Bug Summary

File:trg/ecl/src/TrgEclMaster.cc
Warning:line 1106, column 24
Although the value stored to 'lowmultibit' is used in the enclosing expression, the value is never actually read from 'lowmultibit'

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clang -cc1 -cc1 -triple x86_64-unknown-linux-gnu -O3 -analyze -disable-free -clear-ast-before-backend -disable-llvm-verifier -discard-value-names -main-file-name TrgEclMaster.cc -analyzer-checker=core -analyzer-checker=apiModeling -analyzer-checker=unix -analyzer-checker=deadcode -analyzer-checker=cplusplus -analyzer-checker=security.insecureAPI.UncheckedReturn -analyzer-checker=security.insecureAPI.getpw -analyzer-checker=security.insecureAPI.gets -analyzer-checker=security.insecureAPI.mktemp -analyzer-checker=security.insecureAPI.mkstemp -analyzer-checker=security.insecureAPI.vfork -analyzer-checker=nullability.NullPassedToNonnull -analyzer-checker=nullability.NullReturnedFromNonnull -analyzer-output plist -w -setup-static-analyzer -mrelocation-model pic -pic-level 2 -fhalf-no-semantic-interposition -mframe-pointer=none -fmath-errno -ffp-contract=on -fno-rounding-math -mconstructor-aliases -funwind-tables=2 -target-cpu x86-64 -tune-cpu generic -debugger-tuning=gdb -fdebug-compilation-dir=/data/b2soft/buildbot/development/build -fcoverage-compilation-dir=/data/b2soft/buildbot/development/build -resource-dir /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/lib/clang/21 -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/include/c++ -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/include/c++/x86_64-redhat-linux -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/include/c++/backward -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/include -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/include/python3.12 -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/include/CLHEP -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/include/Geant4 -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/include -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/include/root -isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/include/belle_legacy -I include/ -D _PACKAGE_="trg" -D G4UI_USE_TCSH -D RaveDllExport= -D HAS_SQLITE -D HAS_CALLGRIND -I include -I /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/include/libxml2 -internal-isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/bin/../lib64/gcc/x86_64-redhat-linux/15.2.0/../../../../include/c++ -internal-isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/bin/../lib64/gcc/x86_64-redhat-linux/15.2.0/../../../../include/c++/x86_64-redhat-linux -internal-isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/bin/../lib64/gcc/x86_64-redhat-linux/15.2.0/../../../../include/c++/backward -internal-isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/lib/clang/21/include -internal-isystem /usr/local/include -internal-isystem /cvmfs/belle.cern.ch/el9/externals/v02-04-00/Linux_x86_64/common/bin/../lib64/gcc/x86_64-redhat-linux/15.2.0/../../../../x86_64-redhat-linux/include -internal-externc-isystem /include -internal-externc-isystem /usr/include -Wno-missing-braces -Wno-unused-command-line-argument -std=c++20 -fdeprecated-macro -ferror-limit 19 -fgnuc-version=4.2.1 -fno-implicit-modules -fskip-odr-check-in-gmf -fcxx-exceptions -fexceptions -vectorize-loops -vectorize-slp -analyzer-output=html -faddrsig -D__GCC_HAVE_DWARF2_CFI_ASM=1 -o /scan_build/2026-05-31-004316-385593-1 -x c++ trg/ecl/src/TrgEclMaster.cc
1/**************************************************************************
2 * basf2 (Belle II Analysis Software Framework) *
3 * Author: The Belle II Collaboration *
4 * *
5 * See git log for contributors and copyright holders. *
6 * This file is licensed under LGPL-3.0, see LICENSE.md. *
7 **************************************************************************/
8
9//---------------------------------------------------------------
10// Description : A class to represent TRG ECL
11//---------------------------------------------------------------------------------
12//
13// ECL trigger bit
14// ---------------------------------------------------------------------------------
15// Variable(in Tsim) | N(bit) | Address | Parameter
16// -------------------------------------- ------------------------------------------
17// | 1 | 0 | TRG(Hit or not)
18// | 7 | 7 downto 1 | Timing (LSB = 1 ns )
19// m_Triggerbit[0] | 7 | 14 downto 8 | Revoclk from FAM (LSB = 125 ns)
20// (upto 12th | 3 | 17 downto 15 | ECL-TRG Timing Source
21// bhabha bit) | 1 | 18 | Physics TRG
22// (32bit) | 1 | 19 | Belle type Bhabha
23// ------------------| 14 | 33 downto 20 | Bhabha Type
24// | 13 | 46 downto 34 | Total Energy
25// | 1 | 47 | E low (Etot >0.5 GeV)
26// | 1 | 48 | E High (Etot > 1.0 GeV)
27// m_Triggerbit[1] | 1 | 49 | E lom (Etot > 3.0 GeV)
28// | 7 | 56 dwonto 50 | ICN
29// | 3 | 59 downto 57 | BG veto
30// | 1 | 60 | Cluster Overflow
31// | 1 | 61 | 3D Bhabha Trigger for Veto
32// | 1 | 62 | (lml0) N Cluster >= 3, at least one Cluster >300 MeV (LAB), not 3D ECL Bhabha
33// _________________ | 1 | 63 | (lml1) one Cluster >= 2GeV(CM) with Theta Id = 4~14
34// | 1 | 64 | (lml2) one Cluster >= 2GeV(CM) with Theta Id = 2,3,15 or 16 and not a 3D ECL Bhabha
35// | 1 | 65 | (lml3) one Cluster >= 2GeV(CM) with Theta Id = 2, 3, 15 or 16 and not a 3D ECL Bhabha
36// | 1 | 66 | (lml4) one Cluster >= 2GeV(CM) with Theta Id = 1 or 17 and not a 3D ECL Bhabha
37// | 1 | 67 | (lml5) one Cluster >= 2GeV(CM) with Theta Id = 1 or 17 and a 3D ECL Bhabha
38// m_Triggerbit[2] | 1 | 68 | (lml6) exactly one Cluster >= 1GeV(CM) and one Cluster > 300 MeV (LAB ), in Theta Id 4~15(Barrel)
39// | 1 | 69 | (lml7) exactly one Cluster >= 1GeV(CM) and one Cluster > 300 MeV (LAB), in Theta Id 2, 3 or 16
40// | 1 | 70 | (lml8) 170 < delta phi(CM) < 190 degree, both Clusters > 250 MeV (LAB), and no 2GeV (CM) Cluster
41// | 1 | 71 | (lml9) 170 < delta phi(CM) < 190 degree, one Cluster < 250 MeV (LAB), the other Cluster > 250 MeV(LAB), and no 2GeV (CM) Cluster
42// | 1 | 72 | (lml10) 160 < delta phi(CM) < 200 degree, 160 < Sum Theta (CM)< 200 degree, no 2 GeV(CM) cluster
43// | 1 | 73 | (lml11) No 2GeV(CM) CL in an event
44// | 1 | 74 | 3D Bhabha Trigger for selection
45// | 1 | 75 | mumu bit
46// | 1 | 76 | Bhabha prescale bit
47// | 1 | 77 | E_tot > 20 GeV
48// | 1 | 78 | (lml12) N Cluster >= 3, at least one Cluster >500 MeV (LAB) with Theta Id 2~16, not 3D ECL Bhabha
49// | 1 | 79 | (lml13) Only one Cluster >500 MeV (CM) with Theta Id 6~11 and no other CL >= 300 MeV(LAB) anywhere
50// | 1 | 83 downto 80 | clock counter(set to be "0000" in tsim)
51// | 1 | 85 downto 84 | event timing quality flag
52// | 1 | 86 | 3D Bhabha Veto Intrk
53// | 1 | 88 downto 87 | 3D Bhabha selection theta flag
54// | 1 | 89 | [ecltaub2b] for 1x1 tau process : (110<delta phi(CM)<250, 130<Thata Sum(CM)<230, Etot1to17(Lab)<7GeV, E(1CL)(Lab)<1.9GeV)
55// | 1 | 90 | [hie1] hie && 1CL veto(not (N(CL)=1 && CL in FW)) && 2CL veto-1(not (N(CL)=2 && 160 < dphi < 200 && 150 < sum theta < 250))
56// | 1 | 91 | [hie2] hie && 1CL veto(not (N(CL)=1 && CL in FW)) && 2CL veto-2(not (N(CL)=2 && 160 < dphi < 200 || 150 < sum theta < 250))
