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FWECALDetailViewBuilder.cc
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1 // FIXME - needed to set fixed eta-phi limits. Without the
2 // visible area may change widely depending on energy
3 // deposition availability
4 
5 #include "TEveCaloData.h"
6 #include "TEveViewer.h"
7 #include "TEvePointSet.h"
8 #include "TEveCalo.h"
9 #include "TEveCompound.h"
10 #include "TAxis.h"
11 #include "TMath.h"
12 #include "THLimitsFinder.h"
13 #include "TLatex.h"
14 
22 
23 
27 
28 #include "TGeoMatrix.h"
29 #include "TEveTrans.h"
30 
31 #include <utility>
32 
33 
35  float eta, float phi, int size , Color_t defaultColor)
36 
37 : m_event(event), m_geom(geom),
38  m_eta(eta), m_phi(phi), m_size(size),
39  m_defaultColor(defaultColor), m_towerList(0)
40 {
41 }
42 
43 
45 {
46  // get the hits from the event
47 
48  // data
49  TEveCaloDataVec* data = new TEveCaloDataVec( 1);
50  data->SetWrapTwoPi(false);
51  data->RefSliceInfo(0).Setup("hits (not clustered)", 0.0, m_defaultColor );
52 
53  fillData(data);
54 
55  // axis
56  float etaMin = m_eta - sizeRad();
57  float etaMax = m_eta + sizeRad();
58  float phiMin = m_phi - sizeRad();
59  float phiMax = m_phi + sizeRad();
60 
61  data->AddTower(m_eta - sizeRad(), m_eta + sizeRad(), m_phi - sizeRad(), m_phi + sizeRad());
62 
63  data->FillSlice(0, 0.1);
64 
65 
66 
67  TAxis* eta_axis = 0;
68  TAxis* phi_axis = 0;
69 
70  // printf("data rng %f %f %f %f\n",etaMin, etaMax, phiMin, phiMax );
71  std::vector<double> etaBinsWithinLimits;
72  etaBinsWithinLimits.push_back(etaMin);
73  for (unsigned int i=0; i<83; ++i)
74  if ( fw3dlego::xbins[i] > etaMin && fw3dlego::xbins[i] < etaMax )
75  etaBinsWithinLimits.push_back(fw3dlego::xbins[i]);
76  etaBinsWithinLimits.push_back(etaMax);
77 
78  std::vector<double> phiBinsWithinLimits;
79  phiBinsWithinLimits.push_back(phiMin);
80  for ( double phi = -M_PI; phi < M_PI; phi += M_PI/36 )
81  if ( phi > phiMin && phi < phiMax )
82  phiBinsWithinLimits.push_back(phi);
83  phiBinsWithinLimits.push_back(phiMax);
84 
85  eta_axis = new TAxis((int)etaBinsWithinLimits.size() -1, &etaBinsWithinLimits[0]);
86  phi_axis = new TAxis((int)phiBinsWithinLimits.size() -1, &phiBinsWithinLimits[0]);
87 
88  eta_axis->SetTitleFont(122);
89  eta_axis->SetTitle("h");
90  eta_axis->SetTitleSize(0.07);
91  phi_axis->SetTitleFont(122);
92  phi_axis->SetTitle("f");
93  phi_axis->SetTitleSize(0.07);
94 
95  eta_axis->SetNdivisions(510);
96  phi_axis->SetNdivisions(510);
97  data->SetEtaBins(eta_axis);
98  data->SetPhiBins(phi_axis);
99  return data;
100 }
101 
102 //_______________________________________________________________
104 {
105 
106  // axis
107  float etaMin = m_eta - sizeRad();
108  float etaMax = m_eta + sizeRad();
109  float phiMin = m_phi - sizeRad();
110  float phiMax = m_phi + sizeRad();
111 
112  m_towerList = new TEveElementList("TowerHolder");
113  TEveCaloData* data = buildCaloData(true);
114 
115  // lego
116  TEveCaloLego *lego = new TEveCaloLego();
117  lego->SetData(data);
118  lego->AddElement(m_towerList);
119  lego->SetAutoRange(false);
120  lego->SetDrawNumberCellPixels(100);
121  // scale and translate to real world coordinates
122  lego->SetEta(etaMin, etaMax);
123  lego->SetPhiWithRng((phiMin+phiMax)*0.5, (phiMax-phiMin)*0.5); // phi range = 2* phiOffset
