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#include <MuonMesh.h>
Public Member Functions | |
| void | clearMesh () |
| bool | isClusteredWith (const std::pair< CSCDetId, CSCSegmentRef > &lhs, const std::pair< CSCDetId, CSCSegmentRef > &rhs) const |
| bool | isDuplicateOf (const CSCSegmentRef &lhs, const CSCSegmentRef &rhs) const |
| bool | isDuplicateOf (const std::pair< CSCDetId, CSCSegmentRef > &rhs, const std::pair< CSCDetId, CSCSegmentRef > &lhs) const |
| MuonMesh (const edm::ParameterSet &) | |
| void | runMesh (std::vector< reco::Muon > *p) |
| void | setCSCGeometry (const CSCGeometry *pg) |
Private Types | |
| typedef std::vector< std::pair < reco::Muon *, std::pair < reco::MuonChamberMatch *, reco::MuonSegmentMatch * > > > | AssociationType |
| typedef std::map< reco::Muon *, std::vector< std::pair < reco::Muon *, std::pair < reco::MuonChamberMatch *, reco::MuonSegmentMatch * > > > > | MeshType |
Private Member Functions | |
| void | fillMesh (std::vector< reco::Muon > *) |
| void | pruneMesh () |
| bool | withinTwoSigma (const std::pair< CSCDetId, CSCSegmentRef > &rhs, const std::pair< CSCDetId, CSCSegmentRef > &lhs) const |
Private Attributes | |
| const double | ClusterDPhi |
| const double | ClusterDTheta |
| const bool | doClustering |
| const bool | doME1a |
| const bool | doOverlaps |
| const CSCGeometry * | geometry_ |
| MeshType | mesh_ |
| const double | OverlapDPhi |
| const double | OverlapDTheta |
Definition at line 17 of file MuonMesh.h.
typedef std::vector<std::pair<reco::Muon*, std::pair<reco::MuonChamberMatch*, reco::MuonSegmentMatch* > > > MuonMesh::AssociationType [private] |
Definition at line 33 of file MuonMesh.h.
typedef std::map<reco::Muon*, std::vector<std::pair<reco::Muon*, std::pair<reco::MuonChamberMatch*, reco::MuonSegmentMatch* > > > > MuonMesh::MeshType [private] |
Definition at line 26 of file MuonMesh.h.
| MuonMesh::MuonMesh | ( | const edm::ParameterSet & | parm | ) |
Definition at line 9 of file MuonMesh.cc.
: doME1a(parm.getParameter<bool>("ME1a")), doOverlaps(parm.getParameter<bool>("Overlap")), doClustering(parm.getParameter<bool>("Clustering")), OverlapDPhi(parm.getParameter<double>("OverlapDPhi")), OverlapDTheta(parm.getParameter<double>("OverlapDTheta")), ClusterDPhi(parm.getParameter<double>("ClusterDPhi")), ClusterDTheta(parm.getParameter<double>("ClusterDTheta")) { }
| void MuonMesh::clearMesh | ( | ) | [inline] |
Definition at line 41 of file MuonMesh.h.
References mesh_.
Referenced by MuonIdProducer::fillArbitrationInfo().
{ mesh_.clear(); }
| void MuonMesh::fillMesh | ( | std::vector< reco::Muon > * | inputMuons | ) | [private] |
Definition at line 18 of file MuonMesh.cc.
References begin, reco::MuonSegmentMatch::BelongsToTrackByCleaning, MuonSubdetId::CSC, CSC(), CSCDetId, doClustering, doME1a, doOverlaps, MuonSubdetId::DT, end, spr::find(), i, isClusteredWith(), isDuplicateOf(), j, mesh_, and CSCDetId::ring().
Referenced by runMesh().