57// | 1 | 92 | [hie3] hie && 1CL veto(not (N(CL)=1 && CL in FW)) && 2CL veto-3(not (N(CL)=2 && CL_lowe in FW or BW)
58// | 1 | 93 | [ecltaub2b v2] for 1x1 tau process : (120<delta phi(CM)<240, 140<Thata Sum(CM)<220, Etot1to17(Lab)<7GeV, N(CL) in endcap with E(CL)(3GeV) , E(CL)>0.165 for N(CL)==2, 1CL E(CL)>0.14 and 2CL E(CL)>0.165 for N(CL)==3, 2CL E(CL)>0.14 and 2CL E(CL)>0.165 for N(CL)==4, 1CL E(CL)>0.12 and 2CL E(CL)>0.14 and 2CL E(CL)>0.165 for N(CL)>4
59// | 1 | 94 | [ecltaub2b v3] for 1x1 tau process : (120<delta phi(CM)<240, 140<Thata Sum(CM)<220, Etot1to17(Lab)<7GeV, E(CL)>0.140 in lab for one of 2CL in b2b CLs, CL ThetaID= 2-16 for b2b CLs, CL(E)>0.12GeV in lab for all CLs, CL(E)<4.5GeV in lab for all CLs)
60// | 1 | 95 | [hie4] hie && 1CL veto(not (N(CL)=1 && CL in FW)) && 2CL veto-4(not (N(CL)=2 && CL_lowe in FW or BW) && E(CL_lowe)>0.5GeV)
61// ---------------------------------------------------------------------------------
62
63#define TRG_SHORT_NAMES
64#define TRGECL_SHORT_NAMES
65
66#include "framework/datastore/StoreArray.h"
67#include "trg/ecl/TrgEclMaster.h"
68#include "trg/ecl/TrgEclCluster.h"
69
70#include "trg/ecl/dataobjects/TRGECLTrg.h"
71#include "trg/ecl/dataobjects/TRGECLHit.h"
72#include "trg/ecl/dataobjects/TRGECLCluster.h"
73//
74#include <math.h>
75#include <TRandom3.h>
76//
77//
78using namespace std;
79using namespace Belle2;
80//
81//
82//
83TrgEclMaster::TrgEclMaster():
84 m_TimeWindow(250.0), m_OverlapWindow(0.0), m_Clustering(1),
85 m_EventTiming(1), m_NofTopTC(3), m_ClusterLimit(6), m_Triggerbit{0, 0, 0, 0},
86 m_Lowmultibit(0), m_PrescaleFactor(0), m_PrescaleCounter(0)
87{
88
89 m_obj_cluster = new TrgEclCluster();
90 m_obj_beambkg = new TrgEclBeamBKG();
91 m_obj_bhabha = new TrgEclBhabha();
92 m_obj_timing = new TrgEclTiming();
93 m_obj_map = new TrgEclMapping();
94 m_obj_database = new TrgEclDataBase();
95
96}
97//
98//
99//
100TrgEclMaster::~TrgEclMaster()
101{
102 delete m_obj_cluster;
103 delete m_obj_beambkg;
104 delete m_obj_bhabha;
105 delete m_obj_timing;
106 delete m_obj_map;
107 delete m_obj_database;
108}
109//
110//
111//
112std::string
113TrgEclMaster::name(void) const
114{
115 return "TrgEclMaster";
116}
117//
118//
119//
120std::string
121TrgEclMaster::version(void) const
122{
123 return std::string("TrgEclMaster 2.1");
124}
125//
126//
127//
128void
129TrgEclMaster::initialize()
130{
131 m_TCEnergy.clear();
132 m_TCTiming.clear();
133 m_TCBeamBkgTag.clear();
134 m_HitTCId.clear();
135 m_TCHitEnergy.clear();
136 m_TCHitTiming.clear();
137 m_TCHitBeamBkgTag.clear();
138
139 m_TCEnergy.resize(576);
140 m_TCTiming.resize(576);
141 m_TCBeamBkgTag.resize(576);
142
143 // conversion factor of ADC to Energy in Lab in GeV
144 m_ADCtoEnergy = 0.00525;
145 // lowe, hie, lume in Lab in GeV
146 m_TotalEnergy = {0.5, 1.0, 3.0};
147 // 2D Bhabha E cut in Lab in GeV (forward and backward sides)
148 m_2DBhabhaThresholdFWD =
149 {4.0, 4.0, 4.0, 4.0, 4.0, 4.0, 4.0, 4.0, 4.0, 4.0, 4.0, 4.0, 3.0, 3.5};
150 m_2DBhabhaThresholdBWD =
151 {2.5, 2.5, 2.5, 2.5, 2.5, 2.5, 2.5, 2.5, 2.5, 2.5, 2.5, 2.5, 3.0, 3.0};
152 //
153 m_3DBhabhaVetoAngle = {160, 200, 165, 190}; // /100 MeV
154 m_3DBhabhaVetoThreshold = {30, 45}; // /100 MeV
155 m_3DBhabhaSelectionThreshold = {20, 40}; // /100 MeV
156 m_3DBhabhaSelectionAngle = {140, 220, 160, 200}; // /100 MeV
157 m_3DBhabhaSelectionPreScale = {1, 1, 1};
158 //
159 m_mumuThreshold = 2.0; // GeV
160 m_mumuAngle = {160, 200, 165, 190}; // degree
161 //
162 m_lmlCLELabCut = {0.5, 0.3, 0.25}; // in GeV
163 m_lmlCLECMSCut = {2.0, 1.0, 0.5}; // in GeV
164 m_lml00NCLforMinE = 1;
165 m_lml12NCLforMinE = 1;
166 m_lml13ThetaIdSelection = 2016;
167 //
168 m_ECLBurstThreshold = 20.0; // GeV
169 //
170 m_EventTimingQualityThreshold = {1.0, 20.0}; // GeV
171 //
172 m_3DBhabhaVetoInTrackThetaRegion = {3, 15};
173 // taub2b cut
174 m_taub2bAngleCut = {110, 250, 130, 230}; // degree
175 m_taub2bEtotCut = 7.0; // GeV
176 m_taub2bCLELabCut = 1.9; // GeV
177 // hie1,2 BhabhaVeto angle
178 m_hie12BhabhaVetoAngle = {150, 210, 160, 200}; // degree
179 // taub2b2 cut
180 m_taub2b2AngleCut = {120, 240, 140, 220}; // degree
181 m_taub2b2EtotCut = 7.0; // GeV
182 m_taub2b2CLELabCut = {3.0, 0.162}; // GeV
183 //taub2b3 cut
184 m_taub2b3AngleCut = {120, 240, 140, 220}; // degree
185 m_taub2b3EtotCut = 7.0; // GeV
186 m_taub2b3CLEb2bLabCut = 0.14; // GeV
187 m_taub2b3CLELabCut = {0.12, 4.5}; // GeV
188 // hie4
189 m_hie4LowCLELabCut = 0.5; //GeV
190
191}
192//========================================================
193//
194//========================================================
195void
196TrgEclMaster::simulate01(int m_nEvent) // Firmware simulator(time window 250 ns )
197{
198 // TrgEclFAM* obj_trgeclfam = new TrgEclFAM();
199 // obj_trgeclfam->setup(m_nEvent, 1);
200 // setPRS(obj_trgeclfam);
201 //
202 //----------
203 // TC Etot
204 //----------
205 //
206 // Energy sum of forward and barrel except for extreme forward
207 // so Etot is sum of "phi ring ID" = 1-14
208 // Etot threshold are
209 // 1.0 GeV for Etot01
210 // 0.5 GeV for Etot02nt
211 // 3.0 GeV for Etot03
212 //
213 // Read FAM Output
214 m_TCTiming.clear();
215 m_TCEnergy.clear();
216 m_TCBeamBkgTag.clear();
217 m_TCEnergy.resize(576);
218 m_TCTiming.resize(576);
219 m_TCBeamBkgTag.resize(576);
220
221 StoreArray<TRGECLHit> trgeclHitArray;
222 for (int ii = 0; ii < trgeclHitArray.getEntries(); ii++) {
223
224 TRGECLHit* aTRGECLHit = trgeclHitArray[ii];
225 int iTCID = (aTRGECLHit->getTCId() - 1);
226 double HitTiming = aTRGECLHit->getTimeAve();
227 double HitEnergy = aTRGECLHit->getEnergyDep();
228 double HitBeamBkg = aTRGECLHit->getBeamBkgTag();
229
230 m_TCTiming[iTCID].push_back(HitTiming);
231 m_TCEnergy[iTCID].push_back(HitEnergy);
232 m_TCBeamBkgTag[iTCID].push_back(HitBeamBkg);
233 }
234 //
235 //
236 int nBin = 8000 / (m_TimeWindow / 2) ; //8000/125
237 /* cppcheck-suppress variableScope */
238 double WindowStart;
239 /* cppcheck-suppress variableScope */
240 double WindowEnd;
241 double fluctuation = ((gRandom->Uniform(-1, 0))) * 125;
242 /* cppcheck-suppress variableScope */
243 double check_window_start;
244 /* cppcheck-suppress variableScope */
245 double check_window_end;
246
247 for (int iBin = 0 ; iBin < nBin; iBin ++) {
248
249 check_window_start = iBin * (m_TimeWindow / 3) + fluctuation - 4000;
250 WindowStart = check_window_start;
251 check_window_end = check_window_start + m_TimeWindow / 3;
252 WindowEnd = WindowStart + m_TimeWindow;
253 m_HitTCId.clear();
254 m_TCHitTiming.clear();
255 m_TCHitEnergy.clear();
256 m_TCHitBeamBkgTag.clear();
257
258 // prepare TC Hit in time window --
259 for (int iTCId = 0; iTCId < 576; iTCId++) {
260 const int hitsize = m_TCTiming[iTCId].size();
261 for (int ihit = 0; ihit < hitsize; ihit++) {
262 if (m_TCTiming[iTCId][ihit] > check_window_start &&
263 m_TCTiming[iTCId][ihit] < check_window_end) {
264 m_HitTCId.push_back(iTCId + 1);
265
266 }
267 }
268 }
269 if (m_HitTCId.size() == 0) {continue;}
270 else {
271 m_HitTCId.clear();
272 for (int iTCId = 0; iTCId < 576; iTCId++) {
273 const int hitsize = m_TCTiming[iTCId].size();
274 for (int ihit = 0; ihit < hitsize; ihit++) {
275 if (m_TCTiming[iTCId][ihit] > WindowStart &&
276 m_TCTiming[iTCId][ihit] < WindowEnd) {
277 m_HitTCId.push_back(iTCId + 1);
278 m_TCHitTiming.push_back(m_TCTiming[iTCId][ihit]);