124  Double_t legoScale = sizeRad() *2;
125  lego->InitMainTrans();
126  lego->RefMainTrans().SetScale(legoScale, legoScale, legoScale*0.5);
127  lego->RefMainTrans().SetPos(m_eta, m_phi, -0.01);
128  lego->SetAutoRebin(kFALSE);
129  lego->SetName("ECALDetail Lego");
130 
131  // cut & paste from FWLegoViewBase
132  lego->SetScaleAbs(true);
133  lego->SetHasFixedHeightIn2DMode(true);
134  lego->SetFixedHeightValIn2DMode(0.001);
135 
136 
137  TEvePointSet* ps = new TEvePointSet("origin");
138  ps->SetNextPoint(m_eta, m_phi, 0.01);
139  ps->SetMarkerSize(0.05);
140  ps->SetMarkerStyle(2);
141  ps->SetMainColor(kGreen);
142  ps->SetMarkerColor(kGreen);
143  lego->AddElement(ps);
144 
145  return lego;
146 
147 }
148 
149 void FWECALDetailViewBuilder::setColor(Color_t color, const std::vector<DetId> &detIds)
150 {
151  for (size_t i = 0; i < detIds.size(); ++i)
152  m_detIdsToColor[detIds[i]] = color;
153 }
154 
155 void
157 {
158  std::vector<DetId> clusterDetIds;
159  const std::vector<std::pair<DetId, float> > &hitsAndFractions = cluster.hitsAndFractions();
160  for (size_t j = 0; j < hitsAndFractions.size(); ++j)
161  {
162  clusterDetIds.push_back(hitsAndFractions[j].first);
163  }
164 
165  setColor( color, clusterDetIds );
166 }
167 
168 void
169 FWECALDetailViewBuilder::showSuperClusters( Color_t color1, Color_t color2 )
170 {
171  // get the superclusters from the event
173 
174  if( fabs( m_eta ) < 1.5 ) {
175  try {
176  m_event->getByLabel(edm::InputTag("correctedHybridSuperClusters"), collection);
177  }
178  catch (...)
179  {
180  fwLog(fwlog::kWarning) <<"no barrel superclusters are available" << std::endl;
181  }
182  } else {
183  try {
184  m_event->getByLabel(edm::InputTag("correctedMulti5x5SuperClustersWithPreshower"), collection);
185  }
186  catch (...)
187  {
188  fwLog(fwlog::kWarning) <<"no endcap superclusters are available" << std::endl;
189  }
190  }
191  if( collection.isValid() )
192  {
193  unsigned int colorIndex = 0;
194  // sort clusters in eta so neighboring clusters have distinct colors
195  reco::SuperClusterCollection sorted = *collection.product();
196  std::sort( sorted.begin(), sorted.end(), superClusterEtaLess );
197  for( size_t i = 0; i < sorted.size(); ++i )
198  {
199  if( !(fabs(sorted[i].eta() - m_eta) < sizeRad()
200  && fabs(sorted[i].phi() - m_phi) < sizeRad()) )
201  continue;
202 
203  if( colorIndex %2 == 0 )
204  showSuperCluster( sorted[i], color1 );
205  else
206  showSuperCluster( sorted[i], color2 );
207  ++colorIndex;
208  }
209  }
210 }
211 
212 
213 namespace {
214 float
215 calculateEt( const TEveVector &centre, float e )
216 {
217  TEveVector vec = centre;
218  float et;
219 
220  vec.Normalize();
221  vec *= e;
222  et = vec.Perp();
223 
224  return et;
225 }
226 
227 }
228 //------------------------------------------------------------------
229 void
231 {
232  // printf("filletaphi \n");
233  const float area = sizeRad(); // barrel cell range, AMT this is available in context
234 
235  double eta1 = m_eta - area;
236  double eta2 = m_eta + area;
237  double phi1 = m_phi - area;
238  double phi2 = m_phi + area;
239 
240 
241  std::vector<FWBoxRecHit*> boxes;
242  for( EcalRecHitCollection::const_iterator hitIt = hits->begin(); hitIt != hits->end(); ++hitIt)