{
for(std::vector<reco::Muon>::iterator muonIter1 = inputMuons->begin();
muonIter1 != inputMuons->end();
++muonIter1) {
if(muonIter1->isTrackerMuon()){
mesh_[&*muonIter1]; // create this entry if it's a tracker muon
for(std::vector<reco::Muon>::iterator muonIter2 = inputMuons->begin();
muonIter2 != inputMuons->end();
++muonIter2) {
if(muonIter2->isTrackerMuon()) {
if(muonIter2 != muonIter1) {
// now fill all the edges for muon1 based on overlaps with muon2
for(std::vector<reco::MuonChamberMatch>::iterator chamberIter1 = muonIter1->matches().begin();
chamberIter1 != muonIter1->matches().end();
++chamberIter1) {
for(std::vector<reco::MuonSegmentMatch>::iterator segmentIter1 = chamberIter1->segmentMatches.begin();
segmentIter1 != chamberIter1->segmentMatches.end();
++segmentIter1) {
for(std::vector<reco::MuonChamberMatch>::iterator chamberIter2 = muonIter2->matches().begin();
chamberIter2 != muonIter2->matches().end();
++chamberIter2) {
for(std::vector<reco::MuonSegmentMatch>::iterator segmentIter2 = chamberIter2->segmentMatches.begin();
segmentIter2 != chamberIter2->segmentMatches.end();
++segmentIter2) {
//if(segmentIter1->mask & 0x1e0000 && segmentIter2->mask &0x1e0000) {
bool addsegment(false);
if( segmentIter1->cscSegmentRef.isNonnull() && segmentIter2->cscSegmentRef.isNonnull() ) {
if( doME1a &&
isDuplicateOf(segmentIter1->cscSegmentRef,segmentIter2->cscSegmentRef) &&
CSCDetId(chamberIter1->id).ring() == 4 && CSCDetId(chamberIter2->id).ring() == 4 &&
chamberIter1->id == chamberIter2->id ) {
addsegment = true;
//std::cout << "\tME1/a sharing detected." << std::endl;
}
if( doOverlaps &&
isDuplicateOf(std::make_pair(CSCDetId(chamberIter1->id),segmentIter1->cscSegmentRef),
std::make_pair(CSCDetId(chamberIter2->id),segmentIter2->cscSegmentRef)) ) {
addsegment = true;
//std::cout << "\tChamber Overlap sharing detected." << std::endl;
}
if( doClustering &&
isClusteredWith(std::make_pair(CSCDetId(chamberIter1->id),segmentIter1->cscSegmentRef),
std::make_pair(CSCDetId(chamberIter2->id),segmentIter2->cscSegmentRef)) ) {
addsegment = true;
//std::cout << "\tCluster sharing detected." << std::endl;
}
//std::cout << std::endl;
} // has valid csc segment ref
if(addsegment) { // add segment if clusters/overlaps/replicant and doesn't already exist
if(find(mesh_[&*muonIter1].begin(),
mesh_[&*muonIter1].end(),
std::make_pair(&*muonIter2,
std::make_pair(&*chamberIter2,
&*segmentIter2)
)
) == mesh_[&*muonIter1].end()) {
mesh_[&*muonIter1].push_back(std::make_pair(&*muonIter2,
std::make_pair(&*chamberIter2,
&*segmentIter2)
)
);
} // find
} // add segment?