279 m_TCHitEnergy.push_back(m_TCEnergy[iTCId][ihit]);
280 }
281 }
282 }
283 iBin = iBin + 2;
284 }
285 int noftchit = m_HitTCId.size();
286 if (noftchit == 0) {continue;}
287
288 double eventtiming = 0;
289 // Get EventTiming
290 m_obj_timing->Setup(m_HitTCId, m_TCHitEnergy, m_TCHitTiming);
291 m_obj_timing->setNofTopTC(m_NofTopTC);
292 m_obj_timing->setEventTimingQualityThreshold(m_EventTimingQualityThreshold);
293
294 eventtiming = m_obj_timing->getEventTiming(m_EventTiming);
295 int timingsource = m_obj_timing->getTimingSource();
296 int EventTimingQualityFlag = m_obj_timing->getEventTimingQualityFlag();
297 //--------------------------------------------------
298 // Ring sum and Total Energy Sum
299 //-------------------------------------------------
300 std::vector<std::vector<double>> thetaringsum;
301 std::vector<double> phiringsum;
302
303 thetaringsum.clear();
304 phiringsum.clear();
305 thetaringsum.resize(3, std::vector<double>(36, 0));
306 phiringsum.resize(17, 0);
307 setRS(m_HitTCId, m_TCHitEnergy, phiringsum, thetaringsum);
308
309 double E_phys = 0;
310 double E_total = 0;
311 int E_burst = 0;
312 for (int iii = 0; iii <= 16; iii++) {
313 if (iii > 0 && iii < 15) {E_phys += phiringsum[iii];}
314 E_total += phiringsum[iii];
315 }
316 if (E_total == 0) {continue;}
317 int ELow = 0, EHigh = 0, ELum = 0;
318
319 if (E_total > m_ECLBurstThreshold / 10) {
320 E_burst = 0x01;
321 }
322 if (E_phys > m_TotalEnergy[0]) { // GeV
323 ELow = 0x01;
324 }
325 if (E_phys > m_TotalEnergy[1]) { // GeV
326 EHigh = 0x01;
327 }
328 if (E_phys > m_TotalEnergy[2]) { // GeV
329 ELum = 0x01;
330 }
331 //--------------
332 // Clustering
333 //--------------
334 m_obj_cluster->initialize();
335 m_obj_cluster->setClusteringMethod(m_Clustering);
336 m_obj_cluster->setClusterLimit(m_ClusterLimit);
337 m_obj_cluster->setEventId(m_nEvent);
338 m_obj_cluster->setICN(m_HitTCId, m_TCHitEnergy, m_TCHitTiming);// Clustering
339 m_obj_cluster->setICN(m_HitTCId); // Belle Cluster Counting
340
341 int icn = m_obj_cluster->getICNFwBr();
342 int icnfwd = m_obj_cluster->getICNSub(0);
343 int icnbr = m_obj_cluster->getICNSub(1);
344 int icnbwd = m_obj_cluster->getICNSub(2);
345 //--------------
346 // Bhabha veto
347 //--------------
348 setBhabhaParameter();
349
350 std::vector<double> vct_bhabha;
351 vct_bhabha.clear();
352 int bhabha2D = 0 ;
353 int bhabha3D_veto = 0 ;
354 int bhabha3D_sel = 0;
355 int mumu = 0;
356 int bhabha3DVetoInTrackFlag = 0;
357 int bhabha3DSelectionThetaFlag = 0;
358 int taub2bFlag = 0;
359 int taub2b2Flag = 0;
360 int taub2b3Flag = 0;
361
362 bool b_2Dbhabha = m_obj_bhabha->getBhabha00(phiringsum);
363 vct_bhabha = m_obj_bhabha->getBhabhaComb();
364 if (b_2Dbhabha && (icn < 4)) {bhabha2D = 1;}
365 bool b_3Dbhabha = m_obj_bhabha->getBhabha01();
366 if (b_3Dbhabha) {bhabha3D_veto = 1;}
367 bool b_3Dbhabha_sel = m_obj_bhabha->getBhabha02();
368 if (b_3Dbhabha_sel) {bhabha3D_sel = 1;}
369 bool b_mumu = m_obj_bhabha->getmumu();
370 if (b_mumu) {mumu = 1;}
371 bhabha3DVetoInTrackFlag = m_obj_bhabha->get3DBhabhaVetoInTrackFlag();
372 bhabha3DSelectionThetaFlag = m_obj_bhabha->get3DBhabhaSelectionThetaFlag();
373 taub2bFlag = (m_obj_bhabha->getTaub2b(E_total)) ? 1 : 0;
374 taub2b2Flag = (m_obj_bhabha->getTaub2b2(E_total)) ? 1 : 0;
375 taub2b3Flag = (m_obj_bhabha->getTaub2b3(E_total)) ? 1 : 0;
376
377 //------------------------
378 // Beam Background veto (Old cosmic veto)
379 //------------------------
380 int beambkgtag = 0;
381 beambkgtag = m_obj_beambkg->getBeamBkg(thetaringsum);
382
383 int bhabhaprescale = 0;
384 if (m_PrescaleFactor == m_PrescaleCounter) {
385 bhabhaprescale = 1;
386 m_PrescaleCounter = 0;
387 } else if (m_PrescaleFactor > m_PrescaleCounter) {
388 m_PrescaleCounter ++;
389 }
390 //--------------
391 // Low Multiplicity bit
392 //--------------
393 std::vector<double> ClusterTiming;
394 std::vector<double> ClusterEnergy;
395 std::vector<int> MaxTCId;
396 ClusterTiming.clear();
397 ClusterEnergy.clear();
398 MaxTCId.clear();
399 StoreArray<TRGECLCluster> trgeclClusterArray;
400 for (int ii = 0; ii < trgeclClusterArray.getEntries(); ii++) {
401 TRGECLCluster* aTRGECLCluster = trgeclClusterArray[ii];
402 int maxTCId = aTRGECLCluster->getMaxTCId();
403 double clusterenergy = aTRGECLCluster->getEnergyDep();
404 double clustertiming = aTRGECLCluster->getTimeAve();
405 ClusterTiming.push_back(clustertiming);
406 ClusterEnergy.push_back(clusterenergy);
407 MaxTCId.push_back(maxTCId);
408 }
409 makeLowMultiTriggerBit(MaxTCId, ClusterEnergy, bhabha3D_veto);
410 //-------------
411 // Make ECL Trigger Bit
412 //-------------
413 int hit = 1; // hit or not
414 int Timing = (int)(eventtiming + 0.5);
415 int RevoFAM = 0;
416 int TimingSource = m_obj_timing->getTimingSource(); // FWD(0), Barrel(0), Backward(0);
417 int etot = (int)(E_phys * 1000 + 0.5); // total Energy in theta ID [2~15]
418 int physics = 0;
419 if ((etot > 1000 || icn > 3) && !(bhabha2D == 1)) {physics = 1;}
420 std::vector<int> bhabhabit;
421 bhabhabit.clear();
422 int bhabhabitsize = vct_bhabha.size();
423 for (int ibhabha = 0; ibhabha < bhabhabitsize; ibhabha++) {
424 bhabhabit.push_back((int)vct_bhabha[ibhabha]);
425 }
426 int ClusterOverflow = m_obj_cluster->getNofExceedCluster();
427 int flagoverflow = 0;
428 if (ClusterOverflow > 0) {
429 flagoverflow = 1;
430 }
431
432 makeTriggerBit(hit, Timing, 0, timingsource, E_phys, ELow, EHigh, ELum,
433 bhabha2D, physics, bhabhabit, icn, beambkgtag, flagoverflow,
434 bhabha3D_veto, m_Lowmultibit, bhabha3D_sel, mumu,
435 bhabhaprescale, E_burst,
436 EventTimingQualityFlag,
437 bhabha3DVetoInTrackFlag,
438 bhabha3DSelectionThetaFlag,
439 taub2bFlag,
440 0,
441 taub2b2Flag,
442 taub2b3Flag);
443
444 int m_hitEneNum = 0;
445 StoreArray<TRGECLTrg> trgEcltrgArray;
446 trgEcltrgArray.appendNew();
447 m_hitEneNum = trgEcltrgArray.getEntries() - 1;
448 //-------------
449 // Store
450 //-------------
451 trgEcltrgArray[m_hitEneNum]->setEventId(m_nEvent);
452 trgEcltrgArray[m_hitEneNum]->setPRS01(phiringsum[0]);
453 trgEcltrgArray[m_hitEneNum]->setPRS02(phiringsum[1]);
454 trgEcltrgArray[m_hitEneNum]->setPRS03(phiringsum[2]);
455 trgEcltrgArray[m_hitEneNum]->setPRS04(phiringsum[3]);
456 trgEcltrgArray[m_hitEneNum]->setPRS05(phiringsum[4]);
457 trgEcltrgArray[m_hitEneNum]->setPRS06(phiringsum[5]);
458 trgEcltrgArray[m_hitEneNum]->setPRS07(phiringsum[6]);
459 trgEcltrgArray[m_hitEneNum]->setPRS08(phiringsum[7]);
460 trgEcltrgArray[m_hitEneNum]->setPRS09(phiringsum[8]);
461 trgEcltrgArray[m_hitEneNum]->setPRS10(phiringsum[9]);
462 trgEcltrgArray[m_hitEneNum]->setPRS11(phiringsum[10]);
463 trgEcltrgArray[m_hitEneNum]->setPRS12(phiringsum[11]);
464 trgEcltrgArray[m_hitEneNum]->setPRS13(phiringsum[12]);
465 trgEcltrgArray[m_hitEneNum]->setPRS14(phiringsum[13]);
466 trgEcltrgArray[m_hitEneNum]->setPRS15(phiringsum[14]);
467 trgEcltrgArray[m_hitEneNum]->setPRS16(phiringsum[15]);
468 trgEcltrgArray[m_hitEneNum]->setPRS17(phiringsum[16]);
469 //
470 trgEcltrgArray[m_hitEneNum]->setEtot(E_phys);
471 trgEcltrgArray[m_hitEneNum]->setNofTCHit(noftchit);
472 //
473 trgEcltrgArray[m_hitEneNum]->setBhabha01(vct_bhabha[0]);
474 trgEcltrgArray[m_hitEneNum]->setBhabha02(vct_bhabha[1]);
475 trgEcltrgArray[m_hitEneNum]->setBhabha03(vct_bhabha[2]);
