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OMTFinputMaker Class Reference

#include <OMTFinputMaker.h>

Public Member Functions

OMTFinput buildInputForProcessor (const L1MuDTChambPhContainer *dtPhDigis, const L1MuDTChambThContainer *dtThDigis, const CSCCorrelatedLCTDigiCollection *cscDigis, const RPCDigiCollection *rpcDigis, unsigned int iProcessor, l1t::tftype type=l1t::tftype::omtf_pos)
 Method translating trigger digis into input matrix with global phi coordinates. More...
 
int getFlag () const
 
void initialize (const edm::EventSetup &es, const OMTFConfiguration *)
 
 OMTFinputMaker ()
 
void setFlag (int aFlag)
 
 ~OMTFinputMaker ()
 

Private Member Functions

bool acceptDigi (uint32_t rawId, unsigned int iProcessor, l1t::tftype type)
 
unsigned int getInputNumber (unsigned int rawId, unsigned int iProcessor, l1t::tftype type)
 
OMTFinput processCSC (const CSCCorrelatedLCTDigiCollection *cscDigis, unsigned int iProcessor, l1t::tftype type)
 
OMTFinput processDT (const L1MuDTChambPhContainer *dtPhDigis, const L1MuDTChambThContainer *dtThDigis, unsigned int iProcessor, l1t::tftype type)
 
OMTFinput processRPC (const RPCDigiCollection *rpcDigis, unsigned int iProcessor, l1t::tftype type)
 

Private Attributes

int flag
 
AngleConverter myAngleConverter
 
const OMTFConfigurationmyOmtfConfig
 

Detailed Description

Definition at line 22 of file OMTFinputMaker.h.

Constructor & Destructor Documentation

OMTFinputMaker::OMTFinputMaker ( )

Definition at line 21 of file OMTFinputMaker.cc.

21 {}
OMTFinputMaker::~OMTFinputMaker ( )

Definition at line 33 of file OMTFinputMaker.cc.

33 { }

Member Function Documentation

bool OMTFinputMaker::acceptDigi ( uint32_t  rawId,
unsigned int  iProcessor,
l1t::tftype  type 
)
private

Check if digis are within a give processor input. Simply checks sectors range.

Clean up digis. Remove unconnected detectors

Select RPC chambers connected to OMTF

RPC RE1/2 temporarily not used (aId.region()==1 && aId.station()==1 && aId.ring()<2) ||

Definition at line 36 of file OMTFinputMaker.cc.

References l1t::bmtf, CSCDetId::chamber(), MuonSubdetId::CSC, DetId::det(), MuonSubdetId::DT, dt, l1t::emtf_neg, l1t::emtf_pos, CSCDetId::endcap(), OMTFConfiguration::getBarrelMax(), OMTFConfiguration::getBarrelMin(), OMTFConfiguration::getEndcap10DegMax(), OMTFConfiguration::getEndcap10DegMin(), OMTFConfiguration::getEndcap20DegMax(), OMTFConfiguration::getEndcap20DegMin(), RPCDetId::layer(), DetId::Muon, myOmtfConfig, l1t::omtf_neg, l1t::omtf_pos, RPCDetId::region(), RPCDetId::ring(), CSCDetId::ring(), RPCDetId::roll(), MuonSubdetId::RPC, DTChamberId::sector(), RPCDetId::sector(), CSCDetId::station(), RPCDetId::station(), DetId::subdetId(), RPCDetId::subsector(), and DTChamberId::wheel().

Referenced by processCSC(), processDT(), and processRPC().