//} // both segments won arbitration
} // segmentIter 2
} // chamberIter2
} //segmentIter1
} // chamberIter1
} // if different muon
} // is tracker muon
} // muonIter2
} // is tracker muon
} // muonIter1
// special cases
// one muon: mark all segments belonging to a muon as cleaned as there are no other muons to fight with
if(mesh_.size() == 1) {
for(std::vector<reco::MuonChamberMatch>::iterator chamberIter1 = mesh_.begin()->first->matches().begin();
chamberIter1 != mesh_.begin()->first->matches().end();
++chamberIter1) {
for(std::vector<reco::MuonSegmentMatch>::iterator segmentIter1 = chamberIter1->segmentMatches.begin();
segmentIter1 != chamberIter1->segmentMatches.end();
++segmentIter1) {
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning);
} // segmentIter1
} // chamberIter1
} // if only one tracker muon set winner bit boosted arbitration
// segments that are not shared amongst muons and the have won all segment arbitration flags need to be promoted
// also promote DT segments
if(mesh_.size() > 1) {
for( MeshType::iterator i = mesh_.begin(); i != mesh_.end(); ++i ) {
for( std::vector<reco::MuonChamberMatch>::iterator chamberIter1 = i->first->matches().begin();
chamberIter1 != i->first->matches().end();
++chamberIter1 ) {
for(std::vector<reco::MuonSegmentMatch>::iterator segmentIter1 = chamberIter1->segmentMatches.begin();
segmentIter1 != chamberIter1->segmentMatches.end();
++segmentIter1) {
bool shared(false);
for( AssociationType::iterator j = i->second.begin();
j != i->second.end();
++j ) {
if( segmentIter1->cscSegmentRef.isNonnull() &&
j->second.second->cscSegmentRef.isNonnull() ) {
if(chamberIter1->id.subdetId() == MuonSubdetId::CSC &&
j->second.first->id.subdetId() == MuonSubdetId::CSC ) {
CSCDetId segIterId(chamberIter1->id), shareId(j->second.first->id);
if( doOverlaps &&
isDuplicateOf(std::make_pair(segIterId,segmentIter1->cscSegmentRef),
std::make_pair(shareId,j->second.second->cscSegmentRef)) )
shared = true;
if( doME1a &&
isDuplicateOf(segmentIter1->cscSegmentRef,j->second.second->cscSegmentRef) &&
segIterId.ring() == 4 && shareId.ring() == 4 &&
segIterId == segIterId)
shared = true;
if( doClustering &&
isClusteredWith(std::make_pair(CSCDetId(chamberIter1->id),segmentIter1->cscSegmentRef),
std::make_pair(CSCDetId(j->second.first->id),j->second.second->cscSegmentRef)) )
shared = true;
} // in CSCs?
} // cscSegmentRef non null?
} // j
// Promote segments which have won all arbitration and are not shared or are DT segments
if( ((segmentIter1->mask&0x1e0000) == 0x1e0000 && !shared) ||
(chamberIter1->id.subdetId() == MuonSubdetId::DT && (segmentIter1->mask&0x1e0000)) )
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning);
} // segmentIter1
} // chamberIter1
}// i
} // if non-trivial case
}
| bool MuonMesh::isClusteredWith | ( | const std::pair< CSCDetId, CSCSegmentRef > & | lhs, |
| const std::pair< CSCDetId, CSCSegmentRef > & | rhs | ||
| ) | const |
Definition at line 482 of file MuonMesh.cc.
References CSCGeometry::chamber(), ClusterDPhi, ClusterDTheta, geometry_, M_PI, phi, hitfit::phidiff(), query::result, theta(), and GeomDet::toGlobal().
Referenced by fillMesh(), and pruneMesh().
{
bool result(false);
// try to implement the simple case first just back-to-back segments without treatment of ME1/a ganging
// ME1a should be a simple extension of this
//std::cout << lhs.first << ' ' << rhs.first << std::endl;
if(rhs.first.endcap() == lhs.first.endcap() && lhs.first.station() < rhs.first.station()) {
