BOSS 7.0.3
BESIII Offline Software System
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MucCalibMgr Class Reference

#include <MucCalibMgr.h>

Public Member Functions

 MucCalibMgr (std::vector< double > jobInfo, std::vector< int > configInfo, std::string outputFile)
 
 ~MucCalibMgr ()
 
StatusCode InitNtuple ()
 
StatusCode InitHisto ()
 
StatusCode InitArea ()
 
StatusCode DimuSelect ()
 
StatusCode ReadEvent ()
 
StatusCode CheckEvent ()
 
StatusCode FillEvent ()
 
StatusCode AnalyseEffAndNoise ()
 
StatusCode AnalyseCluster ()
 
StatusCode AnalyseRes ()
 
StatusCode SaveConst ()
 
StatusCode EndRun ()
 
 MucCalibMgr (std::vector< double > jobInfo, std::vector< int > configInfo, std::string outputFile)
 
 ~MucCalibMgr ()
 
StatusCode InitNtuple ()
 
StatusCode InitHisto ()
 
StatusCode InitArea ()
 
StatusCode DimuSelect ()
 
StatusCode ReadEvent ()
 
StatusCode CheckEvent ()
 
StatusCode FillEvent ()
 
StatusCode AnalyseEffAndNoise ()
 
StatusCode AnalyseCluster ()
 
StatusCode AnalyseRes ()
 
StatusCode SaveConst ()
 
StatusCode EndRun ()
 

Public Attributes

IMessageSvc * msgSvc
 
INTupleSvc * ntupleSvc
 
IDataProviderSvc * eventSvc
 

Protected Member Functions

StatusCode InitOnlineHisto ()
 
StatusCode InitHistoLV0 ()
 
StatusCode InitHistoLV1 ()
 
StatusCode InitHistoLV2 ()
 
StatusCode Init2DEffHisto ()
 
StatusCode InitClusterHisto ()
 
StatusCode InitResHisto ()
 
StatusCode InitConstTree ()
 
StatusCode FillDigi (int part, int segment, int layer, int strip)
 
StatusCode FillExpHit (int part, int segment, int layer, int strip)
 
StatusCode FillEffHit (int part, int segment, int layer, int strip)
 
StatusCode FillNosHit (int part, int segment, int layer, int strip)
 
StatusCode FillCluster (int part, int segment, int layer, int size)
 
StatusCode EffAndNoiseLV0 ()
 
StatusCode EffAndNoiseLV1 ()
 
StatusCode EffAndNoiseLV2 ()
 
StatusCode PadEff ()
 
StatusCode ClearOnlineHisto ()
 
StatusCode ClearHistoLV0 ()
 
StatusCode ClearHistoLV1 ()
 
StatusCode ClearHistoLV2 ()
 
StatusCode Clear2DEffHisto ()
 
StatusCode ClearClusterHisto ()
 
StatusCode ClearResHisto ()
 
StatusCode ClearConstTree ()
 
StatusCode InitOnlineHisto ()
 
StatusCode InitHistoLV0 ()
 
StatusCode InitHistoLV1 ()
 
StatusCode InitHistoLV2 ()
 
StatusCode Init2DEffHisto ()
 
StatusCode InitClusterHisto ()
 
StatusCode InitResHisto ()
 
StatusCode InitConstTree ()
 
StatusCode FillDigi (int part, int segment, int layer, int strip)
 
StatusCode FillExpHit (int part, int segment, int layer, int strip)
 
StatusCode FillEffHit (int part, int segment, int layer, int strip)
 
StatusCode FillNosHit (int part, int segment, int layer, int strip)
 
StatusCode FillCluster (int part, int segment, int layer, int size)
 
StatusCode EffAndNoiseLV0 ()
 
StatusCode EffAndNoiseLV1 ()
 
StatusCode EffAndNoiseLV2 ()
 
StatusCode PadEff ()
 
StatusCode ClearOnlineHisto ()
 
StatusCode ClearHistoLV0 ()
 
StatusCode ClearHistoLV1 ()
 
StatusCode ClearHistoLV2 ()
 
StatusCode Clear2DEffHisto ()
 
StatusCode ClearClusterHisto ()
 
StatusCode ClearResHisto ()
 
StatusCode ClearConstTree ()
 

Detailed Description

Constructor & Destructor Documentation

◆ MucCalibMgr() [1/2]

MucCalibMgr::MucCalibMgr ( std::vector< double >  jobInfo,
std::vector< int >  configInfo,
std::string  outputFile 
)

Definition at line 65 of file MucCalibMgr.cxx.

66{
67 MsgStream log(msgSvc, "MucCalibMgr");
68 log << MSG::INFO << "-------Initializing------- " << endreq;
69
70 // init Gaudi service
71 log << MSG::INFO << "Initialize Gaudi service" << endreq;
72 Gaudi::svcLocator() -> service("MessageSvc", msgSvc);
73 ntupleSvc = NULL;
74 eventSvc = NULL;
75
76 m_jobStart = clock();
77
78 // init parameters
79 log << MSG::INFO << "Initialize parameters" << endreq;
80
81 m_vs = jobInfo[0]; m_hv = jobInfo[1]; m_th = jobInfo[2];
82
83 if( jobInfo[3] <= 0 ) m_er = TRIGGER_RATE; // 4000Hz
84 else m_er = jobInfo[3];
85
86 if( jobInfo[4] <= 0 || jobInfo[4] >5 ) m_tag = 0;
87 else m_tag = jobInfo[4];
88
89 if( configInfo[0] < 0 || configInfo[0] > 2 )
90 m_recMode = 0;
91 else
92 m_recMode = configInfo[0];
93
94 m_usePad = configInfo[1];
95
96 if( configInfo[2] < 0 || configInfo[2] > STRIP_INBOX_MAX )
97 m_effWindow = EFF_WINDOW; // 4 strip-width
98 else m_effWindow = configInfo[2];
99
100 if( configInfo[3]<0 || configInfo[3] >4 )
101 m_clusterMode = DEFAULT_BUILD_MODE;
102 else m_clusterMode = configInfo[3];
103
104 m_clusterSave = configInfo[4];
105 m_checkEvent = configInfo[5];
106 m_dimuSelect = configInfo[6];
107 m_dimuOnly = configInfo[7];
108
109 m_outputFile = outputFile;
110
111 m_fdata = NULL;
112 if( m_clusterMode ==1 && m_clusterSave == 1 )
113 m_fdata = new ofstream("MucCluster.dat", ios::out);
114
115 m_fStartRun = m_fEndRun = 0;
116 m_currentRun = m_currentEvent = 0;
117 m_eventTag = 0;
118
119 for( int i=0; i<PART_MAX; i++ )
120 for( int j=0; j<SEGMENT_MAX; j++ )
121 for( int k=0; k<LAYER_MAX; k++ )
122 for( int n=0; n<STRIP_INBOX_MAX; n++ )
123 {
124 m_record[i][j][k][n][0] = 0;
125 m_record[i][j][k][n][1] = 0;
126 m_record[i][j][k][n][2] = 0;
127 m_record[i][j][k][n][3] = 0;
128 m_record[i][j][k][n][4] = 0;
129 }
130
131 for( int i=0; i<LAYER_MAX; i++ )
132 {
133 m_layerResults[0][i] = 0;
134 m_layerResults[1][i] = 0;
135 m_layerResults[2][i] = 0;
136 m_layerResults[3][i] = 0;
137 m_layerResults[4][i] = 0;
138 }
139
140 for( int i=0; i<BOX_MAX; i++ )
141 {
142 m_boxResults[0][i] = 0;
143 m_boxResults[1][i] = 0;
144 m_boxResults[2][i] = 0;
145 m_boxResults[3][i] = 0;
146 m_boxResults[4][i] = 0;
147 }
148
149 for( int i=0; i<STRIP_MAX; i++ )
150 {
151 m_stripResults[0][i] = 0;
152 m_stripResults[1][i] = 0;
153 m_stripResults[2][i] = 0;
154 m_stripResults[3][i] = 0;
155 // strip no cluster
156 }
157
158 m_fTotalDAQTime = 0;
159
160 m_ptrMucMark = new MucMark(0,0,0,0);
161 m_ptrIdTr = new MucIdTransform();
162
163 m_digiCol.resize(0);
164 m_calHitCol.resize(0);
165 m_expHitCol.resize(0);
166 m_effHitCol.resize(0);
167 m_nosHitCol.resize(0);
168 m_clusterCol.resize(0);
169
170 for( int i=0; i<PART_MAX; i++ )
171 for( int j=0; j<SEGMENT_MAX; j++ ) {
172 m_segDigiCol[i][j].resize(0);
173 }
174
175 // init Gaudi Ntuple
176 InitNtuple();
177
178 // init ROOT histograms
179 InitHisto();
180
181 // init Tree
182 InitConstTree();
183
184 // init area of units
185 InitArea();
186 log << MSG::INFO << "Initialize done!" << endreq;
187}
const Int_t n
StatusCode InitHisto()
StatusCode InitConstTree()
StatusCode InitArea()
StatusCode InitNtuple()

◆ ~MucCalibMgr() [1/2]

MucCalibMgr::~MucCalibMgr ( )

Definition at line 190 of file MucCalibMgr.cxx.

191{
193
197 if( m_usePad != 0 ) Clear2DEffHisto();
198
202
203 if(m_ptrMucMark) delete m_ptrMucMark;
204 if(m_ptrIdTr) delete m_ptrIdTr;
205
206 m_digiCol.clear();
207 m_calHitCol.clear();
208 m_effHitCol.clear();
209 m_nosHitCol.clear();
210 m_clusterCol.clear();
211
212 for( int i=0; i<PART_MAX; i++ )
213 for( int j=0; j<SEGMENT_MAX; j++ ) {
214 m_segDigiCol[i][j].clear();
215 }
216
217 if(m_record) delete []m_record;
218 if(m_layerResults) delete []m_layerResults;
219 if(m_boxResults) delete []m_boxResults;
220 if(m_stripResults) delete []m_stripResults;
221}
StatusCode ClearHistoLV2()
StatusCode ClearResHisto()
StatusCode ClearHistoLV0()
StatusCode ClearClusterHisto()
StatusCode ClearHistoLV1()
StatusCode ClearOnlineHisto()
StatusCode ClearConstTree()
StatusCode Clear2DEffHisto()

◆ MucCalibMgr() [2/2]

MucCalibMgr::MucCalibMgr ( std::vector< double >  jobInfo,
std::vector< int >  configInfo,
std::string  outputFile 
)

◆ ~MucCalibMgr() [2/2]

MucCalibMgr::~MucCalibMgr ( )

Member Function Documentation

◆ AnalyseCluster() [1/2]

StatusCode MucCalibMgr::AnalyseCluster ( )

Definition at line 2469 of file MucCalibMgr.cxx.

2470{
2471 MsgStream log(msgSvc, "MucCalibMgr");
2472
2473 return StatusCode::SUCCESS;
2474}

◆ AnalyseCluster() [2/2]

StatusCode MucCalibMgr::AnalyseCluster ( )

◆ AnalyseEffAndNoise() [1/2]

StatusCode MucCalibMgr::AnalyseEffAndNoise ( )

Definition at line 2089 of file MucCalibMgr.cxx.

2090{
2091 MsgStream log(msgSvc, "MucCalibMgr");
2092 log<< MSG::INFO << "Start efficiency and noise calibration" << endreq;
2093
2094 // Set time
2095 m_fTotalDAQTime = m_fTotalEvent/m_er;
2096 log<< MSG::INFO << "Total run time:\t" << m_fTotalDAQTime << endreq;
2097
2101
2102 if( m_usePad != 0 ) PadEff();
2103
2104 return StatusCode::SUCCESS;
2105}
StatusCode PadEff()
StatusCode EffAndNoiseLV2()
StatusCode EffAndNoiseLV1()
StatusCode EffAndNoiseLV0()

Referenced by MucCalibAlg::finalize().

◆ AnalyseEffAndNoise() [2/2]

StatusCode MucCalibMgr::AnalyseEffAndNoise ( )

◆ AnalyseRes() [1/2]

StatusCode MucCalibMgr::AnalyseRes ( )

Definition at line 2476 of file MucCalibMgr.cxx.

2477{
2478 MsgStream log(msgSvc, "MucCalibMgr");
2479 log << MSG::INFO << "Analyse spacial resolution" << endreq;
2480
2481 double resMean, resMeanErr, resSigma, resSigmaErr;
2482 resMean = resMeanErr = resSigma = resSigmaErr = 0.;
2483
2484 for( int i=0; i<B_LAY_NUM; i++ )
2485 {
2486 m_hBarrelResDist[i]->Fit("gaus");
2487 resMean = m_hBarrelResDist[i]->GetFunction("gaus")->GetParameter("Mean");
2488 resSigma = m_hBarrelResDist[i]->GetFunction("gaus")->GetParameter("Sigma");
2489 resMeanErr = m_hBarrelResDist[i]->GetFunction("gaus")->GetParError(1);
2490 resSigmaErr = m_hBarrelResDist[i]->GetFunction("gaus")->GetParError(2);
2491
2492 m_hBarrelResComp[0]->Fill( i, resMean );
2493 m_hBarrelResComp[0]->SetBinError( i+1, resMeanErr );
2494 m_hBarrelResComp[1]->Fill( i, resSigma );
2495 m_hBarrelResComp[1]->SetBinError( i+1, resSigmaErr );
2496 }
2497
2498 for( int i=0; i<E_LAY_NUM; i++ )
2499 {
2500 m_hEndcapResDist[i]->Fit("gaus");
2501 resMean = m_hEndcapResDist[i]->GetFunction("gaus")->GetParameter("Mean");
2502 resSigma = m_hEndcapResDist[i]->GetFunction("gaus")->GetParameter("Sigma");
2503 resMeanErr = m_hEndcapResDist[i]->GetFunction("gaus")->GetParError(1);
2504 resSigmaErr = m_hEndcapResDist[i]->GetFunction("gaus")->GetParError(2);
2505
2506 m_hEndcapResComp[0]->Fill( i, resMean );
2507 m_hEndcapResComp[0]->SetBinError( i+1, resMeanErr );
2508 m_hEndcapResComp[1]->Fill( i, resSigma );
2509 m_hEndcapResComp[1]->SetBinError( i+1, resSigmaErr );
2510 }
2511
2512 return StatusCode::SUCCESS;
2513}

Referenced by MucCalibAlg::finalize().

◆ AnalyseRes() [2/2]

StatusCode MucCalibMgr::AnalyseRes ( )

◆ CheckEvent() [1/2]

StatusCode MucCalibMgr::CheckEvent ( )

Definition at line 1786 of file MucCalibMgr.cxx.

1787{
1788 MsgStream log(msgSvc, "MucCalibMgr");
1789 log << MSG::INFO << "Check event" << endreq;
1790
1791 // Find over digis in digis
1792 // Note that only one digi relates to one strip
1793 log << MSG::INFO << "Searching over digi" << endreq;
1794 int overDigi = 0;
1795 for( unsigned int i=0; i < m_digiCol.size(); i++ )
1796 for( unsigned int j=i+1; j < m_digiCol.size(); j++ ) {
1797 if( (*m_digiCol[i]) == (*m_digiCol[j]) ) overDigi ++;
1798 }
1799
1800 if( overDigi !=0 )
1801 log << MSG::ERROR << overDigi << " over digi found in digis!" << endreq;
1802
1803 // Find over hits in reconstruction hits
1804 // Note that two tracks may pass thought one strip
1805 log << MSG::INFO << "Searching over hit" << endreq;
1806 int overHit = 0;
1807 for( unsigned int i=0; i < m_expHitCol.size(); i++ )
1808 for( unsigned int j=i+1; j < m_expHitCol.size(); j++ ) {
1809 if( (*m_expHitCol[i]) == (*m_expHitCol[j]) ) overHit ++;
1810 }
1811
1812 if( overHit != 0 )
1813 log << MSG::WARNING << overHit << " over hits found in rec hits!" << endreq;
1814
1815 // Find hits of reconstruction not in MUCdigis
1816 log << MSG::INFO << "Searching new hit" << endreq;
1817 int newHit = 0;
1818 int num = 0;
1819 for( unsigned int i=0; i < m_expHitCol.size(); i++ )
1820 {
1821 num = m_expHitCol[i]->NumInCol( m_digiCol );
1822 if( num == 0 )
1823 {
1824 log << MSG::ERROR << "Exp hit not in digis!"
1825 << "prt: " << (*m_expHitCol[i]).Part()
1826 << "\tseg: " << (*m_expHitCol[i]).Segment()
1827 << "\tlay: " << (*m_expHitCol[i]).Layer()
1828 << "\tstr: " << (*m_expHitCol[i]).Strip() << endreq;
1829
1830 newHit ++;
1831 }
1832 }
1833
1834 if( newHit != 0 )
1835 log << MSG::WARNING << newHit << " new hit(s) found in rec hits!" << endreq;
1836
1837 return StatusCode::SUCCESS;
1838}

Referenced by MucCalibAlg::execute().

◆ CheckEvent() [2/2]

StatusCode MucCalibMgr::CheckEvent ( )

◆ Clear2DEffHisto() [1/2]

StatusCode MucCalibMgr::Clear2DEffHisto ( )
protected

Definition at line 305 of file MucCalibMgr.cxx.

306{
307
308 for( int i=0; i<PART_MAX; i++ )
309 for( int j=0; j<((i==BRID)?B_SEG_NUM:E_SEG_NUM); j++ )
310 for( int k=0; k<((i==BRID)?B_LAY_NUM:E_LAY_NUM); k++ )
311 {
312 if(m_h2DExpMap[i][j][k]) delete m_h2DExpMap[i][j][k];
313 if(m_h2DHitMap[i][j][k]) delete m_h2DHitMap[i][j][k];
314 if(m_h2DEffMap[i][j][k]) delete m_h2DEffMap[i][j][k];
315 }
316
317 return StatusCode::SUCCESS;
318}

Referenced by ~MucCalibMgr().

◆ Clear2DEffHisto() [2/2]

StatusCode MucCalibMgr::Clear2DEffHisto ( )
protected

◆ ClearClusterHisto() [1/2]

StatusCode MucCalibMgr::ClearClusterHisto ( )
protected

Definition at line 321 of file MucCalibMgr.cxx.

322{
323 for( int i=0; i<LAYER_MAX; i++ ) {
324 if(m_hLayerCluster[i]) delete m_hLayerCluster[i];
325 }
326
327 for( int i=0; i<BOX_MAX; i++ ) {
328 if(m_hBoxCluster[i]) delete m_hBoxCluster[i];
329 }
330
331 if(m_hLayerClusterCmp) delete m_hLayerClusterCmp;
332 if(m_hBoxClusterCmp) delete m_hBoxClusterCmp;
333
334 return StatusCode::SUCCESS;
335}

Referenced by ~MucCalibMgr().

