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UCTRegion.cc
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1 #include <iostream>
2 #include <cstdlib>
3 #include <cstdint>
4 
5 #include <bitset>
6 using std::bitset;
7 #include <string>
8 using std::string;
9 
10 #include "UCTRegion.hh"
11 
12 #include "UCTGeometry.hh"
13 #include "UCTLogging.hh"
14 
15 #include "UCTTower.hh"
16 
17 using namespace l1tcalo;
18 
19 // Activity fraction to determine how active a tower compared to a region is
20 // To avoid ratio calculation, one can use comparison to bit-shifted RegionET
21 // (activityLevelShift, %) = (1, 50%), (2, 25%), (3, 12.5%), (4, 6.125%), (5, 3.0625%)
22 // Cutting any tighter is rather dangerous
23 // For the moment we use floating point arithmetic
24 
25 const float activityFraction = 0.125;
26 const float ecalActivityFraction = 0.25;
27 const float miscActivityFraction = 0.25;
28 
29 bool vetoBit(bitset<4> etaPattern, bitset<4> phiPattern) {
30  bitset<4> badPattern5(string("0101"));
31  bitset<4> badPattern7(string("0111"));
32  bitset<4> badPattern9(string("1001"));
33  bitset<4> badPattern10(string("1010"));
34  bitset<4> badPattern11(string("1011"));
35  bitset<4> badPattern13(string("1101"));
36  bitset<4> badPattern14(string("1110"));
37  bitset<4> badPattern15(string("1111"));
38 
39  bool answer = true;
40 
41  if (etaPattern != badPattern5 && etaPattern != badPattern7 && etaPattern != badPattern10 &&
42  etaPattern != badPattern11 && etaPattern != badPattern13 && etaPattern != badPattern14 &&
43  etaPattern != badPattern15 && phiPattern != badPattern5 &&
44  // phiPattern != badPattern7 && phiPattern != badPattern10 &&
45  phiPattern != badPattern10 && phiPattern != badPattern11 && phiPattern != badPattern13 &&
46  //phiPattern != badPattern14 && phiPattern != badPattern15 &&
47  etaPattern != badPattern9 && phiPattern != badPattern9) {
48  answer = false;
49  }
50  return answer;
51 }
52 
53 uint32_t getHitTowerLocation(uint32_t* et) {
54  uint32_t etSum = et[0] + et[1] + et[2] + et[3];
55  uint32_t iEtSum = (et[0] >> 1) + // 0.5xet[0]
56  (et[1] >> 1) + et[1] + // 1.5xet[1]
57  (et[2] >> 1) + (et[2] << 1) + // 2.5xet[2]
58  (et[3] << 2) - (et[3] >> 1); // 3.5xet[3]
59  uint32_t iAve = 0xDEADBEEF;
60  if (iEtSum <= etSum)
61  iAve = 0;
62  else if (iEtSum <= (etSum << 1))
63  iAve = 1;
64  else if (iEtSum <= (etSum + (etSum << 1)))
65  iAve = 2;
66  else
67  iAve = 3;
68  return iAve;
69 }
70 
71 UCTRegion::UCTRegion(uint32_t crt, uint32_t crd, bool ne, uint32_t rgn, int fwv)
72  : crate(crt), card(crd), region(rgn), negativeEta(ne), regionSummary(0), fwVersion(fwv) {
73  UCTGeometry g;
74  uint32_t nEta = g.getNEta(region);
75  uint32_t nPhi = g.getNPhi(region);
76  towers.clear();
77  for (uint32_t iEta = 0; iEta < nEta; iEta++) {
78  for (uint32_t iPhi = 0; iPhi < nPhi; iPhi++) {
79  towers.push_back(new UCTTower(crate, card, ne, region, iEta, iPhi, fwVersion));
80  }
81  }
82 }
83 
84 UCTRegion::~UCTRegion() {
85  for (uint32_t i = 0; i < towers.size(); i++) {
86  if (towers[i] != nullptr)
87  delete towers[i];
88  }
89 }
90 
91 const UCTTower* UCTRegion::getTower(uint32_t caloEta, uint32_t caloPhi) const {
92  UCTGeometry g;
93  uint32_t nPhi = g.getNPhi(region);
94  uint32_t iEta = g.getiEta(caloEta);
95  uint32_t iPhi = g.getiPhi(caloPhi);
96  UCTTower* tower = towers[iEta * nPhi + iPhi];
97  return tower;
98 }
99 
100 bool UCTRegion::process() {
101  // Determine region dimension