38  {
39 
40  unsigned int aMin = myOmtfConfig->getBarrelMin()[iProcessor];
41  unsigned int aMax = myOmtfConfig->getBarrelMax()[iProcessor];
42  unsigned int aSector = 99;
43 
45  DetId detId(rawId);
46  if (detId.det() != DetId::Muon)
47  edm::LogError("Critical OMTFinputMaker") << "PROBLEM: hit in unknown Det, detID: "<<detId.det()<<std::endl;
48  switch (detId.subdetId()) {
49  case MuonSubdetId::RPC: {
50  RPCDetId aId(rawId);
51 
54  (aId.region()<0 ||
55  (aId.region()==0 && aId.ring()!=2) ||
56  (aId.region()==0 && aId.station()==4) ||
57  (aId.region()==0 && aId.station()==2 && aId.layer()==2 && aId.roll()==1) ||
58  (aId.region()==0 && aId.station()==3 && aId.roll()==1) ||
59  (aId.region()==1 && aId.station()==4) ||
61  (aId.region()==1 && aId.station()>0 && aId.ring()<3))
62  ) return false;
63 
65  (aId.region()>0 ||
66  (aId.region()==0 && aId.ring()!=-2) ||
67  (aId.region()==0 && aId.station()==4) ||
68  (aId.region()==0 && aId.station()==2 && aId.layer()==2 && aId.roll()==1) ||
69  (aId.region()==0 && aId.station()==3 && aId.roll()==1) ||
70  (aId.region()==-1 && aId.station()==4) ||
71  //RPC RE1/2 temporarily not used (aId.region()==1 && aId.station()==1 && aId.ring()<2) ||
72  (aId.region()==-1 && aId.station()>0 && aId.ring()<3))
73  ) return false;
74 
75  if(type==l1t::tftype::bmtf && aId.region()!=0) return false;
76 
78  (aId.region()<=0 ||
79  (aId.station()==1 && aId.ring()==3))) return false;
81  (aId.region()>=0 ||
82  (aId.station()==1 && aId.ring()==3))) return false;
84  if(aId.region()==0) aSector = aId.sector();
85  if(aId.region()!=0){
86  aSector = (aId.sector()-1)*6+aId.subsector();
87  aMin = myOmtfConfig->getEndcap10DegMin()[iProcessor];
88  aMax = myOmtfConfig->getEndcap10DegMax()[iProcessor];
89  }
90 
91  break;
92  }
93  case MuonSubdetId::DT: {
94  DTChamberId dt(rawId);
95 
96  if(type==l1t::tftype::omtf_pos && dt.wheel()!=2) return false;
97  if(type==l1t::tftype::omtf_neg && dt.wheel()!=-2) return false;
99 
100  aSector = dt.sector();
101  break;
102  }
103  case MuonSubdetId::CSC: {
104 
105  CSCDetId csc(rawId);
107  (csc.endcap()==2 || csc.ring()==1 || csc.station()==4)) return false;
109  (csc.endcap()==1 || csc.ring()==1 || csc.station()==4)) return false;
110 
112  (csc.endcap()==2 || (csc.station()==1 && csc.ring()==3))
113  ) return false;
115  (csc.endcap()==1 || (csc.station()==1 && csc.ring()==3))
116  ) return false;
117 
118  aSector = csc.chamber();
119  aMin = myOmtfConfig->getEndcap10DegMin()[iProcessor];
120  aMax = myOmtfConfig->getEndcap10DegMax()[iProcessor];
121 
123  csc.station()>1 && csc.ring()==1){
124  aMin = myOmtfConfig->getEndcap20DegMin()[iProcessor];
125  aMax = myOmtfConfig->getEndcap20DegMax()[iProcessor];
126  }
127  break;
128  }
129  }
130 
131  if(aMax>aMin && aSector>=aMin && aSector<=aMax) return true;
132  if(aMax<aMin && (aSector>=aMin || aSector<=aMax)) return true;
133 
134  return false;
135 }
type
Definition: HCALResponse.h:21
float dt
Definition: AMPTWrapper.h:126
const std::vector< unsigned int > & getBarrelMax() const
const std::vector< unsigned int > & getEndcap10DegMin() const
const OMTFConfiguration * myOmtfConfig
static const int CSC
Definition: MuonSubdetId.h:13
const std::vector< unsigned int > & getEndcap20DegMax() const
const std::vector< unsigned int > & getEndcap10DegMax() const
Definition: DetId.h:18
const std::vector< unsigned int > & getBarrelMin() const
static const int RPC
Definition: MuonSubdetId.h:14
const std::vector< unsigned int > & getEndcap20DegMin() const
static const int DT
Definition: MuonSubdetId.h:12
OMTFinput OMTFinputMaker::buildInputForProcessor ( const L1MuDTChambPhContainer dtPhDigis,
const L1MuDTChambThContainer dtThDigis,
const CSCCorrelatedLCTDigiCollection cscDigis,
const RPCDigiCollection rpcDigis,
unsigned int  iProcessor,
l1t::tftype  type = l1t::tftype::omtf_pos 
)

Method translating trigger digis into input matrix with global phi coordinates.

