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HFClusterAlgo.cc
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1 #include "HFClusterAlgo.h"
2 #include <sstream>
3 #include <iostream>
4 #include <algorithm>
5 #include <list>
9 
10 using namespace std;
11 using namespace reco;
21 {
22  m_isMC=true; // safest
23 
24 }
25 
27 public:
29  return h1.et>h2.et;
30  }
31 };
32 
34 public:
35  bool operator()(const double c1,const double c2) const {
36  return c1>c2;
37  }
38 };
39 
40 static int indexByEta(HcalDetId id) {
41  return (id.zside()>0)?(id.ietaAbs()-29+13):(41-id.ietaAbs());
42 }
43 static const double MCMaterialCorrections_3XX[] = { 1.000,1.000,1.105,0.970,0.965,0.975,0.956,0.958,0.981,1.005,0.986,1.086,1.000,
44  1.000,1.086,0.986,1.005,0.981,0.958,0.956,0.975,0.965,0.970,1.105,1.000,1.000 };
45 
46 
47 
48 void HFClusterAlgo::setup(double minTowerEnergy, double seedThreshold,double maximumSL,double maximumRenergy,
49  bool usePMTflag,bool usePulseflag, bool forcePulseFlagMC, int correctionSet){
50  m_seedThreshold=seedThreshold;
51  m_minTowerEnergy=minTowerEnergy;
52  m_maximumSL=maximumSL;
53  m_usePMTFlag=usePMTflag;
54  m_usePulseFlag=usePulseflag;
55  m_forcePulseFlagMC=forcePulseFlagMC;
56  m_maximumRenergy=maximumRenergy;
57  m_correctionSet = correctionSet;
58 
59  for(int ii=0;ii<13;ii++){
60  m_cutByEta.push_back(-1);
61  m_seedmnEta.push_back(99);
62  m_seedMXeta.push_back(-1);
63  }
64  for(int ii=0;ii<73;ii++){
65  double minphi=0.0872664*(ii-1);
66  double maxphi=0.0872664*(ii+1);
67  while (minphi < -M_PI)
68  minphi+=2*M_PI;
69  while (minphi > M_PI)
70  minphi-=2*M_PI;
71  while (maxphi < -M_PI)
72  maxphi+=2*M_PI;
73  while (maxphi > M_PI)
74  maxphi-=2*M_PI;
75  if(ii==37)
76  minphi=-3.1415904;
77  m_seedmnPhi.push_back(minphi);
78  m_seedMXphi.push_back(maxphi);
79  }
80 
81  // always set all the corrections to one...
82  for (int ii=0; ii<13*2; ii++)
83  m_correctionByEta.push_back(1.0);
84  if (m_correctionSet==1) { // corrections for material from MC
85  for (int ii=0; ii<13*2; ii++)
86  m_correctionByEta[ii]=MCMaterialCorrections_3XX[ii];
87  }
88 }
89 
92  const CaloGeometry& geom,
93  HFEMClusterShapeCollection& clusterShapes,
94  SuperClusterCollection& SuperClusters) {
95 
96  std::vector<HFCompleteHit> protoseeds, seeds;
98  std::vector<HFCompleteHit>::iterator i;
99  std::vector<HFCompleteHit>::iterator k;
100  int dP, dE, PWrap;
101  bool isok=true;
102  HFEMClusterShape clusShp;
103 
104  SuperCluster Sclus;
105  bool doCluster=false;
106 
107  for (j=hf.begin(); j!= hf.end(); j++) {
108  const int aieta=j->id().ietaAbs();
109  int iz=(aieta-29);
110  // only long fibers and not 29,40,41 allowed to be considered as seeds
111  if (j->id().depth()!=1) continue;
112  if (aieta==40 || aieta==41 || aieta==29) continue;
113 
114 
115  if (iz<0 || iz>12) {
116  edm::LogWarning("HFClusterAlgo") << "Strange invalid HF hit: " << j->id();
117  continue;
118  }
119 
120  if (m_cutByEta[iz]<0) {
121  double eta=geom.getPosition(j->id()).eta();
122  m_cutByEta[iz]=m_seedThreshold*cosh(eta); // convert ET to E for this ring
123  const CaloCellGeometry* ccg=geom.getGeometry(j->id());