243  {
244  const float *corners = m_geom->getCorners( hitIt->detid() );
245  float energy, et;
246  std::vector<TEveVector> etaphiCorners(8);
247 
248  if( corners == 0 )
249  continue;
250 
251 
252  for( int i = 0; i < 4; ++i )
253  {
254  TEveVector cv = TEveVector( corners[i*3], corners[i*3+1], corners[i*3+2] );
255  etaphiCorners[i].fX = cv.Eta(); // Conversion of rechit X/Y values for plotting in Eta/Phi
256  etaphiCorners[i].fY = cv.Phi();
257  etaphiCorners[i].fZ = 0.0;
258 
259  etaphiCorners[i+4].fX = etaphiCorners[i].fX; // Top can simply be plotted exactly over the top of the bottom face
260  etaphiCorners[i+4].fY = etaphiCorners[i].fY;
261  etaphiCorners[i+4].fZ = 0.001;
262  // printf("%f %f %d \n", etaphiCorners[i].fX, etaphiCorners[i].fY, i);
263  }
264 
265  TEveVector center;
266  for( int i = 0; i < 4; ++i )
267  center += etaphiCorners[i];
268  center *= 1.f / 4.f;
269 
270 
271  if ( center.fX < eta1 || center.fX > eta2) continue;
272  if ( center.fY < phi1 || center.fY > phi2) continue;
273 
274 
275 
276  // Stop phi wrap
277  float dPhi1 = etaphiCorners[2].fY - etaphiCorners[1].fY;
278  float dPhi2 = etaphiCorners[3].fY - etaphiCorners[0].fY;
279  float dPhi3 = etaphiCorners[1].fY - etaphiCorners[2].fY;
280  float dPhi4 = etaphiCorners[0].fY - etaphiCorners[3].fY;
281 
282  if( dPhi1 > 1 )
283  etaphiCorners[2].fY = etaphiCorners[2].fY - ( 2 * TMath::Pi() );
284  if( dPhi2 > 1 )
285  etaphiCorners[3].fY = etaphiCorners[3].fY - ( 2 * TMath::Pi() );
286  if( dPhi3 > 1 )
287  etaphiCorners[2].fY = etaphiCorners[2].fY + ( 2 * TMath::Pi() );
288  if( dPhi4 > 1 )
289  etaphiCorners[3].fY = etaphiCorners[3].fY + ( 2 * TMath::Pi() );
290 
291 
292 
293  energy = hitIt->energy();
294  et = calculateEt( center, energy );
295  Color_t bcolor = m_defaultColor;
296  std::map<DetId, int>::const_iterator itr = m_detIdsToColor.find(hitIt->id());
297  if (itr != m_detIdsToColor.end()) bcolor = itr->second;
298 
299  m_boxes.push_back(new FWBoxRecHit( etaphiCorners, m_towerList, energy, et ));
300  TEveElement::List_i pIt = m_boxes.back()->getTower()->BeginParents();
301  TEveCompound* comp = dynamic_cast<TEveCompound*>(*pIt);
302  comp->SetMainColor(bcolor);
303  m_boxes.back()->getTower()->SetPickable(true);
304  m_boxes.back()->getTower()->SetElementTitle(Form("rawId = %d, et = %f", hitIt->id().rawId(), et));
305  } // loop hits
306 
307 }
308 
309 
310 //---------------------------------------------------------------------------------------
311 
312 
313 void
315 {
316  { // barrel
317  const EcalRecHitCollection *hitsEB = 0;
318  edm::Handle<EcalRecHitCollection> handle_hitsEB;
319 
320  // RECO
321  try
322  {
323  edm::InputTag tag("ecalRecHit", "EcalRecHitsEB");
324  m_event->getByLabel(tag, handle_hitsEB);
325  if (handle_hitsEB.isValid())
326  {
327  hitsEB = &*handle_hitsEB;
328  }
329  }
330  catch (...)
331  {
332  fwLog(fwlog::kWarning) <<"FWECALDetailViewBuilder::fillData():: Failed to access EcalRecHitsEB collection." << std::endl;
333  }
334 
335 
336  // AOD
337  if ( ! handle_hitsEB.isValid()) {
338  try{
339  edm::InputTag tag("reducedEcalRecHitsEB");
340  m_event->getByLabel(tag, handle_hitsEB);
341  if (handle_hitsEB.isValid())
342  {
343  hitsEB = &*handle_hitsEB;
344  }
345 
346  }
347  catch (...)