◆ ClearClusterHisto() [2/2]

StatusCode MucCalibMgr::ClearClusterHisto ( )
protected

◆ ClearConstTree() [1/2]

StatusCode MucCalibMgr::ClearConstTree ( )
protected

Definition at line 356 of file MucCalibMgr.cxx.

357{
358
359 if(m_tJobLog) delete m_tJobLog;
360 if(m_tStatLog) delete m_tStatLog;
361 if(m_tLayConst) delete m_tLayConst;
362 if(m_tBoxConst) delete m_tBoxConst;
363 if(m_tStrConst) delete m_tStrConst;
364
365 return StatusCode::SUCCESS;
366}

Referenced by ~MucCalibMgr().

◆ ClearConstTree() [2/2]

StatusCode MucCalibMgr::ClearConstTree ( )
protected

◆ ClearHistoLV0() [1/2]

StatusCode MucCalibMgr::ClearHistoLV0 ( )
protected

Definition at line 245 of file MucCalibMgr.cxx.

246{
247 if(m_hBrLayerFire) delete m_hBrLayerFire;
248 if(m_hEcLayerFire) delete m_hEcLayerFire;
249 if(m_hLayerFire) delete m_hLayerFire;
250 if(m_hLayerExpHit) delete m_hLayerExpHit;
251 if(m_hLayerExpHit) delete m_hLayerEffHit;
252 if(m_hLayerNosHit) delete m_hLayerNosHit;
253 if(m_hLayerEff) delete m_hLayerEff;
254 if(m_hLayerNosRatio)delete m_hLayerNosRatio;
255 if(m_hLayerArea) delete m_hLayerArea;
256 if(m_hLayerNos) delete m_hLayerNos;
257 if(m_hLayerCnt) delete m_hLayerCnt;
258
259 return StatusCode::SUCCESS;
260}

Referenced by ~MucCalibMgr().

◆ ClearHistoLV0() [2/2]

StatusCode MucCalibMgr::ClearHistoLV0 ( )
protected

◆ ClearHistoLV1() [1/2]

StatusCode MucCalibMgr::ClearHistoLV1 ( )
protected

Definition at line 263 of file MucCalibMgr.cxx.

264{
265 if(m_hBoxFire) delete m_hBoxFire;
266 if(m_hBoxExpHit) delete m_hBoxExpHit;
267 if(m_hBoxEffHit) delete m_hBoxEffHit;
268 if(m_hBoxNosHit) delete m_hBoxNosHit;
269 if(m_hBoxEff) delete m_hBoxEff;
270 if(m_hBoxNosRatio)delete m_hBoxNosRatio;
271 if(m_hBoxArea) delete m_hBoxArea;
272 if(m_hBoxNos) delete m_hBoxNos;
273 if(m_hBoxCnt) delete m_hBoxCnt;
274
275 return StatusCode::SUCCESS;
276}

Referenced by ~MucCalibMgr().

◆ ClearHistoLV1() [2/2]

StatusCode MucCalibMgr::ClearHistoLV1 ( )
protected

◆ ClearHistoLV2() [1/2]

StatusCode MucCalibMgr::ClearHistoLV2 ( )
protected

Definition at line 279 of file MucCalibMgr.cxx.

280{
281 for( int i=0; i< BOX_MAX; i++ )
282 {
283 if(m_hStripFireMap[i]) delete m_hStripFireMap[i];
284 if(m_hStripExpHitMap[i]) delete m_hStripExpHitMap[i];
285 if(m_hStripEffHitMap[i]) delete m_hStripEffHitMap[i];
286 if(m_hStripNosHitMap[i]) delete m_hStripNosHitMap[i];
287 if(m_hStripEffMap[i]) delete m_hStripEffMap[i];
288 if(m_hStripNosRatioMap[i])delete m_hStripNosRatioMap[i];
289 }
290
291 if(m_hStripFire) delete m_hStripFire;
292 if(m_hStripExpHit) delete m_hStripExpHit;
293 if(m_hStripEffHit) delete m_hStripEffHit;
294 if(m_hStripNosHit) delete m_hStripNosHit;
295 if(m_hStripEff) delete m_hStripEff;
296 if(m_hStripNosRatio)delete m_hStripNosRatio;
297 if(m_hStripArea) delete m_hStripArea;
298 if(m_hStripNos) delete m_hStripNos;
299 if(m_hStripCnt) delete m_hStripCnt;
300
301 return StatusCode::SUCCESS;
302}

Referenced by ~MucCalibMgr().

◆ ClearHistoLV2() [2/2]

StatusCode MucCalibMgr::ClearHistoLV2 ( )
protected

◆ ClearOnlineHisto() [1/2]

StatusCode MucCalibMgr::ClearOnlineHisto ( )
protected

Definition at line 224 of file MucCalibMgr.cxx.

225{
226 if(m_hHitMapBarrel_Lay) delete []m_hHitMapBarrel_Lay;
227 if(m_hHitMapEndcap_Lay) delete []m_hHitMapEndcap_Lay;
228 if(m_hHitMapBarrel_Seg) delete []m_hHitMapBarrel_Seg;
229 if(m_hHitMapEndcap_Seg) delete []m_hHitMapEndcap_Seg;
230
231 if(m_hHitVsEvent) delete m_hHitVsEvent;
232 if(m_hTrackDistance) delete m_hTrackDistance;
233 if(m_hTrackPosPhiDiff) delete m_hTrackPosPhiDiff;
234 if(m_hTrackPosThetaDiff)delete m_hTrackPosThetaDiff;
235 if(m_hTrackMomPhiDiff) delete m_hTrackMomPhiDiff;
236 if(m_hTrackMomThetaDiff)delete m_hTrackMomThetaDiff;
237 if(m_hDimuTracksPosDiff)delete m_hDimuTracksPosDiff;
238 if(m_hDimuTracksMomDiff)delete m_hDimuTracksMomDiff;
239 if(m_hPhiCosTheta) delete m_hPhiCosTheta;
240
241 return StatusCode::SUCCESS;
242}

Referenced by ~MucCalibMgr().

◆ ClearOnlineHisto() [2/2]

StatusCode MucCalibMgr::ClearOnlineHisto ( )
protected

◆ ClearResHisto() [1/2]

StatusCode MucCalibMgr::ClearResHisto ( )
protected

Definition at line 338 of file MucCalibMgr.cxx.

339{
340 for( int i=0; i<B_LAY_NUM; i++ ) {
341 if(m_hBarrelResDist[i]) delete m_hBarrelResDist[i];
342 }
343 for( int i=0; i<E_LAY_NUM; i++ ) {
344 if(m_hEndcapResDist[i]) delete m_hEndcapResDist[i];
345 }
346
347 if(m_hBarrelResComp[0]) delete m_hBarrelResComp[0];
348 if(m_hBarrelResComp[1]) delete m_hBarrelResComp[1];
349 if(m_hEndcapResComp[0]) delete m_hEndcapResComp[0];
350 if(m_hEndcapResComp[1]) delete m_hEndcapResComp[1];
351
352 return StatusCode::SUCCESS;
353}

Referenced by ~MucCalibMgr().

◆ ClearResHisto() [2/2]

StatusCode MucCalibMgr::ClearResHisto ( )
protected

◆ DimuSelect() [1/2]

StatusCode MucCalibMgr::DimuSelect ( )

Definition at line 1033 of file MucCalibMgr.cxx.

1034{
1035 MsgStream log(msgSvc, "MucCalibMgr");
1036 log << MSG::INFO << "Dimu select" << endreq;
1037 Gaudi::svcLocator()->service("EventDataSvc", eventSvc);
1038
1039 if( m_tag > 0) { m_eventTag = (int)m_tag; return ( StatusCode::SUCCESS ); }
1040
1041 m_eventTag = 0;
1042 SmartDataPtr<Event::EventHeader> eventHeader(eventSvc,"/Event/EventHeader");
1043 if(!eventHeader) {
1044 log << MSG::FATAL << "Could not find event header" << endreq;
1045 return( StatusCode::FAILURE );
1046 }
1047
1048 // Select by MDC Info
1049 SmartDataPtr<RecMdcTrackCol> mdcTrackCol(eventSvc,"/Event/Recon/RecMdcTrackCol");
1050 if(!mdcTrackCol) {
1051 log << MSG::FATAL << "Could not find mdc tracks" << endreq;
1052 return( StatusCode::FAILURE);
1053 }
1054 log << MSG::INFO << mdcTrackCol->size() << endreq;
1055 if( mdcTrackCol->size() != 2 ) return ( StatusCode::FAILURE );
1056
1057 log << MSG::INFO << "r1:\t" << (*mdcTrackCol)[0]->r() << "\tz1:" << (*mdcTrackCol)[0]->z() << endreq;
1058 log << MSG::INFO << "r2:\t" << (*mdcTrackCol)[1]->r() << "\tz2:" << (*mdcTrackCol)[1]->z() << endreq;
1059 log << MSG::INFO << "p1:\t" << (*mdcTrackCol)[0]->p() << "\tp2:" << (*mdcTrackCol)[1]->p() << endreq;
1060
1061 bool mdcFlag1 = (*mdcTrackCol)[0]->charge() + (*mdcTrackCol)[1]->charge() == 0;
1062 bool mdcFlag2 = fabs((*mdcTrackCol)[0]->r())<=1 && fabs((*mdcTrackCol)[0]->z())<3;
1063 bool mdcFlag3 = fabs((*mdcTrackCol)[1]->r())<=1 && fabs((*mdcTrackCol)[1]->z())<3;
1064 bool mdcFlag4 = (*mdcTrackCol)[0]->p()<2 && (*mdcTrackCol)[1]->p()<2;
1065 bool mdcFlag5 = fabs( (*mdcTrackCol)[0]->p() - (*mdcTrackCol)[1]->p() )/( (*mdcTrackCol)[0]->p() + (*mdcTrackCol)[1]->p() ) < 0.5;
1066 bool mdcPass = false;
1067 if( mdcFlag1 && mdcFlag2 && mdcFlag3 && mdcFlag4 && mdcFlag5 ) mdcPass = true;
1068
1069 // Select by TOF Info
1070 SmartDataPtr<RecTofTrackCol> tofTrackCol(eventSvc,"/Event/Recon/RecTofTrackCol");
1071 if(!tofTrackCol) {
1072 log << MSG::FATAL << "Could not find RecTofTrackCol!" << endreq;
1073 return( StatusCode::FAILURE);
1074 }
1075 log << MSG::INFO << "TOF tracks:\t" << tofTrackCol->size() << endreq;
1076
1077 double t1, t2;
1078 t1 = 0., t2 = 1000;
1079 // if(tofTrackCol->size() < 8 && tofTrackCol->size() > 20)
1080 if(tofTrackCol->size() > 7 && tofTrackCol->size() < 21)
1081 {
1082 int goodtof = 0;
1083 for(unsigned int itof = 0; itof < tofTrackCol->size(); itof++)
1084 {
1085 TofHitStatus *status = new TofHitStatus;
1086 status->setStatus((*tofTrackCol)[itof]->status());
1087
1088 if( !(status->is_cluster()) ) { delete status; continue; }
1089 if(goodtof==0) t1 = (*tofTrackCol)[itof]->tof();
1090 if(goodtof==1) t2 = (*tofTrackCol)[itof]->tof();
1091
1092 goodtof++;
1093 delete status;
1094 }
1095 }
1096 bool tofPass = false;
1097 if( fabs( t1-t2 ) < 4) tofPass = true; // ns
1098
1099 // Select by EMC Info
1100 SmartDataPtr<RecEmcShowerCol> emcShowerCol(eventSvc,"/Event/Recon/RecEmcShowerCol");
1101 if (!emcShowerCol) {
1102 log << MSG::FATAL << "Could not find RecEmcShowerCol!" << endreq;
1103 return( StatusCode::FAILURE);
1104 }
1105 log << MSG::INFO << "EMC showers:\t" << emcShowerCol->size() << endreq;
1106
1107 if( emcShowerCol->size() < 2 ) return ( StatusCode::SUCCESS );
1108
1109 double e1, e2, theta1, theta2, phi1, phi2;
1110 int part;
1111
1112 e1 = (*emcShowerCol)[0]->energy(); e2 = (*emcShowerCol)[1]->energy();
1113 theta1 = (*emcShowerCol)[0]->theta(); theta2 = (*emcShowerCol)[1]->theta();
1114 phi1 = (*emcShowerCol)[0]->phi(); phi2 = (*emcShowerCol)[1]->phi();
1115 part = (*emcShowerCol)[0]->module();
1116
1117 log << MSG::INFO << "e1:\t" << e1 << "\te2:\t" << e2 << endreq;
1118 log << MSG::INFO << "theta1:\t" << theta1 << "\ttheta2:\t" << theta2 << endreq;
1119 log << MSG::INFO << "phi1:\t" << phi1 << "\tphi2:\t" << phi2 << endreq;
1120
1121 bool emcFlag1 = e1 < 1.0 && e1 > 0.1;
1122 bool emcFlag2 = e2 < 1.0 && e2 > 0.1;
1123 bool emcFlag3 = fabs(theta1 + theta2 - PI) < 0.05;
1124 bool emcFlag4 = fabs(phi1 - phi2) - PI < 0.4;
1125
1126 bool emcPass = false;
1127 if( emcFlag1 && emcFlag2 && emcFlag3 && emcFlag4 ) emcPass = true;
1128
1129 // Select by MUC Info
1130 SmartDataPtr<MucDigiCol> mucDigiCol(eventSvc,"/Event/Digi/MucDigiCol");
1131 if(!mucDigiCol) {
1132 log << MSG::FATAL << "Could not find MUC digi" << endreq;
1133 return( StatusCode::FAILURE);
1134 }
1135 SmartDataPtr<RecMucTrackCol> mucTrackCol(eventSvc,"/Event/Recon/RecMucTrackCol");
1136 if (!mucTrackCol) {
1137 log << MSG::FATAL << "Could not find RecMucTrackCol" << endreq;
1138 return( StatusCode::FAILURE);
1139 }
1140 log << MSG::INFO << "digi:\t" << mucDigiCol->size() << "tracks:\t" << mucTrackCol->size() << endreq;
1141
1142 bool mucFlag1 = mucDigiCol->size()>6;
1143 bool mucFlag2 = mucTrackCol->size()>1;
1144 bool mucPass = false;
1145 if( mucFlag1 && mucFlag2 ) mucPass = true;
1146
1147 if( mdcPass && tofPass && emcPass && mucPass ) m_eventTag = 1;
1148 else m_eventTag = (int)m_tag;
1149
1150 return( StatusCode::SUCCESS );
1151}
Double_t phi2
Double_t phi1
Double_t e1
Double_t e2
const double PI
Definition: PipiJpsi.cxx:55
void setStatus(unsigned int status)

Referenced by ReadEvent().

◆ DimuSelect() [2/2]

StatusCode MucCalibMgr::DimuSelect ( )

◆ EffAndNoiseLV0() [1/2]

StatusCode MucCalibMgr::EffAndNoiseLV0 ( )
protected

Definition at line 2107 of file MucCalibMgr.cxx.

2108{
2109 MsgStream log(msgSvc, "MucCalibMgr");
2110 log<< MSG::INFO << "Analyse layer efficiency and noise" << endreq;
2111
2112 int part, segment, layer, stripMax;
2113 part = segment = layer = stripMax = 0;
2114
2115 double digi, effHit, trackNum, nosHit, recHit;
2116 double eff, effErr, noise, nosRatio, nosRatioErr, cnt, cluster;
2117 eff = effErr = noise = nosRatio = nosRatioErr = cnt = cluster = 0.;
2118
2119 for( int i=0; i<LAYER_MAX; i++ )
2120 {
2121 digi = effHit = trackNum = nosHit = recHit = 0;
2122
2123 for( int j=0; j<PART_MAX; j++ )
2124 {
2125 for( int k=0; k<SEGMENT_MAX; k++)
2126 {
2127 stripMax = m_ptrIdTr->GetStripMax( j, k, i );
2128 for( int n=0; n<stripMax; n++ )
2129 {
2130 digi += m_record[j][k][i][n][0];
2131 trackNum += m_record[j][k][i][n][1];
2132 effHit += m_record[j][k][i][n][2];
2133 nosHit += m_record[j][k][i][n][3];
2134 recHit += m_record[j][k][i][n][4];
2135 }
2136 }
2137 }
2138
2139 // Efficiency
2140 if( trackNum == 0 ) {
2141 eff = effErr = 0.0;
2142 //eff = DEFAULT_EFF_VALUE;
2143 //effErr = DEFAULT_EFF_ERR;
2144 }
2145 else
2146 {
2147 eff = ( (double)effHit )/trackNum;
2148 effErr = sqrt( eff*(1-eff)/trackNum );
2149 m_fCalibLayerNum ++;
2150 }
2151
2152 // Noise
2153 if( m_layerResults[3][i] < LIMIT_CUT || m_fTotalDAQTime < LIMIT_CUT )
2154 noise = DEFAULT_NOS_VALUE;
2155 else {
2156 if( m_recMode == 2 ) noise = (double)nosHit/(m_fTotalEvent*TRIGGER_WINDOW*m_layerResults[3][i]);
2157 else noise = (double)nosHit/(m_fTotalDAQTime * m_layerResults[3][i]);
2158 }
2159
2160 if( digi != 0 ) {
2161 nosRatio = ( (double)nosHit )/digi;
2162 nosRatioErr = sqrt( nosRatio*(1-nosRatio)/digi );
2163 }
2164 else {
2165 nosRatio = DEFAULT_INC_VALUE;
2166 nosRatioErr = 0;
2167 }
2168
2169 // Counting rate
2170 if( m_recMode == 2 )
2171 cnt = (double)digi/(m_fTotalEvent*TRIGGER_WINDOW * m_layerResults[3][i]);
2172 else
2173 cnt = (double)digi/(m_fTotalDAQTime * m_layerResults[3][i]);
2174
2175 // Cluster
2176 cluster = m_hLayerCluster[i]->GetMean();
2177
2178 m_layerResults[0][ i ] = eff;
2179 m_layerResults[1][ i ] = effErr;
2180 m_layerResults[2][ i ] = noise;
2181 m_layerResults[4][ i ] = cluster;
2182 m_layerResults[5][ i ] = trackNum;
2183
2184 // Fill histogram
2185 m_hLayerEff->Fill( i, eff );
2186 m_hLayerEff->SetBinError( i+1, effErr );
2187 m_hLayerNosRatio->Fill( i, nosRatio );
2188 m_hLayerNosRatio->SetBinError( i+1, nosRatioErr );
2189 m_hLayerNos->Fill( i, noise );
2190 m_hLayerCnt->Fill( i, cnt );
2191
2192 // Add cluster histogram
2193 m_hLayerClusterCmp->Fill( i, cluster );
2194
2195 // Fill tree
2196 m_fLayerId = i;
2197 m_fLayerEff = eff;
2198 m_fLayerEffErr = effErr;
2199 m_fLayerTrkNum = trackNum;
2200 m_fLayerExpHit = recHit;
2201 m_fLayerEffHit = effHit;
2202 m_fLayerNosRatio = nosRatio;
2203 m_fLayerDigi = digi;
2204 m_fLayerNosHit = nosHit;
2205 m_fLayerNos = noise;
2206 m_fLayerCnt = cnt;
2207 m_tLayConst->Fill();
2208
2209 // Add cluster ntuple
2210 m_fLayerCluster = cluster;
2211
2212 } // End layer
2213
2214 return StatusCode::SUCCESS;
2215}
int GetStripMax(int part, int segment, int layer)

Referenced by AnalyseEffAndNoise().