476 trgEcltrgArray[m_hitEneNum]->setBhabha04(vct_bhabha[3]);
477 trgEcltrgArray[m_hitEneNum]->setBhabha05(vct_bhabha[4]);
478 trgEcltrgArray[m_hitEneNum]->setBhabha06(vct_bhabha[5]);
479 trgEcltrgArray[m_hitEneNum]->setBhabha07(vct_bhabha[6]);
480 trgEcltrgArray[m_hitEneNum]->setBhabha08(vct_bhabha[7]);
481 trgEcltrgArray[m_hitEneNum]->setBhabha09(vct_bhabha[8]);
482 trgEcltrgArray[m_hitEneNum]->setBhabha10(vct_bhabha[9]);
483 trgEcltrgArray[m_hitEneNum]->setBhabha11(vct_bhabha[10]);
484 trgEcltrgArray[m_hitEneNum]->setBhabha12(vct_bhabha[11]);
485 trgEcltrgArray[m_hitEneNum]->setBhabha13(vct_bhabha[12]);
486 trgEcltrgArray[m_hitEneNum]->setBhabha14(vct_bhabha[13]);
487 trgEcltrgArray[m_hitEneNum]->setBhabha15(vct_bhabha[14]);
488 trgEcltrgArray[m_hitEneNum]->setBhabha16(vct_bhabha[15]);
489 trgEcltrgArray[m_hitEneNum]->setBhabha17(vct_bhabha[16]);
490 trgEcltrgArray[m_hitEneNum]->setBhabha18(vct_bhabha[17]);
491 //
492 trgEcltrgArray[m_hitEneNum]->setICN(icn);
493 trgEcltrgArray[m_hitEneNum]->setICNFw(icnfwd);
494 trgEcltrgArray[m_hitEneNum]->setICNBr(icnbr);
495 trgEcltrgArray[m_hitEneNum]->setICNBw(icnbwd);
496 //
497 trgEcltrgArray[m_hitEneNum]->setECLtoGDL(m_Triggerbit[0], 0);
498 trgEcltrgArray[m_hitEneNum]->setECLtoGDL(m_Triggerbit[1], 1);
499 trgEcltrgArray[m_hitEneNum]->setECLtoGDL(m_Triggerbit[2], 2);
500 trgEcltrgArray[m_hitEneNum]->setECLtoGDL(m_Triggerbit[3], 3);
501
502 trgEcltrgArray[m_hitEneNum]->setBhabhaVeto(bhabha2D);
503 trgEcltrgArray[m_hitEneNum]->setBeamBkgVeto(beambkgtag);
504 trgEcltrgArray[m_hitEneNum]->setEventTiming(eventtiming);
505
506 trgEcltrgArray[m_hitEneNum]->setHit(hit);
507 trgEcltrgArray[m_hitEneNum]->setRevoclk(RevoFAM);
508 trgEcltrgArray[m_hitEneNum]->setTimingSource(TimingSource);
509 trgEcltrgArray[m_hitEneNum]->setPhysics(physics) ;
510 trgEcltrgArray[m_hitEneNum]->set2DBhabha(bhabha2D);
511 trgEcltrgArray[m_hitEneNum]->set3DBhabha(bhabha3D_veto);
512 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSel(bhabha3D_sel);
513 trgEcltrgArray[m_hitEneNum]->setmumuBit(mumu);
514 trgEcltrgArray[m_hitEneNum]->setBhabhaPrescaleBit(bhabhaprescale);
515
516 trgEcltrgArray[m_hitEneNum]->setELow(ELow) ;
517 trgEcltrgArray[m_hitEneNum]->setEHihg(EHigh);
518 trgEcltrgArray[m_hitEneNum]->setELum(ELum) ;
519 trgEcltrgArray[m_hitEneNum]->setClusterOverflow(ClusterOverflow) ;
520 trgEcltrgArray[m_hitEneNum]->setLowMultiBit(m_Lowmultibit);
521 }
522
523 return;
524}
525//========================================================
526//
527//========================================================
528void
529TrgEclMaster::simulate02(int m_nEvent) // select one window for analyze trigger logic
530{
531 // TrgEclFAM* obj_trgeclfam = new TrgEclFAM();
532 // obj_trgeclfam->setup(m_nEvent, 1);
533 // setPRS(obj_trgeclfam);
534 //
535 //----------
536 // TC Etot
537 //----------
538 //
539 // Energy sum of forward and barrel except for extreme forward
540 // so Etot is sum of "phi ring ID" = 1-14
541 // Etot threshold are
542 // 1.0 GeV for Etot01
543 // 0.5 GeV for Etot02nt
544 // 3.0 GeV for Etot03
545 //
546 // Read FAM Output
547 m_TCTiming.clear();
548 m_TCEnergy.clear();
549 m_TCBeamBkgTag.clear();
550 m_TCEnergy.resize(576);
551 m_TCTiming.resize(576);
552 m_TCBeamBkgTag.resize(576);
553
554 StoreArray<TRGECLHit> trgeclHitArray;
555 for (int ii = 0; ii < trgeclHitArray.getEntries(); ii++) {
556
557 TRGECLHit* aTRGECLHit = trgeclHitArray[ii];
558 int iTCID = (aTRGECLHit->getTCId() - 1);
559 double HitTiming = aTRGECLHit->getTimeAve();
560 double HitEnergy = aTRGECLHit->getEnergyDep();
561 double HitBeamBkg = aTRGECLHit->getBeamBkgTag();
562
563 m_TCTiming[iTCID].push_back(HitTiming);
564 m_TCEnergy[iTCID].push_back(HitEnergy);
565 m_TCBeamBkgTag[iTCID].push_back(HitBeamBkg);
566 }
567 //
568 //
569 int nBin = 2 * 8000 / m_TimeWindow ;
570 double WindowStart = 0;
571 double WindowEnd = 0;
572 double fluctuation = ((gRandom->Uniform(-1, 0))) * 125;
573
574 int startBin = nBin / 2 - 1; //start previous bin near 0s
575
576 int endBin = nBin / 2 + 1; //start next bin near 0s
577
578 if (m_EventTiming == 0) {
579 m_TimeWindow = 500;
580 m_OverlapWindow = 0;
581 }
582
583 double maxE = 0;
584 int max_bin = 0;
585
586 for (int iBin = startBin ; iBin <= endBin; iBin ++) {
587 WindowStart = iBin * (m_TimeWindow - m_OverlapWindow) + fluctuation - 4000;
588
589 if (iBin == 0) {WindowStart = - 4000 + fluctuation;}
590 WindowEnd = WindowStart + m_TimeWindow;
591
592 double totalE = 0;
593 // prepare TC Hit in time window --
594 for (int iTCId = 0; iTCId < 576; iTCId++) {
595 const int hitsize = m_TCTiming[iTCId].size();
596 for (int ihit = 0; ihit < hitsize; ihit++) {
597 if (m_TCTiming[iTCId][ihit] > WindowStart &&
598 m_TCTiming[iTCId][ihit] < WindowEnd) {
599 totalE += m_TCEnergy[iTCId][ihit] ;
600 }
601 }
602 }
603 if (totalE == 0) {continue;}
604 if (maxE < totalE) { //select the bin having the highest total energy
605 maxE = totalE;
606 max_bin = iBin;
607 }
608 }
609
610 WindowStart = max_bin * (m_TimeWindow - m_OverlapWindow) + fluctuation - 4000;
611 if (max_bin == 0) {WindowStart = - 4000 + fluctuation;}
612 WindowEnd = WindowStart + m_TimeWindow;
613
614 m_HitTCId.clear();
615 m_TCHitTiming.clear();
616 m_TCHitEnergy.clear();
617 m_TCHitBeamBkgTag.clear();
618
619 // prepare TC Hit in time window --
620 for (int iTCId = 0; iTCId < 576; iTCId++) {
621 const int hitsize = m_TCTiming[iTCId].size();
622 for (int ihit = 0; ihit < hitsize; ihit++) {
623 if (m_TCTiming[iTCId][ihit] > WindowStart &&
624 m_TCTiming[iTCId][ihit] < WindowEnd) {
625 m_HitTCId.push_back(iTCId + 1);
626 m_TCHitTiming.push_back(m_TCTiming[iTCId][ihit]);
627 m_TCHitEnergy.push_back(m_TCEnergy[iTCId][ihit]);
628 m_TCHitBeamBkgTag.push_back(m_TCBeamBkgTag[iTCId][ihit]);
629 }
630 }
631 }
632
633 int noftchit = m_HitTCId.size();
634 if (noftchit == 0) { return;}
635
636 double eventtiming = 0;
637 // Get EventTiming
638 m_obj_timing->Setup(m_HitTCId, m_TCHitEnergy, m_TCHitTiming);
639 m_obj_timing->setNofTopTC(m_NofTopTC);
640 m_obj_timing->setEventTimingQualityThreshold(m_EventTimingQualityThreshold);
641
642 eventtiming = m_obj_timing->getEventTiming(m_EventTiming);
643 int timingsource = m_obj_timing->getTimingSource();
644
645 int EventTimingQualityFlag = m_obj_timing->getEventTimingQualityFlag();
646 //--------------------------------------------------
647 // Ring sum and Total Energy Sum
648 //-------------------------------------------------
649 std::vector<std::vector<double>> thetaringsum;
650 std::vector<double> phiringsum;
651
652 thetaringsum.clear();
653 phiringsum.clear();
654 thetaringsum.resize(3, std::vector<double>(36, 0));
655 phiringsum.resize(17, 0);
656 setRS(m_HitTCId, m_TCHitEnergy, phiringsum, thetaringsum);
657
658 //double E_br; //variable not used
659 //double E_fwd; //variable not used
660 //double E_bwd; //variable not used
661 double E_phys = 0;
662 double E_total = 0;
663 int E_burst = 0;
664
665 for (int iii = 0; iii <= 16; iii++) {
666 if (iii > 0 && iii < 15) {E_phys += phiringsum[iii];}
667 //if (iii < 3) {E_fwd += phiringsum[iii];} //TODO variable not used, should be?
668 //if (iii > 2 && iii < 15) {E_br += phiringsum[iii];} //TODO not used, should be?
669 //if (iii > 14) {E_bwd += phiringsum[iii];} //TODO not used, should be?