Definition at line 372 of file OMTFinputMaker.cc.

References myOmtfConfig, processCSC(), processDT(), processRPC(), and mps_fire::result.

Referenced by OMTFPatternMaker::analyze(), and OMTFReconstruction::getProcessorCandidates().

377  {
379  result += processDT(dtPhDigis, dtThDigis, iProcessor, type);
380  result += processCSC(cscDigis, iProcessor, type);
381  result += processRPC(rpcDigis, iProcessor, type);
382  return result;
383 }
type
Definition: HCALResponse.h:21
OMTFinput processCSC(const CSCCorrelatedLCTDigiCollection *cscDigis, unsigned int iProcessor, l1t::tftype type)
OMTFinput processRPC(const RPCDigiCollection *rpcDigis, unsigned int iProcessor, l1t::tftype type)
const OMTFConfiguration * myOmtfConfig
tuple result
Definition: mps_fire.py:84
OMTFinput processDT(const L1MuDTChambPhContainer *dtPhDigis, const L1MuDTChambThContainer *dtThDigis, unsigned int iProcessor, l1t::tftype type)
int OMTFinputMaker::getFlag ( ) const
inline

Definition at line 42 of file OMTFinputMaker.h.

References flag.

Referenced by OMTFReconstruction::getProcessorCandidates().

42 { return flag;}
unsigned int OMTFinputMaker::getInputNumber ( unsigned int  rawId,
unsigned int  iProcessor,
l1t::tftype  type 
)
private

Give input number for givedn processor, using the chamber sector number. Result is modulo allowed number of hits per chamber

on the 0-2pi border we need to add 1 30 deg sector to get the correct index

Set roll number by hand to keep common input number shift formula for all stations

Only one roll from station 3 is connected.

At the moment do not use RPC chambers splitting into rolls for bmtf part

on the 0-2pi border we need to add 4 10 deg sectors to get the correct index

on the 0-2pi border we need to add 1 30 deg sector to get the correct index

on the 0-2pi border we need to add 4 10deg sectors to get the correct index

Endcap region covers algo 10 deg sectors on the 0-2pi border we need to add 2 20deg sectors to get the correct index

Assume 2 hits per chamber

Chambers divided into two rolls have rolls number 1 and 3

Definition at line 138 of file OMTFinputMaker.cc.

References l1t::bmtf, CSCDetId::chamber(), MuonSubdetId::CSC, DetId::det(), MuonSubdetId::DT, dt, l1t::emtf_neg, l1t::emtf_pos, OMTFConfiguration::getBarrelMin(), OMTFConfiguration::getEndcap10DegMin(), OMTFConfiguration::getEndcap20DegMin(), RPCDetId::layer(), DetId::Muon, myOmtfConfig, RPCDetId::region(), CSCDetId::ring(), RPCDetId::roll(), MuonSubdetId::RPC, DTChamberId::sector(), RPCDetId::sector(), CSCDetId::station(), RPCDetId::station(), DetId::subdetId(), and RPCDetId::subsector().

Referenced by processCSC(), processDT(), and processRPC().