std::vector<CSCSegment> thesegments;
thesegments.push_back(*(lhs.second));
/*
if(lhs.second->isME11a_duplicate())
thesegments.insert(thesegments.begin(),
lhs.second->duplicateSegments().begin(),
lhs.second->duplicateSegments().end());
*/
//std::cout << "lhs is in neighoring chamber of rhs." << std::endl;
// rhs local direction info
/*
double rhs_dydz = geometry_->chamber(rhs.first)->toGlobal(rhs.second->localDirection()).y()/
geometry_->chamber(rhs.first)->toGlobal(rhs.second->localDirection()).z();
double rhs_dxdz = geometry_->chamber(rhs.first)->toGlobal(rhs.second->localDirection()).x()/
geometry_->chamber(rhs.first)->toGlobal(rhs.second->localDirection()).z();
double rhs_dydz_err = rhs.second->localDirectionError().yy();
double rhs_dxdz_err = rhs.second->localDirectionError().xx();
*/
//rhs global position info
double rhs_phi = geometry_->chamber(rhs.first)->toGlobal(rhs.second->localPosition()).phi();
double rhs_theta = geometry_->chamber(rhs.first)->toGlobal(rhs.second->localPosition()).theta();
for(std::vector<CSCSegment>::const_iterator ilhs = thesegments.begin(); ilhs != thesegments.end(); ++ilhs) {
// lhs local direction info
/*
double lhs_dydz = geometry_->chamber(lhs.first)->toGlobal(ilhs->localDirection()).y()/
geometry_->chamber(lhs.first)->toGlobal(ilhs->localDirection()).z();
double lhs_dxdz = geometry_->chamber(lhs.first)->toGlobal(ilhs->localDirection()).x()/
geometry_->chamber(lhs.first)->toGlobal(ilhs->localDirection()).z();
double lhs_dydz_err = ilhs->localDirectionError().yy();
double lhs_dxdz_err = ilhs->localDirectionError().xx();
*/
//lhs global position info
double lhs_phi = geometry_->chamber(lhs.first)->toGlobal(ilhs->localPosition()).phi();
double lhs_theta = geometry_->chamber(lhs.first)->toGlobal(ilhs->localPosition()).theta();
/*
std::cout << "RHS Segment Parameters:" << std::endl
<< "\t RHS Phi : " << rhs_phi << std::endl
<< "\t RHS Theta : " << rhs_theta << std::endl
<< "\t RHS dx/dz : " << rhs_dxdz << " +- " << rhs_dxdz_err << std::endl
<< "\t RHS dy/dz : " << rhs_dydz << " +- " << rhs_dydz_err << std::endl;
std::cout << "LHS Segment Parameters:" << std::endl
<< "\t LHS Phi : " << lhs_phi << std::endl
<< "\t LHS Theta : " << lhs_theta << std::endl
<< "\t LHS dx/dz : " << lhs_dxdz << " +- " << lhs_dxdz_err << std::endl
<< "\t LHS dy/dz : " << lhs_dydz << " +- " << lhs_dydz_err << std::endl;
*/
double phidiff = (fabs(rhs_phi - lhs_phi) > 2*M_PI ? fabs(rhs_phi - lhs_phi) - 2*M_PI : fabs(rhs_phi - lhs_phi));
if(phidiff < ClusterDPhi && fabs(rhs_theta - lhs_theta) < ClusterDTheta) // phi overlap region is 37 degrees
result = true;
} // loop over duplicate segments
} // same endcap,station,ring
return result;
}
| bool MuonMesh::isDuplicateOf | ( | const CSCSegmentRef & | lhs, |
| const CSCSegmentRef & | rhs | ||
| ) | const |
Definition at line 342 of file MuonMesh.cc.
References query::result.
Referenced by MuonIdProducer::fillArbitrationInfo(), fillMesh(), and pruneMesh().
{
bool result(false);
if(!lhs->isME11a_duplicate())
return result;
std::vector<CSCSegment> lhs_duplicates = lhs->duplicateSegments();
if(fabs(lhs->localPosition().x() - rhs->localPosition().x() ) < 1E-3 &&
fabs(lhs->localPosition().y() - rhs->localPosition().y() ) < 1E-3 &&
fabs(lhs->localDirection().x()/lhs->localDirection().z() - rhs->localDirection().x()/rhs->localDirection().z() ) < 1E-3 &&