◆ EffAndNoiseLV0() [2/2]

StatusCode MucCalibMgr::EffAndNoiseLV0 ( )
protected

◆ EffAndNoiseLV1() [1/2]

StatusCode MucCalibMgr::EffAndNoiseLV1 ( )
protected

Definition at line 2217 of file MucCalibMgr.cxx.

2218{
2219 MsgStream log(msgSvc, "MucCalibMgr");
2220 log<< MSG::INFO << "Analyse box efficiency and noise" << endreq;
2221
2222 int part, segment, layer, stripMax;
2223 part = segment = layer = stripMax = 0;
2224
2225 double digi, effHit, trackNum, nosHit, recHit;
2226 double eff, effErr, noise, nosRatio, nosRatioErr, cnt, cluster;
2227 eff = effErr = noise = nosRatio = nosRatioErr = cnt = cluster = 0.;
2228
2229 for( int i=0; i<BOX_MAX; i++ )
2230 {
2231 m_ptrIdTr->SetBoxPos( i, &part, &segment, &layer );
2232 stripMax = m_ptrIdTr->GetStripMax( part, segment, layer );
2233
2234 digi = effHit = trackNum = nosHit = recHit = 0;
2235 for( int j=0; j<stripMax; j++ )
2236 {
2237 digi += m_record[part][segment][layer][j][0];
2238 trackNum += m_record[part][segment][layer][j][1];
2239 effHit += m_record[part][segment][layer][j][2];
2240 nosHit += m_record[part][segment][layer][j][3];
2241 recHit += m_record[part][segment][layer][j][4];
2242 }
2243
2244 // Efficiency
2245 if( trackNum == 0 ) {
2246 eff = effErr = 0.0;
2247 //eff = DEFAULT_EFF_VALUE;
2248 //effErr = DEFAULT_EFF_ERR;
2249 }
2250 else
2251 {
2252 eff = ( (double)effHit )/trackNum;
2253 effErr = sqrt( eff*(1-eff)/trackNum );
2254 m_fCalibBoxNum ++;
2255 }
2256
2257 // Noise
2258 if( m_boxResults[3][i] < LIMIT_CUT || m_fTotalDAQTime < LIMIT_CUT )
2259 noise = DEFAULT_NOS_VALUE;
2260 else {
2261 if( m_recMode == 2 )
2262 noise = (double)nosHit/(m_fTotalEvent*TRIGGER_WINDOW * m_boxResults[3][i]);
2263 else
2264 noise = (double)nosHit/(m_fTotalDAQTime * m_boxResults[3][i]);
2265 }
2266
2267 if( digi != 0 ) {
2268 nosRatio = ( (double)nosHit )/digi;
2269 nosRatioErr = sqrt( nosRatio*(1-nosRatio)/digi );
2270 }
2271 else {
2272 nosRatio = DEFAULT_INC_VALUE;
2273 nosRatioErr = 0;
2274 }
2275
2276 // Counting rate
2277 if( m_recMode == 2 )
2278 cnt = (double)digi/(m_fTotalEvent*TRIGGER_WINDOW * m_boxResults[3][i]);
2279 else
2280 cnt = (double)digi/(m_fTotalDAQTime * m_boxResults[3][i]);
2281
2282 // Cluster
2283 cluster = m_hBoxCluster[i]->GetMean();
2284
2285 m_boxResults[0][ i ] = eff;
2286 m_boxResults[1][ i ] = effErr;
2287 m_boxResults[2][ i ] = noise;
2288 m_boxResults[4][ i ] = cluster;
2289 m_boxResults[5][ i ] = trackNum;
2290
2291 // Fill histograms
2292 m_hBoxEff->Fill( i, eff );
2293 m_hBoxEff->SetBinError( i+1, effErr );
2294 m_hBoxNosRatio->Fill( i, nosRatio );
2295 m_hBoxNosRatio->SetBinError( i+1, nosRatioErr );
2296 m_hBoxNos->Fill( i, noise );
2297 m_hBoxCnt->Fill( i, cnt );
2298
2299 // add cluster histogram
2300 m_hBoxClusterCmp->Fill( i, cluster );
2301
2302 // Fill tree
2303 m_fBoxId = i;
2304 m_fBoxPart = part;
2305 m_fBoxSegment = segment;
2306 m_fBoxLayer = layer;
2307 m_fBoxEff = eff;
2308 m_fBoxEffErr = effErr;
2309 m_fBoxTrkNum = trackNum;
2310 m_fBoxExpHit = recHit;
2311 m_fBoxEffHit = effHit;
2312 m_fBoxNosRatio = nosRatio;
2313 m_fBoxDigi = digi;
2314 m_fBoxNosHit = nosHit;
2315 m_fBoxNos = noise;
2316 m_fBoxCnt = cnt;
2317 m_tBoxConst->Fill();
2318
2319 // add box cluster ntuple
2320 m_fBoxCluster = cluster;
2321
2322 }// End BOX_MAX
2323
2324 return StatusCode::SUCCESS;
2325}
bool SetBoxPos(int boxid, int *part, int *segment, int *layer)

Referenced by AnalyseEffAndNoise().

◆ EffAndNoiseLV1() [2/2]

StatusCode MucCalibMgr::EffAndNoiseLV1 ( )
protected

◆ EffAndNoiseLV2() [1/2]

StatusCode MucCalibMgr::EffAndNoiseLV2 ( )
protected

Definition at line 2327 of file MucCalibMgr.cxx.

2328{
2329 MsgStream log(msgSvc, "MucCalibMgr");
2330 log<< MSG::INFO << "Analyse strip efficiency and noise" << endreq;
2331
2332 int part, segment, layer, stripMax;
2333 part = segment = layer = stripMax = 0;
2334
2335 double digi, effHit, trackNum, nosHit, recHit;
2336 double eff, effErr, noise, nosRatio, nosRatioErr, cnt, cluster;
2337 eff = effErr = noise = nosRatio = nosRatioErr = cnt = cluster = 0.;
2338
2339 for( int i=0; i<BOX_MAX; i++ )
2340 {
2341 m_ptrIdTr->SetBoxPos( i, &part, &segment, &layer );
2342 stripMax = m_ptrIdTr->GetStripMax( part, segment, layer );
2343
2344 for( int j=0; j<stripMax; j++ )
2345 {
2346 digi = m_record[part][segment][layer][j][0];
2347 trackNum = m_record[part][segment][layer][j][1];
2348 effHit = m_record[part][segment][layer][j][2];
2349 nosHit = m_record[part][segment][layer][j][3];
2350 recHit = m_record[part][segment][layer][j][4];
2351
2352 int stripId = m_ptrIdTr->GetStripId( part, segment, layer, j );
2353
2354 // Efficiency
2355 if( trackNum == 0 ) {
2356 eff = effErr = 0.0;
2357 //eff = DEFAULT_EFF_VALUE;
2358 //effErr = DEFAULT_EFF_ERR;
2359 }
2360 else
2361 {
2362 eff = ( (double)effHit )/trackNum;
2363 effErr = sqrt( eff*(1-eff)/trackNum );
2364 m_fCalibStripNum ++;
2365 }
2366
2367 // Noise
2368 if( m_stripResults[3][stripId] < LIMIT_CUT || m_fTotalDAQTime < LIMIT_CUT )
2369 noise = DEFAULT_NOS_VALUE;
2370 else {
2371 if( m_recMode == 2 )
2372 noise = (double)nosHit/(m_fTotalEvent*TRIGGER_WINDOW * m_stripResults[3][stripId]);
2373 else
2374 noise = (double)nosHit/(m_fTotalDAQTime * m_stripResults[3][stripId]);
2375 }
2376
2377 if( digi != 0 ) {
2378 nosRatio = ( (double)nosHit )/digi;
2379 nosRatioErr = sqrt( nosRatio*(1-nosRatio)/digi );
2380 }
2381 else {
2382 nosRatio = DEFAULT_INC_VALUE;
2383 nosRatioErr = 0.;
2384 }
2385
2386 // Counting rate
2387 if( m_recMode == 2 )
2388 cnt = (double)digi/(m_fTotalEvent*TRIGGER_WINDOW * m_stripResults[3][stripId]);
2389 else
2390 cnt = (double)digi/(m_fTotalDAQTime * m_stripResults[3][stripId]);
2391
2392 // Strip itself no clusters
2393 m_stripResults[0][ stripId ] = eff;
2394 m_stripResults[1][ stripId ] = effErr;
2395 m_stripResults[2][ stripId ] = noise;
2396 m_stripResults[5][ stripId ] = trackNum;
2397
2398 // Fill histotram
2399 m_hStripEffMap[i]->Fill( j, eff );
2400 m_hStripEffMap[i]->SetBinError( j+1, effErr );
2401 m_hStripEff->Fill( stripId, eff );
2402 m_hStripEff->SetBinError( stripId+1, effErr );
2403 m_hStripNosRatioMap[i]->Fill( j, nosRatio );
2404 m_hStripNosRatioMap[i]->SetBinError( j+1, nosRatioErr );
2405 m_hStripNosRatio->Fill( stripId, nosRatio );
2406 m_hStripNosRatio->SetBinError( stripId+1, nosRatioErr );
2407 m_hStripNos->Fill( stripId, noise );
2408 m_hStripCnt->Fill( stripId, cnt );
2409
2410 // Fill Tree
2411 m_fStripId = stripId;
2412 m_fStripPart = part;
2413 m_fStripSegment = segment;
2414 m_fStripLayer = layer;
2415 m_fStripEff = eff;
2416 m_fStripEffErr = effErr;
2417 m_fStripNosRatio = nosRatio;
2418 m_fStripDigi = digi;
2419 m_fStripNos = noise;
2420 m_fStripCnt = cnt;
2421 m_fStripEffHit = effHit;
2422 m_fStripExpHit = recHit;
2423 m_fStripNosHit = nosHit;
2424 m_fStripTrkNum = trackNum;
2425 m_tStrConst->Fill();
2426
2427 } // End stripMax
2428 } // End BOX_MAX
2429
2430 return StatusCode::SUCCESS;
2431}
int GetStripId(int part, int segment, int layer, int subid)

Referenced by AnalyseEffAndNoise().

◆ EffAndNoiseLV2() [2/2]

StatusCode MucCalibMgr::EffAndNoiseLV2 ( )
protected

◆ EndRun() [1/2]

StatusCode MucCalibMgr::EndRun ( )

Definition at line 2730 of file MucCalibMgr.cxx.

2731{
2732 MsgStream log(msgSvc, "MucCalibMgr");
2733 log << MSG::INFO << endreq;
2734 log << MSG::INFO << "Total events : " << m_fTotalEvent << endreq;
2735 log << MSG::INFO << "Total digis : " << m_fTotalDigi << endreq;
2736 log << MSG::INFO << "Total rec hits : " << m_fTotalExpHit << endreq;
2737 log << MSG::INFO << "Total eff hits : " << m_fTotalEffHit << endreq;
2738 log << MSG::INFO << "Total inc hits : " << m_fTotalNosHit << endreq;
2739 log << MSG::INFO << "Total clusters : " << m_fTotalClstNum<< endreq;
2740
2741 log << MSG::INFO << "Strip calibrated percentage: "
2742 << 100*(double)m_fCalibStripNum/STRIP_MAX << "%" << endreq;
2743 log << MSG::INFO << "Box calibrated percentage: "
2744 << 100*(double)m_fCalibBoxNum/BOX_MAX << "%" << endreq;
2745 log << MSG::INFO << "Layer calibrated percentage: "
2746 << 100*(double)m_fCalibLayerNum/LAYER_MAX << "%" << endreq;
2747
2748 log << MSG::INFO << "Calibration run successfully" << endreq << endreq;
2749
2750 return StatusCode::SUCCESS;
2751}

Referenced by MucCalibAlg::finalize().

◆ EndRun() [2/2]

StatusCode MucCalibMgr::EndRun ( )

◆ FillCluster() [1/2]

StatusCode MucCalibMgr::FillCluster ( int  part,
int  segment,
int  layer,
int  size 
)
protected

Definition at line 2074 of file MucCalibMgr.cxx.

2075{
2076 int boxId = m_ptrIdTr->GetBoxId( part, segment, layer );
2077
2078 m_hLayerCluster[layer]->Fill( size );
2079 m_hBoxCluster[boxId]->Fill( size );
2080
2081 return StatusCode::SUCCESS;
2082}
int GetBoxId(int part, int segment, int layer)

Referenced by FillEvent().

◆ FillCluster() [2/2]

StatusCode MucCalibMgr::FillCluster ( int  part,
int  segment,
int  layer,
int  size 
)
protected

◆ FillDigi() [1/2]

StatusCode MucCalibMgr::FillDigi ( int  part,
int  segment,
int  layer,
int  strip 
)
protected

Definition at line 1971 of file MucCalibMgr.cxx.

1972{
1973 // Hit map for online check
1974 int tmpId;
1975
1976 if( (int)m_tag || m_dimuOnly==0 || (m_dimuOnly==1&&m_eventTag==1) )
1977 {
1978 if( part == BRID )
1979 {
1980 // According to layer
1981 if( layer%2 == 0 ) {
1982 if( segment > 4 ) tmpId = segment*48 + (47 - strip);
1983 else tmpId = segment*48 + strip;
1984 }
1985 else if( segment < 3 ) tmpId = segment*96 + strip;
1986 else tmpId = (segment-1)*96 + 112 + strip;
1987
1988 m_hHitMapBarrel_Lay[layer]->Fill(tmpId);
1989
1990 // According to segment
1991 if( segment != B_TOP ) {
1992 if( segment > 4 )
1993 tmpId = 48*((layer+1)/2) + 96*(layer/2) + ( ((layer+1)%2)*48 + (layer%2)*96 - strip - 1 );
1994 else tmpId = 48*((layer+1)/2) + 96*(layer/2) + strip;
1995 }
1996 else tmpId = 48*((layer+1)/2) + 112*(layer/2) + strip;
1997
1998 m_hHitMapBarrel_Seg[segment]->Fill(tmpId);
1999 }
2000 else if( part == EEID )
2001 {
2002 // According to layer
2003 tmpId = segment*64 + strip;
2004 m_hHitMapEndcap_Lay[0][layer]->Fill(tmpId);
2005 // According to segment
2006 tmpId = layer*64 + strip;
2007 m_hHitMapEndcap_Seg[0][segment]->Fill(tmpId);
2008 }
2009 else if( part == EWID )
2010 {
2011 // According to layer
2012 tmpId = segment*64 + strip;
2013 m_hHitMapEndcap_Lay[1][layer]->Fill(tmpId);
2014 // According to segment
2015 tmpId = layer*64 + strip;
2016 m_hHitMapEndcap_Seg[1][segment]->Fill(tmpId);
2017 }
2018 }
2019
2020 // Total units
2021 int boxId = m_ptrIdTr->GetBoxId( part, segment, layer );
2022 int strId = m_ptrIdTr->GetStripId( part, segment, layer, strip );
2023
2024 m_hStripFireMap[boxId]->Fill( strip );
2025 m_hStripFire->Fill( strId );
2026 m_hBoxFire->Fill( boxId );
2027 m_hLayerFire->Fill( layer );
2028 if( part==BRID ) m_hBrLayerFire->Fill( layer );
2029 else if( part== EEID ) m_hEcLayerFire->Fill( layer+1 );
2030 else m_hEcLayerFire->Fill( -(layer+1) );
2031
2032 return StatusCode::SUCCESS;
2033}

Referenced by FillEvent().

◆ FillDigi() [2/2]

StatusCode MucCalibMgr::FillDigi ( int  part,
int  segment,
int  layer,
int  strip 
)
protected

◆ FillEffHit() [1/2]

StatusCode MucCalibMgr::FillEffHit ( int  part,
int  segment,
int  layer,
int  strip 
)
protected

Definition at line 2048 of file MucCalibMgr.cxx.

2049{
2050 int boxId = m_ptrIdTr->GetBoxId( part, segment, layer );
2051 int strId = m_ptrIdTr->GetStripId( part, segment, layer, strip );
2052
2053 m_hStripEffHitMap[boxId]->Fill( strip );
2054 m_hStripEffHit->Fill( strId );
2055 m_hBoxEffHit->Fill( boxId );
2056 m_hLayerEffHit->Fill( layer );
2057
2058 return StatusCode::SUCCESS;
2059}

Referenced by FillEvent().

◆ FillEffHit() [2/2]

StatusCode MucCalibMgr::FillEffHit ( int  part,
int  segment,
int  layer,
int  strip 
)
protected

◆ FillEvent() [1/2]

StatusCode MucCalibMgr::FillEvent ( )

Definition at line 1841 of file MucCalibMgr.cxx.