348  {
349  fwLog(fwlog::kWarning) <<"FWECALDetailViewBuilder::filData():: Failed to access reducedEcalRecHitsEB collection." << std::endl;
350  }
351  }
352 
353  // MINIAOD
354  if ( ! handle_hitsEB.isValid()) {
355  try{
356  edm::InputTag tag("reducedEgamma", "reducedEBRecHits");
357  m_event->getByLabel(tag, handle_hitsEB);
358  if (handle_hitsEB.isValid())
359  {
360  hitsEB = &*handle_hitsEB;
361  }
362 
363 
364 
365 
366  }
367  catch (...)
368  {
369  fwLog(fwlog::kWarning) <<"FWECALDetailViewBuilder::filData():: Failed to access reducedEgamma collection." << std::endl;
370  }
371  }
372 
373  if( handle_hitsEB.isValid() )
374  {
375  fillEtaPhi( hitsEB, data);
376  }
377  }
378 
379  {// endcap
380 
381  const EcalRecHitCollection *hitsEE = 0;
382  edm::Handle<EcalRecHitCollection> handle_hitsEE;
383 
384  // RECO
385  try
386  {
387  edm::InputTag tag("ecalRecHit", "EcalRecHitsEE");
388  m_event->getByLabel(tag, handle_hitsEE);
389  if (handle_hitsEE.isValid())
390  hitsEE = &*handle_hitsEE;
391  }
392  catch (...)
393  {
394  fwLog(fwlog::kWarning) <<"FWECALDetailViewBuilder::fillData():: Failed to access ecalRecHitsEE collection." << std::endl;
395  }
396 
397  // AOD
398  if ( ! handle_hitsEE.isValid()) {
399  try {
400  edm::InputTag tag("reducedEcalRecHitsEE");
401  m_event->getByLabel(tag, handle_hitsEE);
402  if (handle_hitsEE.isValid())
403  {
404  hitsEE = &*handle_hitsEE;
405  }
406 
407  }
408  catch (...)
409  {
410  fwLog(fwlog::kWarning) <<"FWECALDetailViewBuilder::fillData():: Failed to access reducedEcalRecHitsEE collection." << std::endl;
411  }
412 
413  // MINIAOD
414  if ( ! handle_hitsEE.isValid()) {
415  try {
416  edm::InputTag tag("reducedEgamma", "reducedEERecHits");
417  m_event->getByLabel(tag, handle_hitsEE);
418  if (handle_hitsEE.isValid())
419  {
420  hitsEE = &*handle_hitsEE;
421  }
422 
423  }
424  catch (...)
425  {
426  fwLog(fwlog::kWarning) <<"FWECALDetailViewBuilder::fillData():: Failed to access reducedEcalRecHitsEE collection." << std::endl;
427  }
428  }
429 
430  }
431 
432  if( handle_hitsEE.isValid() )
433  {
434  fillEtaPhi( hitsEE, data);
435  }
436  }
437 
438  if ( m_boxes.empty()) return;
439 
440  bool plotEt = true;
441  float maxEnergy = 0;
442  int maxEnergyIdx = 0;
443  // get max energy in EE and EB
444 
445  int cnt = 0;
446  for (auto & i : m_boxes) {
447  if (i->getEnergy(plotEt) > maxEnergy) {
448  maxEnergy = i->getEnergy(plotEt);
449  maxEnergyIdx = cnt;
450  }
451  cnt++;
452  }
453 
454  m_boxes[maxEnergyIdx]->setIsTallest();
455 
456  // AMT ... max size can be an external parameter
457  float scale = 0.3/maxEnergy;
458  for (auto & i : m_boxes) {
459  i->updateScale(scale, log(maxEnergy + 1), plotEt);
460  i->getTower()->SetDrawFrame(true);
461  }
462  data->DataChanged();
463 }
464 
465 double
467  Color_t clustered1, Color_t clustered2,
468  Color_t supercluster
469  )
470 {
471  Double_t fontsize = 0.07;
472  TLatex* latex = new TLatex();
473  Double_t x = x0;
474  Double_t y = y0;
475  Double_t boxH = 0.25*fontsize;
476  Double_t yStep = 0.04;
477 
478  y -= yStep;
479  latex->DrawLatex(x, y, "Energy types:");
480  y -= yStep;
481 
482  Double_t pos[4];
483  pos[0] = x+0.05;
484  pos[2] = x+0.20;
485 
486  pos[1] = y; pos[3] = pos[1] + boxH;
488  latex->DrawLatex(x+0.25, y, "unclustered");
489  y -= yStep;
490  if (clustered1<0) return y;
491 
492  pos[1] = y; pos[3] = pos[1] + boxH;
493  FWDetailViewBase::drawCanvasBox(pos, clustered1);