fabs(lhs->localDirection().y()/lhs->localDirection().z() - rhs->localDirection().y()/rhs->localDirection().z() ) < 1E-3 &&
fabs(lhs->localPositionError().xx() - rhs->localPositionError().xx() ) < 1E-3 &&
fabs(lhs->localPositionError().yy() - rhs->localPositionError().yy() ) < 1E-3 &&
fabs(lhs->localDirectionError().xx() - rhs->localDirectionError().xx()) < 1E-3 &&
fabs(lhs->localDirectionError().yy() - rhs->localDirectionError().yy()) < 1E-3)
result = true;
for( std::vector<CSCSegment>::const_iterator segIter1 = lhs_duplicates.begin();
segIter1 != lhs_duplicates.end();
++segIter1 ) { // loop over lhs duplicates
if(fabs(segIter1->localPosition().x() - rhs->localPosition().x() ) < 1E-3 &&
fabs(segIter1->localPosition().y() - rhs->localPosition().y() ) < 1E-3 &&
fabs(segIter1->localDirection().x()/segIter1->localDirection().z() - rhs->localDirection().x()/rhs->localDirection().z() ) < 1E-3 &&
fabs(segIter1->localDirection().y()/segIter1->localDirection().z() - rhs->localDirection().y()/rhs->localDirection().z() ) < 1E-3 &&
fabs(segIter1->localPositionError().xx() - rhs->localPositionError().xx() ) < 1E-3 &&
fabs(segIter1->localPositionError().yy() - rhs->localPositionError().yy() ) < 1E-3 &&
fabs(segIter1->localDirectionError().xx() - rhs->localDirectionError().xx()) < 1E-3 &&
fabs(segIter1->localDirectionError().yy() - rhs->localDirectionError().yy()) < 1E-3)
result = true;
/*
if(fabs(segIter1->localPosition().x() - rhs->localPosition().x() ) < 2*sqrt(segIter1->localPositionError().xx()) &&
fabs(segIter1->localPosition().y() - rhs->localPosition().y() ) < 2*sqrt(segIter1->localPositionError().yy()) &&
fabs(segIter1->localDirection().x()/segIter1->localDirection().z() - rhs->localDirection().x()/rhs->localDirection().z() )
< 2*std::sqrt(std::max(segIter1->localDirectionError().yy(),rhs->localDirectionError().xx())) &&
fabs(segIter1->localDirection().y()/segIter1->localDirection().z() - rhs->localDirection().y()/rhs->localDirection().z() )
< 2*std::sqrt(std::max(segIter1->localDirectionError().yy(),rhs->localDirectionError().yy())))
result = true;
*/
} // loop over duplicates
return result;
}
| bool MuonMesh::isDuplicateOf | ( | const std::pair< CSCDetId, CSCSegmentRef > & | rhs, |
| const std::pair< CSCDetId, CSCSegmentRef > & | lhs | ||
| ) | const |
Definition at line 389 of file MuonMesh.cc.
References M_PI, phi, hitfit::phidiff(), query::result, theta(), and z.
{
bool result(false);
// try to implement the simple case first just back-to-back segments without treatment of ME1/a ganging
// ME1a should be a simple extension of this
if(rhs.first.endcap() == lhs.first.endcap() &&
rhs.first.station() == lhs.first.station() &&
rhs.first.ring() == lhs.first.ring()) { // if same endcap,station,ring (minimal requirement for ovl candidate)
/*
std::cout << "Chamber 1: " << rhs.first << std::endl
<< "Chamber 2: " << lhs.first << std::endl;
std::cout << "Same endcap,ring,station." << std::endl;
*/
//create neighboring chamber labels, treat ring as (Z mod 36 or 18) + 1 number line: left, right defined accordingly.
unsigned modulus = ((rhs.first.ring() != 1 || rhs.first.station() == 1) ? 36 : 18);
int left_neighbor = (((rhs.first.chamber() - 1 + modulus)%modulus == 0 ) ? modulus : (rhs.first.chamber() - 1 + modulus)%modulus ); // + modulus to ensure positivity
int right_neighbor = (((rhs.first.chamber() + 1)%modulus == 0 ) ? modulus : (rhs.first.chamber() + 1)%modulus );
if(lhs.first.chamber() == left_neighbor ||