1842{
1843 MsgStream log(msgSvc, "MucCalibMgr");
1844 log << MSG::INFO << "Fill event" << endreq;
1845
1846 int part, segment, layer, strip, size;
1847 part = segment = layer = strip = size = 0;
1848
1849 // Fill digis
1850 log << MSG::INFO << "Fill digis" << endreq;
1851 for( unsigned int i=0; i<m_digiCol.size(); i++ )
1852 {
1853 part = (*m_digiCol[i]).Part();
1854 segment = (*m_digiCol[i]).Segment();
1855 layer = (*m_digiCol[i]).Layer();
1856 strip = (*m_digiCol[i]).Strip();
1857
1858 FillDigi( part, segment, layer, strip );
1859 m_record[part][segment][layer][strip][0] ++;
1860 m_fTotalDigi ++;
1861 }
1862
1863 // Fill rec hits
1864 log << MSG::INFO << "Fill rec hits" << endreq;
1865 for( unsigned int i=0; i<m_expHitCol.size(); i++ )
1866 {
1867 part = (*m_expHitCol[i]).Part();
1868 segment = (*m_expHitCol[i]).Segment();
1869 layer = (*m_expHitCol[i]).Layer();
1870 strip = (*m_expHitCol[i]).Strip();
1871
1872 FillExpHit( part, segment, layer, strip );
1873 m_record[part][segment][layer][strip][4] ++;
1874 m_fTotalExpHit ++;
1875 }
1876
1877 // Fill eff hits
1878 log << MSG::INFO << "Fill eff hits" << endreq;
1879 for( unsigned int i=0; i<m_effHitCol.size(); i++ )
1880 {
1881 part = (*m_effHitCol[i]).Part();
1882 segment = (*m_effHitCol[i]).Segment();
1883 layer = (*m_effHitCol[i]).Layer();
1884 strip = (*m_effHitCol[i]).Strip();
1885
1886 FillEffHit( part, segment, layer, strip );
1887 m_fTotalEffHit ++;
1888 }
1889
1890 // Fill clusters
1891 log << MSG::INFO << "Fill clusters" << endreq;
1892 for( unsigned int i=0; i<m_clusterCol.size(); i++ )
1893 {
1894 size = m_clusterCol[i].size();
1895 // may include the special cluster, size = 1
1896 if( size > CLUSTER_CUT )
1897 {
1898 part = (*m_clusterCol[i][0]).Part();
1899 segment = (*m_clusterCol[i][0]).Segment();
1900 layer = (*m_clusterCol[i][0]).Layer();
1901
1902 FillCluster( part, segment, layer, size );
1903 m_ntClusterSize = size;
1904 m_clusterSizeTuple->write();
1905 }
1906 }
1907
1908 // Fill inc/noise hits
1909 log << MSG::INFO << "Fill inc/noise hits" << endreq;
1910 for( unsigned int i=0; i<m_nosHitCol.size(); i++ )
1911 {
1912 part = (*m_nosHitCol[i]).Part();
1913 segment = (*m_nosHitCol[i]).Segment();
1914 layer = (*m_nosHitCol[i]).Layer();
1915 strip = (*m_nosHitCol[i]).Strip();
1916
1917 FillNosHit( part, segment, layer, strip );
1918 m_record[part][segment][layer][strip][3] ++;
1919 }
1920
1921 // Event log
1922 m_ntEventId = m_currentEvent;
1923 m_ntEventTag = m_eventTag;
1924 m_ntDigiNum = m_digiCol.size();
1925 m_ntExpHitNum = m_expHitCol.size();
1926 m_ntEffHitNum = m_effHitCol.size();
1927 m_ntNosHitNum = m_nosHitCol.size();
1928 m_ntClusterNum = m_clusterCol.size();
1929
1930 // Reset mark collection
1931 for( unsigned int i=0; i<m_digiCol.size(); i++ ) {
1932 if( m_digiCol[i] != NULL ) delete m_digiCol[i];
1933 }
1934
1935 for( unsigned int i=0; i<m_expHitCol.size(); i++ ) {
1936 if( m_expHitCol[i] != NULL ) delete m_expHitCol[i];
1937 }
1938/*
1939 for( unsigned int i=0; i<m_effHitCol.size(); i++ ) {
1940 if( m_effHitCol[i] != NULL ) delete m_effHitCol[i];
1941 }
1942 log << MSG::INFO << m_effHitCol.size() << endreq;
1943*/
1944 for( unsigned int i=0; i<m_calHitCol.size(); i++ ) {
1945 if( m_calHitCol[i] != NULL ) delete m_calHitCol[i];
1946 }
1947
1948 if( m_digiCol.size() != 0 ) m_digiCol.clear();
1949 if( m_expHitCol.size() != 0 ) m_expHitCol.clear();
1950 if( m_calHitCol.size() != 0 ) m_calHitCol.clear();
1951 if( m_effHitCol.size() != 0 ) m_effHitCol.clear();
1952 if( m_nosHitCol.size() != 0 ) m_nosHitCol.clear();
1953 if( m_clusterCol.size() != 0 ) m_clusterCol.clear();
1954
1955
1956 for( int i=0; i<PART_MAX; i++ ) {
1957 for( int j=0; j<SEGMENT_MAX; j++ ) {
1958 if( m_segDigiCol[i][j].size() != 0 ) m_segDigiCol[i][j].clear();
1959 }
1960 }
1961
1962 m_evtEnd = clock();
1963
1964 m_ntEventTime = (double(m_evtEnd - m_evtBegin))/CLOCKS_PER_SEC;
1965 log << MSG::INFO << "Event time:\t" << m_ntEventTime << "s" << endreq;
1966 m_eventLogTuple->write();
1967
1968 return StatusCode::SUCCESS;
1969}
StatusCode FillEffHit(int part, int segment, int layer, int strip)
StatusCode FillExpHit(int part, int segment, int layer, int strip)
StatusCode FillCluster(int part, int segment, int layer, int size)
StatusCode FillNosHit(int part, int segment, int layer, int strip)
StatusCode FillDigi(int part, int segment, int layer, int strip)

Referenced by MucCalibAlg::execute().

◆ FillEvent() [2/2]

StatusCode MucCalibMgr::FillEvent ( )

◆ FillExpHit() [1/2]

StatusCode MucCalibMgr::FillExpHit ( int  part,
int  segment,
int  layer,
int  strip 
)
protected

Definition at line 2035 of file MucCalibMgr.cxx.

2036{
2037 int boxId = m_ptrIdTr->GetBoxId( part, segment, layer );
2038 int strId = m_ptrIdTr->GetStripId( part, segment, layer, strip );
2039
2040 m_hStripExpHitMap[boxId]->Fill( strip );
2041 m_hStripExpHit->Fill( strId );
2042 m_hBoxExpHit->Fill( boxId );
2043 m_hLayerExpHit->Fill( layer );
2044
2045 return StatusCode::SUCCESS;
2046}

Referenced by FillEvent().

◆ FillExpHit() [2/2]

StatusCode MucCalibMgr::FillExpHit ( int  part,
int  segment,
int  layer,
int  strip 
)
protected

◆ FillNosHit() [1/2]

StatusCode MucCalibMgr::FillNosHit ( int  part,
int  segment,
int  layer,
int  strip 
)
protected

Definition at line 2061 of file MucCalibMgr.cxx.

2062{
2063 int boxId = m_ptrIdTr->GetBoxId( part, segment, layer );
2064 int strId = m_ptrIdTr->GetStripId( part, segment, layer, strip );
2065
2066 m_hStripNosHitMap[boxId]->Fill( strip );
2067 m_hStripNosHit->Fill( strId );
2068 m_hBoxNosHit->Fill( boxId );
2069 m_hLayerNosHit->Fill( layer );
2070
2071 return StatusCode::SUCCESS;
2072}

Referenced by FillEvent().

◆ FillNosHit() [2/2]

StatusCode MucCalibMgr::FillNosHit ( int  part,
int  segment,
int  layer,
int  strip 
)
protected

◆ Init2DEffHisto() [1/2]

StatusCode MucCalibMgr::Init2DEffHisto ( )
protected

Definition at line 791 of file MucCalibMgr.cxx.

792{
793 char name[60];
794 int stripMax, boxID, stripID, xBin, yBin;
795 stripMax = boxID = stripID = xBin = yBin = 0;
796 double xStart, xEnd, yStart, yEnd, sWidth;
797 xStart = xEnd = yStart = yEnd = sWidth = 0.;
798
799 m_histArray = new TObjArray();
800
801 for( int i=0; i<PART_MAX; i++ )
802 for( int j=0; j<((i==BRID)?B_SEG_NUM:E_SEG_NUM); j++ )
803 for( int k=0; k<((i==BRID)?B_LAY_NUM:E_LAY_NUM); k++ )
804 {
805 boxID = m_ptrIdTr->GetBoxId(i,j,k);
806
807 if( i==BRID )
808 {
809 xStart = -2000, xEnd = 2000;
810 sWidth = B_STR_DST[k];
811 xBin = int((xEnd - xStart)/sWidth);
812 yStart = -B_BOX_WT[k]/2-100, yEnd = B_BOX_WT[k]/2+100;
813 yBin = int((B_BOX_WT[k]+200)/sWidth);
814 }
815 else
816 {
817 xStart = yStart = -1250;
818 xEnd = yEnd = 1250;
819 sWidth = E_STR_DST;
820 xBin = yBin = int((xEnd - xStart)/sWidth);
821 }
822
823 sprintf(name, "ExpMap2D_P%d_S%d_L%d_Box%d", i, j, k, boxID);
824 m_h2DExpMap[i][j][k] = new TH2F(name, name, xBin, xStart, xEnd, yBin, yStart, yEnd);
825 sprintf(name, "HitMap2D_P%d_S%d_L%d_Box%d", i, j, k, boxID);
826 m_h2DHitMap[i][j][k] = new TH2F(name, name, xBin, xStart, xEnd, yBin, yStart, yEnd);
827 sprintf(name, "EffMap2D_P%d_S%d_L%d_Box%d", i, j, k, boxID);
828 m_h2DEffMap[i][j][k] = new TH2F(name, name, xBin, xStart, xEnd, yBin, yStart, yEnd);
829
830 //m_histArray->Add(m_h2DExpMap[i][j][k]);
831 //m_histArray->Add(m_h2DHitMap[i][j][k]);
832 m_histArray->Add(m_h2DEffMap[i][j][k]);
833 }
834
835 return StatusCode::SUCCESS;
836}

Referenced by InitHisto().

◆ Init2DEffHisto() [2/2]

StatusCode MucCalibMgr::Init2DEffHisto ( )
protected

◆ InitArea() [1/2]

StatusCode MucCalibMgr::InitArea ( )

Definition at line 992 of file MucCalibMgr.cxx.

993{
994 int stripMax, boxID, stripID;
995 stripMax = boxID = stripID = 0;
996 double totalArea = 0;
997
998 for( int i=0; i<PART_MAX; i++ )
999 for( int j=0; j<((i==BRID)?B_SEG_NUM:E_SEG_NUM); j++ )
1000 for( int k=0; k<((i==BRID)?B_LAY_NUM:E_LAY_NUM); k++ )
1001 {
1002 MucBoxCal* aBox = new MucBoxCal( i, j, k );
1003 boxID = m_ptrIdTr->GetBoxId(i, j, k);
1004 m_boxResults[3][boxID] = aBox->GetArea();
1005 m_layerResults[3][k] += aBox->GetArea();
1006 delete aBox;
1007
1008 stripMax = m_ptrIdTr->GetStripMax( i, j, k );
1009 for( int m=0; m<stripMax; m++ )
1010 {
1011 MucStripCal* aStrip = new MucStripCal( i, j, k, m );
1012 stripID =m_ptrIdTr->GetStripId(i, j, k, m );
1013 m_stripResults[3][stripID] = aStrip->GetArea();
1014 totalArea += m_stripResults[3][stripID];
1015 delete aStrip;
1016 }
1017 }
1018
1019 for( int i=0; i<LAYER_MAX; i++ ) m_hLayerArea->Fill(i, m_layerResults[3][i]);
1020 for( int i=0; i<BOX_MAX; i++ ) m_hBoxArea->Fill(i, m_boxResults[3][i]);
1021 for( int i=0; i<STRIP_MAX; i++ ) m_hStripArea->Fill(i, m_stripResults[3][i]);
1022
1023 m_fTotalStripArea = totalArea;
1024
1025 return StatusCode::SUCCESS;
1026}
double GetArea()

Referenced by MucCalibMgr().

◆ InitArea() [2/2]

StatusCode MucCalibMgr::InitArea ( )

◆ InitClusterHisto() [1/2]

StatusCode MucCalibMgr::InitClusterHisto ( )
protected

Definition at line 839 of file MucCalibMgr.cxx.

840{
841 char name[60];
842 char title[60];
843 int part, segment, layer, stripMax;
844 part = segment = layer = stripMax = 0;
845
846 for( int i=0; i<LAYER_MAX; i++ )
847 {
848 sprintf( name, "LayerCluster_L%d", i );
849 sprintf( title, "Clusters in L%d",i );
850 m_hLayerCluster[i] = new TH1F(name,title, CLUSTER_RANGE, 0, CLUSTER_RANGE );
851 }
852
853 for( int i=0; i<BOX_MAX; i++ )
854 {
855 m_ptrIdTr->SetBoxPos( i, &part, &segment, &layer );
856 stripMax = m_ptrIdTr->GetStripMax( part, segment, layer );
857 sprintf( name, "BoxCluster_P%d_S%d_L%d_Box%d", part, segment, layer, i );
858 sprintf( title, "Clusters in P%d_S%d_L%d Box%d", part, segment, layer, i );
859 m_hBoxCluster[i] = new TH1F(name,title, CLUSTER_RANGE, 0, CLUSTER_RANGE );
860 }
861
862 m_hLayerClusterCmp = new TH1F("LayerCluster", "LayerCluster", LAYER_MAX+1, -0.5, LAYER_MAX+0.5 );
863 m_hBoxClusterCmp = new TH1F("BoxCluster", "BoxCluster", BOX_MAX+1, -0.5, BOX_MAX+0.5 );
864
865 return StatusCode::SUCCESS;
866}
titledef title[20]

Referenced by InitHisto().

◆ InitClusterHisto() [2/2]

StatusCode MucCalibMgr::InitClusterHisto ( )
protected

◆ InitConstTree() [1/2]

StatusCode MucCalibMgr::InitConstTree ( )
protected

Definition at line 897 of file MucCalibMgr.cxx.

898{
899 MsgStream log(msgSvc, "MucCalibMgr");
900 log << MSG::INFO << "Initialize Trees" << endreq;
901
902 // job log tree
903 m_tJobLog = new TTree("JobLog","Job information");
904 m_tJobLog->Branch("version", &m_vs, "m_vs/D");
905 m_tJobLog->Branch("high_voltage", &m_hv, "m_hv/D");
906 m_tJobLog->Branch("threshold", &m_th, "m_th/D");
907 m_tJobLog->Branch("event_rate", &m_er, "m_er/D");
908 m_tJobLog->Branch("input_tag", &m_tag, "m_tag/D");
909 m_tJobLog->Branch("rec_mode", &m_recMode, "m_recMode/I");
910 m_tJobLog->Branch("use_pad", &m_usePad, "m_usePad/I");
911 m_tJobLog->Branch("eff_window", &m_effWindow, "m_effWindow/I");
912 m_tJobLog->Branch("cluster_mode", &m_clusterMode, "m_clusterMode/I");
913 m_tJobLog->Branch("check_event", &m_checkEvent, "m_checkEvent/I");
914 m_tJobLog->Branch("dimu_select", &m_dimuSelect, "m_dimuSelect/I");
915 m_tJobLog->Branch("dimu_only", &m_dimuOnly, "m_dimuOnly/I");
916
917 m_tJobLog->Branch("run_start", &m_fStartRun, "m_fStartRun/I");
918 m_tJobLog->Branch("run_end", &m_fEndRun, "m_fEndRun/I");
919 m_tJobLog->Branch("daq_time", &m_fTotalDAQTime, "m_fTotalDAQTime/D");
920 m_tJobLog->Branch("job_time", &m_fTotalJobTime, "m_fTotalJobTime/D");
921 m_tJobLog->Branch("calib_layer", &m_fCalibLayerNum, "m_fCalibLayerNum/D");
922 m_tJobLog->Branch("calib_box", &m_fCalibBoxNum, "m_fCalibBoxNum/D");
923 m_tJobLog->Branch("calib_strip", &m_fCalibStripNum, "m_fCalibStripNum/D");
924 m_tJobLog->Branch("total_event", &m_fTotalEvent, "m_fTotalEvent/D");
925 m_tJobLog->Branch("total_digi", &m_fTotalDigi, "m_fTotalDigi/D");
926 m_tJobLog->Branch("total_exphit", &m_fTotalExpHit, "m_fTotalExpHit/D");
927 m_tJobLog->Branch("total_effhit", &m_fTotalEffHit, "m_fTotalEffHit/D");
928 m_tJobLog->Branch("total_noshit", &m_fTotalNosHit, "m_fTotalNosHit/D");
929 m_tJobLog->Branch("total_cluster", &m_fTotalClstNum, "m_fTotalClstNum/D");
930 m_tJobLog->Branch("total_strip_area",&m_fTotalStripArea,"m_fTotalStripArea/D");
931 m_tJobLog->Branch("layer_coverage", &m_fLayerCoverage, "m_fLayerCoverage/D");
932 m_tJobLog->Branch("box_coverage", &m_fBoxCoverage, "m_fBoxCoverage/D");
933 m_tJobLog->Branch("strip_coverage", &m_fStripCoverage, "m_fStripCoverage/D");
934
935 // statistic log tree
936 m_tStatLog = new TTree("StatLog","Statistic results");
937
938 // layer constants tree, level 0
939 m_tLayConst = new TTree("LayConst","layer constants");
940 m_tLayConst->Branch("layer_id", &m_fLayerId, "m_fLayerId/D");
941 m_tLayConst->Branch("layer_eff", &m_fLayerEff, "m_fLayerEff/D");
942 m_tLayConst->Branch("layer_efferr", &m_fLayerEffErr, "m_fLayerEffErr/D");
943 m_tLayConst->Branch("layer_nosratio", &m_fLayerNosRatio,"m_fLayerNosRatio/D");
944 m_tLayConst->Branch("layer_digi", &m_fLayerDigi, "m_fLayerDigi/D");
945 m_tLayConst->Branch("layer_noise", &m_fLayerNos, "m_fLayerNos/D");
946 m_tLayConst->Branch("layer_cnt", &m_fLayerCnt, "m_fLayerCnt/D");
947 m_tLayConst->Branch("layer_exphit", &m_fLayerExpHit, "m_fLayerExpHit/D");
948 m_tLayConst->Branch("layer_effHit", &m_fLayerEffHit, "m_fLayerEffHit/D");
949 m_tLayConst->Branch("layer_nosHit", &m_fLayerNosHit, "m_fLayerNosHit/D");
950 m_tLayConst->Branch("layer_cluster", &m_fLayerCluster, "m_fLayerCluster/D");
951 m_tLayConst->Branch("layer_trknum", &m_fLayerTrkNum, "m_fLayerTrkNum/D");
952
953 // box constants tree, level 1
954 m_tBoxConst = new TTree("BoxConst","box constants");
955 m_tBoxConst->Branch("box_id", &m_fBoxId, "m_fBoxId/D");
956 m_tBoxConst->Branch("box_part", &m_fBoxPart, "m_fBoxPart/D");
957 m_tBoxConst->Branch("box_segment", &m_fBoxSegment, "m_fBoxSegment/D");
958 m_tBoxConst->Branch("box_layer", &m_fBoxLayer, "m_fBoxLayer/D");
959 m_tBoxConst->Branch("box_eff", &m_fBoxEff, "m_fBoxEff/D");
960 m_tBoxConst->Branch("box_efferr", &m_fBoxEffErr, "m_fBoxEffErr/D");
961 m_tBoxConst->Branch("box_nosratio", &m_fBoxNosRatio,"m_fBoxNosRatio/D");
962 m_tBoxConst->Branch("box_digi", &m_fBoxDigi, "m_fBoxDigi/D");
963 m_tBoxConst->Branch("box_noise", &m_fBoxNos, "m_fBoxNos/D");
964 m_tBoxConst->Branch("box_cnt", &m_fBoxCnt, "m_fBoxCnt/D");
965 m_tBoxConst->Branch("box_exphit", &m_fBoxExpHit, "m_fBoxExpHit/D");
966 m_tBoxConst->Branch("box_effhit", &m_fBoxEffHit, "m_fBoxEffHit/D");
967 m_tBoxConst->Branch("box_noshit", &m_fBoxNosHit, "m_fBoxNosHit/D");
968 m_tBoxConst->Branch("box_cluster", &m_fBoxCluster, "m_fBoxCluster/D");
969 m_tBoxConst->Branch("box_trknum", &m_fBoxTrkNum, "m_fBoxTrkNum/D");
970
971 // strip constants tree, level 2
972 m_tStrConst = new TTree("StrConst","strip constants");
973 m_tStrConst->Branch("strip_id", &m_fStripId, "m_fStripId/D");
974 m_tStrConst->Branch("strip_part", &m_fStripPart, "m_fStripPart/D");
975 m_tStrConst->Branch("strip_segment", &m_fStripSegment, "m_fStripSegment/D");
976 m_tStrConst->Branch("strip_layer", &m_fStripLayer, "m_fStripLayer/D");
977 m_tStrConst->Branch("strip_eff", &m_fStripEff, "m_fStripEff/D");
978 m_tStrConst->Branch("strip_efferr", &m_fStripEffErr, "m_fStripEffErr/D");
979 m_tStrConst->Branch("strip_nosratio", &m_fStripNosRatio, "m_fStripNosRatio/D");
980 m_tStrConst->Branch("strip_digi", &m_fStripDigi, "m_fStripDigi/D");
981 m_tStrConst->Branch("strip_noise", &m_fStripNos, "m_fStripNos/D");
982 m_tStrConst->Branch("strip_cnt", &m_fStripCnt, "m_fStripCnt/D");
983 m_tStrConst->Branch("strip_effhit", &m_fStripEffHit, "m_fStripEffHit/D");
984 m_tStrConst->Branch("strip_exphit", &m_fStripExpHit, "m_fStripExpHit/D");
985 m_tStrConst->Branch("strip_noshit", &m_fStripNosHit, "m_fStripNosHit/D");
986 m_tStrConst->Branch("strip_trknum", &m_fStripTrkNum, "m_fStripTrkNum/D");
987
988 return StatusCode::SUCCESS;
989}

Referenced by MucCalibMgr().