670 E_total += phiringsum[iii];
671 }
672
673 if (E_total == 0) {return;}
674 int ELow = 0, EHigh = 0, ELum = 0;
675 if (E_total > m_ECLBurstThreshold) {
676 E_burst = 0x01;
677 }
678
679 if (E_phys > m_TotalEnergy[0]) { // GeV
680 ELow = 0x01;
681 }
682 if (E_phys > m_TotalEnergy[1]) { // GeV
683 EHigh = 0x01;
684 }
685 if (E_phys > m_TotalEnergy[2]) { // GeV
686 ELum = 0x01;
687 }
688 //--------------
689 // Clustering
690 //--------------
691 m_obj_cluster->initialize();
692 m_obj_cluster->setClusteringMethod(m_Clustering);
693 m_obj_cluster->setClusterLimit(m_ClusterLimit);
694 m_obj_cluster->setEventId(m_nEvent);
695 m_obj_cluster->setICN(m_HitTCId, m_TCHitEnergy, m_TCHitTiming);// Clustering
696 m_obj_cluster->setICN(m_HitTCId); // Belle Cluster Counting
697
698 int icn = m_obj_cluster->getICNFwBr();
699 int icnfwd = m_obj_cluster->getICNSub(0);
700 int icnbr = m_obj_cluster->getICNSub(1);
701 int icnbwd = m_obj_cluster->getICNSub(2);
702
703 int NofCluster1to17 = m_obj_cluster->getNofCluster();
704 //--------------
705 // Bhabha veto (and mumu and tau b2b trigger)
706 //--------------
707 setBhabhaParameter();
708
709 std::vector<double> vct_bhabha;
710 vct_bhabha.clear();
711 int bhabha2D = 0 ;
712 int bhabha3D_veto = 0 ;
713 int bhabha3D_sel = 0;
714 int mumu = 0;
715 int bhabha3DVetoInTrackFlag = -1;
716 int bhabha3DSelectionThetaFlag = -1;
717 int taub2bFlag = 0;
718 int taub2b2Flag = 0;
719 int taub2b3Flag = 0;
720
721 bool b_2Dbhabha = m_obj_bhabha->getBhabha00(phiringsum);
722 vct_bhabha = m_obj_bhabha->getBhabhaComb();
723 if (b_2Dbhabha && (icn < 4)) {bhabha2D = 1;}
724 bool b_3Dbhabha = m_obj_bhabha->getBhabha01();
725 if (b_3Dbhabha) {bhabha3D_veto = 1;}
726 bool b_3Dbhabha_sel = m_obj_bhabha->getBhabha02();
727 if (b_3Dbhabha_sel) {bhabha3D_sel = 1;}
728 bool b_mumu = m_obj_bhabha->getmumu();
729 if (b_mumu) {mumu = 1;}
730 int bhabhaprescale = 0;
731 if (m_PrescaleFactor == m_PrescaleCounter) {
732 bhabhaprescale = 1;
733 m_PrescaleCounter = 0;
734 } else if (m_PrescaleFactor > m_PrescaleCounter) {
735 m_PrescaleCounter ++;
736 }
737 bhabha3DVetoInTrackFlag = m_obj_bhabha->get3DBhabhaVetoInTrackFlag();
738 bhabha3DSelectionThetaFlag = m_obj_bhabha->get3DBhabhaSelectionThetaFlag();
739 taub2bFlag = (m_obj_bhabha->getTaub2b(E_total)) ? 1 : 0;
740 taub2b2Flag = (m_obj_bhabha->getTaub2b2(E_total)) ? 1 : 0;
741 taub2b3Flag = (m_obj_bhabha->getTaub2b3(E_total)) ? 1 : 0;
742
743 //------------------------
744 // additional Bhabha veto
745 //------------------------
746 int bhabha_addition = m_obj_bhabha->getBhabhaAddition();
747 //------------------------
748 // hie with additional Bhabha veto
749 //------------------------
750 int beambkgtag = 0;
751 beambkgtag = m_obj_beambkg->getBeamBkg(thetaringsum);
752
753 int bit_hie_bhav = 0;
754 if (E_phys > 1.0) {
755 bit_hie_bhav |= (~bhabha_addition & 0x01) & (~bhabha_addition >> 4 & 0x01); // hie4
756 bit_hie_bhav <<= 1;
757 bit_hie_bhav |= (~bhabha_addition & 0x01) & (~bhabha_addition >> 3 & 0x01); // hie3
758 bit_hie_bhav <<= 1;
759 bit_hie_bhav |= (~bhabha_addition & 0x01) & (~bhabha_addition >> 2 & 0x01); // hie2
760 bit_hie_bhav <<= 1;
761 bit_hie_bhav |= (~bhabha_addition & 0x01) & (~bhabha_addition >> 1 & 0x01); // hie1
762 }
763 //--------------
764 // Low Multiplicity bit
765 //--------------
766 std::vector<double> ClusterTiming;
767 std::vector<double> ClusterEnergy;
768 std::vector<int> MaxTCId;
769 std::vector<int> MaxThetaId;
770 ClusterTiming.clear();
771 ClusterEnergy.clear();
772 MaxTCId.clear();
773 MaxThetaId.clear();
774 StoreArray<TRGECLCluster> trgeclClusterArray;
775 for (int ii = 0; ii < trgeclClusterArray.getEntries(); ii++) {
776 TRGECLCluster* aTRGECLCluster = trgeclClusterArray[ii];
777 int maxTCId = aTRGECLCluster->getMaxTCId();
778 int maxThetaId = aTRGECLCluster->getMaxThetaId();
779 double clusterenergy = aTRGECLCluster->getEnergyDep();
780 double clustertiming = aTRGECLCluster->getTimeAve();
781 ClusterTiming.push_back(clustertiming);
782 ClusterEnergy.push_back(clusterenergy);
783 MaxTCId.push_back(maxTCId);
784 MaxThetaId.push_back(maxThetaId);
785 }
786 makeLowMultiTriggerBit(MaxTCId, ClusterEnergy, bhabha3D_veto);
787 //-------------
788 // Make ECL Trigger Bit
789 //-------------
790 int hit = 1; // hit or not
791 int Timing = (int)(eventtiming + 0.5);
792 int RevoFAM = 0;
793 int TimingSource = m_obj_timing->getTimingSource(); // FWD(0), Barrel(0), Backward(0);
794 int etot = (int)(E_phys * 1000 + 0.5); // total Energy in theta ID [2~15]
795
796 //int bhabha2D = BtoBTag ;
797 int physics = 0;
798 if ((etot > 1000 || icn > 3) && !(bhabha2D == 1)) {physics = 1;}
799 std::vector<int> bhabhabit;
800 bhabhabit.clear();
801 int bhabhabitsize = vct_bhabha.size();
802 for (int ibhabha = 0; ibhabha < bhabhabitsize; ibhabha++) {
803 bhabhabit.push_back((int)vct_bhabha[ibhabha]);
804 }
805 int ClusterOverflow = m_obj_cluster->getNofExceedCluster();
806 int flagoverflow = 0;
807 if (ClusterOverflow > 0) {
808 flagoverflow = 1;
809 }
810
811 makeTriggerBit(hit, Timing, 0, timingsource, E_phys, ELow, EHigh, ELum,
812 bhabha2D, physics, bhabhabit, icn, beambkgtag, flagoverflow,
813 bhabha3D_veto, m_Lowmultibit, bhabha3D_sel, mumu,
814 bhabhaprescale, E_burst,
815 EventTimingQualityFlag,
816 bhabha3DVetoInTrackFlag,
817 bhabha3DSelectionThetaFlag,
818 taub2bFlag,
819 bit_hie_bhav,
820 taub2b2Flag,
821 taub2b3Flag);
822
823 //----------------------------------------------------
824 // ECL trigger
825 //----------------------------------------------------
826 // Integer GDL "Output word to GDL:"
827 // "bit0-2 = Etot1,2,3"
828 // "bit3 = Bhabha,"
829 // "bit4 = prescaled Bhabha,"
830 // "bit5-8 = ICN(3bits)+FORWARD(1bit) OR ICN(3+1 carry),"
831 // "bit9 = cosmic,"
832 // "bit10 = neutral timing trigger"
833 //
834 //------------------------------
835 // 2 10 16
836 //------------------------------
837 // 1 0000000000001 1 1 Etot1
838 // 2 0000000000010 2 2 Etot2
839 // 3 0000000000100 4 4 Etot3
840 // 4 0000000001000 8 8 Bhabha
841 // 5 0000000010000 16 10 preBhabha
842 // 6 0000000100000 32 20 ICN
843 // 7 0000001000000 64 40 ICN
844 // 8 0000010000000 128 80 ICN
845 // 9 0000100000000 256 100 ForwardICN
846 // 10 0001000000000 512 200 BeamBkgVeto
847 // 11 0010000000000 1024 400 Timing
848 //------------------------------
849 // int bitEtot1 = 0x0001;
850 // int bitEtot2 = 0x0002;
851 // int bitEtot3 = 0x0004;
852 // int bitBhabha = 0x0008;
853 // int bitPreBhabha = 0x0010;
854 // int bitForwardICN = 0x0100;
855 // int bitBeamBkgVeto = 0x0200;
856 // int bitTiming = 0x0400;
857
858 // bool boolEtot[3] = {false};
859 // if (E_phys > 1.0) boolEtot[1] = true;
860 // bool boolBhabha = (boolBtoBTag && icn > 4);
861 // bool boolPreBhabha = false;
862 // bool boolForwardICN = icnfwd;
863 // bool boolBeamBkgVeto = boolBeamBkgTag;
864 // int bit = 0;
865 // //
866 // // bit 5-7
867 // bit = (icn >= 7) ? 0x0007 : icn;
868 // bit <<= 5;
869 // // bit 0
870 // bit |= boolEtot[0] ? bitEtot1 : 0;
871 // // bit 1
872 // bit |= boolEtot[1] ? bitEtot2 : 0;
873 // // bit 2
874 // bit |= boolEtot[2] ? bitEtot3 : 0;
875 // // bit 3
876 // bit |= boolBhabha ? bitBhabha : 0;
877 // // bit 4
878 // bit |= boolPreBhabha ? bitPreBhabha : 0;
879 // // bit 8
880 // bit |= boolForwardICN ? bitForwardICN : 0;
881 // // bit 9
882 // bit |= boolBeamBkgVeto ? bitBeamBkgVeto : 0;
883 // // bit 10
884 // bit |= bitTiming;
885
886
887 int m_hitEneNum = 0;
888 StoreArray<TRGECLTrg> trgEcltrgArray;