lhs.first.chamber() == right_neighbor) { // if this is a neighboring chamber then it can be an overlap
std::vector<CSCSegment> thesegments;
thesegments.push_back(*(lhs.second));
/*
if(lhs.second->isME11a_duplicate())
thesegments.insert(thesegments.begin(),
lhs.second->duplicateSegments().begin(),
lhs.second->duplicateSegments().end());
*/
//std::cout << "lhs is in neighoring chamber of rhs." << std::endl;
// rhs local direction info
/*
double rhs_dydz = geometry_->chamber(rhs.first)->toGlobal(rhs.second->localDirection()).y()/
geometry_->chamber(rhs.first)->toGlobal(rhs.second->localDirection()).z();
double rhs_dxdz = geometry_->chamber(rhs.first)->toGlobal(rhs.second->localDirection()).x()/
geometry_->chamber(rhs.first)->toGlobal(rhs.second->localDirection()).z();
double rhs_dydz_err = rhs.second->localDirectionError().yy();
double rhs_dxdz_err = rhs.second->localDirectionError().xx();
*/
//rhs global position info
double rhs_phi = geometry_->chamber(rhs.first)->toGlobal(rhs.second->localPosition()).phi();
double rhs_theta = geometry_->chamber(rhs.first)->toGlobal(rhs.second->localPosition()).theta();
double rhs_z = geometry_->chamber(rhs.first)->toGlobal(rhs.second->localPosition()).z();
for(std::vector<CSCSegment>::const_iterator ilhs = thesegments.begin(); ilhs != thesegments.end(); ++ilhs) {
// lhs local direction info
/*
double lhs_dydz = geometry_->chamber(lhs.first)->toGlobal(ilhs->localDirection()).y()/
geometry_->chamber(lhs.first)->toGlobal(ilhs->localDirection()).z();
double lhs_dxdz = geometry_->chamber(lhs.first)->toGlobal(ilhs->localDirection()).x()/
geometry_->chamber(lhs.first)->toGlobal(ilhs->localDirection()).z();
double lhs_dydz_err = ilhs->localDirectionError().yy();
double lhs_dxdz_err = ilhs->localDirectionError().xx();
*/
//lhs global position info
double lhs_phi = geometry_->chamber(lhs.first)->toGlobal(ilhs->localPosition()).phi();
double lhs_theta = geometry_->chamber(lhs.first)->toGlobal(ilhs->localPosition()).theta();
double lhs_z = geometry_->chamber(lhs.first)->toGlobal(ilhs->localPosition()).z();
/*
std::cout << "RHS Segment Parameters:" << std::endl
<< "\t RHS Phi : " << rhs_phi << std::endl
<< "\t RHS Theta : " << rhs_theta << std::endl
<< "\t RHS dx/dz : " << rhs_dxdz << " +- " << rhs_dxdz_err << std::endl
<< "\t RHS dy/dz : " << rhs_dydz << " +- " << rhs_dydz_err << std::endl;
std::cout << "LHS Segment Parameters:" << std::endl
<< "\t LHS Phi : " << lhs_phi << std::endl
<< "\t LHS Theta : " << lhs_theta << std::endl
<< "\t LHS dx/dz : " << lhs_dxdz << " +- " << lhs_dxdz_err << std::endl
<< "\t LHS dy/dz : " << lhs_dydz << " +- " << lhs_dydz_err << std::endl;
*/
double phidiff = (fabs(rhs_phi - lhs_phi) > 2*M_PI ? fabs(rhs_phi - lhs_phi) - 2*M_PI : fabs(rhs_phi - lhs_phi));
if(phidiff < OverlapDPhi && fabs(rhs_theta - lhs_theta) < OverlapDTheta &&
fabs(rhs_z) < fabs(lhs_z) && rhs_z*lhs_z > 0) // phi overlap region is 3.5 degrees and rhs is infront of lhs
result = true;
} // loop over duplicate segments
}// neighboring chamber
} // same endcap,station,ring
return result;
}
| void MuonMesh::pruneMesh | ( | ) | [private] |
Definition at line 175 of file MuonMesh.cc.
References reco::MuonSegmentMatch::BelongsToTrackByCleaning, reco::MuonSegmentMatch::BelongsToTrackByClusClean, reco::MuonSegmentMatch::BelongsToTrackByOvlClean, CSCDetId, doClustering, doME1a, doOverlaps, i, isClusteredWith(), isDuplicateOf(), j, mesh_, dt_dqm_sourceclient_common_cff::reco, and CSCDetId::ring().
Referenced by runMesh().