◆ InitConstTree() [2/2]

StatusCode MucCalibMgr::InitConstTree ( )
protected

◆ InitHisto() [1/2]

StatusCode MucCalibMgr::InitHisto ( )

Definition at line 576 of file MucCalibMgr.cxx.

577{
578 MsgStream log(msgSvc, "MucCalibMgr");
579 log << MSG::INFO << "Initialize Histograms" << endreq;
580
581 // Init online monitor histo
583
584 // Init eff map and so on
585 InitHistoLV2();
586 InitHistoLV1();
587 InitHistoLV0();
588
589 // Init 2D eff map
590 if( m_usePad != 0 ) Init2DEffHisto();
591
592 // Init cluster histo
594
595 // Init spacial resolution histo
596 InitResHisto();
597
598 return StatusCode::SUCCESS;
599}
StatusCode InitResHisto()
StatusCode InitOnlineHisto()
StatusCode Init2DEffHisto()
StatusCode InitHistoLV1()
StatusCode InitHistoLV2()
StatusCode InitClusterHisto()
StatusCode InitHistoLV0()

Referenced by MucCalibMgr().

◆ InitHisto() [2/2]

StatusCode MucCalibMgr::InitHisto ( )

◆ InitHistoLV0() [1/2]

StatusCode MucCalibMgr::InitHistoLV0 ( )
protected

Definition at line 705 of file MucCalibMgr.cxx.

706{
707 m_hBrLayerFire = new TH1F("BrLayerFire","Fires per layer in Barrel", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
708 m_hEcLayerFire = new TH1F("EcLayerFire","Fires per layer in Endcap", 2*LAYER_MAX-1, -LAYER_MAX+1, LAYER_MAX-0.5);
709
710 m_hLayerFire = new TH1F("LayerFire","Fires per layer", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
711 m_hLayerExpHit = new TH1F("LayerExpHit","Exp hits per layer", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
712 m_hLayerEffHit = new TH1F("LayerEffHit","Eff hits per layer", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
713 m_hLayerNosHit = new TH1F("LayerNosHit","Nos hits per layer", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
714 m_hLayerEff = new TH1F("LayerEff","Layer efficiency", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
715 m_hLayerNosRatio= new TH1F("LayerNosRatio","Layer noise hit ratio", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
716 m_hLayerArea = new TH1F("LayerArea","Layer area", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
717 m_hLayerNos = new TH1F("LayerNos","Layer noise", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
718 m_hLayerCnt = new TH1F("LayerCnt","Layer count", LAYER_MAX+1, -0.5, LAYER_MAX+0.5);
719
720 return StatusCode::SUCCESS;
721}

Referenced by InitHisto().

◆ InitHistoLV0() [2/2]

StatusCode MucCalibMgr::InitHistoLV0 ( )
protected

◆ InitHistoLV1() [1/2]

StatusCode MucCalibMgr::InitHistoLV1 ( )
protected

Definition at line 724 of file MucCalibMgr.cxx.

725{
726 m_hBoxFire = new TH1F("BoxFire","Fires per box", BOX_MAX+1, -0.5, BOX_MAX+0.5);
727 m_hBoxExpHit = new TH1F("BoxExpHit","Exp hits per box", BOX_MAX+1, -0.5, BOX_MAX+0.5);
728 m_hBoxEffHit = new TH1F("BoxEffHit","Eff hits per box", BOX_MAX+1, -0.5, BOX_MAX+0.5);
729 m_hBoxNosHit = new TH1F("BoxNosHit","Nos hits per box", BOX_MAX+1, -0.5, BOX_MAX+0.5);
730 m_hBoxEff = new TH1F("BoxEff","Box efficiency", BOX_MAX+1, -0.5, BOX_MAX+0.5);
731 m_hBoxNosRatio = new TH1F("BoxNosRatio","Box noise hit ratio", BOX_MAX+1, -0.5, BOX_MAX+0.5);
732 m_hBoxArea = new TH1F("BoxArea","Box area", BOX_MAX+1, -0.5, BOX_MAX+0.5);
733 m_hBoxNos = new TH1F("BoxNos","Box noise", BOX_MAX+1, -0.5, BOX_MAX+0.5);
734 m_hBoxCnt = new TH1F("BoxCnt","Box count", BOX_MAX+1, -0.5, BOX_MAX+0.5);
735
736 return StatusCode::SUCCESS;
737}

Referenced by InitHisto().

◆ InitHistoLV1() [2/2]

StatusCode MucCalibMgr::InitHistoLV1 ( )
protected

◆ InitHistoLV2() [1/2]

StatusCode MucCalibMgr::InitHistoLV2 ( )
protected

Definition at line 740 of file MucCalibMgr.cxx.

741{
742 char name[60];
743 char title[60];
744 int part, segment, layer, stripMax;
745 part = segment = layer = stripMax = 0;
746
747 for( int i=0; i<BOX_MAX; i++ )
748 {
749 m_ptrIdTr->SetBoxPos( i, &part, &segment, &layer );
750 stripMax = m_ptrIdTr->GetStripMax( part, segment, layer );
751
752 sprintf( name, "StripFireMap_P%d_S%d_L%d_Box%d", part, segment, layer, i );
753 sprintf( title, "Fires per strip in P%d_S%d_L%d Box%d",part, segment, layer, i );
754 m_hStripFireMap[i] = new TH1F(name,title, stripMax, 0, stripMax);
755
756 sprintf( name, "StripExpHitMap_P%d_S%d_L%d_Box%d", part, segment, layer, i );
757 sprintf( title, "Exp hits per strip in P%d_S%d_L%d Box%d",part, segment, layer, i );
758 m_hStripExpHitMap[i] = new TH1F(name,title, stripMax, 0, stripMax);
759
760 sprintf( name, "StripEffHitMap_P%d_S%d_L%d_Box%d", part, segment, layer, i );
761 sprintf( title, "Eff hits per strip in P%d_S%d_L%d Box%d",part, segment, layer, i );
762 m_hStripEffHitMap[i] = new TH1F(name,title, stripMax, 0, stripMax);
763
764 sprintf( name, "StripNosHitMap_P%d_S%d_L%d_Box%d", part, segment, layer, i );
765 sprintf( title, "Inc hits per strip in P%d_S%d_L%d Box%d",part, segment, layer, i );
766 m_hStripNosHitMap[i] = new TH1F(name,title, stripMax, 0, stripMax);
767
768 sprintf( name, "StripEffMap_P%d_S%d_L%d_Box%d", part, segment, layer, i );
769 sprintf( title, "Strip efficiency in P%d_S%d_L%d Box%d",part, segment, layer, i );
770 m_hStripEffMap[i] = new TH1F(name,title, stripMax, 0, stripMax);
771
772 sprintf( name, "StripNosRatioMap_P%d_S%d_L%d_Box%d", part, segment, layer, i );
773 sprintf( title, "Strip noise hit ratio in P%d_S%d_L%d Box%d",part, segment, layer, i );
774 m_hStripNosRatioMap[i] = new TH1F(name,title, stripMax, 0, stripMax);
775 }
776
777 m_hStripFire = new TH1F("StripFire", "Fires per strip", STRIP_MAX+1, -0.5, STRIP_MAX+0.5 );
778 m_hStripExpHit = new TH1F("StripExpHit", "Exp hit per strip", STRIP_MAX+1, -0.5, STRIP_MAX+0.5 );
779 m_hStripEffHit = new TH1F("StripEffHit", "Eff hit per strip", STRIP_MAX+1, -0.5, STRIP_MAX+0.5 );
780 m_hStripNosHit = new TH1F("StripNoshit", "Nos hit per strip", STRIP_MAX+1, -0.5, STRIP_MAX+0.5 );
781 m_hStripEff = new TH1F("StripEff", "Strip efficiency", STRIP_MAX+1, -0.5, STRIP_MAX+0.5 );
782 m_hStripNosRatio= new TH1F("StripNosRatio", "Strip noise hit ratio", STRIP_MAX+1, -0.5, STRIP_MAX+0.5 );
783 m_hStripArea = new TH1F("StripArea", "Strip area", STRIP_MAX+1, -0.5, STRIP_MAX+0.5 );
784 m_hStripNos = new TH1F("StripNos", "Strip noise", STRIP_MAX+1, -0.5, STRIP_MAX+0.5 );
785 m_hStripCnt = new TH1F("StripCnt", "Strip count", STRIP_MAX+1, -0.5, STRIP_MAX+0.5 );
786
787 return StatusCode::SUCCESS;
788}

Referenced by InitHisto().

◆ InitHistoLV2() [2/2]

StatusCode MucCalibMgr::InitHistoLV2 ( )
protected

◆ InitNtuple() [1/2]

StatusCode MucCalibMgr::InitNtuple ( )

Definition at line 374 of file MucCalibMgr.cxx.

375{
376 MsgStream log(msgSvc, "MucCalibMgr");
377 log << MSG::INFO << "Initialize NTuples" << endreq;
378
379 // Book ntuple
380 Gaudi::svcLocator() -> service("NTupleSvc", ntupleSvc);
381
382 StatusCode sc;
383
384 // event log
385 NTuplePtr nt1(ntupleSvc, "FILE450/EventLog");
386 if ( nt1 ) { m_eventLogTuple = nt1; }
387 else
388 {
389 m_eventLogTuple = ntupleSvc->book ("FILE450/EventLog", CLID_RowWiseTuple, "MucCalibConst N-Tuple");
390 if ( m_eventLogTuple )
391 {
392 sc = m_eventLogTuple->addItem ("event_id", m_ntEventId);
393 sc = m_eventLogTuple->addItem ("event_tag", m_ntEventTag);
394 sc = m_eventLogTuple->addItem ("start_time", m_ntEsTime);
395 sc = m_eventLogTuple->addItem ("digi_num", m_ntDigiNum);
396 sc = m_eventLogTuple->addItem ("track_num", m_ntTrackNum);
397 sc = m_eventLogTuple->addItem ("exphit_num", m_ntExpHitNum);
398 sc = m_eventLogTuple->addItem ("effhit_num", m_ntEffHitNum);
399 sc = m_eventLogTuple->addItem ("noshit_num", m_ntNosHitNum);
400 sc = m_eventLogTuple->addItem ("cluster_num", m_ntClusterNum);
401 sc = m_eventLogTuple->addItem ("event_time", m_ntEventTime);
402 }
403 else {
404 log << MSG::ERROR << "Cannot book N-tuple:" << long(m_eventLogTuple) << endmsg;
405 return StatusCode::FAILURE;
406 }
407 }
408
409 // track info
410
411 NTuplePtr nt2(ntupleSvc, "FILE450/MdcTrkInfo");
412 if ( nt2 ) { m_mdcTrkInfoTuple = nt2; }
413 else
414 {
415 m_mdcTrkInfoTuple = ntupleSvc->book ("FILE450/MdcTrkInfo", CLID_RowWiseTuple, "MucCalibConst N-Tuple");
416 if ( m_mdcTrkInfoTuple )
417 {
418 sc = m_mdcTrkInfoTuple->addItem ("charge", m_charge);
419 sc = m_mdcTrkInfoTuple->addItem ("mdcpx", m_mdcpx);
420 sc = m_mdcTrkInfoTuple->addItem ("mdcpy", m_mdcpy);
421 sc = m_mdcTrkInfoTuple->addItem ("mdcpz", m_mdcpz);
422 sc = m_mdcTrkInfoTuple->addItem ("mdcpt", m_mdcpt);
423 sc = m_mdcTrkInfoTuple->addItem ("mdcpp", m_mdcpp);
424 sc = m_mdcTrkInfoTuple->addItem ("mdcphi", m_mdcphi);
425 sc = m_mdcTrkInfoTuple->addItem ("mdctheta", m_mdctheta);
426 }
427 else {
428 log << MSG::ERROR << "Cannot book N-tuple:" << long(m_mdcTrkInfoTuple) << endmsg;
429 return StatusCode::FAILURE;
430 }
431 }
432
433
434 NTuplePtr nt3(ntupleSvc, "FILE450/TrackInfo");
435 if ( nt3 ) { m_trackInfoTuple = nt3; }
436 else
437 {
438 m_trackInfoTuple = ntupleSvc->book ("FILE450/TrackInfo", CLID_RowWiseTuple, "MucCalibConst N-Tuple");
439 if ( m_trackInfoTuple )
440 {
441 sc = m_trackInfoTuple->addItem ("track_event", m_ntTrackEvent);
442 sc = m_trackInfoTuple->addItem ("track_tag", m_ntTrackTag);
443 sc = m_trackInfoTuple->addItem ("track_hits", m_ntTrackHits);
444 sc = m_trackInfoTuple->addItem ("segment_fly", m_ntTrackSegFly);
445 sc = m_trackInfoTuple->addItem ("layer_fly_a", m_ntTrackLayFlyA);
446 sc = m_trackInfoTuple->addItem ("layer_fly_b", m_ntTrackLayFlyB);
447 sc = m_trackInfoTuple->addItem ("layer_fly_c", m_ntTrackLayFlyC);
448 sc = m_trackInfoTuple->addItem ("rec_mode", m_trkRecMode);
449 sc = m_trackInfoTuple->addItem ("chi2", m_chi2);
450 sc = m_trackInfoTuple->addItem ("px", m_px);
451 sc = m_trackInfoTuple->addItem ("py", m_py);
452 sc = m_trackInfoTuple->addItem ("pz", m_pz);
453 sc = m_trackInfoTuple->addItem ("pt", m_pt);
454 sc = m_trackInfoTuple->addItem ("pp", m_pp);
455 sc = m_trackInfoTuple->addItem ("r", m_r );
456 sc = m_trackInfoTuple->addItem ("costheta", m_cosTheta);
457 sc = m_trackInfoTuple->addItem ("theta", m_theta);
458 sc = m_trackInfoTuple->addItem ("phi", m_phi);
459 sc = m_trackInfoTuple->addItem ("depth", m_depth);
460 sc = m_trackInfoTuple->addItem ("br_last_lay", m_brLastLayer);
461 sc = m_trackInfoTuple->addItem ("ec_last_lay", m_ecLastLayer);
462 sc = m_trackInfoTuple->addItem ("total_hits", m_totalHits);
463 sc = m_trackInfoTuple->addItem ("fired_layers", m_totalLayers);
464 sc = m_trackInfoTuple->addItem ("maxhits_in_layer", m_maxHitsInLayer);
465 }
466 else {
467 log << MSG::ERROR << "Cannot book N-tuple:" << long(m_trackInfoTuple) << endmsg;
468 return StatusCode::FAILURE;
469 }
470 }
471
472 // track collinearity
473 NTuplePtr nt4(ntupleSvc, "FILE450/TrackDiff");
474 if ( nt4 ) { m_trackDiffTuple = nt4; }
475 else
476 {
477 m_trackDiffTuple = ntupleSvc->book ("FILE450/TrackDiff", CLID_RowWiseTuple, "MucCalibConst N-Tuple");
478 if ( m_trackDiffTuple ) {
479 sc = m_trackDiffTuple->addItem ("dimu_tag", m_ntDimuTag);
480 sc = m_trackDiffTuple->addItem ("pos_phi_diff", m_ntPosPhiDiff);
481 sc = m_trackDiffTuple->addItem ("pos_theta_diff", m_ntPosThetaDiff);
482 sc = m_trackDiffTuple->addItem ("mom_phi_diff", m_ntMomPhiDiff);
483 sc = m_trackDiffTuple->addItem ("mom_theta_diff", m_ntMomThetaDiff);
484 }
485 else {
486 log << MSG::ERROR << "Cannot book N-tuple:" << long(m_trackDiffTuple) << endmsg;
487 return StatusCode::FAILURE;
488 }
489 }
490
491 // cluster size
492 NTuplePtr nt5(ntupleSvc, "FILE450/ClusterSize");
493 if ( nt5 ) { m_clusterSizeTuple = nt5; }
494 else
495 {
496 m_clusterSizeTuple = ntupleSvc->book ("FILE450/ClusterSize", CLID_RowWiseTuple, "MucCalibConst N-Tuple");
497 if ( m_clusterSizeTuple ) {
498 sc = m_clusterSizeTuple->addItem ("cluster_size", m_ntClusterSize);
499 }
500 else {
501 log << MSG::ERROR << "Cannot book N-tuple:" << long(m_clusterSizeTuple) << endmsg;
502 return StatusCode::FAILURE;
503 }
504 }
505
506 // eff window
507 NTuplePtr nt6(ntupleSvc, "FILE450/EffWindow");
508 if ( nt6 ) { m_effWindowTuple = nt6; }
509 else
510 {
511 m_effWindowTuple = ntupleSvc->book ("FILE450/EffWindow", CLID_RowWiseTuple, "MucCalibConst N-Tuple");
512 if ( m_effWindowTuple ) {
513 sc = m_effWindowTuple->addItem ("hit_window", m_ntEffWindow);
514 }
515 else {
516 log << MSG::ERROR << "Cannot book N-tuple:" << long(m_effWindowTuple) << endmsg;
517 return StatusCode::FAILURE;
518 }
519 }
520 // res info
521 NTuplePtr nt7(ntupleSvc, "FILE450/ResInfo");
522 if ( nt7 ) { m_resInfoTuple = nt7; }
523 else
524 {
525 m_resInfoTuple = ntupleSvc->book ("FILE450/ResInfo", CLID_RowWiseTuple, "MucCalibConst N-Tuple");
526 if ( m_resInfoTuple ) {
527 sc = m_resInfoTuple->addItem ("line_res", m_lineRes);
528 sc = m_resInfoTuple->addItem ("quad_res", m_quadRes);
529 sc = m_resInfoTuple->addItem ("extr_res", m_extrRes);
530 sc = m_resInfoTuple->addItem ("res_part", m_resPart);
531 sc = m_resInfoTuple->addItem ("res_segment", m_resSegment);
532 sc = m_resInfoTuple->addItem ("res_layer", m_resLayer);
533 sc = m_resInfoTuple->addItem ("res_fired", m_resFired);
534 sc = m_resInfoTuple->addItem ("res_mode", m_resMode);
535 }
536 else {
537 log << MSG::ERROR << "Cannot book N-tuple:" << long(m_resInfoTuple) << endmsg;
538 return StatusCode::FAILURE;
539 }
540 }
541
542/*
543 NTuplePtr nt7(ntupleSvc, "FILE450/ResInfo");
544 if ( nt7 ) { m_resInfoTuple = nt7; }
545 else
546 {
547 m_resInfoTuple = ntupleSvc->book ("FILE450/ResInfo", CLID_ColumnWiseTuple, "MucCalibConst N-Tuple");
548 if ( m_resInfoTuple ) {
549 sc = m_resInfoTuple->addItem ("exp_num", m_nExpNum, 0, 30);
550 sc = m_resInfoTuple->addIndexedItem ("res", m_nExpNum, m_res);
551 sc = m_resInfoTuple->addIndexedItem ("res_part", m_nExpNum, m_resPart);
552 sc = m_resInfoTuple->addIndexedItem ("res_segment", m_nExpNum, m_resSegment);
553 sc = m_resInfoTuple->addIndexedItem ("res_layer", m_nExpNum, m_resLayer);
554 sc = m_resInfoTuple->addIndexedItem ("res_fired", m_nExpNum, m_resFired);
555 }
556 else {
557 log << MSG::ERROR << "Cannot book N-tuple:" << long(m_resInfoTuple) << endmsg;
558 return StatusCode::FAILURE;
559 }
560 }
561
562 for(int i=0; i<24; i++ )
563 {
564 m_res[i] = 211;
565 m_resPart[i] = -1;
566 m_resSegment[i] = -1;
567 m_resLayer[i] = -1;
568 m_resFired[i] = false;
569 }
570*/
571
572 return StatusCode::SUCCESS;
573}

Referenced by MucCalibMgr().