889 trgEcltrgArray.appendNew();
890 m_hitEneNum = trgEcltrgArray.getEntries() - 1;
891 //----------------------------------------------------
892 // Store
893 //----------------------------------------------------
894 trgEcltrgArray[m_hitEneNum]->setEventId(m_nEvent);
895 trgEcltrgArray[m_hitEneNum]->setPRS01(phiringsum[0]);
896 trgEcltrgArray[m_hitEneNum]->setPRS02(phiringsum[1]);
897 trgEcltrgArray[m_hitEneNum]->setPRS03(phiringsum[2]);
898 trgEcltrgArray[m_hitEneNum]->setPRS04(phiringsum[3]);
899 trgEcltrgArray[m_hitEneNum]->setPRS05(phiringsum[4]);
900 trgEcltrgArray[m_hitEneNum]->setPRS06(phiringsum[5]);
901 trgEcltrgArray[m_hitEneNum]->setPRS07(phiringsum[6]);
902 trgEcltrgArray[m_hitEneNum]->setPRS08(phiringsum[7]);
903 trgEcltrgArray[m_hitEneNum]->setPRS09(phiringsum[8]);
904 trgEcltrgArray[m_hitEneNum]->setPRS10(phiringsum[9]);
905 trgEcltrgArray[m_hitEneNum]->setPRS11(phiringsum[10]);
906 trgEcltrgArray[m_hitEneNum]->setPRS12(phiringsum[11]);
907 trgEcltrgArray[m_hitEneNum]->setPRS13(phiringsum[12]);
908 trgEcltrgArray[m_hitEneNum]->setPRS14(phiringsum[13]);
909 trgEcltrgArray[m_hitEneNum]->setPRS15(phiringsum[14]);
910 trgEcltrgArray[m_hitEneNum]->setPRS16(phiringsum[15]);
911 trgEcltrgArray[m_hitEneNum]->setPRS17(phiringsum[16]);
912 //
913 trgEcltrgArray[m_hitEneNum]->setEtot(E_phys);
914 trgEcltrgArray[m_hitEneNum]->setNofTCHit(noftchit);
915 //
916 trgEcltrgArray[m_hitEneNum]->setBhabha01(vct_bhabha[0]);
917 trgEcltrgArray[m_hitEneNum]->setBhabha02(vct_bhabha[1]);
918 trgEcltrgArray[m_hitEneNum]->setBhabha03(vct_bhabha[2]);
919 trgEcltrgArray[m_hitEneNum]->setBhabha04(vct_bhabha[3]);
920 trgEcltrgArray[m_hitEneNum]->setBhabha05(vct_bhabha[4]);
921 trgEcltrgArray[m_hitEneNum]->setBhabha06(vct_bhabha[5]);
922 trgEcltrgArray[m_hitEneNum]->setBhabha07(vct_bhabha[6]);
923 trgEcltrgArray[m_hitEneNum]->setBhabha08(vct_bhabha[7]);
924 trgEcltrgArray[m_hitEneNum]->setBhabha09(vct_bhabha[8]);
925 trgEcltrgArray[m_hitEneNum]->setBhabha10(vct_bhabha[9]);
926 trgEcltrgArray[m_hitEneNum]->setBhabha11(vct_bhabha[10]);
927 trgEcltrgArray[m_hitEneNum]->setBhabha12(vct_bhabha[11]);
928 trgEcltrgArray[m_hitEneNum]->setBhabha13(vct_bhabha[12]);
929 trgEcltrgArray[m_hitEneNum]->setBhabha14(vct_bhabha[13]);
930 trgEcltrgArray[m_hitEneNum]->setBhabha15(vct_bhabha[14]);
931 trgEcltrgArray[m_hitEneNum]->setBhabha16(vct_bhabha[15]);
932 trgEcltrgArray[m_hitEneNum]->setBhabha17(vct_bhabha[16]);
933 trgEcltrgArray[m_hitEneNum]->setBhabha18(vct_bhabha[17]);
934 //
935 trgEcltrgArray[m_hitEneNum]->setICN(icn);
936 trgEcltrgArray[m_hitEneNum]->setICNFw(icnfwd);
937 trgEcltrgArray[m_hitEneNum]->setICNBr(icnbr);
938 trgEcltrgArray[m_hitEneNum]->setICNBw(icnbwd);
939 //
940 trgEcltrgArray[m_hitEneNum]->setECLtoGDL(m_Triggerbit[0], 0);
941 trgEcltrgArray[m_hitEneNum]->setECLtoGDL(m_Triggerbit[1], 1);
942 trgEcltrgArray[m_hitEneNum]->setECLtoGDL(m_Triggerbit[2], 2);
943 trgEcltrgArray[m_hitEneNum]->setECLtoGDL(m_Triggerbit[3], 3);
944
945 trgEcltrgArray[m_hitEneNum]->setBhabhaVeto(bhabha2D);
946 trgEcltrgArray[m_hitEneNum]->setBeamBkgVeto(beambkgtag);
947 trgEcltrgArray[m_hitEneNum]->setEventTiming(eventtiming);
948
949 trgEcltrgArray[m_hitEneNum]->setHit(hit);
950 trgEcltrgArray[m_hitEneNum]->setRevoclk(RevoFAM);
951 trgEcltrgArray[m_hitEneNum]->setTimingSource(TimingSource);
952 trgEcltrgArray[m_hitEneNum]->setPhysics(physics) ;
953 trgEcltrgArray[m_hitEneNum]->set2DBhabha(bhabha2D);
954 trgEcltrgArray[m_hitEneNum]->set3DBhabha(bhabha3D_veto);
955 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSel(bhabha3D_sel);
956 trgEcltrgArray[m_hitEneNum]->setmumuBit(mumu);
957 trgEcltrgArray[m_hitEneNum]->setBhabhaPrescaleBit(bhabhaprescale);
958
959 trgEcltrgArray[m_hitEneNum]->setELow(ELow) ;
960 trgEcltrgArray[m_hitEneNum]->setEHihg(EHigh);
961 trgEcltrgArray[m_hitEneNum]->setELum(ELum) ;
962 trgEcltrgArray[m_hitEneNum]->setClusterOverflow(ClusterOverflow) ;
963 trgEcltrgArray[m_hitEneNum]->setLowMultiBit(m_Lowmultibit);
964
965 trgEcltrgArray[m_hitEneNum]->set3DBhabhaVetoInTrackFlag(m_obj_bhabha->get3DBhabhaVetoInTrackFlag());
966 trgEcltrgArray[m_hitEneNum]->set3DBhabhaVetoClusterTCId(m_obj_bhabha->get3DBhabhaVetoClusterTCId(0), 0);
967 trgEcltrgArray[m_hitEneNum]->set3DBhabhaVetoClusterTCId(m_obj_bhabha->get3DBhabhaVetoClusterTCId(1), 1);
968 trgEcltrgArray[m_hitEneNum]->set3DBhabhaVetoClusterEnergy(m_obj_bhabha->get3DBhabhaVetoClusterEnergy(0), 0);
969 trgEcltrgArray[m_hitEneNum]->set3DBhabhaVetoClusterEnergy(m_obj_bhabha->get3DBhabhaVetoClusterEnergy(1), 1);
970 trgEcltrgArray[m_hitEneNum]->set3DBhabhaVetoClusterTiming(m_obj_bhabha->get3DBhabhaVetoClusterTiming(0), 0);
971 trgEcltrgArray[m_hitEneNum]->set3DBhabhaVetoClusterTiming(m_obj_bhabha->get3DBhabhaVetoClusterTiming(1), 1);
972 trgEcltrgArray[m_hitEneNum]->set3DBhabhaVetoClusterThetaId(m_obj_bhabha->get3DBhabhaVetoClusterThetaId(0), 0);
973 trgEcltrgArray[m_hitEneNum]->set3DBhabhaVetoClusterThetaId(m_obj_bhabha->get3DBhabhaVetoClusterThetaId(1), 1);
974
975 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSelectionThetaFlag(m_obj_bhabha->get3DBhabhaSelectionThetaFlag());
976 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSelectionClusterTCId(m_obj_bhabha->get3DBhabhaSelectionClusterTCId(0), 0);
977 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSelectionClusterTCId(m_obj_bhabha->get3DBhabhaSelectionClusterTCId(1), 1);
978 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSelectionClusterEnergy(m_obj_bhabha->get3DBhabhaSelectionClusterEnergy(0), 0);
979 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSelectionClusterEnergy(m_obj_bhabha->get3DBhabhaSelectionClusterEnergy(1), 1);
980 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSelectionClusterTiming(m_obj_bhabha->get3DBhabhaSelectionClusterTiming(0), 0);
981 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSelectionClusterTiming(m_obj_bhabha->get3DBhabhaSelectionClusterTiming(1), 1);
982 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSelectionClusterThetaId(m_obj_bhabha->get3DBhabhaSelectionClusterThetaId(0), 0);
983 trgEcltrgArray[m_hitEneNum]->set3DBhabhaSelectionClusterThetaId(m_obj_bhabha->get3DBhabhaSelectionClusterThetaId(1), 1);
984
985 trgEcltrgArray[m_hitEneNum]->setEventTimingQualityFlag(m_obj_timing->getEventTimingQualityFlag());
986 trgEcltrgArray[m_hitEneNum]->setEventTimingTCId(m_obj_timing->getEventTimingTCId());
987 trgEcltrgArray[m_hitEneNum]->setEventTimingTCThetaId(m_obj_timing->getEventTimingTCThetaId());
988 trgEcltrgArray[m_hitEneNum]->setEventTimingTCEnergy(m_obj_timing->getEventTimingTCEnergy());
989
990 trgEcltrgArray[m_hitEneNum]->setEtot1to17(E_total);
991 trgEcltrgArray[m_hitEneNum]->setTaub2bFlag(taub2bFlag);
992 trgEcltrgArray[m_hitEneNum]->setTaub2bAngleFlag(m_obj_bhabha->getTaub2bAngleFlag());
993 trgEcltrgArray[m_hitEneNum]->setTaub2bEtotFlag(m_obj_bhabha->getTaub2bEtotFlag());
994 trgEcltrgArray[m_hitEneNum]->setTaub2bClusterEFlag(m_obj_bhabha->getTaub2bClusterEFlag());
995
996 trgEcltrgArray[m_hitEneNum]->setNofCluster1to17(NofCluster1to17);
997
998 trgEcltrgArray[m_hitEneNum]->setDataClockWindowStartTime(WindowStart);
999
1000 return;
1001}
1002//========================================================
1003//
1004//========================================================
1005void
1006TrgEclMaster::setRS(std::vector<int> TCId,
1007 std::vector<double> TCHit,
1008 std::vector<double>& phiringsum,
1009 std::vector<std::vector<double>>& thetaringsum)
1010{
1011 //
1012 //