494  latex->DrawLatex(x+0.25, y, "clustered");
495  y -= yStep;
496  if (clustered2<0) return y;
497 
498  pos[1] = y; pos[3] = pos[1] + boxH;
499  FWDetailViewBase::drawCanvasBox(pos, clustered2);
500  latex->DrawLatex(x+0.25, y, "clustered");
501  y -= yStep;
502  if (supercluster<0) return y;
503 
504  pos[1] = y; pos[3] = pos[1] + boxH;
505  FWDetailViewBase::drawCanvasBox(pos, supercluster);
506  latex->DrawLatex(x+0.25, y, "super-cluster");
507  y -= yStep;
508 
509  return y;
510 }
511 //______________________________________________________________________________
512 
514 {
515  float rs = m_size * TMath::DegToRad();
516  return rs;
517 }
518 
const double Pi
void showSuperCluster(const reco::SuperCluster &cluster, Color_t color=kYellow)
int i
Definition: DBlmapReader.cc:9
const double xbins[]
double makeLegend(double x0=0.02, double y0=0.95, Color_t clustered1=kGreen+1, Color_t clustered2=kTeal, Color_t supercluster=kYellow)
void fillData(TEveCaloDataVec *data)
std::vector< EcalRecHit >::const_iterator const_iterator
const std::vector< std::pair< DetId, float > > & hitsAndFractions() const
Definition: CaloCluster.h:192
void fillEtaPhi(const EcalRecHitCollection *hits, TEveCaloDataVec *data)
const edm::EventBase * m_event
std::map< DetId, int > m_detIdsToColor
FWECALDetailViewBuilder(const edm::EventBase *event, const FWGeometry *geom, float eta, float phi, int size=50, Color_t defaultColor=kMagenta+1)
std::vector< SuperCluster > SuperClusterCollection
collection of SuperCluser objectr
TEveCaloData * buildCaloData(bool xyEE)
int j
Definition: DBlmapReader.cc:9
How EventSelector::AcceptEvent() decides whether to accept an event for output otherwise it is excluding the probing of A single or multiple positive and the trigger will pass if any such matching triggers are PASS or EXCEPTION[A criterion thatmatches no triggers at all is detected and causes a throw.] A single negative with an expectation of appropriate bit checking in the decision and the trigger will pass if any such matching triggers are FAIL or EXCEPTION A wildcarded negative criterion that matches more than one trigger in the trigger but the state exists so we define the behavior If all triggers are the negative crieriion will lead to accepting the event(this again matches the behavior of"!*"before the partial wildcard feature was incorporated).The per-event"cost"of each negative criterion with multiple relevant triggers is about the same as!*was in the past
bool isValid() const
Definition: HandleBase.h:75
float calculateEt(const TEveVector &centre, float e)
Definition: FWPFMaths.cc:115
#define M_PI
dictionary cv
Definition: cuy.py:362
const_iterator end() const
void showSuperClusters(Color_t color1=kGreen+2, Color_t color2=kTeal)
const float * getCorners(unsigned int id) const
Definition: FWGeometry.cc:280
T const * product() const
Definition: Handle.h:81
#define fwLog(_level_)
Definition: fwLog.h:50
void setColor(Color_t color, const std::vector< DetId > &detIds)
Geom::Phi< T > phi() const
bool getByLabel(InputTag const &, Handle< T > &) const
Definition: EventBase.h:90
char data[epos_bytes_allocation]
Definition: EPOS_Wrapper.h:82
static bool superClusterEtaLess(const reco::CaloCluster &lhs, const reco::CaloCluster &rhs)
std::vector< FWBoxRecHit * > m_boxes
tuple size
Write out results.
const_iterator begin() const
static void drawCanvasBox(Double_t *pos, Color_t fillCol, Int_t fillType=0, bool bg=kTRUE)