102  UCTGeometry g;
103  uint32_t nEta = g.getNEta(region);
104  uint32_t nPhi = g.getNPhi(region);
105 
106  // Process towers and calculate total ET for the region
107  uint32_t regionET = 0;
108  uint32_t regionEcalET = 0;
109  for (uint32_t twr = 0; twr < towers.size(); twr++) {
110  if (!towers[twr]->process()) {
111  LOG_ERROR << "Tower level processing failed. Bailing out :(" << std::endl;
112  return false;
113  }
114  regionET += towers[twr]->et();
115  // Calculate regionEcalET
116  regionEcalET += towers[twr]->getEcalET();
117  }
118  if (regionET > RegionETMask) {
119  // Region ET can easily saturate, suppress error spam
120  // LOG_ERROR << "L1TCaloLayer1::UCTRegion::Pegging RegionET" << std::endl;
121  regionET = RegionETMask;
122  }
123  regionSummary = (RegionETMask & regionET);
124  if (regionEcalET > RegionETMask)
125  regionEcalET = RegionETMask;
126 
127  // For central regions determine extra bits
128 
129  if (region < NRegionsInCard) {
130  // Identify active towers
131  // Tower ET must be a decent fraction of RegionET
132  bool activeTower[nEta][nPhi];
133  uint32_t activityLevel = ((uint32_t)((float)regionET) * activityFraction);
134  uint32_t nActiveTowers = 0;
135  uint32_t activeTowerET = 0;
136  for (uint32_t iPhi = 0; iPhi < nPhi; iPhi++) {
137  for (uint32_t iEta = 0; iEta < nEta; iEta++) {
138  uint32_t towerET = towers[iEta * nPhi + iPhi]->et();
139  if (towerET > activityLevel) {
140  activeTower[iEta][iPhi] = true;
141  nActiveTowers++;
142  activeTowerET += towers[iEta * nPhi + iPhi]->et();
143  } else
144  activeTower[iEta][iPhi] = false;
145  }
146  }
147  if (activeTowerET > RegionETMask)
148  activeTowerET = RegionETMask;
149  // Determine "hit" tower as weighted position of ET
150  uint32_t sumETIEta[4] = {0, 0, 0, 0};
151  for (uint32_t iEta = 0; iEta < nEta; iEta++) {
152  for (uint32_t iPhi = 0; iPhi < nPhi; iPhi++) {
153  uint32_t towerET = towers[iEta * nPhi + iPhi]->et();
154  sumETIEta[iEta] += towerET;
155  }
156  }
157  uint32_t hitIEta = getHitTowerLocation(sumETIEta);
158  uint32_t sumETIPhi[4] = {0, 0, 0, 0};
159  for (uint32_t iPhi = 0; iPhi < nPhi; iPhi++) {
160  for (uint32_t iEta = 0; iEta < nEta; iEta++) {
161  uint32_t towerET = towers[iEta * nPhi + iPhi]->et();
162  sumETIPhi[iPhi] += towerET;
163  }
164  }
165  uint32_t hitIPhi = getHitTowerLocation(sumETIPhi);
166  uint32_t hitTowerLocation = hitIEta * nPhi + hitIPhi;
167  // Calculate (energy deposition) active tower pattern
168  bitset<4> activeTowerEtaPattern = 0;
169  for (uint32_t iEta = 0; iEta < nEta; iEta++) {
170  bool activeStrip = false;
171  for (uint32_t iPhi = 0; iPhi < nPhi; iPhi++) {
172  if (activeTower[iEta][iPhi])
173  activeStrip = true;
174  }
175  if (activeStrip)
176  activeTowerEtaPattern |= (0x1 << iEta);
177  }
178  bitset<4> activeTowerPhiPattern = 0;
179  for (uint32_t iPhi = 0; iPhi < nPhi; iPhi++) {
180  bool activeStrip = false;
181  for (uint32_t iEta = 0; iEta < nEta; iEta++) {
182  if (activeTower[iEta][iPhi])
183  activeStrip = true;
184  }
185  if (activeStrip)
186  activeTowerPhiPattern |= (0x1 << iPhi);
187  }
188  // Calculate veto bits for eg and tau patterns
189  bool veto = vetoBit(activeTowerEtaPattern, activeTowerPhiPattern);
190  bool egVeto = veto;
191  bool tauVeto = veto;
192  uint32_t maxMiscActivityLevelForEG = ((uint32_t)((float)regionET) * ecalActivityFraction);
193  uint32_t maxMiscActivityLevelForTau = ((uint32_t)((float)regionET) * miscActivityFraction);