140  {
141 
142  unsigned int iInput = 99;
143  unsigned int aSector = 99;
144  int aMin = myOmtfConfig->getBarrelMin()[iProcessor];
145  int iRoll = 1;
146  int nInputsPerSector = 2;
147 
148  DetId detId(rawId);
149  if (detId.det() != DetId::Muon) edm::LogError("Critical OMTFinputMaker") << "PROBLEM: hit in unknown Det, detID: "<<detId.det()<<std::endl;
150  switch (detId.subdetId()) {
151  case MuonSubdetId::RPC: {
152  RPCDetId rpc(rawId);
153  if(rpc.region()==0){
154  nInputsPerSector = 4;
155  aSector = rpc.sector();
158  if(iProcessor==5 && aSector<3) aMin = -1;
159  //Use division into rolls
160  iRoll = rpc.roll();
163  if(rpc.station()==2 && rpc.layer()==2 && rpc.roll()==2) iRoll = 1;
165  if(rpc.station()==3){
166  iRoll = 1;
167  nInputsPerSector = 2;
168  }
170  if(type==l1t::tftype::bmtf)iRoll = 1;
171  }
172  if(rpc.region()!=0){
173  aSector = (rpc.sector()-1)*6+rpc.subsector();
174  aMin = myOmtfConfig->getEndcap10DegMin()[iProcessor];
177  if(iProcessor==5 && aSector<5) aMin = -4;
178  }
179  break;
180  }
181  case MuonSubdetId::DT: {
182  DTChamberId dt(rawId);
183  aSector = dt.sector();
186  if(iProcessor==5 && aSector<3) aMin = -1;
187  break;
188  }
189  case MuonSubdetId::CSC: {
190  CSCDetId csc(rawId);
191  aSector = csc.chamber();
192  aMin = myOmtfConfig->getEndcap10DegMin()[iProcessor];
195  if(iProcessor==5 && aSector<5) aMin = -4;
200  csc.station()>1 && csc.ring()==1){
201  aMin = myOmtfConfig->getEndcap20DegMin()[iProcessor];
202  if(iProcessor==5 && aSector<3) aMin = -2;
203  }
204  break;
205  }
206  }
207 
209  iInput = (aSector - aMin)*nInputsPerSector;
211  iInput+=iRoll-1;
212 
213  return iInput;
214 }
type
Definition: HCALResponse.h:21
float dt
Definition: AMPTWrapper.h:126
const std::vector< unsigned int > & getEndcap10DegMin() const
const OMTFConfiguration * myOmtfConfig
static const int CSC
Definition: MuonSubdetId.h:13
Definition: DetId.h:18
const std::vector< unsigned int > & getBarrelMin() const
static const int RPC
Definition: MuonSubdetId.h:14
const std::vector< unsigned int > & getEndcap20DegMin() const
static const int DT
Definition: MuonSubdetId.h:12
void OMTFinputMaker::initialize ( const edm::EventSetup es,
const OMTFConfiguration omtfConfig 
)

Definition at line 24 of file OMTFinputMaker.cc.

References AngleConverter::checkAndUpdateGeometry(), myAngleConverter, myOmtfConfig, and OMTFConfiguration::nPhiBins().

Referenced by OMTFPatternMaker::analyze(), and OMTFReconstruction::beginRun().

24  {
25 
27 
28  myOmtfConfig = omtfConfig;
29 
30 }
unsigned int nPhiBins() const
const OMTFConfiguration * myOmtfConfig
AngleConverter myAngleConverter
void checkAndUpdateGeometry(const edm::EventSetup &, unsigned int)
Update the Geometry with current Event Setup.
OMTFinput OMTFinputMaker::processCSC ( const CSCCorrelatedLCTDigiCollection cscDigis,
unsigned int  iProcessor,
l1t::tftype  type 
)
private

Take the CSC digis, select chambers connected to given processor, convers logal angles to global scale. For CSC do NOT take the bending angle.

Check it the data fits into given processor input range

Check Trigger primitive quality. CSC central BX is 6 for some reason.

Accept CSC digis only up to eta=1.26. The nominal OMTF range is up to 1.24, but cutting at 1.24 kill efficnency at the edge. 1.26 is one eta bin above nominal.

Definition at line 259 of file OMTFinputMaker.cc.

References funct::abs(), acceptDigi(), OMTFinput::addLayerHit(), CSCDetId, AngleConverter::getGlobalEta(), OMTFConfiguration::getHwToLogicLayer(), getInputNumber(), OMTFConfiguration::getLayerNumber(), AngleConverter::getProcessorPhi(), myAngleConverter, myOmtfConfig, and mps_fire::result.

Referenced by buildInputForProcessor().