◆ InitNtuple() [2/2]

StatusCode MucCalibMgr::InitNtuple ( )

◆ InitOnlineHisto() [1/2]

StatusCode MucCalibMgr::InitOnlineHisto ( )
protected

Definition at line 602 of file MucCalibMgr.cxx.

603{
604 char name[60];
605 char title[60];
606 int stripMax = 0;
607
608 // Init hit map
609 for( int i=0; i<B_LAY_NUM; i++ )
610 {
611 // According to layer
612 if(i%2 != 0 ) { stripMax = 96*7 + 112; }
613 else { stripMax = 48*8; }
614 sprintf( name, "HitMapBarrel_Lay_L%d", i );
615 sprintf( title, "Hit map in barrel layer %d", i );
616 m_hHitMapBarrel_Lay[i] = new TH1F(name,title, stripMax, 0, stripMax);
617
618 if( i<E_LAY_NUM )
619 {
620 stripMax = 64*4; // 256
621 sprintf( name, "HitMapEastEndcap_L%d", i );
622 sprintf( title, "Hit map in east-endcap layer %d", i );
623 m_hHitMapEndcap_Lay[0][i] = new TH1F(name,title, stripMax, 0, stripMax);
624
625 sprintf( name, "HitMapWestEndcap_L%d", i );
626 sprintf( title, "Hit map in west-endcap layer %d", i );
627 m_hHitMapEndcap_Lay[1][i] = new TH1F(name,title, stripMax, 0, stripMax);
628 }
629
630 }
631
632 for( int i=0; i<B_SEG_NUM; i++ )
633 {
634 // According to segment
635 sprintf( name, "HitMapBarrel_Seg_S%d", i );
636 sprintf( title, "Hit map in barrel segment %d", i );
637 if(i==2 ) { stripMax = 48*5 + 112*4; } // 688
638 else { stripMax = 48*5 + 96*4; } // 624
639 m_hHitMapBarrel_Seg[i] = new TH1F(name,title, stripMax, 0, stripMax);
640
641 if( i<E_SEG_NUM )
642 {
643 sprintf( name, "HitMapEastEndcap_S%d", i );
644 sprintf( title, "Hit map in east-endcap segment %d", i );
645 stripMax = 64*8; // 512
646 m_hHitMapEndcap_Seg[0][i] = new TH1F(name,title, stripMax, 0, stripMax);
647
648 sprintf( name, "HitMapWestEndcap_S%d", i );
649 sprintf( title, "Hit map in west-endcap segment %d", i );
650 m_hHitMapEndcap_Seg[1][i] = new TH1F(name,title, stripMax, 0, stripMax);
651 }
652 }
653
654 // Init histograms for online monitor
655 // 1D histograms
656 m_hHitVsEvent = new TH1F("HitVsEvent","Hit VS event",10000,0,10000);
657 m_hHitVsEvent->GetXaxis()->SetTitle("Event NO.");
658 m_hHitVsEvent->GetXaxis()->CenterTitle();
659 m_hHitVsEvent->GetYaxis()->SetTitle("Hits");
660 m_hHitVsEvent->GetYaxis()->CenterTitle();
661
662 m_hTrackDistance = new TH1F("TrackDistance","Track distance", 1000,-500,500);
663 m_hTrackDistance->GetXaxis()->SetTitle("Distance of fit pos and hit pos on 1st layer [cm]");
664 m_hTrackDistance->GetXaxis()->CenterTitle();
665
666 m_hTrackPosPhiDiff = new TH1F("TrackPosPhiDiff","#Delta#phi of tracks pos", 720,-2*PI,2*PI);
667 m_hTrackPosPhiDiff->GetXaxis()->SetTitle("#Delta#phi [rad]");
668 m_hTrackPosPhiDiff->GetXaxis()->CenterTitle();
669
670 m_hTrackPosThetaDiff = new TH1F("TrackPosThetaDiff","#Delta#theta of tracks pos", 720,-2*PI,2*PI);
671 m_hTrackPosThetaDiff->GetXaxis()->SetTitle("#Delta#theta [rad]");
672 m_hTrackPosThetaDiff->GetXaxis()->CenterTitle();
673
674 m_hTrackMomPhiDiff = new TH1F("TrackMomPhiDiff","#Delta#phi of tracks mom", 720,-2*PI,2*PI);
675 m_hTrackMomPhiDiff->GetXaxis()->SetTitle("#Delta#phi [rad]");
676 m_hTrackMomPhiDiff->GetXaxis()->CenterTitle();
677
678 m_hTrackMomThetaDiff = new TH1F("TrackMomThetaDiff","#Delta#theta of tracks mom", 720,-2*PI,2*PI);
679 m_hTrackMomThetaDiff->GetXaxis()->SetTitle("#Delta#theta [rad]");
680 m_hTrackMomThetaDiff->GetXaxis()->CenterTitle();
681
682 // 2D histograms
683 m_hDimuTracksPosDiff = new TH2F("DimuTracksPosDiff", "#Delta#phi VS #Delta#theta of dimu tracks pos", 720, -PI, PI, 720, -PI, PI);
684 m_hDimuTracksPosDiff->GetXaxis()->SetTitle("#Delta#theta");
685 m_hDimuTracksPosDiff->GetXaxis()->CenterTitle();
686 m_hDimuTracksPosDiff->GetYaxis()->SetTitle("#Delta#phi");
687 m_hDimuTracksPosDiff->GetYaxis()->CenterTitle();
688
689 m_hDimuTracksMomDiff = new TH2F("DimuTracksMomDiff", "#Delta#phi VS #Delta#theta of dimu tracks mom", 720, -PI, PI, 720, -PI, PI);
690 m_hDimuTracksMomDiff->GetXaxis()->SetTitle("#Delta#theta");
691 m_hDimuTracksMomDiff->GetXaxis()->CenterTitle();
692 m_hDimuTracksMomDiff->GetYaxis()->SetTitle("#Delta#phi");
693 m_hDimuTracksMomDiff->GetYaxis()->CenterTitle();
694
695 m_hPhiCosTheta = new TH2F("PhiVsCosTheta", "#phi VS cos(#theta)", 720, -1, 1, 720, -PI, PI);
696 m_hPhiCosTheta->GetXaxis()->SetTitle("cos(#theta)");
697 m_hPhiCosTheta->GetXaxis()->CenterTitle();
698 m_hPhiCosTheta->GetYaxis()->SetTitle("#phi");
699 m_hPhiCosTheta->GetYaxis()->CenterTitle();
700
701 return StatusCode::SUCCESS;
702}

Referenced by InitHisto().

◆ InitOnlineHisto() [2/2]

StatusCode MucCalibMgr::InitOnlineHisto ( )
protected

◆ InitResHisto() [1/2]

StatusCode MucCalibMgr::InitResHisto ( )
protected

Definition at line 869 of file MucCalibMgr.cxx.

870{
871 char name[60];
872 char title[60];
873
874 for( int i=0; i<B_LAY_NUM; i++ )
875 {
876 sprintf( name, "BarrelRes_L%d", i );
877 sprintf( title, "Barrel spacial resolution in L%d",i );
878 m_hBarrelResDist[i] = new TH1F(name,title, 200, -100, 100 );
879 }
880
881 for( int i=0; i<E_LAY_NUM; i++ )
882 {
883 sprintf( name, "EndcapRes_L%d", i );
884 sprintf( title, "Endcap spacial resolution in L%d",i );
885 m_hEndcapResDist[i] = new TH1F(name,title, 200, -100, 100 );
886 }
887
888 m_hBarrelResComp[0] = new TH1F("BarrelResMean", "BarrelResMean", B_LAY_NUM+1, -0.5, B_LAY_NUM+0.5 );
889 m_hBarrelResComp[1] = new TH1F("BarrelResSigma", "BarrelResSigma", B_LAY_NUM+1, -0.5, B_LAY_NUM+0.5 );
890 m_hEndcapResComp[0] = new TH1F("EndcapResMean", "EndcapResMean", E_LAY_NUM+1, -0.5, E_LAY_NUM+0.5 );
891 m_hEndcapResComp[1] = new TH1F("EndcapResSigma", "EndcapResSigma", E_LAY_NUM+1, -0.5, E_LAY_NUM+0.5 );
892
893 return StatusCode::SUCCESS;
894}

Referenced by InitHisto().

◆ InitResHisto() [2/2]

StatusCode MucCalibMgr::InitResHisto ( )
protected

◆ PadEff() [1/2]

StatusCode MucCalibMgr::PadEff ( )
protected

Definition at line 2433 of file MucCalibMgr.cxx.

2434{
2435 MsgStream log(msgSvc, "MucCalibMgr");
2436
2437 int xBinStart, xBinEnd, yBinStart, yBinEnd;
2438 double expHit, firedHit, eff;
2439 eff = expHit = firedHit = 0.;
2440
2441 for( int i=0; i<PART_MAX; i++ )
2442 for( int j=0; j<((i==BRID)?B_SEG_NUM:E_SEG_NUM); j++ )
2443 for( int k=0; k<((i==BRID)?B_LAY_NUM:E_LAY_NUM); k++ )
2444 {
2445 xBinStart = m_h2DExpMap[i][j][k]->GetXaxis()->GetFirst();
2446 xBinEnd = m_h2DExpMap[i][j][k]->GetXaxis()->GetLast() + 1;
2447 yBinStart = m_h2DExpMap[i][j][k]->GetYaxis()->GetFirst();
2448 yBinEnd = m_h2DExpMap[i][j][k]->GetYaxis()->GetLast() + 1;
2449
2450 for( int xi = xBinStart; xi<xBinEnd; xi++ )
2451 for( int yi = yBinStart; yi<yBinEnd; yi++ )
2452 {
2453 expHit = m_h2DExpMap[i][j][k]->GetBinContent(xi, yi);
2454 firedHit = m_h2DHitMap[i][j][k]->GetBinContent(xi, yi);
2455
2456 if( expHit !=0 ) eff = firedHit / expHit;
2457 else eff = 0;
2458
2459 if( eff>1.0 )
2460 cout<<"Eff error:\t["<<i<<"\t"<<j<<"\t"<<k<<",\t"<<xi<<"\t"<<yi<<"]:\t"
2461 <<eff<<"\t,"<<firedHit<<" "<<expHit<<endl;
2462
2463 m_h2DEffMap[i][j][k]->SetBinContent(xi, yi, eff);
2464 }
2465 }
2466 return StatusCode::SUCCESS;
2467}

Referenced by AnalyseEffAndNoise().

◆ PadEff() [2/2]

StatusCode MucCalibMgr::PadEff ( )
protected

◆ ReadEvent() [1/2]

StatusCode MucCalibMgr::ReadEvent ( )

Definition at line 1154 of file MucCalibMgr.cxx.