194  if ((regionET - regionEcalET) > maxMiscActivityLevelForEG)
195  egVeto = true;
196  if ((regionET - activeTowerET) > maxMiscActivityLevelForTau)
197  tauVeto = true;
198 
199  if (egVeto)
200  regionSummary |= RegionEGVeto;
201  if (tauVeto)
202  regionSummary |= RegionTauVeto;
203 
204  regionSummary |= (hitTowerLocation << LocationShift);
205 
206  // Extra bits, not in readout, but implicit from their location in data packet for full location information
207 
208  if (negativeEta)
209  regionSummary |= NegEtaBit; // Used top bit for +/- eta-side
210  regionSummary |= (region << RegionNoShift); // Max region number 14, so 4 bits needed
211  regionSummary |= (card << CardNoShift); // Max card number is 6, so 3 bits needed
212  regionSummary |= (crate << CrateNoShift); // Max crate number is 2, so 2 bits needed
213  }
214 
215  return true;
216 }
217 
218 bool UCTRegion::clearEvent() {
219  regionSummary = 0;
220  for (uint32_t i = 0; i < towers.size(); i++) {
221  if (!towers[i]->clearEvent())
222  return false;
223  }
224  return true;
225 }
226 
227 bool UCTRegion::setECALData(UCTTowerIndex t, bool ecalFG, uint32_t ecalET) {
228  UCTGeometry g;
229  uint32_t nPhi = g.getNPhi(region);
230  uint32_t absCaloEta = abs(t.first);
231  uint32_t absCaloPhi = abs(t.second);
232  uint32_t iEta = g.getiEta(absCaloEta);
233  uint32_t iPhi = g.getiPhi(absCaloPhi);
234  UCTTower* tower = towers[iEta * nPhi + iPhi];
235  return tower->setECALData(ecalFG, ecalET);
236 }
237 
238 bool UCTRegion::setHCALData(UCTTowerIndex t, uint32_t hcalFB, uint32_t hcalET) {
239  UCTGeometry g;
240  uint32_t nPhi = g.getNPhi(region);
241  uint32_t absCaloEta = abs(t.first);
242  uint32_t absCaloPhi = abs(t.second);
243  uint32_t iEta = g.getiEta(absCaloEta);
244  uint32_t iPhiStart = g.getiPhi(absCaloPhi);
245  if (absCaloEta > 29 && absCaloEta < 40) {
246  // Valid data are:
247  // absCaloEta = 30-39, 1 < absCaloPhi <= 72 (every second value)
248  for (uint32_t iPhi = iPhiStart; iPhi < iPhiStart + 2; iPhi++) { // For artificial splitting in half
249  UCTTower* tower = towers[iEta * nPhi + iPhi];
250  // We divide by 2 in output section, after LUT
251  if (!tower->setHFData(hcalFB, hcalET))
252  return false;
253  }
254  } else if (absCaloEta == 40 || absCaloEta == 41) {
255  // Valid data are:
256  // absCaloEta = 40,41, 1 < absCaloPhi <= 72 (every fourth value)
257  for (uint32_t iPhi = 0; iPhi < 4; iPhi++) { // For artificial splitting in quarter
258  UCTTower* tower = towers[iEta * nPhi + iPhi];
259  // We divide by 4 in output section, after LUT
260  if (!tower->setHFData(hcalFB, hcalET))
261  return false;
262  }
263  } else {
264  uint32_t iPhi = g.getiPhi(absCaloPhi);
265  UCTTower* tower = towers[iEta * nPhi + iPhi];
266  return tower->setHCALData(hcalFB, hcalET);
267  }
268  return true;
269 }
270 
271 std::ostream& operator<<(std::ostream& os, const UCTRegion& r) {
272  if (r.negativeEta)
273  os << "UCTRegion Summary for negative eta " << r.region << " HitTower (eta, phi) = (" << std::dec << r.hitCaloEta()
274  << ", " << r.hitCaloPhi() << ")"
275  << " summary = " << std::hex << r.regionSummary << std::endl;
276  else
277  os << "UCTRegion Summary for positive eta " << r.region << " HitTower (eta, phi) = (" << std::dec << r.hitCaloEta()
278  << ", " << r.hitCaloPhi() << ")"
279  << " summary = " << std::hex << r.regionSummary << std::endl;
280 
281  return os;
282 }
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