1013 // TC Phi & Theta ring sum
1014 //
1015 //----------------------------------------
1016 // FW BR BW total
1017 //----------------------------------------
1018 //TC phi ring 3 12 2 17
1019 //ID 1-3 4-15 16-17
1020 //TC Theta ring 32 36 32
1021 //ID 1-32 1-36 1-32
1022
1023 //----------------------------------------
1024 //
1025 thetaringsum.resize(3, std::vector<double>(36, 0.));
1026 phiringsum.resize(17);
1027 const int size_hit = TCHit.size();
1028 for (int iHit = 0; iHit < size_hit; iHit++) {
1029 int iTCId = TCId[iHit] - 1;
1030 if (TCHit[iHit] > 0) {
1031 int iTCThetaId = m_obj_map->getTCThetaIdFromTCId(iTCId + 1) - 1 ;
1032 int iTCPhiId = m_obj_map->getTCPhiIdFromTCId(iTCId + 1) - 1 ;
1033 phiringsum[iTCThetaId] += TCHit[iHit];
1034 if (iTCThetaId < 3) {
1035 //fwd
1036 if (iTCThetaId != 0) {
1037 thetaringsum[0][iTCPhiId] += TCHit[iHit];
1038 }
1039 } else if (iTCThetaId < 15) {
1040 //barrel
1041 thetaringsum[1][iTCPhiId] += TCHit[iHit];
1042 } else {
1043 //bwd
1044 thetaringsum[2][iTCPhiId] += TCHit[iHit];
1045 }
1046
1047 }
1048
1049 }
1050
1051}
1052//========================================================
1053//
1054//========================================================
1055void
1056TrgEclMaster::makeTriggerBit(int hit, int Timing, int RevoFAM, int TimingSource,
1057 double etot, int elow, int ehigh, int elum,
1058 int bhabha2D, int physics,
1059 std::vector<int> bhabhatype, int ICN, int BGVeto,
1060 int ClusterOverflow, int bhabha3D, int lowmultibit,
1061 int bhabha3D_sel, int mumubit, int prescale, int burst,
1062 int EventTimingQualityFlag, int bhabha3DVetoInTrackFlag,
1063 int bhabha3DSelectionThetaFlag,
1064 int taub2bFlag,
1065 int bit_hie_bhav,
1066 int taub2b2Flag,
1067 int taub2b3Flag)
1068{
1069
1070 m_Triggerbit[0] = 0;
1071 m_Triggerbit[1] = 0;
1072 m_Triggerbit[2] = 0;
1073 m_Triggerbit[3] = 0;
1074
1075 int bhabhaveto = 0;
1076 int Bhabhatype = bhabha2D;
1077
1078 if (bhabhatype.size() > 14) {
1079 for (int ibhabha = 0; ibhabha < 13; ibhabha++) {
1080 int type = 0x00;
1081 if (bhabhatype[ibhabha] == 1) {type = 0x01;}
1082
1083 Bhabhatype |= type;
1084 Bhabhatype <<= 1;
1085
1086 }
1087 }
1088
1089 int bit_hit = hit & 0x01;
1090 int bit_Timing = (Timing & 0x7F) ;
1091 int bit_RevoFAM = (RevoFAM & 0x7F) ;
1092 int bit_TimingSource = (TimingSource & 0x07) ;
1093 int bit_physics = (physics & 0x01) ;
1094 int bit_2Dbhabha = (bhabhaveto & 0x01) ;
1095 int bit_bhabhatype = (Bhabhatype & 0x3FFF);
1096 int bit_etot = (((int)etot) & 0x1FFF) ;
1097 int bit_elow = (elow & 0x01);
1098 int bit_ehigh = (ehigh & 0x01) ;
1099 int bit_elum = (elum & 0x01) ;
1100 int bit_ICN = (ICN & 0x7F) ;
1101 int bit_BGVeto = (BGVeto & 0x07) ;
1102 int bit_ClusterOverflow = (ClusterOverflow & 0x01);
1103 int bit_3Dbhabha = (bhabha3D & 0x01);
1104
1105 int bit_lowmulti1 = lowmultibit & 0x0FFF;
1106 int bit_lowmulti2 = (lowmultibit >>= 12) & 0x3;
Although the value stored to 'lowmultibit' is used in the enclosing expression, the value is never actually read from 'lowmultibit'
1107 int bit_3DBhabha_sel = bhabha3D_sel & 0x01;
1108 int bit_mumu = mumubit & 0x01;
1109 int bit_prescale = prescale & 0x01;
1110 int bit_burst = burst & 0x01;
1111 int bit_clkcc = 0; // 4 bits for revo counter (set to be 0 in tsim)
1112 int bit_eventtimingqualityflag = EventTimingQualityFlag & 0x03;
1113 int bit_bhabha3dvetointrackflag = 0;
1114 if (bhabha3D == 1) {
1115 bit_bhabha3dvetointrackflag = bhabha3DVetoInTrackFlag & 0x01;
1116 }
1117 int bit_bhabha3dselectionthetaflag = 0;
1118 if (bhabha3D_sel == 1) {
1119 bit_bhabha3dselectionthetaflag = bhabha3DSelectionThetaFlag & 0x03;
1120 }
1121 int bit_taub2bflag = taub2bFlag & 0x01;
1122 int bit_taub2b2flag = taub2b2Flag & 0x01;
1123 int bit_taub2b3flag = taub2b3Flag & 0x01;
1124
1125 int bit_hie_bhav_hie123 = bit_hie_bhav & 0x7; // for hie1, hie2, hie3
1126 int bit_hie_bhav_hie4 = (bit_hie_bhav >> 3) & 0x1; // for hie4
1127
1128 m_Triggerbit[2] |= bit_hie_bhav_hie4;
1129 m_Triggerbit[2] <<= 1;
1130 m_Triggerbit[2] |= bit_taub2b3flag;
1131 m_Triggerbit[2] <<= 1;
1132 m_Triggerbit[2] |= bit_taub2b2flag;
1133 m_Triggerbit[2] <<= 3;
1134 m_Triggerbit[2] |= bit_hie_bhav_hie123;
1135 m_Triggerbit[2] <<= 1;
1136 m_Triggerbit[2] |= bit_taub2bflag;
1137 m_Triggerbit[2] <<= 2;
1138 m_Triggerbit[2] |= bit_bhabha3dselectionthetaflag;
1139 m_Triggerbit[2] <<= 1;
1140 m_Triggerbit[2] |= bit_bhabha3dvetointrackflag;
1141 m_Triggerbit[2] <<= 2;
1142 m_Triggerbit[2] |= bit_eventtimingqualityflag;
1143 m_Triggerbit[2] <<= 4;
1144 m_Triggerbit[2] |= bit_clkcc;
1145 m_Triggerbit[2] <<= 2;
1146 m_Triggerbit[2] |= bit_lowmulti2;
1147 m_Triggerbit[2] <<= 1;
1148 m_Triggerbit[2] |= bit_burst;
1149 m_Triggerbit[2] <<= 1;
1150 m_Triggerbit[2] |= bit_prescale;
1151 m_Triggerbit[2] <<= 1;
1152 m_Triggerbit[2] |= bit_mumu;
1153 m_Triggerbit[2] <<= 1;
1154 m_Triggerbit[2] |= bit_3DBhabha_sel;
1155 m_Triggerbit[2] <<= 10;
1156 m_Triggerbit[2] |= ((bit_lowmulti1) >> 2) & 0x3FF;
1157
1158 m_Triggerbit[1] |= (bit_lowmulti1 & 0x03);
1159 m_Triggerbit[1] <<= 1;
1160 m_Triggerbit[1] |= bit_3Dbhabha;
1161 m_Triggerbit[1] <<= 1;
1162 m_Triggerbit[1] |= bit_ClusterOverflow;
1163 m_Triggerbit[1] <<= 3;
1164 m_Triggerbit[1] |= bit_BGVeto;
1165 m_Triggerbit[1] <<= 7;
1166 m_Triggerbit[1] |= bit_ICN;
1167 m_Triggerbit[1] <<= 1;
1168 m_Triggerbit[1] |= bit_elum;
1169 m_Triggerbit[1] <<= 1;
1170 m_Triggerbit[1] |= bit_ehigh;
1171 m_Triggerbit[1] <<= 1;
1172 m_Triggerbit[1] |= bit_elow;
1173 m_Triggerbit[1] <<= 13;
1174 m_Triggerbit[1] |= bit_etot;
1175 m_Triggerbit[1] <<= 2;
1176 m_Triggerbit[1] |= ((bit_bhabhatype >> 12) & 0x03);
1177
1178 m_Triggerbit[0] |= (bit_bhabhatype & 0x0FFF);
1179 m_Triggerbit[0] <<= 1;
1180 m_Triggerbit[0] |= bit_2Dbhabha;
1181 m_Triggerbit[0] <<= 1;
1182 m_Triggerbit[0] |= bit_physics;
1183 m_Triggerbit[0] <<= 3;
1184 m_Triggerbit[0] |= bit_TimingSource;
1185 m_Triggerbit[0] <<= 7;
1186 m_Triggerbit[0] |= bit_RevoFAM;
1187 m_Triggerbit[0] <<= 7;
1188 m_Triggerbit[0] |= bit_Timing;
1189 m_Triggerbit[0] <<= 1;
1190 m_Triggerbit[0] |= bit_hit;
1191
1192}
1193//
1194//
1195//
1196void
1197TrgEclMaster::makeLowMultiTriggerBit(std::vector<int> CenterTCId,
1198 std::vector<double> clusterenergy,
1199 int Bhabha3DVeto)
1200{
1201
1202 //----------------------------------------------------------------------------
1203 // ECL trigger
1204 //----------------------------------------------------------------------------
1205 // Variable in tsim is m_Lowmultibit
1206 //----------------------------------------------------------------------------
1207 // N |Address| documentation
1208 // (bit)|in FW |
1209 //----------------------------------------------------------------------------
1210 // 1 | 62 |(lml0) N Cluster >= 3, at least one Cluster >300 MeV (LAB), not 3D ECL Bhabha
1211 // 1 | 63 |(lml1) one Cluster >= 2GeV(CM) with Theta Id = 4~14
1212 // 1 | 64 |(lml2) one Cluster >= 2GeV(CM) with Theta Id = 2,3,15 or 16 and not a 3D ECL Bhabha
1213 // 1 | 65 |(lml3) one Cluster >= 2GeV(CM) with Theta Id = 2, 3, 15 or 16 and not a 3D ECL Bhabha
1214 // 1 | 66 |(lml4) one Cluster >= 2GeV(CM) with Theta Id = 1 or 17 and not a 3D ECL Bhabha
1215 // 1 | 67 |(lml5) one Cluster >= 2GeV(CM) with Theta Id = 1 or 17 and a 3D ECL Bhabha
1216 // 1 | 68 |(lml6) exactly one Cluster >= 1GeV(CM) and one Cluster > 300 MeV (LAB ), in Theta Id 4~15(Barrel)
1217 // 1 | 69 |(lml7) exactly one Cluster >= 1GeV(CM) and one Cluster > 300 MeV (LAB), in Theta Id 2, 3 or 16