261  {
262 
264  if(!cscDigis) return result;
265 
266  auto chamber = cscDigis->begin();
267  auto chend = cscDigis->end();
268  for( ; chamber != chend; ++chamber ) {
269 
270  unsigned int rawid = (*chamber).first;
272  if(!acceptDigi(rawid, iProcessor, type)) continue;
273  auto digi = (*chamber).second.first;
274  auto dend = (*chamber).second.second;
275  for( ; digi != dend; ++digi ) {
276 
279  if (abs(digi->getBX()- 6)>0) continue;
280 
281  unsigned int hwNumber = myOmtfConfig->getLayerNumber(rawid);
282  if(myOmtfConfig->getHwToLogicLayer().find(hwNumber)==myOmtfConfig->getHwToLogicLayer().end()) continue;
283 
284  unsigned int iLayer = myOmtfConfig->getHwToLogicLayer().at(hwNumber);
285  int iPhi = myAngleConverter.getProcessorPhi(iProcessor, type, CSCDetId(rawid), *digi);
286  int iEta = myAngleConverter.getGlobalEta(rawid, *digi);
290  //if(abs(iEta)>1.26/2.61*240) continue;
291  //if (abs(iEta) > 115) continue;
292  unsigned int iInput= getInputNumber(rawid, iProcessor, type);
293 // std::cout <<" ADDING CSC hit, proc: "<<iProcessor<<" iPhi : " << iPhi <<" iEta: "<< iEta << std::endl;
294  result.addLayerHit(iLayer,iInput,iPhi,iEta);
295  }
296  }
297  return result;
298 }
type
Definition: HCALResponse.h:21
const std::map< int, int > & getHwToLogicLayer() const
int getGlobalEta(unsigned int rawid, const L1MuDTChambPhDigi &aDigi, const L1MuDTChambThContainer *dtThDigis)
Convert local eta coordinate to global digital microGMT scale.
const OMTFConfiguration * myOmtfConfig
tuple result
Definition: mps_fire.py:84
int getProcessorPhi(unsigned int iProcessor, l1t::tftype part, const L1MuDTChambPhDigi &digi) const
AngleConverter myAngleConverter
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
bool acceptDigi(uint32_t rawId, unsigned int iProcessor, l1t::tftype type)
uint32_t getLayerNumber(uint32_t rawId) const
unsigned int getInputNumber(unsigned int rawId, unsigned int iProcessor, l1t::tftype type)
OMTFinput OMTFinputMaker::processDT ( const L1MuDTChambPhContainer dtPhDigis,
const L1MuDTChambThContainer dtThDigis,
unsigned int  iProcessor,
l1t::tftype  type 
)
private

Take the DT digis, select chambers connected to given processor, convers logal angles to global scale. For DT take also the bending angle.

Check it the data fits into given processor input range

Check Trigger primitive quality Ts2Tag() == 0 - take only first track from DT Trigger Server BxCnt() == 0 - ?? code()>=3 - take only double layer hits, HH, HL and LL

Definition at line 217 of file OMTFinputMaker.cc.

References acceptDigi(), OMTFinput::addLayerHit(), L1MuDTChambPhContainer::getContainer(), AngleConverter::getGlobalEta(), OMTFConfiguration::getHwToLogicLayer(), getInputNumber(), OMTFConfiguration::getLayerNumber(), AngleConverter::getProcessorPhi(), myAngleConverter, myOmtfConfig, and mps_fire::result.

Referenced by buildInputForProcessor().