1155{
1156 MsgStream log(msgSvc, "MucCalibMgr");
1157 log << MSG::INFO << "Read event" << endreq;
1158
1159 Gaudi::svcLocator()->service("EventDataSvc", eventSvc);
1160 m_evtBegin = clock();
1161
1162 // Check event head
1163 SmartDataPtr<Event::EventHeader> eventHeader(eventSvc,"/Event/EventHeader");
1164 if(!eventHeader) {
1165 log << MSG::FATAL << "Could not find event header" << endreq;
1166 return( StatusCode::FAILURE );
1167 }
1168
1169 m_currentRun = eventHeader->runNumber();
1170 m_currentEvent = eventHeader->eventNumber();
1171 if( m_fStartRun == 0 ) m_fStartRun = m_currentRun;
1172 m_fEndRun = m_currentRun;
1173 m_fTotalEvent++;
1174
1175 log << MSG::INFO << "Run [ " << m_currentRun << " ]\tEvent [ " << m_currentEvent << " ]" << endreq;
1176 if( ((long)m_fTotalEvent)%2000 == 0 ) cout << m_fTotalEvent << "\tdone!" << endl;
1177
1178 // Select dimu
1179 if( m_dimuSelect ) {
1181 log << MSG::INFO << "Event tag:\t" << m_eventTag << endreq;
1182 if( m_dimuOnly && m_eventTag != 1 ) return( StatusCode::FAILURE );
1183 }
1184
1185 //---> Retrieve MUC digi
1186 log << MSG::INFO << "Retrieve digis" << endreq;
1187
1188 SmartDataPtr<MucDigiCol> mucDigiCol(eventSvc,"/Event/Digi/MucDigiCol");
1189 if(!mucDigiCol) {
1190 log << MSG::FATAL << "Could not find MUC digi" << endreq;
1191 return( StatusCode::FAILURE);
1192 }
1193
1194 int part, segment, layer, strip, pad;
1195 part = segment = layer = strip = pad = 0;
1196 double padX, padY, padZ;
1197 padX = padY = padZ = 0.;
1198 double resMax = 0.;
1199
1200 Identifier mucId;
1201 MucDigiCol::iterator digiIter = mucDigiCol->begin();
1202 int eventDigi = 0;
1203 for ( int digiId =0; digiIter != mucDigiCol->end(); digiIter++, digiId++ )
1204 {
1205 mucId = (*digiIter)->identify();
1206 part = MucID::barrel_ec(mucId);
1207 segment = MucID::segment(mucId);
1208 layer = MucID::layer(mucId);
1209 strip = MucID::channel(mucId);
1210
1211 log << MSG::DEBUG << "[" << part << "\t" << segment << "\t" << layer << "\t" << strip << "]\t" ;
1212 if( (digiId+1)%8 == 0 ) log << MSG::DEBUG << endreq;
1213
1214 eventDigi ++;
1215
1216 if(abs(part)>=PART_MAX || abs(segment)>=SEGMENT_MAX || abs(layer)>=LAYER_MAX || abs(strip)>=STRIP_INBOX_MAX) {
1217 log << MSG::ERROR << endreq << "Digi IDs slop over!" << endreq;
1218 continue;
1219 }
1220
1221 // Add digi
1222 MucMark *aMark = new MucMark( part, segment, layer, strip );
1223 m_digiCol.push_back( aMark );
1224 m_segDigiCol[part][segment].push_back( aMark );
1225 }
1226 log << MSG::DEBUG << endreq;
1227 log << MSG::INFO << "Total digits of this event: " << eventDigi << endreq;
1228 if( eventDigi > 200) log << MSG::ERROR << "Event: " << m_currentEvent << "\tdigits sharply rise:\t" << eventDigi << endreq;
1229
1230 /*
1231 if( (long)m_fTotalEvent%10000 == 0 ) {
1232 log << MSG::INFO << "Delete HitVsEvent." << endreq;
1233 if(m_hHitVsEvent != NULL) delete m_hHitVsEvent;
1234 m_hHitVsEvent = new TH1F("HitVsEvent","Hit VS event",10000,m_fTotalEvent,m_fTotalEvent+10000);
1235 m_hHitVsEvent->GetXaxis()->SetTitle("Event NO.");
1236 log << MSG::INFO << "Recreate HitVsEvent." << endreq;
1237 }
1238 log << MSG::INFO << "Fill HitVsEvent\t" << m_hHitVsEvent << "\t" << m_fTotalEvent << "\t" << m_currentEvent << endreq;
1239 //m_hHitVsEvent->Fill(m_currentEvent+m_currentEvent%10000, eventDigi);
1240 m_hHitVsEvent->Fill(m_fTotalEvent, eventDigi);
1241 log << MSG::INFO << "Fill HitVsEvent done." << endreq;
1242 */
1243
1244 // Search cluster in digis
1245 // Method detail in MucMark class
1246 int clusterNum, bigClusterNum, clusterSize;
1247 clusterNum = bigClusterNum = clusterSize = 0;
1248 if( m_clusterMode ) {
1249 log << MSG::INFO << "Searching clusters" << endreq;
1250 m_clusterCol = (*m_ptrMucMark).CreateClusterCol(m_clusterMode, m_digiCol );
1251 }
1252
1253 for( unsigned int i=0; i<m_clusterCol.size(); i++ )
1254 {
1255 clusterSize = m_clusterCol[i].size();
1256 // real cluster, size >= 2
1257 if( clusterSize > CLUSTER_ALARM )
1258 {
1259 log << MSG::WARNING << "Big cluster:" << endreq;
1260 part = (*m_clusterCol[i][0]).Part();
1261 segment = (*m_clusterCol[i][0]).Segment();
1262 layer = (*m_clusterCol[i][0]).Layer();
1263
1264 if( m_clusterSave ) (*m_fdata) << "Event:\t" << m_currentEvent << "\tbig cluster " << bigClusterNum << endl;
1265
1266 for( int j=0; j<clusterSize; j++ )
1267 {
1268 strip = (*m_clusterCol[i][j]).Strip();
1269 log << MSG::WARNING << "[" << part << "\t" << segment << "\t" << layer << "\t" << strip << "]\t";
1270 if( (j+1)%8 == 0 ) log << MSG::WARNING << endreq;
1271 if( m_clusterSave ) (*m_fdata) << part << "\t" << segment << "\t" << layer << "\t" << strip << endl;
1272 }
1273 log << MSG::WARNING << endreq;
1274 bigClusterNum ++;
1275 }
1276 else if( clusterSize > 1 )
1277 {
1278 log << MSG::DEBUG << "cluster: " << clusterNum << endreq;
1279 clusterNum ++, m_fTotalClstNum ++;
1280 part = (*m_clusterCol[i][0]).Part();
1281 segment = (*m_clusterCol[i][0]).Segment();
1282 layer = (*m_clusterCol[i][0]).Layer();
1283 for( int j=0; j<clusterSize; j++ )
1284 {
1285 strip = (*m_clusterCol[i][j]).Strip();
1286 log << MSG::DEBUG << "[" << part << "\t" << segment << "\t" << layer << "\t" << strip << "]\t";
1287 if( (j+1)%8 == 0 ) log << MSG::DEBUG << endreq;
1288 }
1289 log << MSG::DEBUG << endreq;
1290 }
1291 } // End m_clusterCol.size()
1292
1293 if( m_clusterMode) log << MSG::INFO << "Total clusters in this event: " << clusterNum << endreq;
1294 else log << MSG::INFO << "Clusters not built" << endreq;
1295 //<--- End retrieve digis
1296
1297 //---> Retrieve rec tracks
1298 log << MSG::INFO << "Retrieve tracks" << endreq;
1299 // MDC tracks
1300 SmartDataPtr<RecMdcTrackCol> mdcTrackCol(eventSvc,"/Event/Recon/RecMdcTrackCol");
1301 if(!mdcTrackCol) {
1302 log << MSG::FATAL << "Could not find mdc tracks" << endreq;
1303 return( StatusCode::FAILURE);
1304 }
1305
1306 RecMdcTrackCol::iterator mdctrkIter = mdcTrackCol->begin();
1307 for (; mdctrkIter != mdcTrackCol->end(); mdctrkIter++)
1308 {
1309 m_charge = (*mdctrkIter)->charge();
1310 m_mdcpx = (*mdctrkIter)->px();
1311 m_mdcpy = (*mdctrkIter)->py();
1312 m_mdcpz = (*mdctrkIter)->pz();
1313 m_mdcpt = (*mdctrkIter)->pxy();
1314 m_mdcpp = (*mdctrkIter)->p();
1315 m_mdcphi = (*mdctrkIter)->phi();
1316 m_mdctheta = (*mdctrkIter)->theta();
1317 m_mdcTrkInfoTuple->write();
1318 }
1319
1320 // MUC tracks
1321 SmartDataPtr<RecMucTrackCol> mucTrackCol(eventSvc,"/Event/Recon/RecMucTrackCol");
1322 if (!mucTrackCol) {
1323 log << MSG::FATAL << "Could not find RecMucTrackCol" << endreq;
1324 return( StatusCode::FAILURE);
1325 }
1326
1327 RecMucTrackCol *aRecMucTrackCol = mucTrackCol;
1328 if (aRecMucTrackCol->size() < 1) {
1329 log << MSG::INFO << "No MUC tracks in this event" << endreq;
1330 return StatusCode::SUCCESS;
1331 }
1332 log << MSG::INFO << "Total tracks of this event: " << aRecMucTrackCol->size() << endreq;
1333
1334 // Get RecEsTimeCol
1335 //int esTimeflag;
1336 //if( m_recMode == 0 ) // only for ExtTrk
1337 if( 0 ) // only for ExtTrk
1338 {
1339 SmartDataPtr<RecEsTimeCol> aRecEsTimeCol(eventSvc,"/Event/Recon/RecEsTimeCol");
1340 if( ! aRecEsTimeCol ){
1341 log << MSG::ERROR << "Could not find RecEsTimeCol" << endreq;
1342 return StatusCode::FAILURE;
1343 }else{
1344 RecEsTimeCol::iterator iter_evt = aRecEsTimeCol->begin();
1345 //tes = (*iter_evt)->getTest();
1346 //esTimeflag = (*iter_evt)->getStat();
1347 m_ntEsTime = (*iter_evt)->getStat();
1348 if( (*iter_evt)->getStat() != 211 ) {
1349 log << MSG::WARNING << "Event time not by TOF, skip!" << endreq;
1350 return StatusCode::SUCCESS;
1351 }
1352 }
1353 }
1354
1355 // Phi diff of two tracks( dimuon event )
1356 double phi1, phi2, phiDiff, theta1, theta2, thetaDiff;
1357 phiDiff = thetaDiff = 0.;
1358 if( aRecMucTrackCol->size()==2 && (*aRecMucTrackCol)[0]->GetTotalHits() > 4 && (*aRecMucTrackCol)[1]->GetTotalHits() > 4 )
1359 {
1360 // Pos phi diff
1361 phi1 = (*aRecMucTrackCol)[0]->getMucPos().phi(); phi2 = (*aRecMucTrackCol)[1]->getMucPos().phi();
1362 if( phi1 > 0 ) phiDiff = phi1 - phi2 - PI;
1363 else phiDiff = phi2 - phi1 - PI;
1364
1365 // Pos theta diff
1366 theta1 = (*aRecMucTrackCol)[0]->getMucPos().theta(); theta2 = (*aRecMucTrackCol)[1]->getMucPos().theta();
1367 thetaDiff = theta1 + theta2 - PI;
1368 m_hTrackPosPhiDiff->Fill( phiDiff );
1369 m_hTrackPosThetaDiff->Fill( thetaDiff );
1370 m_hDimuTracksPosDiff->Fill( thetaDiff, phiDiff );
1371 m_ntPosPhiDiff = phiDiff;
1372 m_ntPosThetaDiff = thetaDiff;
1373
1374 log << MSG::INFO << "PosPhiDiff:\t" << phiDiff << "\tPosThetaDiff:\t" << thetaDiff << endreq;
1375
1376 // Mom phi diff
1377 phi1 = (*aRecMucTrackCol)[0]->getMucMomentum().phi(); phi2 = (*aRecMucTrackCol)[1]->getMucMomentum().phi();
1378 if( phi1 > 0 ) phiDiff = phi1 - phi2 - PI;
1379 else phiDiff = phi2 - phi1 - PI;
1380
1381 // Mom theta diff
1382 theta1 = (*aRecMucTrackCol)[0]->getMucMomentum().theta(); theta2 = (*aRecMucTrackCol)[1]->getMucMomentum().theta();
1383 thetaDiff = theta1 + theta2 - PI;
1384
1385 m_hTrackMomPhiDiff->Fill( phiDiff );
1386 m_hTrackMomThetaDiff->Fill( thetaDiff );
1387 m_hDimuTracksMomDiff->Fill( thetaDiff, phiDiff );
1388 m_ntMomPhiDiff = phiDiff;
1389 m_ntMomThetaDiff = thetaDiff;
1390
1391 log << MSG::INFO << "MomPhiDiff:\t" << phiDiff << "\tMomThetaDiff:\t" << thetaDiff << endreq;
1392 m_ntDimuTag = m_eventTag;
1393 m_trackDiffTuple->write();
1394 }
1395
1396 // Retrieve tracks for calibration
1397 RecMucTrackCol::iterator trackIter = mucTrackCol->begin();
1398 int trackHitNum, rawHitNum, expectedHitNum, segNum, trkRecMode, lastLayerBR, lastLayerEC;
1399 int layerPassNum[3], passMax[TRACK_SEG_MAX][2];
1400 bool firedLay[TRACK_SEG_MAX][LAYER_MAX];
1401 bool seedList[PART_MAX][LAYER_MAX];
1402 trackHitNum = rawHitNum = expectedHitNum = segNum = trkRecMode = lastLayerBR = lastLayerEC = 0;
1403 layerPassNum[0] = layerPassNum[1] = layerPassNum[2] = 0;
1404 for( int segi=0; segi<TRACK_SEG_MAX; segi++ ) {
1405 passMax[segi][0] = passMax[segi][1] = 0;
1406 for( int layi=0; layi<LAYER_MAX; layi++ ) firedLay[segi][layi] = 0;
1407 }
1408
1409 mark_col trkSeg[TRACK_SEG_MAX];
1410 vector<MucRecHit*> mucRawHitCol;
1411 vector<MucRecHit*> mucExpHitCol;
1412
1413 for (int trackId = 0; trackIter != mucTrackCol->end(); trackIter++, trackId++)
1414 {
1415 trackHitNum = (*trackIter)->GetTotalHits();
1416 log << MSG::DEBUG << "Track: " << trackId << " Hits: " << trackHitNum << endreq;
1417
1418 if( trackHitNum == 0 ) {
1419 log << MSG::INFO << "Track " << trackId << " no hits" << endreq;
1420 continue;
1421 }
1422
1423 m_ntTrackHits = trackHitNum;
1424
1425 m_trkRecMode = trkRecMode = (*trackIter)->GetRecMode();
1426 m_chi2 = (*trackIter)->chi2();
1427 m_px = (*trackIter)->getMucMomentum().x();
1428 m_py = (*trackIter)->getMucMomentum().y();
1429 m_pz = (*trackIter)->getMucMomentum().z();
1430 m_pt = sqrt(m_px*m_px + m_py*m_py);
1431 m_pp = sqrt(m_px*m_px + m_py*m_py + m_pz*m_pz);
1432
1433 // First fit position in MUC
1434 m_r = (*trackIter)->getMucPos().mag();
1435 m_cosTheta = (*trackIter)->getMucPos().cosTheta();
1436 m_theta = (*trackIter)->getMucPos().theta();
1437 m_phi = (*trackIter)->getMucPos().phi();
1438 m_depth = (*trackIter)->depth();
1439 m_brLastLayer = lastLayerBR = (*trackIter)->brLastLayer();
1440 m_ecLastLayer = lastLayerEC = (*trackIter)->ecLastLayer();
1441 m_totalHits = (*trackIter)->numHits();
1442 m_totalLayers = (*trackIter)->numLayers();
1443 m_maxHitsInLayer = (*trackIter)->maxHitsInLayer();
1444
1445
1446 m_hPhiCosTheta->Fill(m_cosTheta, m_phi);
1447 log << MSG::INFO << "Fill track info" << endreq;
1448
1449 MucRecHit* pMucRawHit;
1450 MucRecHit* pMucExpHit;
1451 if( m_calHitCol.size() != 0 ) m_calHitCol.clear(); // Fresh each track
1452
1453 // Digis belong to this rec track
1454 log << MSG::DEBUG << "Reconstruction hits(digis in a track): " << endreq;
1455 mucRawHitCol = (*trackIter)->GetHits(); // Get hit collection of a track
1456 rawHitNum += mucRawHitCol.size();
1457
1458 segNum = 0;
1459 if( trkRecMode == 3 ) { // By SlfTrk
1460 for(int iPart=0; iPart<PART_MAX; iPart++)
1461 for(int iLayer=0; iLayer<LAYER_MAX; iLayer++) seedList[iPart][iLayer] = false;
1462 }
1463
1464 for(unsigned int hitId = 0; hitId < mucRawHitCol.size(); hitId++)
1465 {
1466 pMucRawHit = mucRawHitCol[ hitId ];
1467 part = pMucRawHit->Part();
1468 segment = pMucRawHit->Seg();
1469 layer = pMucRawHit->Gap();
1470 strip = pMucRawHit->Strip();
1471
1472 log << MSG::DEBUG << "[" << part << "\t" << segment << "\t" << layer << "\t" << strip << "]\t";
1473 //if( (hitId+1)%8 == 0 ) log << MSG::DEBUG << endreq;
1474
1475 // Add hit
1476 MucMark *aMark = new MucMark( part, segment, layer, strip );
1477 m_calHitCol.push_back( aMark );
1478
1479 // Set seed flag
1480 if( trkRecMode == 3 ) seedList[part][layer] = pMucRawHit->HitIsSeed(); // By SlfTrk
1481
1482 // Find track segment
1483 if(hitId == 0) { trkSeg[segNum].push_back( aMark ); segNum ++; }
1484 else
1485 {
1486 log << MSG::DEBUG << "segNum: " << segNum << endreq;
1487 bool notInSeg = true;
1488 for( int segi=0; segi<segNum; segi++ )
1489 {
1490 if( aMark->IsInSegWith( *(trkSeg[segi][0]) ) )
1491 {
1492 trkSeg[segi].push_back( aMark );
1493 notInSeg = false;
1494 break;
1495 }
1496 }
1497 // new track seg
1498 if( notInSeg == true )
1499 {
1500 trkSeg[segNum].push_back( aMark );
1501 segNum ++;
1502 if( segNum > TRACK_SEG_MAX ) {
1503 log << MSG::ERROR << "Track segment overflow: " << segNum << endreq;
1504 break;
1505 }
1506 }
1507 } // End else
1508 } // End raw hits
1509 log << MSG::DEBUG << endreq;
1510
1511 // Find maximal layers passed in track segments
1512 layerPassNum[0] = layerPassNum[1] = layerPassNum[2] = 0;
1513 for( int segi=0; segi<segNum; segi++ )
1514 {
1515 int tmpLayNum = 0;
1516 passMax[segi][0] = passMax[segi][1] = trkSeg[segi][0]->Layer();
1517 for( unsigned int hiti=1; hiti<trkSeg[segi].size(); hiti++ )
1518 {
1519 if( trkSeg[segi][hiti]->Layer() < passMax[segi][0] )
1520 passMax[segi][0] = trkSeg[segi][hiti]->Layer();
1521 if( trkSeg[segi][hiti]->Layer() > passMax[segi][1] )
1522 passMax[segi][1] = trkSeg[segi][hiti]->Layer();
1523 firedLay[segi][trkSeg[segi][hiti]->Layer()] = 1;
1524 }
1525
1526 for( int layi=0; layi<LAYER_MAX; layi++ ) {
1527 if( firedLay[segi][layi] ) tmpLayNum ++;
1528 }
1529
1530 if( segi == 0 ) layerPassNum[0] += passMax[segi][1] + 1;
1531 else layerPassNum[0] += (passMax[segi][1] - passMax[segi][0] + 1);
1532
1533 layerPassNum[1] += (passMax[segi][1] - passMax[segi][0] + 1);
1534 layerPassNum[2] += tmpLayNum;
1535
1536 trkSeg[segi].clear();
1537 }
1538 m_ntTrackEvent = m_currentEvent;
1539 m_ntTrackTag = m_eventTag;
1540 m_ntTrackSegFly = segNum;
1541 m_ntTrackLayFlyA = layerPassNum[0];
1542 m_ntTrackLayFlyB = layerPassNum[1];
1543 m_ntTrackLayFlyC = layerPassNum[2];
1544 m_trackInfoTuple->write();
1545 log << MSG::INFO << "Track\t" << trackId << "\tsegment(s):\t" << segNum
1546 << "\tlayer passed:\t" << layerPassNum[0] <<"\t" << layerPassNum[1] << "\t" << layerPassNum[2] << endreq;
1547 //if( layerPassNum[0]>B_LAY_NUM || layerPassNum[1]>B_LAY_NUM || layerPassNum[2]>B_LAY_NUM )
1548 // log << MSG::ERROR << "Over max layer:\t" << m_currentRun << "\t" << m_currentEvent << endreq;
1549
1550 // Expected hits in this rec track
1551 log << MSG::DEBUG << "Fitting hits(expected hits in a track): " << endreq;
1552 mucExpHitCol = (*trackIter)->GetExpectedHits();
1553 expectedHitNum += mucExpHitCol.size();
1554 for(unsigned int hitId = 0; hitId < mucExpHitCol.size(); hitId++)
1555 {
1556 pMucRawHit = mucExpHitCol[ hitId ];
1557 part = pMucRawHit->Part(); segment = pMucRawHit->Seg();
1558 layer = pMucRawHit->Gap(); strip = pMucRawHit->Strip();
1559
1560 if( m_usePad != 0 )
1561 {
1562 pad = pMucRawHit->GetPadID(); padZ = pMucRawHit->GetIntersectZ();
1563 padX = pMucRawHit->GetIntersectY(); padY = pMucRawHit->GetIntersectX(); // Note: local coordinate
1564
1565 if( part != BRID )
1566 {
1567 if(segment == 1) { padX = -padX; }
1568 else if(segment == 2) { padX = -padX, padY = -padY; }
1569 else if(segment == 3) { padY = -padY; }
1570 }
1571 }
1572
1573 // Avoid bias in seed layers
1574 // if( seedList[part][layer] == true ) continue;
1575
1576 MucMark* currentMark = new MucMark( part, segment, layer, strip );
1577 m_expHitCol.push_back( currentMark );
1578 //log << MSG::DEBUG << "[" << part << "\t" << segment << "\t" << layer << "\t" << strip << "]\t";
1579 //if( (hitId+1)%8 == 0 ) log << MSG::DEBUG << endreq;
1580
1581 // Judge efficiency hit
1582 int isInPos = -1;
1583 bool isInEffWindow = false;
1584 isInPos = currentMark->IsInCol( m_segDigiCol[part][segment] );
1585
1586 // Avoid bias in outer layers caused by low momentum tracks
1587 if( part == BRID && (layer-lastLayerBR>1) ) continue;
1588 if( part != BRID && (layer-lastLayerEC>1) ) continue;
1589
1590 // Avoid bias in both sides of the innermost layer of Barrel
1591 if( part==BRID && layer==0 && (strip<2 || strip>45) )
1592 {
1593 if( isInPos != -1) // expHit is fired
1594 {
1595 m_record[part][segment][layer][strip][2] ++; // Efficiency hit number
1596 m_record[part][segment][layer][strip][1] ++; // Rec track number
1597 m_effHitCol.push_back( m_segDigiCol[part][segment][isInPos] );
1598
1599 if( m_usePad != 0 ) {
1600 m_h2DExpMap[part][segment][layer]->Fill(padX, padY);
1601 m_h2DHitMap[part][segment][layer]->Fill(padX, padY);
1602 }
1603
1604 }
1605 else {
1606 m_record[part][segment][layer][strip][1] ++;
1607 if( m_usePad != 0 ) m_h2DExpMap[part][segment][layer]->Fill(padX, padY);
1608 }
1609 continue; // Judge next hit
1610 }
1611
1612 // Eff calibration
1613 if( isInPos != -1 ) // expHit is fired
1614 {
1615 m_record[part][segment][layer][strip][2] ++; // Efficiency hit number
1616 m_record[part][segment][layer][strip][1] ++; // Rec track number
1617 m_effHitCol.push_back( m_segDigiCol[part][segment][isInPos] );
1618
1619 if( m_usePad != 0 ) {
1620 m_h2DExpMap[part][segment][layer]->Fill(padX, padY);
1621 m_h2DHitMap[part][segment][layer]->Fill(padX, padY);
1622 }
1623
1624 continue; // Judge next hit
1625 }
1626 else for(int tempStrip=0, hiti=-m_effWindow; hiti<=m_effWindow; hiti++ )
1627 {
1628 if( hiti == 0 ) continue;
1629 tempStrip = strip + hiti;
1630 if( tempStrip < 0 || tempStrip > m_ptrIdTr->GetStripMax(part,segment,layer) ) continue;
1631
1632 isInPos = m_ptrMucMark->IsInCol( part, segment, layer, tempStrip, m_segDigiCol[part][segment] );
1633 if( isInPos != -1 )
1634 {
1635 m_record[part][segment][layer][tempStrip][2] ++; // Efficiency hit number
1636 m_record[part][segment][layer][tempStrip][1] ++; // Rec track number
1637 m_effHitCol.push_back( m_segDigiCol[part][segment][isInPos] );
1638
1639 if( m_usePad != 0 ) {
1640 m_h2DExpMap[part][segment][layer]->Fill(padX, padY);
1641 m_h2DHitMap[part][segment][layer]->Fill(padX, padY);
1642 }
1643
1644 m_ntEffWindow = hiti;
1645 m_effWindowTuple->write();
1646 isInEffWindow = true;
1647 }
1648
1649 } // End else
1650
1651 if( isInEffWindow ) { continue; } // Judge next hit
1652 else { // A hit should be fired but not fired and not in the EffWindow
1653 m_record[part][segment][layer][strip][1] ++; // Rec track number
1654 if( m_usePad != 0 ) m_h2DExpMap[part][segment][layer]->Fill(padX, padY);
1655 }
1656
1657 } // End expected hits
1658
1659 // Fill residual, and for the other way of eff calculation
1660 log << MSG::INFO << "Fill residual" << endreq;
1661 vector<float> m_lineResCol = (*trackIter)->getDistHits();
1662 vector<float> m_quadResCol = (*trackIter)->getQuadDistHits();
1663 vector<float> m_extrResCol = (*trackIter)->getExtDistHits();
1664 int mode = (*trackIter)->GetRecMode();
1665
1666 for(unsigned int nres = 0; nres < m_lineResCol.size(); nres++ )
1667 if( fabs(m_lineResCol[nres])>resMax ) resMax = fabs(m_lineResCol[nres]);
1668
1669 log << MSG::INFO << "Good track for res" << endreq;
1670 if( trackHitNum > 4 && m_lineResCol[0] != -99) // track is good for res
1671 {
1672 // Fill res histograms
1673 bool firedFlag[PART_MAX][LAYER_MAX][2];
1674 for(int iprt=0; iprt<PART_MAX; iprt++)
1675 for(int jlay=0; jlay<LAYER_MAX; jlay++)
1676 firedFlag[iprt][jlay][0] = firedFlag[iprt][jlay][1] = false;
1677
1678 for(unsigned int hitId = 0; hitId < mucExpHitCol.size(); hitId++)
1679 {
1680 pMucExpHit = mucExpHitCol[ hitId ];
1681 part = pMucExpHit->Part(); segment = pMucExpHit->Seg(); layer = pMucExpHit->Gap();
1682 firedFlag[part][layer][0] = true;
1683 }
1684
1685 log << MSG::INFO << "Fit res" << endreq;
1686 for(unsigned int hitId = 0; hitId < mucRawHitCol.size(); hitId++)
1687 {
1688 pMucRawHit = mucRawHitCol[ hitId ];
1689 part = pMucRawHit->Part(); segment = pMucRawHit->Seg(); layer = pMucRawHit->Gap();
1690
1691 if( part == BRID ) m_hBarrelResDist[layer]->Fill( m_lineResCol[hitId] );
1692 else m_hEndcapResDist[layer]->Fill( m_lineResCol[hitId] );
1693
1694 // if exp is true and fired is true, and not filled yet
1695 if( firedFlag[part][layer][0] == true && firedFlag[part][layer][1] == false )
1696 {
1697 m_resPart = part;
1698 m_resSegment = segment;
1699 m_resLayer = layer;
1700 m_lineRes = m_lineResCol[hitId];
1701 m_quadRes = m_quadResCol[hitId];
1702 m_extrRes = m_extrResCol[hitId];
1703 m_resFired = 1;
1704 m_resMode = mode;
1705 m_resInfoTuple->write();
1706 }
1707
1708 firedFlag[part][layer][1] = true;
1709 }
1710
1711 log << MSG::INFO << "Exp res" << endreq;
1712 for(unsigned int hitId = 0; hitId < mucExpHitCol.size(); hitId++)
1713 {
1714 pMucExpHit = mucExpHitCol[ hitId ];
1715 part = pMucExpHit->Part(); segment = pMucExpHit->Seg(); layer = pMucExpHit->Gap();
1716
1717 if(firedFlag[part][layer][0] == true && firedFlag[part][layer][1] == false)
1718 {
1719 m_resPart = part;
1720 m_resSegment = segment;
1721 m_resLayer = layer;
1722 m_lineRes = 1000;
1723 m_quadRes = 1000;
1724 m_extrRes = 1000;
1725 m_resFired = 0;
1726 m_resMode = mode;
1727 m_resInfoTuple->write();
1728 }
1729 }
1730
1731 } // End fill residual, if track is good for res
1732
1733 mucRawHitCol.clear();
1734 mucExpHitCol.clear();
1735
1736 } // End read all tracks
1737
1738 if( resMax > 300 ) cout <<"Res too big!\t"<< m_fTotalEvent <<"\t"<< m_currentRun <<"\t"<< m_currentEvent <<"\t"<< resMax << endl;
1739
1740 m_ntTrackNum = mucTrackCol->size();
1741
1742 m_fTotalEffHit += rawHitNum;
1743 log << MSG::INFO << "Total hits in this event, raw: " << rawHitNum << "\texpected: " << expectedHitNum << endreq;
1744 //<--- End retrieve rec tracks
1745
1746 //---> Searching inc/noise hits
1747 log << MSG::INFO << "Searching inc/noise hits" << endreq;
1748 bool isNosHit;
1749 bool hasEffHit;
1750 for( unsigned int i=0; i < m_digiCol.size(); i++ )
1751 {
1752 isNosHit = true;
1753
1754 if( m_digiCol[i]->IsInCol( m_effHitCol ) !=-1) continue; // digi in effHitCol
1755 else
1756 {
1757 for( unsigned int j=0; j < m_clusterCol.size(); j++ )
1758 {
1759 hasEffHit = false;
1760 for( unsigned int k=0; k<m_clusterCol[j].size(); k++)
1761 {
1762 if( m_clusterCol[j][k]->IsInCol(m_effHitCol) != -1) // Clusters have efficiency hit
1763 {
1764 hasEffHit = true;
1765 break; // Out a cluster
1766 }
1767 }
1768
1769 if ( hasEffHit && (m_digiCol[i]->IsInCol( m_clusterCol[j] ) != -1) ) {
1770 isNosHit = false;
1771 break; // Out cluster collection
1772 }
1773 } // End cluster col
1774
1775 if( isNosHit ) {
1776 m_nosHitCol.push_back( m_digiCol[i] );
1777 m_fTotalNosHit ++;
1778 }
1779 }// End else
1780 } // End digi collection
1781
1782 return StatusCode::SUCCESS;
1783}
ObjectVector< RecMucTrack > RecMucTrackCol
StatusCode DimuSelect()
static int barrel_ec(const Identifier &id)
Values of different levels.
Definition: MucID.cxx:41
static int layer(const Identifier &id)
Definition: MucID.cxx:61
static int channel(const Identifier &id)
Definition: MucID.cxx:71
static int segment(const Identifier &id)
Definition: MucID.cxx:51
bool IsInSegWith(MucMark &other)
Definition: MucMark.cxx:144
int IsInCol(int part, int segment, int layer, int strip, mark_col &aCol)
Definition: MucMark.cxx:100