{
for( MeshType::iterator i = mesh_.begin(); i != mesh_.end(); ++i ) {
for( AssociationType::iterator j = i->second.begin();
j != i->second.end();
++j ) {
for( std::vector<reco::MuonChamberMatch>::iterator chamberIter1 = i->first->matches().begin();
chamberIter1 != i->first->matches().end();
++chamberIter1 ) {
for(std::vector<reco::MuonSegmentMatch>::iterator segmentIter1 = chamberIter1->segmentMatches.begin();
segmentIter1 != chamberIter1->segmentMatches.end();
++segmentIter1) {
if(j->second.second->cscSegmentRef.isNonnull() && segmentIter1->cscSegmentRef.isNonnull()) {
//UNUSED: bool me1a(false), overlap(false), cluster(false);
// remove physical overlap duplicates first
if( doOverlaps &&
isDuplicateOf(std::make_pair(CSCDetId(chamberIter1->id),segmentIter1->cscSegmentRef),
std::make_pair(CSCDetId(j->second.first->id),j->second.second->cscSegmentRef)) ) {
if ( i->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) >
j->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) ) {
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByOvlClean);
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning);
//UNUSED: overlap = true;
} else if ( i->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) ==
j->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) ) { // muon with more matched stations wins
if((segmentIter1->mask & 0x1e0000) > (j->second.second->mask & 0x1e0000)) { // segment with better match wins
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByOvlClean);
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning);
//UNUSED: overlap = true;
} else { // ??
// leave this available for later
}
} // overlap duplicate resolution
} // is overlap duplicate
// do ME1/a arbitration second since the tie breaker depends on other stations
// Unlike the other cleanings this one removes the bits from segments associated to tracks which
// fail cleaning. (Instead of setting bits for the segments which win.)
if( doME1a &&
isDuplicateOf(segmentIter1->cscSegmentRef,j->second.second->cscSegmentRef) &&
CSCDetId(chamberIter1->id).ring() == 4 && CSCDetId(j->second.first->id).ring() == 4 &&
chamberIter1->id == j->second.first->id ) {
if( j->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) <
i->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) ) {
for(AssociationType::iterator AsscIter1 = i->second.begin();
AsscIter1 != i->second.end();
++AsscIter1) {
if(AsscIter1->second.second->cscSegmentRef.isNonnull())
if(j->first == AsscIter1->first &&
j->second.first == AsscIter1->second.first &&
isDuplicateOf(segmentIter1->cscSegmentRef,AsscIter1->second.second->cscSegmentRef)) {
AsscIter1->second.second->mask &= ~reco::MuonSegmentMatch::BelongsToTrackByME1aClean;
}
}
//UNUSED: me1a = true;
} else if ( j->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) ==
i->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) ) { // muon with best arbitration wins
bool bestArb(true);
for(AssociationType::iterator AsscIter1 = i->second.begin();
AsscIter1 != i->second.end();
++AsscIter1) {
if(AsscIter1->second.second->cscSegmentRef.isNonnull())
if(j->first == AsscIter1->first &&
j->second.first == AsscIter1->second.first &&
isDuplicateOf(segmentIter1->cscSegmentRef,AsscIter1->second.second->cscSegmentRef) &&
(segmentIter1->mask & 0x1e0000) < (AsscIter1->second.second->mask & 0x1e0000))
bestArb = false;
}
if(bestArb) {
for(AssociationType::iterator AsscIter1 = i->second.begin();
AsscIter1 != i->second.end();
++AsscIter1) {
if(AsscIter1->second.second->cscSegmentRef.isNonnull())
if(j->first == AsscIter1->first &&
j->second.first == AsscIter1->second.first &&
isDuplicateOf(segmentIter1->cscSegmentRef,AsscIter1->second.second->cscSegmentRef)) {
AsscIter1->second.second->mask &= ~reco::MuonSegmentMatch::BelongsToTrackByME1aClean;
}
}
}
//UNUSED me1a = true;
} // ME1/a duplicate resolution
} // is ME1/aduplicate?