124  const CaloCellGeometry::CornersVec& CellCorners=ccg->getCorners();
125  for(size_t sc=0;sc<CellCorners.size();sc++){
126  if(fabs(CellCorners[sc].z())<1200){
127  if(fabs(CellCorners[sc].eta())<m_seedmnEta[iz])m_seedmnEta[iz]=fabs(CellCorners[sc].eta());
128  if(fabs(CellCorners[sc].eta())>m_seedMXeta[iz])m_seedMXeta[iz]=fabs(CellCorners[sc].eta());
129  }
130  }
131  }
132  double elong=j->energy()*m_correctionByEta[indexByEta(j->id())];
133  if (elong>m_cutByEta[iz]) {
134  j2=hf.find(HcalDetId(HcalForward,j->id().ieta(),j->id().iphi(),2));
135  double eshort=(j2==hf.end())?(0):(j2->energy());
136  if (j2!=hf.end())
137  eshort*=m_correctionByEta[indexByEta(j2->id())];
138  if (((elong-eshort)/(elong+eshort))>m_maximumSL) continue;
139  //if ((m_usePMTFlag)&&(j->flagField(4,1))) continue;
140  //if ((m_usePulseFlag)&&(j->flagField(1,1))) continue;
141  if(isPMTHit(*j)) continue;
142 
143  HFCompleteHit ahit;
144  double eta=geom.getPosition(j->id()).eta();
145  ahit.id=j->id();
146  ahit.energy=elong;
147  ahit.et=ahit.energy/cosh(eta);
148  protoseeds.push_back(ahit);
149  }
150  }
151 
152  if(!protoseeds.empty()){
153  std::sort(protoseeds.begin(), protoseeds.end(), CompareHFCompleteHitET());
154  for (i=protoseeds.begin(); i!= protoseeds.end(); i++) {
155  isok=true;
156  doCluster=false;
157 
158  if ( (i==protoseeds.begin()) && (isok) ) {
159  doCluster=true;
160  }else {
161  // check for overlap with existing clusters
162  for (k=seeds.begin(); isok && k!=seeds.end(); k++) { //i->hits, k->seeds
163 
164  for (dE=-2; dE<=2; dE++)
165  for (dP=-4;dP<=4; dP+=2) {
166  PWrap=k->id.iphi()+dP;
167  if (PWrap<0)
168  PWrap+=72;
169  if (PWrap>72)
170  PWrap-=72;
171 
172  if ( (i->id.iphi()==PWrap) && (i->id.ieta()==k->id.ieta()+dE))
173  isok = false;
174  }
175  }
176  if (isok) {
177  doCluster=true;
178  }
179  }
180  if (doCluster) {
181  seeds.push_back(*i);
182 
183  bool clusterOk=makeCluster( i->id(),hf, geom,clusShp,Sclus);
184  if (clusterOk) { // cluster is _not_ ok if seed is rejected due to other cuts
185  clusterShapes.push_back(clusShp);
186  SuperClusters.push_back(Sclus);
187  }
188 
189  }
190  }//end protoseed loop
191  }//end if seeCount
192 }
193 
194 
196  const HFRecHitCollection& hf,
197  const CaloGeometry& geom,
198  HFEMClusterShape& clusShp,
199  SuperCluster& Sclus) {
200 
201 
202  double w=0;//sum over all log E's
203  double wgt=0;
204  double w_e=0;//sum over ieat*energy
205  double w_x=0;
206  double w_y=0;
207  double w_z=0;
208  double wp_e=0;//sum over iphi*energy
209  double e_e=0;//nonwieghted eta sum
210  double e_ep=0; //nonweighted phi sum
211 
212  double l_3=0;//sum for enenergy in 3x3 long fibers etc.
213  double s_3=0;
214  double l_5=0;
215  double s_5=0;
216  double l_1=0;
217  double s_1=0;
218  int de, dp, phiWrap;
219  double l_1e=0;
220  GlobalPoint sp=geom.getPosition(seedid);
221  std::vector<double> coreCanid;
222  std::vector<double>::const_iterator ci;
224  std::vector<DetId> usedHits;
225 
227  HcalDetId sid(HcalForward,seedid.ieta(),seedid.iphi(),1);
228  si=hf.find(sid);
229 
230  bool clusterOk=true; // assume the best to start...