221 {
222 
224  if(!dtPhDigis) return result;
225 
226  for (const auto digiIt: *dtPhDigis->getContainer()) {
227 
228  DTChamberId detid(digiIt.whNum(),digiIt.stNum(),digiIt.scNum()+1);
229 
231  if(!acceptDigi(detid.rawId(), iProcessor, type)) continue;
232 
237  // FIXME (MK): at least Ts2Tag selection is not correct! Check it
238 // if (digiIt.bxNum()!= 0 || digiIt.BxCnt()!= 0 || digiIt.Ts2Tag()!= 0 || digiIt.code()<4) continue;
239  if (digiIt.bxNum()!= 0) continue;
240  if (digiIt.code() != 4 && digiIt.code() != 5 && digiIt.code() != 6) continue;
241 
242  unsigned int hwNumber = myOmtfConfig->getLayerNumber(detid.rawId());
243  if(myOmtfConfig->getHwToLogicLayer().find(hwNumber)==myOmtfConfig->getHwToLogicLayer().end()) continue;
244 
245  auto iter = myOmtfConfig->getHwToLogicLayer().find(hwNumber);
246  unsigned int iLayer = iter->second;
247  int iPhi = myAngleConverter.getProcessorPhi(iProcessor, type, digiIt);
248  int iEta = myAngleConverter.getGlobalEta(detid.rawId(), digiIt, dtThDigis);
249  unsigned int iInput= getInputNumber(detid.rawId(), iProcessor, type);
250  result.addLayerHit(iLayer,iInput,iPhi,iEta);
251  result.addLayerHit(iLayer+1,iInput,digiIt.phiB(),iEta);
252  }
253 
254  return result;
255 
256 }
type
Definition: HCALResponse.h:21
const std::map< int, int > & getHwToLogicLayer() const
int getGlobalEta(unsigned int rawid, const L1MuDTChambPhDigi &aDigi, const L1MuDTChambThContainer *dtThDigis)
Convert local eta coordinate to global digital microGMT scale.
const OMTFConfiguration * myOmtfConfig
tuple result
Definition: mps_fire.py:84
int getProcessorPhi(unsigned int iProcessor, l1t::tftype part, const L1MuDTChambPhDigi &digi) const
AngleConverter myAngleConverter
bool acceptDigi(uint32_t rawId, unsigned int iProcessor, l1t::tftype type)
uint32_t getLayerNumber(uint32_t rawId) const
unsigned int getInputNumber(unsigned int rawId, unsigned int iProcessor, l1t::tftype type)
Phi_Container const * getContainer() const
OMTFinput OMTFinputMaker::processRPC ( const RPCDigiCollection rpcDigis,
unsigned int  iProcessor,
l1t::tftype  type 
)
private

Decluster nearby hits in single chamber, by taking average cluster position, expressed in half RPC strip: pos = (cluster_begin + cluster_end)

Find clusters of consecutive fired strips. Have to copy the digis in chamber to sort them (not optimal). NOTE: when copying I select only digis with bx==0 //FIXME: find a better place/way to filtering digi against quality/BX etc.

Definition at line 304 of file OMTFinputMaker.cc.

References funct::abs(), acceptDigi(), OMTFinput::addLayerHit(), RPCDigi::bx(), HLT_25ns10e33_v2_cff::clusters, AngleConverter::getGlobalEta(), OMTFConfiguration::getHwToLogicLayer(), getInputNumber(), OMTFConfiguration::getLayerNumber(), AngleConverter::getProcessorPhi(), myAngleConverter, myOmtfConfig, DetId::rawId(), mps_fire::result, reco::return(), and rpcPrimitiveCmp().

Referenced by buildInputForProcessor().