if(doClustering &&
isClusteredWith(std::make_pair(CSCDetId(chamberIter1->id),segmentIter1->cscSegmentRef),
std::make_pair(CSCDetId(j->second.first->id),j->second.second->cscSegmentRef))) {
if (i->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) >
j->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) ) {
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByClusClean);
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning);
//UNUSED: cluster = true;
} else if (i->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000) <
j->first->numberOfMatches((reco::Muon::ArbitrationType)0x1e0000)) {
j->second.second->setMask(reco::MuonSegmentMatch::BelongsToTrackByClusClean);
j->second.second->setMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning);
//UNUSED: cluster = true;
} else { // muon with more matched stations wins
if((segmentIter1->mask & 0x1e0000) > (j->second.second->mask & 0x1e0000)) { // segment with better match wins
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByClusClean);
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning);
//UNUSED: cluster = true;
} else if ((segmentIter1->mask & 0x1e0000) < (j->second.second->mask & 0x1e0000)){ //
j->second.second->setMask(reco::MuonSegmentMatch::BelongsToTrackByClusClean);
j->second.second->setMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning);
//UNUSED: cluster = true;
} else {
}
} // cluster sharing resolution
} // is clustered with?
} // csc ref nonnull
} // segmentIter1
} // chamberIter1
} // j, associated segments iterator
} // i, map iterator
// final step: make sure everything that's won a cleaning flag has the "BelongsToTrackByCleaning" flag
for( MeshType::iterator i = mesh_.begin(); i != mesh_.end(); ++i ) {
for( std::vector<reco::MuonChamberMatch>::iterator chamberIter1 = i->first->matches().begin();
chamberIter1 != i->first->matches().end();
++chamberIter1 ) {
for(std::vector<reco::MuonSegmentMatch>::iterator segmentIter1 = chamberIter1->segmentMatches.begin();
segmentIter1 != chamberIter1->segmentMatches.end();
++segmentIter1) {
// set cleaning bit if initial no cleaning bit but there are cleaning algorithm bits set.
if( !segmentIter1->isMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning) &&
segmentIter1->isMask(0xe00000) )
segmentIter1->setMask(reco::MuonSegmentMatch::BelongsToTrackByCleaning);
}// segmentIter1
} // chamberIter1
} // i
}
| void MuonMesh::runMesh | ( | std::vector< reco::Muon > * | p | ) | [inline] |
Definition at line 39 of file MuonMesh.h.
References fillMesh(), and pruneMesh().
Referenced by MuonIdProducer::fillArbitrationInfo().
| void MuonMesh::setCSCGeometry | ( | const CSCGeometry * | pg | ) | [inline] |
Definition at line 43 of file MuonMesh.h.
References geometry_.
Referenced by MuonIdProducer::beginRun().
{ geometry_ = pg; }
| bool MuonMesh::withinTwoSigma | ( | const std::pair< CSCDetId, CSCSegmentRef > & | rhs, |
| const std::pair< CSCDetId, CSCSegmentRef > & | lhs | ||
| ) | const [inline, private] |
Definition at line 60 of file MuonMesh.h.
{ return false; }
const double MuonMesh::ClusterDPhi [private] |
Definition at line 75 of file MuonMesh.h.
Referenced by isClusteredWith().
const double MuonMesh::ClusterDTheta [private] |
Definition at line 75 of file MuonMesh.h.
Referenced by isClusteredWith().
const bool MuonMesh::doClustering [private] |
Definition at line 73 of file MuonMesh.h.
Referenced by fillMesh(), and pruneMesh().
const bool MuonMesh::doME1a [private] |
Definition at line 73 of file MuonMesh.h.
Referenced by fillMesh(), and pruneMesh().
const bool MuonMesh::doOverlaps [private] |
Definition at line 73 of file MuonMesh.h.
Referenced by fillMesh(), and pruneMesh().
const CSCGeometry* MuonMesh::geometry_ [private] |
Definition at line 70 of file MuonMesh.h.
Referenced by isClusteredWith(), and setCSCGeometry().
MeshType MuonMesh::mesh_ [private] |
Definition at line 67 of file MuonMesh.h.
Referenced by clearMesh(), fillMesh(), and pruneMesh().
const double MuonMesh::OverlapDPhi [private] |
Definition at line 75 of file MuonMesh.h.
const double MuonMesh::OverlapDTheta [private] |
Definition at line 75 of file MuonMesh.h.
1.7.3