231 
232  // lots happens here
233  // edge type 1 has 40/41 in 3x3 and 5x5
234  bool edge_type1=seedid.ietaAbs()==39 && (seedid.iphi()%4)==3;
235 
236  double e_seed=si->energy()*m_correctionByEta[indexByEta(si->id())];
237 
238  for (de=-2; de<=2; de++)
239  for (dp=-4;dp<=4; dp+=2) {
240  phiWrap=seedid.iphi()+dp;
241  if (phiWrap<0)
242  phiWrap+=72;
243  if (phiWrap>72)
244  phiWrap-=72;
245 
246 
247  /* Handling of phi-width change problems */
248  if (edge_type1 && de==seedid.zside()) {
249  if (dp==-2) { // we want it in the 3x3
250  phiWrap-=2;
251  if (phiWrap<0)
252  phiWrap+=72;
253  }
254  else if (dp==-4) {
255  continue; // but not double counted in 5x5
256  }
257  }
258 
259  HcalDetId idl(HcalForward,seedid.ieta()+de,phiWrap,1);
260  HcalDetId ids(HcalForward,seedid.ieta()+de,phiWrap,2);
261 
262 
263  il=hf.find(idl);
264  is=hf.find(ids);
265 
266 
267 
268 
269  double e_long=1.0;
270  double e_short=0.0;
271  if (il!=hf.end()) e_long=il->energy()*m_correctionByEta[indexByEta(il->id())];
272  if (e_long <= m_minTowerEnergy) e_long=0.0;
273  if (is!=hf.end()) e_short=is->energy()*m_correctionByEta[indexByEta(is->id())];
274  if (e_short <= m_minTowerEnergy) e_short=0.0;
275  double eRatio=(e_long-e_short)/std::max(1.0,(e_long+e_short));
276 
277  // require S/L > a minimum amount for inclusion
278  if ((abs(eRatio) > m_maximumSL)&&(std::max(e_long,e_short) > m_maximumRenergy)) {
279  if (dp==0 && de==0) clusterOk=false; // somehow, the seed is hosed
280  continue;
281  }
282 
283  if((il!=hf.end())&&(isPMTHit(*il))){
284  if (dp==0 && de==0) clusterOk=false; // somehow, the seed is hosed
285  continue;//continue to next hit, do not include this one in cluster
286  }
287 
288 
289 
290 
291 
292  if (e_long > m_minTowerEnergy && il!=hf.end()) {
293 
294  // record usage
295  usedHits.push_back(idl.rawId());
296  // always in the 5x5
297  l_5+=e_long;
298  // maybe in the 3x3
299  if ((de>-2)&&(de<2)&&(dp>-4)&&(dp<4)) {
300  l_3+=e_long;
301 
302  // sometimes in the 1x1
303  if ((dp==0)&&(de==0)) {
304  l_1=e_long;
305  }
306 
307  // maybe in the core?
308  if ((de>-2)&&(de<2)&&(dp>-4)&&(dp<4)&&(e_long>(.5*e_seed))) {
309  coreCanid.push_back(e_long);
310  }
311 
312  // position calculation
313  GlobalPoint p=geom.getPosition(idl);
314 
315  double d_p = p.phi()-sp.phi();
316  while (d_p < -M_PI)
317  d_p+=2*M_PI;
318  while (d_p > M_PI)
319  d_p-=2*M_PI;
320  double d_e = p.eta()-sp.eta();
321 
322  wgt=log((e_long));
323  if (wgt>0){
324  w+=wgt;
325  w_e+=(d_e)*wgt;
326  wp_e+=(d_p)*wgt;
327  e_e+=d_e;
328  e_ep+=d_p;
329 
330  w_x+=(p.x())*wgt;//(p.x()-sp.x())*wgt;
331  w_y+=(p.y())*wgt;
332  w_z+=(p.z())*wgt;
333  }
334  }
335  } else {
336  if (dp==0 && de==0) clusterOk=false; // somehow, the seed is hosed
337  }
338 
339  if (e_short > m_minTowerEnergy && is!=hf.end()) {
340  // record usage
341  usedHits.push_back(ids.rawId());
342  // always in the 5x5
343  s_5+=e_short;
344  // maybe in the 3x3
345  if ((de>-2)&&(de<2)&&(dp>-4)&&(dp<4)) {
346  s_3+=e_short;
347  }
348  // sometimes in the 1x1
349  if ((dp==0)&&(de==0)) {
350  s_1=e_short;
351  }
352  }
353  }
354 
355 
356  if (!clusterOk) return false;
357 
358  //Core sorting done here
359  std::sort(coreCanid.begin(), coreCanid.end(), CompareHFCore());
360  for (ci=coreCanid.begin();ci!=coreCanid.end();ci++){
361  if(ci==coreCanid.begin()){
362  l_1e=*ci;
363  }else if (*ci>.5*l_1e){
364  l_1e+=*ci;
365  }
366  }//core sorting end
367 
368  double z_=w_z/w;
369  double x_=w_x/w;
370  double y_=w_y/w;
371  math::XYZPoint xyzclus(x_,y_,z_);
372  //calcualte position, final
373  double eta=xyzclus.eta();//w_e/w+sp.eta();
374 
375  double phi=xyzclus.phi();//(wp_e/w)+sp.phi();