306  {
307 
309  if(!rpcDigis) return result;
310  std::stringstream str;
311 
312 // std::cout <<" RPC HITS, processor : " << iProcessor << std::endl;
313 
314  const RPCDigiCollection & rpcDigiCollection = *rpcDigis;
315  for (auto rollDigis : rpcDigiCollection) {
316  RPCDetId roll = rollDigis.first;
317  unsigned int rawid = roll.rawId();
318  int nClusters = 0;
319  if(!acceptDigi(rawid, iProcessor, type)) continue;
323 // for (auto tdigi = rollDigis.second.first; tdigi != rollDigis.second.second; tdigi++) { std::cout << "RPC DIGIS: " << roll.rawId()<< " "<<roll<<" digi: " << tdigi->strip() <<" bx: " << tdigi->bx() << std::endl; }
324  std::vector<RPCDigi> digisCopy;
325  std::copy_if(rollDigis.second.first, rollDigis.second.second, std::back_inserter(digisCopy), [](const RPCDigi & aDigi){return (aDigi.bx()==0);});
326  std::sort(digisCopy.begin(),digisCopy.end(),rpcPrimitiveCmp);
327  typedef std::pair<unsigned int, unsigned int> Cluster;
328  std::vector<Cluster> clusters;
329  for(auto & digi: digisCopy) {
330  if(clusters.empty()) clusters.push_back(Cluster(digi.strip(),digi.strip()));
331  else if (digi.strip() - clusters.back().second == 1) clusters.back().second = digi.strip();
332  else if (digi.strip() - clusters.back().second > 1) clusters.push_back(Cluster(digi.strip(),digi.strip()));
333  }
334 
335  for (auto & cluster: clusters) {
336 // int iPhiHalfStrip1 = myAngleConverter.getProcessorPhi(iProcessor, type, roll, cluster.first);
337 // int iPhiHalfStrip2 = myAngleConverter.getProcessorPhi(iProcessor, type, roll, cluster.second);
338  int iPhi = myAngleConverter.getProcessorPhi(iProcessor, type, roll, cluster.first, cluster.second);
339  int cSize = abs(int(cluster.first)-int(cluster.second))+1;
340 // std::cout << " HStrip_1: " << iPhiHalfStrip1 <<" HStrip_2: "<<iPhiHalfStrip2<<" iPhi: " << iPhi << " cluster: ["<< cluster.first << ", "<< cluster.second <<"]"<< std::endl;
341  if (cSize>3) continue;
342  int iEta = myAngleConverter.getGlobalEta(rawid, cluster.first);
343  unsigned int hwNumber = myOmtfConfig->getLayerNumber(rawid);
344  unsigned int iLayer = myOmtfConfig->getHwToLogicLayer().at(hwNumber);
345  unsigned int iInput= getInputNumber(rawid, iProcessor, type);
346 // std::cout <<"ADDING HIT: iLayer = " << iLayer << " iInput: " << iInput << " iPhi: " << iPhi << std::endl;
347  if (iLayer==17 && (iInput==0 || iInput==1)) continue; // FIXME (MK) there is no RPC link for that input, because it is taken by DAQ link
348  bool outres =
349  result.addLayerHit(iLayer,iInput,iPhi,iEta);
350 // if (cSize>2) flag |= 2;
351 // if (!outres) flag |= 1;
352  nClusters++;
353 
354  str <<" RPC halfDigi "
355  <<" begin: "<<cluster.first<<" end: "<<cluster.second
356  <<" iPhi: "<<iPhi
357  <<" iEta: "<<iEta
358  <<" hwNumber: "<<hwNumber
359  <<" iInput: "<<iInput
360  <<" iLayer: "<<iLayer
361  <<" out: " << outres
362  <<std::endl;
363  }
364 // if (nClusters > 2) flag=1;
365  }
366 
367  edm::LogInfo("OMTFInputMaker")<<str.str();
368  return result;
369 }
type
Definition: HCALResponse.h:21
const std::map< int, int > & getHwToLogicLayer() const
int bx() const
Definition: RPCDigi.cc:47
int getGlobalEta(unsigned int rawid, const L1MuDTChambPhDigi &aDigi, const L1MuDTChambThContainer *dtThDigis)
Convert local eta coordinate to global digital microGMT scale.
const OMTFConfiguration * myOmtfConfig
tuple result
Definition: mps_fire.py:84
uint32_t rawId() const
get the raw id
Definition: DetId.h:43
int getProcessorPhi(unsigned int iProcessor, l1t::tftype part, const L1MuDTChambPhDigi &digi) const
AngleConverter myAngleConverter
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
bool acceptDigi(uint32_t rawId, unsigned int iProcessor, l1t::tftype type)
uint32_t getLayerNumber(uint32_t rawId) const
unsigned int getInputNumber(unsigned int rawId, unsigned int iProcessor, l1t::tftype type)
return(e1-e2)*(e1-e2)+dp *dp
bool rpcPrimitiveCmp(const RPCDigi &a, const RPCDigi &b)
void OMTFinputMaker::setFlag ( int  aFlag)
inline

Definition at line 41 of file OMTFinputMaker.h.

References flag.

Referenced by OMTFReconstruction::getProcessorCandidates().

41 {flag = aFlag; }

Member Data Documentation

int OMTFinputMaker::flag
private

Definition at line 85 of file OMTFinputMaker.h.

Referenced by getFlag(), and setFlag().

AngleConverter OMTFinputMaker::myAngleConverter
private

Definition at line 81 of file OMTFinputMaker.h.

Referenced by initialize(), processCSC(), processDT(), and processRPC().

const OMTFConfiguration* OMTFinputMaker::myOmtfConfig
private