
    result.swap(newResult);
  }
  for (int idet=posStart; idet < posStart + quarter-1; idet++) {
    std::vector<DetGroup> tmp1;
    std::vector<DetGroup> newResult;
    if(innerDisk) {
      const GeometricSearchDet* neighbor = theComps[theBinFinder_inner.binIndex(idet)];
      // if (!overlap( gCrossingPos, *neighbor, window)) break; // mybe not needed?
      // maybe also add shallow crossing angle test here???
      if (!Adder::add( *neighbor, tsos, prop, est, tmp1)) break;
      int theHelicity = computeHelicity(theComps[theBinFinder_inner.binIndex(idet-1)],
                                        theComps[theBinFinder_inner.binIndex(idet)] );
      std::vector<DetGroup> tmp2; tmp2.swap(result);
      Merger::orderAndMergeTwoLevels(std::move(tmp2), std::move(tmp1), newResult, theHelicity, crossingSide);
    } else {
      const GeometricSearchDet* neighbor = theComps[(theBinFinder_outer.binIndex(idet)) + _num_innerpanels];
      // if (!overlap( gCrossingPos, *neighbor, window)) break; // mybe not needed?
      // maybe also add shallow crossing angle test here???
      if (!Adder::add( *neighbor, tsos, prop, est, tmp1)) break;
      int theHelicity = computeHelicity(theComps[(theBinFinder_outer.binIndex(idet-1)) + _num_innerpanels],
                                        theComps[(theBinFinder_outer.binIndex(idet)) + _num_innerpanels] );
      std::vector<DetGroup> tmp2; tmp2.swap(result);
      Merger::orderAndMergeTwoLevels(std::move(tmp2), std::move(tmp1), newResult, theHelicity, crossingSide);
    }
    result.swap(newResult);
  }
}

virtual SubDetector PixelForwardLayerPhase1::subDetector ( ) const

inlinevirtual

The type of detector (PixelBarrel, PixelEndcap, TIB, TOB, TID, TEC, CSC, DT, RPCBarrel, RPCEndcap)

Implements DetLayer.

Definition at line 33 of file PixelForwardLayerPhase1.h.

References GeomDetEnumerators::P1PXEC, and GeomDetEnumerators::subDetGeom.

{return GeomDetEnumerators::subDetGeom[GeomDetEnumerators::P1PXEC];}

Member Data Documentation

unsigned int PixelForwardLayerPhase1::_num_innerpanels

private

Definition at line 73 of file PixelForwardLayerPhase1.h.

Referenced by computeCrossings(), groupedCompatibleDetsV(), PixelForwardLayerPhase1(), and searchNeighbors().

unsigned int PixelForwardLayerPhase1::_num_outerpanels

private

Definition at line 74 of file PixelForwardLayerPhase1.h.

Referenced by PixelForwardLayerPhase1(), and searchNeighbors().

std::vector<const GeomDet*> PixelForwardLayerPhase1::theBasicComps

private

Definition at line 81 of file PixelForwardLayerPhase1.h.

Referenced by basicComponents(), and PixelForwardLayerPhase1().

std::vector<float> PixelForwardLayerPhase1::theBinFinder_byR

private

Definition at line 76 of file PixelForwardLayerPhase1.h.

std::vector<unsigned int> PixelForwardLayerPhase1::theBinFinder_byR_index

private

Definition at line 77 of file PixelForwardLayerPhase1.h.

std::vector<unsigned int> PixelForwardLayerPhase1::theBinFinder_byR_nextindex

private

Definition at line 78 of file PixelForwardLayerPhase1.h.

BinFinderType PixelForwardLayerPhase1::theBinFinder_inner

private

Definition at line 71 of file PixelForwardLayerPhase1.h.

Referenced by computeCrossings(), groupedCompatibleDetsV(), PixelForwardLayerPhase1(), and searchNeighbors().

BinFinderType PixelForwardLayerPhase1::theBinFinder_outer

private

Definition at line 72 of file PixelForwardLayerPhase1.h.

Referenced by computeCrossings(), groupedCompatibleDetsV(), PixelForwardLayerPhase1(), and searchNeighbors().

std::vector<const GeometricSearchDet*> PixelForwardLayerPhase1::theComps

private

Definition at line 80 of file PixelForwardLayerPhase1.h.

Referenced by components(), computeCrossings(), groupedCompatibleDetsV(), PixelForwardLayerPhase1(), searchNeighbors(), and ~PixelForwardLayerPhase1().