376 
377  while (phi < -M_PI)
378  phi+=2*M_PI;
379  while (phi > M_PI)
380  phi-=2*M_PI;
381 
382  //calculate cell phi and cell eta
383  int idx= fabs(seedid.ieta())-29;
384  int ipx=seedid.iphi();
385  double Cphi =(phi-m_seedmnPhi[ipx])/(m_seedMXphi[ipx]-m_seedmnPhi[ipx]);
386  double Ceta=(fabs(eta)- m_seedmnEta[idx])/(m_seedMXeta[idx]-m_seedmnEta[idx]);
387 
388  //return HFEMClusterShape, SuperCluster
389  HFEMClusterShape myClusShp(l_1, s_1, l_3, s_3, l_5,s_5, l_1e,Ceta, Cphi,seedid);
390  clusShp = myClusShp;
391 
392  SuperCluster MySclus(l_3,xyzclus);
393  Sclus=MySclus;
394 
395  return clusterOk;
396 
397 }
399 
400  bool pmthit=false;
401 
402  if((hfr.flagField(HcalCaloFlagLabels::HFLongShort))&&(m_usePMTFlag)) pmthit=true;
403  if (!(m_isMC && !m_forcePulseFlagMC))
404  if((hfr.flagField(HcalCaloFlagLabels::HFDigiTime))&&(m_usePulseFlag)) pmthit=true;
405 
406  return pmthit;
407 }
409  edm::LogInfo("HFClusterAlgo")<<"Resetting for Run!";
410  for(int ii=0;ii<13;ii++){
411  m_cutByEta.push_back(-1);
412  m_seedmnEta.push_back(99);
413  m_seedMXeta.push_back(-1);
414  }
415 }
416 
int i
Definition: DBlmapReader.cc:9
void clusterize(const HFRecHitCollection &hf, const CaloGeometry &geom, reco::HFEMClusterShapeCollection &clusters, reco::SuperClusterCollection &SuperClusters)
int zside() const
get the z-side of the cell (1/-1)
Definition: HcalDetId.h:32
Geom::Phi< T > phi() const
Definition: PV3DBase.h:69
std::vector< HFRecHit >::const_iterator const_iterator
T y() const
Definition: PV3DBase.h:63
int zside(DetId const &)
T eta() const
int ii
Definition: cuy.py:588
std::vector< HFEMClusterShape > HFEMClusterShapeCollection
float float float z
static const double MCMaterialCorrections_3XX[]
bool makeCluster(const HcalDetId &seedid, const HFRecHitCollection &hf, const CaloGeometry &geom, reco::HFEMClusterShape &clusShp, reco::SuperCluster &SClus)
bool operator()(const HFClusterAlgo::HFCompleteHit &h1, const HFClusterAlgo::HFCompleteHit &h2) const
const T & max(const T &a, const T &b)
std::vector< SuperCluster > SuperClusterCollection
collection of SuperCluser objectr
T z() const
Definition: PV3DBase.h:64
int ieta() const
get the cell ieta
Definition: HcalDetId.h:36
Abs< T >::type abs(const T &t)
Definition: Abs.h:22
int j
Definition: DBlmapReader.cc:9
const GlobalPoint & getPosition(const DetId &id) const
Get the position of a given detector id.
Definition: CaloGeometry.cc:68
#define M_PI
int k[5][pyjets_maxn]
int ietaAbs() const
get the absolute value of the cell ieta
Definition: HcalDetId.h:34
const_iterator end() const
static int indexByEta(HcalDetId id)
int iphi() const
get the cell iphi
Definition: HcalDetId.h:38
size_type size() const
Definition: EZArrayFL.h:81
bool operator()(const double c1, const double c2) const
auto dp
Definition: deltaR.h:24
XYZPointD XYZPoint
point in space with cartesian internal representation
Definition: Point3D.h:12
tuple idx
DEBUGGING if hasattr(process,&quot;trackMonIterativeTracking2012&quot;): print &quot;trackMonIterativeTracking2012 D...
T eta() const
Definition: PV3DBase.h:76
iterator find(key_type k)
const CaloCellGeometry * getGeometry(const DetId &id) const
Get the cell geometry of a given detector id.
Definition: CaloGeometry.cc:76
T w() const
const CornersVec & getCorners() const
Returns the corner points of this cell&#39;s volume.
T x() const
Definition: PV3DBase.h:62
bool isPMTHit(const HFRecHit &hfr)
void setup(double minTowerEnergy, double seedThreshold, double maximumSL, double m_maximumRenergy, bool usePMTflag, bool usePulseflag, bool forcePulseFlagMC, int correctionSet)
uint32_t flagField(int base, int width=1) const
Definition: CaloRecHit.cc:31
const_iterator begin() const
Definition: DDAxes.h:10