1218 // 1 | 70 |(lml8) 170 < delta phi(CM) < 190 degree, both Clusters > 250 MeV (LAB), and no 2GeV (CM) Cluster
1219 // 1 | 71 |(lml9) 170 < delta phi(CM) < 190 degree, one Cluster < 250 MeV (LAB), the other Cluster > 250 MeV(LAB), and no 2GeV (CM) Cluster
1220 // 1 | 72 |(lml10) 160 < delta phi(CM) < 200 degree, 160 < Sum Theta (CM)< 200 degree, no 2 GeV(CM) cluster
1221 // 1 | 73 |(lml11) No 2GeV (CM) Cluster
1222 // 1 | 78 |(lml12) N Cluster >= 3, at least one Cluster >500 MeV (LAB) with Theta Id 2~16, not 3D ECL Bhabha
1223 // 1 | 79 |(lml13) Only one Cluster >500 MeV (CM) with Theta Id 6~11 and no other CL >= 300 MeV(LAB) anywhere
1224 //----------------------------------------------------------------------------
1225 m_Lowmultibit = 0;
1226 int _nClust = CenterTCId.size();
1227 int _n300MeV = 0;
1228 int _n2GeV = 0;
1229 int _n2GeV414 = 0;
1230 int _n2GeV231516 = 0;
1231 int _n2GeV117 = 0;
1232 int _n1GeV415 = 0;
1233 int _n1GeV2316 = 0;
1234 int _nClust216 = 0;
1235 int _n500MeV216 = 0;
1236 int _n500MeV611 = 0;
1237 for (int ic = 0; ic < _nClust; ic++) {
1238 if (clusterenergy[ic] > m_lmlCLELabCut[1]) {
1239 _n300MeV++;
1240 }
1241 int thetaid = m_obj_map->getTCThetaIdFromTCId(CenterTCId[ic]);
1242 int lut = m_obj_database->get3DBhabhaLUT(CenterTCId[ic]);
1243 double thresh = 0.1 * (double)(15 & lut);
1244 if (thetaid >= 2 && thetaid <= 16) {_nClust216++;}
1245
1246 // lml13ThetaIdBit is decimal, but indicates thetaID with binary
1247 // In lml13ThetaIdBit = 2016 case, (thetaID 17 to 1) = 0 0000 0111 1110 0000
1248 int lml13ThetaIdBit = (m_lml13ThetaIdSelection >> (thetaid - 1)) & 0x1;
1249 if (lml13ThetaIdBit == 1) {
1250 if (clusterenergy[ic] > thresh * m_lmlCLECMSCut[2]) {
1251 _n500MeV611++;
1252 }
1253 }
1254 // lml12
1255 if (clusterenergy[ic] > m_lmlCLELabCut[0] &&
1256 thetaid >= 2 &&
1257 thetaid <= 16) {
1258 _n500MeV216++;
1259 }
1260
1261 if (clusterenergy[ic] > thresh * m_lmlCLECMSCut[0]) { // GeV
1262 _n2GeV++;
1263 if (thetaid >= 4 && thetaid <= 14) {_n2GeV414++;}
1264 if (thetaid == 2 || thetaid == 3 || thetaid == 15 || thetaid == 16) {_n2GeV231516++;}
1265 if (thetaid == 1 || thetaid == 17) {_n2GeV117++;}
1266 }
1267
1268 if (clusterenergy[ic] > thresh * m_lmlCLECMSCut[1]) { // GeV
1269 if (thetaid >= 4 && thetaid <= 15) {_n1GeV415++;}
1270 if (thetaid == 2 || thetaid == 3 || thetaid == 16) {_n1GeV2316++;}
1271 }
1272 }
1273 //---------------------------------------------------------------------
1274 //..Trigger objects using back-to-back ECL clusters, plus Bhabha vetoes
1275 // nPhiPairHigh nPhiPairLow n3DPair nECLBhabha nTrkBhabha
1276
1277 int _nPhiPairHigh = 0;
1278 int _nPhiPairLow = 0;
1279 int _n3DPair = 0;
1280 for (int i0 = 0; i0 < _nClust - 1; i0++) {
1281 for (int i1 = i0 + 1; i1 < _nClust; i1++) {
1282
1283 int lut1 = m_obj_database->get3DBhabhaLUT(CenterTCId[i0]);
1284 int lut2 = m_obj_database->get3DBhabhaLUT(CenterTCId[i1]);
1285
1286 lut1 >>= 4;
1287 lut2 >>= 4;
1288 int phi1 = 511 & lut1;
1289 int phi2 = 511 & lut2;
1290 lut1 >>= 9;
1291 lut2 >>= 9;
1292 int theta1 = lut1;
1293 int theta2 = lut2;
1294
1295 //..back to back in phi
1296 int dphi = abs(phi1 - phi2);
1297 if (dphi > 180) {dphi = 360 - dphi;}
1298 int thetaSum = theta1 + theta2;
1299
1300 // lml8
1301 if (dphi > 170. &&
1302 clusterenergy[i0] > m_lmlCLELabCut[2] &&
1303 clusterenergy[i1] > m_lmlCLELabCut[2]) {
1304 _nPhiPairHigh++;
1305 }
1306 // lml9
1307 if (dphi > 170. &&
1308 ((clusterenergy[i0] < m_lmlCLELabCut[2] &&
1309 clusterenergy[i1] > m_lmlCLELabCut[2]) ||
1310 (clusterenergy[i0] > m_lmlCLELabCut[2] &&
1311 clusterenergy[i1] < m_lmlCLELabCut[2]))) {
1312 _nPhiPairLow++;
1313 }
1314 // lml10
1315 if (dphi > 160. &&
1316 thetaSum > 160. &&
1317 thetaSum < 200) {
1318 _n3DPair++;
1319 }
1320 }
1321 }
1322
1323 int bitlml0 = 0;
1324 int bitlml1 = 0;
1325 int bitlml2 = 0;
1326 int bitlml3 = 0;
1327 int bitlml4 = 0;
1328 int bitlml5 = 0;
1329 int bitlml6 = 0;
1330 int bitlml7 = 0;
1331 int bitlml8 = 0;
1332 int bitlml9 = 0;
1333 int bitlml10 = 0;
1334 int bitlml11 = 0;
1335 int bitlml12 = 0;
1336 int bitlml13 = 0;
1337
1338 if (_nClust >= 3 &&
1339 _n300MeV >= m_lml00NCLforMinE &&
1340 Bhabha3DVeto == 0) {
1341 bitlml0 = 0x01;
1342 }
1343 if (_n2GeV414 > 0) {
1344 bitlml1 = 0x01;
1345 }
1346 if (_n2GeV231516 && Bhabha3DVeto == 0) {
1347 bitlml2 = 0x01;
1348 }
1349 if (_n2GeV231516 && Bhabha3DVeto != 0) {
1350 bitlml3 = 0x01;
1351 }
1352 if (_n2GeV117 && Bhabha3DVeto == 0) {
1353 bitlml4 = 0x01;
1354 }
1355 if (_n2GeV117 && Bhabha3DVeto != 0) {
1356 bitlml5 = 0x01;
1357 }
1358 if (_n1GeV415 == 1 && _n300MeV == 1) {
1359 bitlml6 = 0x01;
1360 }
1361 if (_n1GeV2316 == 1 && _n300MeV == 1) {
1362 bitlml7 = 0x01;
1363 }
1364 if (_nPhiPairHigh > 0 && _n2GeV == 0) {
1365 bitlml8 = 0x01;
1366 }
1367 if (_nPhiPairLow > 0 && _n2GeV == 0) {
1368 bitlml9 = 0x01;
1369 }
1370 if (_n3DPair > 0 && _n2GeV == 0) {
1371 bitlml10 = 0x01;
1372 }
1373 if (_n2GeV == 0) {
1374 bitlml11 = 0x01;
1375 }
1376 if (_nClust216 >= 3 &&
1377 _n500MeV216 >= m_lml12NCLforMinE &&
1378 Bhabha3DVeto == 0) {
1379 bitlml12 = 0x01;
1380 }
1381 if (_n500MeV611 == 1 && _n300MeV == 1) {
1382 bitlml13 = 0x01;
1383 }
1384
1385 int total_bit = 0;
1386 total_bit |= bitlml13;
1387 total_bit <<= 1;
1388 total_bit |= bitlml12;
1389 total_bit <<= 1;
1390 total_bit |= bitlml11;
1391 total_bit <<= 1;
1392 total_bit |= bitlml10;
1393 total_bit <<= 1;
1394 total_bit |= bitlml9;
1395 total_bit <<= 1;
1396 total_bit |= bitlml8;
1397 total_bit <<= 1;
1398 total_bit |= bitlml7;
1399 total_bit <<= 1;
1400 total_bit |= bitlml6;
1401 total_bit <<= 1;
1402 total_bit |= bitlml5;
1403 total_bit <<= 1;
1404 total_bit |= bitlml4;
1405 total_bit <<= 1;
1406 total_bit |= bitlml3;
1407 total_bit <<= 1;
1408 total_bit |= bitlml2;
1409 total_bit <<= 1;
1410 total_bit |= bitlml1;
1411 total_bit <<= 1;
1412 total_bit |= bitlml0;
1413
1414 m_Lowmultibit = total_bit ;
1415}
1416//
1417//
1418//
1419double TrgEclMaster::setTotalEnergy(std::vector<double> phisum)
1420{
1421
1422 double E_phys = 0;
1423 for (int iii = 0; iii <= 16; iii++) {
1424 if (iii > 0 && iii < 15) {E_phys += phisum[iii];}
1425 }
1426 return E_phys;
1427}
1428//
1429//
1430//
1431void TrgEclMaster::setBhabhaParameter(void)
1432{
1433
1434 m_obj_bhabha->set2DBhabhaThreshold(m_2DBhabhaThresholdFWD,
1435 m_2DBhabhaThresholdBWD);
1436
1437 m_obj_bhabha->set3DBhabhaVetoThreshold(m_3DBhabhaVetoThreshold);
1438 m_obj_bhabha->set3DBhabhaVetoAngle(m_3DBhabhaVetoAngle);
1439
1440 m_obj_bhabha->set3DBhabhaSelectionThreshold(m_3DBhabhaSelectionThreshold);
1441 m_obj_bhabha->set3DBhabhaSelectionAngle(m_3DBhabhaSelectionAngle);
1442 m_obj_bhabha->set3DBhabhaSelectionPreScale(m_3DBhabhaSelectionPreScale);
1443
1444 m_obj_bhabha->setmumuThreshold(m_mumuThreshold);
1445 m_obj_bhabha->setmumuAngle(m_mumuAngle);
1446
1447 m_obj_bhabha->set3DBhabhaVetoInTrackThetaRegion(m_3DBhabhaVetoInTrackThetaRegion);
1448
1449 m_obj_bhabha->setTaub2bAngleCut(m_taub2bAngleCut);
1450 m_obj_bhabha->setTaub2bEtotCut(m_taub2bEtotCut);
1451 m_obj_bhabha->setTaub2bCLELabCut(m_taub2bCLELabCut);
1452
1453 m_obj_bhabha->sethie12BhabhaVetoAngle(m_hie12BhabhaVetoAngle);
1454
1455 m_obj_bhabha->setTaub2b2Cut(m_taub2b2AngleCut,
1456 m_taub2b2EtotCut,
1457 m_taub2b2CLELabCut);
1458 m_obj_bhabha->setTaub2b3Cut(m_taub2b3AngleCut,
1459 m_taub2b3EtotCut,
1460 m_taub2b3CLEb2bLabCut,
1461 m_taub2b3CLELabCut);
1462
1463 m_obj_bhabha->sethie4LowCLELabCut(m_hie4LowCLELabCut);
1464
1465}