Referenced by MucCalibAlg::execute().

◆ ReadEvent() [2/2]

StatusCode MucCalibMgr::ReadEvent ( )

◆ SaveConst() [1/2]

StatusCode MucCalibMgr::SaveConst ( )

Definition at line 2515 of file MucCalibMgr.cxx.

2516{
2517 MsgStream log(msgSvc, "MucCalibMgr");
2518 log << MSG::INFO << "Save calibration constants" << endreq;
2519
2520 // Save calibrated eff in graphes
2521 // LV0
2522 double layerXY[2][LAYER_MAX];
2523 double layerEXY[2][LAYER_MAX];
2524 for( int i=0; i<LAYER_MAX; i++ )
2525 {
2526 layerXY[0][i] = i;
2527 layerEXY[0][i] = 0;
2528 if( m_layerResults[5][i] >= 100*TRACK_THRESHOLD ) {
2529 layerXY[1][i] = m_layerResults[0][i];
2530 layerEXY[1][i] = m_layerResults[1][i];
2531 }
2532 else {
2533 layerXY[1][i] = 0;
2534 layerEXY[1][i] = 0;
2535 }
2536 }
2537 m_geLayerEff = new TGraphErrors(LAYER_MAX, layerXY[0], layerXY[1], layerEXY[0], layerEXY[1]);
2538 m_geLayerEff->SetMarkerStyle(25);
2539 m_geLayerEff->SetMarkerSize(0.5);
2540 m_cv[0] = new TCanvas("GoodLayerEff","Layer efficiency", 50, 50, 800, 600);
2541 m_cv[0]->SetFillColor(0);
2542 m_cv[0]->SetBorderMode(0);
2543 m_geLayerEff->Draw("AP");
2544 m_cv[0]->Write();
2545
2546 // LV1
2547 double boxXY[2][BOX_MAX];
2548 double boxEXY[2][BOX_MAX];
2549 for( int i=0; i<BOX_MAX; i++ )
2550 {
2551 boxXY[0][i] = i;
2552 boxEXY[0][i] = 0;
2553 if( m_boxResults[5][i] >= 10*TRACK_THRESHOLD ) {
2554 boxXY[1][i] = m_boxResults[0][i];
2555 boxEXY[1][i] = m_boxResults[1][i];
2556 }
2557 else {
2558 boxXY[1][i] = 0;
2559 boxEXY[1][i] = 0;
2560 }
2561 }
2562 m_geBoxEff = new TGraphErrors(BOX_MAX, boxXY[0], boxXY[1], boxEXY[0], boxEXY[1]);
2563 m_geBoxEff->SetMarkerStyle(25);
2564 m_geBoxEff->SetMarkerSize(0.5);
2565 m_cv[1] = new TCanvas("GoodBoxEff","Box efficiency", 75, 75, 800, 600);
2566 m_cv[1]->SetFillColor(0);
2567 m_cv[1]->SetBorderMode(0);
2568 m_geBoxEff->Draw("AP");
2569 m_cv[1]->Write();
2570
2571 // LV2
2572 double stripXY[2][STRIP_MAX];
2573 double stripEXY[2][STRIP_MAX];
2574 for( int i=0; i<STRIP_MAX; i++ )
2575 {
2576 stripXY[0][i] = i;
2577 stripEXY[0][i] = 0;
2578 if( m_stripResults[5][i] >= TRACK_THRESHOLD ) {
2579 stripXY[1][i] = m_stripResults[0][i];
2580 stripEXY[1][i] = m_stripResults[1][i];
2581 }
2582 else {
2583 stripXY[1][i] = 0;
2584 stripEXY[1][i] = 0;
2585 }
2586 }
2587 m_geStripEff = new TGraphErrors(STRIP_MAX, stripXY[0], stripXY[1], stripEXY[0], stripEXY[1]);
2588 m_geStripEff->SetMarkerStyle(25);
2589 m_geStripEff->SetMarkerSize(0.5);
2590 m_cv[2] = new TCanvas("GoodStripEff","Strip efficiency", 100, 100, 800, 600);
2591 m_cv[2]->SetFillColor(0);
2592 m_cv[2]->SetBorderMode(0);
2593 m_geStripEff->Draw("AP");
2594 m_cv[2]->Write();
2595
2596 // Save histograms
2597 for(int i=0; i<B_LAY_NUM; i++ )
2598 {
2599 m_hHitMapBarrel_Lay[i]->Write();
2600
2601 if( i<E_LAY_NUM ) {
2602 m_hHitMapEndcap_Lay[0][i]->Write();
2603 m_hHitMapEndcap_Lay[1][i]->Write();
2604 }
2605 }
2606
2607 for(int i=0; i<B_SEG_NUM; i++)
2608 {
2609 m_hHitMapBarrel_Seg[i]->Write();
2610
2611 if( i< E_SEG_NUM ) {
2612 m_hHitMapEndcap_Seg[0][i]->Write();
2613 m_hHitMapEndcap_Seg[1][i]->Write();
2614 }
2615 }
2616 m_hTrackDistance->Fit("gaus");
2617 m_hTrackPosPhiDiff->Fit("gaus");
2618 m_hTrackPosThetaDiff->Fit("gaus");
2619 m_hTrackMomPhiDiff->Fit("gaus");
2620 m_hTrackMomThetaDiff->Fit("gaus");
2621
2622 m_hTrackDistance->Write();
2623 m_hTrackPosPhiDiff->Write();
2624 m_hTrackPosThetaDiff->Write();
2625 m_hTrackMomPhiDiff->Write();
2626 m_hTrackMomThetaDiff->Write();
2627
2628 for( int i=0; i<B_LAY_NUM; i++ ) m_hBarrelResDist[i]->Write();
2629 for( int i=0; i<E_LAY_NUM; i++ ) m_hEndcapResDist[i]->Write();
2630
2631 m_hBarrelResComp[0]->Write();
2632 m_hBarrelResComp[1]->Write();
2633 m_hEndcapResComp[0]->Write();
2634 m_hEndcapResComp[1]->Write();
2635
2636 if( m_usePad != 0 ) m_histArray->Write();
2637
2638 for( int i=0; i<BOX_MAX; i++ )
2639 {
2640 m_hStripFireMap[ i ]->Write();
2641 m_hStripExpHitMap[ i ]->Write();
2642 m_hStripEffHitMap[ i ]->Write();
2643 m_hStripNosHitMap[ i ]->Write();
2644 m_hStripEffMap[ i ]->Write();
2645 m_hStripNosRatioMap[ i ]->Write();
2646 }
2647 m_hStripFire->Write();
2648 m_hStripExpHit->Write();
2649 m_hStripEffHit->Write();
2650 m_hStripNosHit->Write();
2651 m_hStripEff->Write();
2652 m_hStripArea->Write();
2653 m_hStripNos->Write();
2654 m_hStripNosRatio->Write();
2655 log << MSG::INFO << "Save LV2 histograms done!" << endreq;
2656
2657 m_hBoxFire->Write();
2658 m_hBoxExpHit->Write();
2659 m_hBoxEffHit->Write();
2660 m_hBoxNosHit->Write();
2661 m_hBoxEff->Write();
2662 m_hBoxArea->Write();
2663 m_hBoxNos->Write();
2664 m_hBoxNosRatio->Write();
2665 log << MSG::INFO << "Save LV1 histograms done!" << endreq;
2666
2667 m_hBrLayerFire->Write();
2668 m_hEcLayerFire->Write();
2669 m_hLayerFire->Write();
2670 m_hLayerExpHit->Write();
2671 m_hLayerEffHit->Write();
2672 m_hLayerNosHit->Write();
2673 m_hLayerEff->Write();
2674 m_hLayerArea->Write();
2675 m_hLayerNos->Write();
2676 m_hLayerNosRatio->Write();
2677
2678 for( int i=0; i<LAYER_MAX; i++ ) m_hLayerCluster[i]->Write();
2679 for( int i=0; i<BOX_MAX; i++ ) m_hBoxCluster[i]->Write();
2680 m_hLayerClusterCmp->Write();
2681 m_hBoxClusterCmp->Write();
2682
2683 log << MSG::INFO << "Save histograms done!" << endreq;
2684
2685 // Save trees
2686 m_fLayerCoverage = 100*(double)m_fCalibLayerNum/LAYER_MAX;
2687 m_fBoxCoverage = 100*(double)m_fCalibBoxNum/BOX_MAX;
2688 m_fStripCoverage = 100*(double)m_fCalibStripNum/STRIP_MAX;
2689
2690 long digi_num, trk_num, eff_hit, nos_hit, exp_hit;
2691 m_tStatLog->Branch("digi_num", &digi_num, "digi_num/I");
2692 m_tStatLog->Branch("trk_num", &trk_num, "trk_num/I");
2693 m_tStatLog->Branch("eff_hit", &eff_hit, "eff_hit/I");
2694 m_tStatLog->Branch("nos_hit", &nos_hit, "nos_hit/I");
2695 m_tStatLog->Branch("exp_hit", &exp_hit, "exp_hit/I");
2696
2697 int stripMax;
2698 for( int i=0; i<PART_MAX; i++ )
2699 for( int j=0; j<((i==BRID)?B_SEG_NUM:E_SEG_NUM); j++ )
2700 for( int k=0; k<((i==BRID)?B_LAY_NUM:E_LAY_NUM); k++ )
2701 {
2702 stripMax = m_ptrIdTr->GetStripMax( i, j, k );
2703 for( int n=0; n<stripMax; n++ )
2704 {
2705 digi_num = m_record[i][j][k][n][0];
2706 trk_num = m_record[i][j][k][n][1];
2707 eff_hit = m_record[i][j][k][n][2];
2708 nos_hit = m_record[i][j][k][n][3];
2709 exp_hit = m_record[i][j][k][n][4];
2710 m_tStatLog->Fill();
2711 }
2712 }
2713
2714 m_jobFinish = clock();
2715 m_fTotalJobTime = (double)(m_jobFinish - m_jobStart)/CLOCKS_PER_SEC;
2716
2717 m_tJobLog->Fill();
2718 m_tJobLog->Write();
2719 m_tStatLog->Write();
2720 m_tLayConst->Write();
2721 m_tBoxConst->Write();
2722 m_tStrConst->Write();
2723
2724 // Close cluster output file
2725 if( m_fdata != NULL ) m_fdata->close();
2726
2727 return StatusCode::SUCCESS;
2728}

Referenced by MucCalibAlg::finalize().

◆ SaveConst() [2/2]

StatusCode MucCalibMgr::SaveConst ( )

Member Data Documentation

◆ eventSvc

IDataProviderSvc * MucCalibMgr::eventSvc

◆ msgSvc

◆ ntupleSvc

INTupleSvc * MucCalibMgr::ntupleSvc

The documentation for this class was generated from the following files: