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Vx3DHLTAnalyzer Class Reference

#include <Vx3DHLTAnalyzer.h>

Inheritance diagram for Vx3DHLTAnalyzer:
DQMEDAnalyzer edm::stream::EDAnalyzer< edm::RunSummaryCache< dqmDetails::NoCache >, edm::LuminosityBlockSummaryCache< dqmDetails::NoCache > > edm::stream::EDAnalyzerBase edm::EDConsumerBase

Public Member Functions

 Vx3DHLTAnalyzer (const edm::ParameterSet &)
 
 ~Vx3DHLTAnalyzer ()
 
- Public Member Functions inherited from DQMEDAnalyzer
virtual void beginRun (edm::Run const &, edm::EventSetup const &) final
 
virtual void beginStream (edm::StreamID id) final
 
virtual void dqmBeginRun (edm::Run const &, edm::EventSetup const &)
 
 DQMEDAnalyzer (void)
 
virtual void endLuminosityBlockSummary (edm::LuminosityBlock const &, edm::EventSetup const &, dqmDetails::NoCache *) const final
 
virtual void endRunSummary (edm::Run const &, edm::EventSetup const &, dqmDetails::NoCache *) const final
 
uint32_t streamId () const
 
- Public Member Functions inherited from edm::stream::EDAnalyzer< edm::RunSummaryCache< dqmDetails::NoCache >, edm::LuminosityBlockSummaryCache< dqmDetails::NoCache > >
 EDAnalyzer ()=default
 
- Public Member Functions inherited from edm::stream::EDAnalyzerBase
void callWhenNewProductsRegistered (std::function< void(BranchDescription const &)> const &func)
 
 EDAnalyzerBase ()
 
ModuleDescription const & moduleDescription () const
 
virtual ~EDAnalyzerBase ()
 
- Public Member Functions inherited from edm::EDConsumerBase
std::vector< ConsumesInfoconsumesInfo () const
 
 EDConsumerBase ()
 
 EDConsumerBase (EDConsumerBase const &)=delete
 
 EDConsumerBase (EDConsumerBase &&)=default
 
ProductResolverIndexAndSkipBit indexFrom (EDGetToken, BranchType, TypeID const &) const
 
void itemsMayGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
 
void itemsToGet (BranchType, std::vector< ProductResolverIndexAndSkipBit > &) const
 
std::vector< ProductResolverIndexAndSkipBit > const & itemsToGetFrom (BranchType iType) const
 
void labelsForToken (EDGetToken iToken, Labels &oLabels) const
 
void modulesWhoseProductsAreConsumed (std::vector< ModuleDescription const * > &modules, ProductRegistry const &preg, std::map< std::string, ModuleDescription const * > const &labelsToDesc, std::string const &processName) const
 
EDConsumerBase const & operator= (EDConsumerBase const &)=delete
 
EDConsumerBaseoperator= (EDConsumerBase &&)=default
 
bool registeredToConsume (ProductResolverIndex, bool, BranchType) const
 
bool registeredToConsumeMany (TypeID const &, BranchType) const
 
void updateLookup (BranchType iBranchType, ProductResolverIndexHelper const &, bool iPrefetchMayGet)
 
virtual ~EDConsumerBase () noexcept(false)
 

Protected Member Functions

double Gauss3DFunc (const double *par)
 
- Protected Member Functions inherited from edm::EDConsumerBase
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType > consumes (edm::InputTag const &tag)
 
EDGetToken consumes (const TypeToGet &id, edm::InputTag const &tag)
 
template<BranchType B>
EDGetToken consumes (TypeToGet const &id, edm::InputTag const &tag)
 
ConsumesCollector consumesCollector ()
 Use a ConsumesCollector to gather consumes information from helper functions. More...
 
template<typename ProductType , BranchType B = InEvent>
void consumesMany ()
 
void consumesMany (const TypeToGet &id)
 
template<BranchType B>
void consumesMany (const TypeToGet &id)
 
template<typename ProductType , BranchType B = InEvent>
EDGetTokenT< ProductType > mayConsume (edm::InputTag const &tag)
 
EDGetToken mayConsume (const TypeToGet &id, edm::InputTag const &tag)
 
template<BranchType B>
EDGetToken mayConsume (const TypeToGet &id, edm::InputTag const &tag)
 

Private Member Functions

void analyze (const edm::Event &iEvent, const edm::EventSetup &iSetup) override
 
void beginLuminosityBlock (const edm::LuminosityBlock &lumiBlock, const edm::EventSetup &iSetup) override
 
void bookHistograms (DQMStore::IBooker &, edm::Run const &, edm::EventSetup const &) override
 
void endLuminosityBlock (const edm::LuminosityBlock &lumiBlock, const edm::EventSetup &iSetup) override
 
std::string formatTime (const time_t &t)
 
unsigned int HitCounter (const edm::Event &iEvent)
 
int MyFit (std::vector< double > *vals)
 
void printFitParams (const std::vector< double > &fitResults)
 
void reset (std::string ResetType)
 
void writeToFile (std::vector< double > *vals, edm::TimeValue_t BeginTimeOfFit, edm::TimeValue_t EndTimeOfFit, unsigned int BeginLumiOfFit, unsigned int EndLumiOfFit, int dataType)
 

Private Attributes

unsigned int beginLumiOfFit
 
edm::TimeValue_t beginTimeOfFit
 
bool considerVxCovariance
 
unsigned int counterVx
 
bool dataFromFit
 
bool debugMode
 
MonitorElementdxdzlumi
 
MonitorElementdydzlumi
 
unsigned int endLumiOfFit
 
edm::TimeValue_t endTimeOfFit
 
std::string fileName
 
MonitorElementfitResults
 
MonitorElementgoodVxCounter
 
MonitorElementhitCounter
 
bool internalDebug
 
unsigned int lastLumiOfFit
 
unsigned int lumiCounter
 
double maxLongLength
 
unsigned int maxLumiIntegration
 
double maxTransRadius
 
unsigned int minNentries
 
double minVxDoF
 
double minVxWgt
 
MonitorElementmXlumi
 
MonitorElementmYlumi
 
MonitorElementmZlumi
 
unsigned int nLumiFit
 
unsigned int nLumiXaxisRange
 
unsigned int nParams
 
unsigned int numberFits
 
unsigned int numberGoodFits
 
std::ofstream outputDebugFile
 
std::ofstream outputFile
 
double pi
 
edm::EDGetTokenT< SiPixelRecHitCollectionpixelHitCollection
 
MonitorElementreportSummary
 
MonitorElementreportSummaryMap
 
unsigned int runNumber
 
MonitorElementstatusCounter
 
MonitorElementsXlumi
 
MonitorElementsYlumi
 
MonitorElementsZlumi
 
unsigned int totalHits
 
edm::EDGetTokenT< reco::VertexCollectionvertexCollection
 
std::vector< VertexTypeVertices
 
MonitorElementVx_X
 
MonitorElementVx_X_Cum
 
MonitorElementVx_XY
 
MonitorElementVx_XY_Cum
 
MonitorElementVx_Y
 
MonitorElementVx_Y_Cum
 
MonitorElementVx_Z
 
MonitorElementVx_Z_Cum
 
MonitorElementVx_ZX
 
MonitorElementVx_ZX_Cum
 
MonitorElementVx_ZY
 
MonitorElementVx_ZY_Cum
 
double VxErrCorr
 
double xPos
 
double xRange
 
double xStep
 
double yPos
 
double yRange
 
double yStep
 
double zPos
 
double zRange
 
double zStep
 

Additional Inherited Members

- Public Types inherited from edm::stream::EDAnalyzer< edm::RunSummaryCache< dqmDetails::NoCache >, edm::LuminosityBlockSummaryCache< dqmDetails::NoCache > >
typedef CacheContexts< T... > CacheTypes
 
typedef CacheTypes::GlobalCache GlobalCache
 
typedef AbilityChecker< T... > HasAbility
 
typedef CacheTypes::LuminosityBlockCache LuminosityBlockCache
 
typedef LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCacheLuminosityBlockContext
 
typedef CacheTypes::LuminosityBlockSummaryCache LuminosityBlockSummaryCache
 
typedef CacheTypes::RunCache RunCache
 
typedef RunContextT< RunCache, GlobalCacheRunContext
 
typedef CacheTypes::RunSummaryCache RunSummaryCache
 
- Public Types inherited from edm::stream::EDAnalyzerBase
typedef EDAnalyzerAdaptorBase ModuleType
 
- Public Types inherited from edm::EDConsumerBase
typedef ProductLabels Labels
 
- Static Public Member Functions inherited from DQMEDAnalyzer
static std::shared_ptr< dqmDetails::NoCacheglobalBeginLuminosityBlockSummary (edm::LuminosityBlock const &, edm::EventSetup const &, LuminosityBlockContext const *)
 
static std::shared_ptr< dqmDetails::NoCacheglobalBeginRunSummary (edm::Run const &, edm::EventSetup const &, RunContext const *)
 
static void globalEndLuminosityBlockSummary (edm::LuminosityBlock const &, edm::EventSetup const &, LuminosityBlockContext const *, dqmDetails::NoCache *)
 
static void globalEndRunSummary (edm::Run const &, edm::EventSetup const &, RunContext const *, dqmDetails::NoCache *)
 
- Static Public Member Functions inherited from edm::stream::EDAnalyzerBase
static const std::string & baseType ()
 
static void fillDescriptions (ConfigurationDescriptions &descriptions)
 
static void prevalidate (ConfigurationDescriptions &descriptions)
 

Detailed Description

Definition at line 48 of file Vx3DHLTAnalyzer.h.

Constructor & Destructor Documentation

Vx3DHLTAnalyzer::Vx3DHLTAnalyzer ( const edm::ParameterSet iConfig)

Definition at line 27 of file Vx3DHLTAnalyzer.cc.

References MillePedeFileConverter_cfg::fileName, edm::ParameterSet::getParameter(), edm::ParameterSet::getUntrackedParameter(), pi, particleFlowSuperClusterECAL_cfi::vertexCollection, and HiClusterCompatibility_cfi::zStep.

28 {
29  debugMode = true;
30  nLumiFit = 2; // Number of integrated lumis to perform the fit
31  maxLumiIntegration = 15; // If failing fits, this is the maximum number of integrated lumis after which a reset is issued
32  nLumiXaxisRange = 5000; // Correspond to about 32h of data taking: 32h * 60min * 60s / 23s per lumi-block = 5009
33  dataFromFit = true; // The Beam Spot data can be either taken from the histograms or from the fit results
34  minNentries = 20; // Minimum number of good vertices to perform the fit
35  xRange = 0.8; // [cm]
36  xStep = 0.001; // [cm]
37  yRange = 0.8; // [cm]
38  yStep = 0.001; // [cm]
39  zRange = 30.; // [cm]
40  zStep = 0.04; // [cm]
41  VxErrCorr = 1.3;
42  minVxDoF = 10.; // Good-vertex selection cut
43  // For vertex fitter without track-weight: d.o.f. = 2*NTracks - 3
44  // For vertex fitter with track-weight: d.o.f. = sum_NTracks(2*track_weight) - 3
45  minVxWgt = 0.5; // Good-vertex selection cut
46  fileName = "BeamPixelResults.txt";
47 
48  vertexCollection = consumes<VertexCollection> (iConfig.getUntrackedParameter<InputTag>("vertexCollection", InputTag("pixelVertices")));
49  pixelHitCollection = consumes<SiPixelRecHitCollection>(iConfig.getUntrackedParameter<InputTag>("pixelHitCollection", InputTag("siPixelRecHits")));
50 
51  debugMode = iConfig.getParameter<bool>("debugMode");
52  nLumiFit = iConfig.getParameter<unsigned int>("nLumiFit");
53  maxLumiIntegration = iConfig.getParameter<unsigned int>("maxLumiIntegration");
54  nLumiXaxisRange = iConfig.getParameter<unsigned int>("nLumiXaxisRange");
55  dataFromFit = iConfig.getParameter<bool>("dataFromFit");
56  minNentries = iConfig.getParameter<unsigned int>("minNentries");
57  xRange = iConfig.getParameter<double>("xRange");
58  xStep = iConfig.getParameter<double>("xStep");
59  yRange = iConfig.getParameter<double>("yRange");
60  yStep = iConfig.getParameter<double>("yStep");
61  zRange = iConfig.getParameter<double>("zRange");
62  zStep = iConfig.getParameter<double>("zStep");
63  VxErrCorr = iConfig.getParameter<double>("VxErrCorr");
64  minVxDoF = iConfig.getParameter<double>("minVxDoF");
65  minVxWgt = iConfig.getParameter<double>("minVxWgt");
66  fileName = iConfig.getParameter<string>("fileName");
67 
68 
69  // ### Set internal variables ###
70  nParams = 9; // Number of free parameters in the fit
71  internalDebug = false;
72  considerVxCovariance = true; // Deconvolute vertex covariance matrix
73  pi = 3.141592653589793238;
74  // ##############################
75 }
T getParameter(std::string const &) const
T getUntrackedParameter(std::string const &, T const &) const
unsigned int maxLumiIntegration
edm::EDGetTokenT< reco::VertexCollection > vertexCollection
unsigned int nLumiXaxisRange
unsigned int minNentries
edm::EDGetTokenT< SiPixelRecHitCollection > pixelHitCollection
unsigned int nParams
std::string fileName
unsigned int nLumiFit
Vx3DHLTAnalyzer::~Vx3DHLTAnalyzer ( )

Definition at line 78 of file Vx3DHLTAnalyzer.cc.

References reset().

79 {
80  reset("scratch");
81 }
void reset(std::string ResetType)

Member Function Documentation

void Vx3DHLTAnalyzer::analyze ( const edm::Event iEvent,
const edm::EventSetup iSetup 
)
overrideprivate

Definition at line 84 of file Vx3DHLTAnalyzer.cc.

References gather_cfg::cout, VertexType::Covariance, DIM, MillePedeFileConverter_cfg::fileName, edm::Event::getByToken(), edm::Event::getLuminosityBlock(), mps_fire::i, edm::EventBase::id(), edm::isNotFinite(), MillePedeFileConverter_cfg::out, reset(), edm::EventID::run(), convertSQLiteXML::runNumber, tmp, particleFlowSuperClusterECAL_cfi::vertexCollection, fftjetpfpileupcleaner_cfi::Vertices, VertexType::x, VertexType::y, and VertexType::z.

85 {
86  Handle<VertexCollection> Vx3DCollection;
87  iEvent.getByToken(vertexCollection, Vx3DCollection);
88 
89  unsigned int i,j;
90  double det;
91  VertexType MyVertex;
92 
93  if (runNumber != iEvent.id().run())
94  {
95  reset("scratch");
96  runNumber = iEvent.id().run();
97 
98  if (debugMode == true)
99  {
100  stringstream debugFile;
101  string tmp(fileName);
102 
103  if (outputDebugFile.is_open() == true) outputDebugFile.close();
104  tmp.erase(strlen(fileName.c_str())-4,4);
105  debugFile << tmp.c_str() << "_Run" << iEvent.id().run() << ".txt";
106  outputDebugFile.open(debugFile.str().c_str(), ios::out);
107  outputDebugFile.close();
108  outputDebugFile.open(debugFile.str().c_str(), ios::app);
109  }
110 
111  beginLuminosityBlock(iEvent.getLuminosityBlock(),iSetup);
112  }
113  else if (beginTimeOfFit != 0)
114  {
115  totalHits += HitCounter(iEvent);
116 
117  if (internalDebug == true)
118  {
119  cout << "[Vx3DHLTAnalyzer]::\tI found " << totalHits << " pixel hits until now" << endl;
120  cout << "[Vx3DHLTAnalyzer]::\tIn this event there are " << Vx3DCollection->size() << " vertex cadidates" << endl;
121  }
122 
123  for (vector<Vertex>::const_iterator it3DVx = Vx3DCollection->begin(); it3DVx != Vx3DCollection->end(); it3DVx++)
124  {
125  if (internalDebug == true)
126  {
127  cout << "[Vx3DHLTAnalyzer]::\tVertex selections:" << endl;
128  cout << "[Vx3DHLTAnalyzer]::\tisValid = " << it3DVx->isValid() << endl;
129  cout << "[Vx3DHLTAnalyzer]::\tisFake = " << it3DVx->isFake() << endl;
130  cout << "[Vx3DHLTAnalyzer]::\tnodof = " << it3DVx->ndof() << endl;
131  cout << "[Vx3DHLTAnalyzer]::\ttracksSize = " << it3DVx->tracksSize() << endl;
132  }
133 
134  if ((it3DVx->isValid() == true) &&
135  (it3DVx->isFake() == false) &&
136  (it3DVx->ndof() >= minVxDoF) &&
137  (it3DVx->tracksSize() > 0) &&
138  ((it3DVx->ndof()+3.) / ((double)it3DVx->tracksSize()) >= 2.*minVxWgt))
139  {
140  for (i = 0; i < DIM; i++)
141  {
142  for (j = 0; j < DIM; j++)
143  {
144  MyVertex.Covariance[i][j] = it3DVx->covariance(i,j);
145  if (isNotFinite(MyVertex.Covariance[i][j]) == true) break;
146  }
147 
148  if (j != DIM) break;
149  }
150 
151  if (i == DIM)
152  det = std::fabs(MyVertex.Covariance[0][0])*(std::fabs(MyVertex.Covariance[1][1])*std::fabs(MyVertex.Covariance[2][2]) - MyVertex.Covariance[1][2]*MyVertex.Covariance[1][2]) -
153  MyVertex.Covariance[0][1]*(MyVertex.Covariance[0][1]*std::fabs(MyVertex.Covariance[2][2]) - MyVertex.Covariance[0][2]*MyVertex.Covariance[1][2]) +
154  MyVertex.Covariance[0][2]*(MyVertex.Covariance[0][1]*MyVertex.Covariance[1][2] - MyVertex.Covariance[0][2]*std::fabs(MyVertex.Covariance[1][1]));
155 
156  if ((i == DIM) && (det > 0.))
157  {
158  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tVertex accepted !" << endl;
159 
160  MyVertex.x = it3DVx->x();
161  MyVertex.y = it3DVx->y();
162  MyVertex.z = it3DVx->z();
163  Vertices.push_back(MyVertex);
164 
165  Vx_X->Fill(it3DVx->x());
166  Vx_Y->Fill(it3DVx->y());
167  Vx_Z->Fill(it3DVx->z());
168 
169  Vx_ZX->Fill(it3DVx->z(), it3DVx->x());
170  Vx_ZY->Fill(it3DVx->z(), it3DVx->y());
171  Vx_XY->Fill(it3DVx->x(), it3DVx->y());
172 
173  Vx_X_Cum->Fill(it3DVx->x());
174  Vx_Y_Cum->Fill(it3DVx->y());
175  Vx_Z_Cum->Fill(it3DVx->z());
176 
177  Vx_ZX_Cum->Fill(it3DVx->z(), it3DVx->x());
178  Vx_ZY_Cum->Fill(it3DVx->z(), it3DVx->y());
179  Vx_XY_Cum->Fill(it3DVx->x(), it3DVx->y());
180  }
181  else if (internalDebug == true)
182  {
183  cout << "[Vx3DHLTAnalyzer]::\tVertex discarded !" << endl;
184 
185  for (i = 0; i < DIM; i++)
186  for (j = 0; j < DIM; j++)
187  cout << "(i,j) --> " << i << "," << j << " --> " << MyVertex.Covariance[i][j] << endl;
188  }
189  }
190  else if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tVertex discarded !" << endl;
191  }
192  }
193 }
RunNumber_t run() const
Definition: EventID.h:39
MonitorElement * Vx_ZX
unsigned int totalHits
MonitorElement * Vx_Y_Cum
edm::EDGetTokenT< reco::VertexCollection > vertexCollection
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:460
MonitorElement * Vx_X
edm::TimeValue_t beginTimeOfFit
unsigned int HitCounter(const edm::Event &iEvent)
void beginLuminosityBlock(const edm::LuminosityBlock &lumiBlock, const edm::EventSetup &iSetup) override
void Fill(long long x)
MonitorElement * Vx_XY
double Covariance[3][3]
bool isNotFinite(T x)
Definition: isFinite.h:10
MonitorElement * Vx_ZY
std::string fileName
MonitorElement * Vx_ZY_Cum
std::ofstream outputDebugFile
LuminosityBlock const & getLuminosityBlock() const
Definition: Event.h:86
MonitorElement * Vx_ZX_Cum
MonitorElement * Vx_Z
void reset(std::string ResetType)
MonitorElement * Vx_X_Cum
std::vector< VertexType > Vertices
#define DIM
MonitorElement * Vx_XY_Cum
std::vector< std::vector< double > > tmp
Definition: MVATrainer.cc:100
edm::EventID id() const
Definition: EventBase.h:60
unsigned int runNumber
MonitorElement * Vx_Z_Cum
MonitorElement * Vx_Y
void Vx3DHLTAnalyzer::beginLuminosityBlock ( const edm::LuminosityBlock lumiBlock,
const edm::EventSetup iSetup 
)
overrideprivate

Definition at line 876 of file Vx3DHLTAnalyzer.cc.

References edm::LuminosityBlockBase::beginTime(), edm::LuminosityBlockBase::luminosityBlock(), reset(), and edm::Timestamp::value().

877 {
878  // @@@ If statement to avoid problems with non-sequential lumisections @@@
879  if ((lumiCounter == 0) && (lumiBlock.luminosityBlock() > lastLumiOfFit))
880  {
881  beginTimeOfFit = lumiBlock.beginTime().value();
882  beginLumiOfFit = lumiBlock.luminosityBlock();
883  lumiCounter++;
884  }
885  else if ((lumiCounter != 0) && (lumiBlock.luminosityBlock() >= (beginLumiOfFit+lumiCounter))) lumiCounter++;
886  else reset("scratch");
887 }
unsigned int lumiCounter
unsigned int beginLumiOfFit
edm::TimeValue_t beginTimeOfFit
Timestamp const & beginTime() const
LuminosityBlockNumber_t luminosityBlock() const
void reset(std::string ResetType)
unsigned int lastLumiOfFit
TimeValue_t value() const
Definition: Timestamp.h:56
void Vx3DHLTAnalyzer::bookHistograms ( DQMStore::IBooker ibooker,
edm::Run const &  iRun,
edm::EventSetup const &   
)
overrideprivatevirtual

Implements DQMEDAnalyzer.

Definition at line 1170 of file Vx3DHLTAnalyzer.cc.

References DQMStore::IBooker::book1D(), DQMStore::IBooker::book2D(), DQMStore::IBooker::bookFloat(), DEFINE_FWK_MODULE, MonitorElement::Fill(), MonitorElement::getTH1(), reset(), MonitorElement::setAxisTitle(), DQMStore::IBooker::setCurrentFolder(), and HiClusterCompatibility_cfi::zStep.

1171 {
1172  ibooker.setCurrentFolder("BeamPixel");
1173 
1174  Vx_X = ibooker.book1D("F - vertex x", "Primary Vertex X Distribution", int(rint(xRange/xStep)), -xRange/2., xRange/2.);
1175  Vx_Y = ibooker.book1D("F - vertex y", "Primary Vertex Y Distribution", int(rint(yRange/yStep)), -yRange/2., yRange/2.);
1176  Vx_Z = ibooker.book1D("F - vertex z", "Primary Vertex Z Distribution", int(rint(zRange/zStep)), -zRange/2., zRange/2.);
1177  Vx_X->setAxisTitle("Primary Vertices X [cm]",1);
1178  Vx_X->setAxisTitle("Entries [#]",2);
1179  Vx_Y->setAxisTitle("Primary Vertices Y [cm]",1);
1180  Vx_Y->setAxisTitle("Entries [#]",2);
1181  Vx_Z->setAxisTitle("Primary Vertices Z [cm]",1);
1182  Vx_Z->setAxisTitle("Entries [#]",2);
1183 
1184  Vx_X_Cum = ibooker.book1D("H - vertex x cum", "Primary Vertex X Distribution (Cumulative)", int(rint(xRange/xStep)), -xRange/2., xRange/2.);
1185  Vx_Y_Cum = ibooker.book1D("H - vertex y cum", "Primary Vertex Y Distribution (Cumulative)", int(rint(yRange/yStep)), -yRange/2., yRange/2.);
1186  Vx_Z_Cum = ibooker.book1D("H - vertex z cum", "Primary Vertex Z Distribution (Cumulative)", int(rint(zRange/zStep)), -zRange/2., zRange/2.);
1187  Vx_X_Cum->setAxisTitle("Primary Vertices X [cm]",1);
1188  Vx_X_Cum->setAxisTitle("Entries [#]",2);
1189  Vx_Y_Cum->setAxisTitle("Primary Vertices Y [cm]",1);
1190  Vx_Y_Cum->setAxisTitle("Entries [#]",2);
1191  Vx_Z_Cum->setAxisTitle("Primary Vertices Z [cm]",1);
1192  Vx_Z_Cum->setAxisTitle("Entries [#]",2);
1193 
1194  mXlumi = ibooker.book1D("B - muX vs lumi", "#mu_{x} vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1195  mYlumi = ibooker.book1D("B - muY vs lumi", "#mu_{y} vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1196  mZlumi = ibooker.book1D("B - muZ vs lumi", "#mu_{z} vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1197  mXlumi->setAxisTitle("Lumisection [#]",1);
1198  mXlumi->setAxisTitle("#mu_{x} [cm]",2);
1199  mXlumi->getTH1()->SetOption("E1");
1200  mYlumi->setAxisTitle("Lumisection [#]",1);
1201  mYlumi->setAxisTitle("#mu_{y} [cm]",2);
1202  mYlumi->getTH1()->SetOption("E1");
1203  mZlumi->setAxisTitle("Lumisection [#]",1);
1204  mZlumi->setAxisTitle("#mu_{z} [cm]",2);
1205  mZlumi->getTH1()->SetOption("E1");
1206 
1207  sXlumi = ibooker.book1D("C - sigmaX vs lumi", "#sigma_{x} vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1208  sYlumi = ibooker.book1D("C - sigmaY vs lumi", "#sigma_{y} vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1209  sZlumi = ibooker.book1D("C - sigmaZ vs lumi", "#sigma_{z} vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1210  sXlumi->setAxisTitle("Lumisection [#]",1);
1211  sXlumi->setAxisTitle("#sigma_{x} [cm]",2);
1212  sXlumi->getTH1()->SetOption("E1");
1213  sYlumi->setAxisTitle("Lumisection [#]",1);
1214  sYlumi->setAxisTitle("#sigma_{y} [cm]",2);
1215  sYlumi->getTH1()->SetOption("E1");
1216  sZlumi->setAxisTitle("Lumisection [#]",1);
1217  sZlumi->setAxisTitle("#sigma_{z} [cm]",2);
1218  sZlumi->getTH1()->SetOption("E1");
1219 
1220  dxdzlumi = ibooker.book1D("D - dxdz vs lumi", "dX/dZ vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1221  dydzlumi = ibooker.book1D("D - dydz vs lumi", "dY/dZ vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1222  dxdzlumi->setAxisTitle("Lumisection [#]",1);
1223  dxdzlumi->setAxisTitle("dX/dZ [rad]",2);
1224  dxdzlumi->getTH1()->SetOption("E1");
1225  dydzlumi->setAxisTitle("Lumisection [#]",1);
1226  dydzlumi->setAxisTitle("dY/dZ [rad]",2);
1227  dydzlumi->getTH1()->SetOption("E1");
1228 
1229  Vx_ZX = ibooker.book2D("E - vertex zx", "Primary Vertex ZX Distribution", int(rint(zRange/zStep)), -zRange/2., zRange/2., int(rint(xRange/xStep)), -xRange/2., xRange/2.);
1230  Vx_ZY = ibooker.book2D("E - vertex zy", "Primary Vertex ZY Distribution", int(rint(zRange/zStep)), -zRange/2., zRange/2., int(rint(yRange/yStep)), -yRange/2., yRange/2.);
1231  Vx_XY = ibooker.book2D("E - vertex xy", "Primary Vertex XY Distribution", int(rint(xRange/xStep)), -xRange/2., xRange/2., int(rint(yRange/yStep)), -yRange/2., yRange/2.);
1232  Vx_ZX->setAxisTitle("Primary Vertices Z [cm]",1);
1233  Vx_ZX->setAxisTitle("Primary Vertices X [cm]",2);
1234  Vx_ZX->setAxisTitle("Entries [#]",3);
1235  Vx_ZY->setAxisTitle("Primary Vertices Z [cm]",1);
1236  Vx_ZY->setAxisTitle("Primary Vertices Y [cm]",2);
1237  Vx_ZY->setAxisTitle("Entries [#]",3);
1238  Vx_XY->setAxisTitle("Primary Vertices X [cm]",1);
1239  Vx_XY->setAxisTitle("Primary Vertices Y [cm]",2);
1240  Vx_XY->setAxisTitle("Entries [#]",3);
1241 
1242  Vx_ZX_Cum = ibooker.book2D("G - vertex zx cum", "Primary Vertex ZX Distribution (Cumulative)", int(rint(zRange/zStep)), -zRange/2., zRange/2., int(rint(xRange/xStep)), -xRange/2., xRange/2.);
1243  Vx_ZY_Cum = ibooker.book2D("G - vertex zy cum", "Primary Vertex ZY Distribution (Cumulative)", int(rint(zRange/zStep)), -zRange/2., zRange/2., int(rint(yRange/yStep)), -yRange/2., yRange/2.);
1244  Vx_XY_Cum = ibooker.book2D("G - vertex xy cum", "Primary Vertex XY Distribution (Cumulative)", int(rint(xRange/xStep)), -xRange/2., xRange/2., int(rint(yRange/yStep)), -yRange/2., yRange/2.);
1245  Vx_ZX_Cum->setAxisTitle("Primary Vertices Z [cm]",1);
1246  Vx_ZX_Cum->setAxisTitle("Primary Vertices X [cm]",2);
1247  Vx_ZX_Cum->setAxisTitle("Entries [#]",3);
1248  Vx_ZY_Cum->setAxisTitle("Primary Vertices Z [cm]",1);
1249  Vx_ZY_Cum->setAxisTitle("Primary Vertices Y [cm]",2);
1250  Vx_ZY_Cum->setAxisTitle("Entries [#]",3);
1251  Vx_XY_Cum->setAxisTitle("Primary Vertices X [cm]",1);
1252  Vx_XY_Cum->setAxisTitle("Primary Vertices Y [cm]",2);
1253  Vx_XY_Cum->setAxisTitle("Entries [#]",3);
1254 
1255  hitCounter = ibooker.book1D("J - pixelHits vs lumi", "# Pixel-Hits vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1256  hitCounter->setAxisTitle("Lumisection [#]",1);
1257  hitCounter->setAxisTitle("Pixel-Hits [#]",2);
1258  hitCounter->getTH1()->SetOption("E1");
1259 
1260  goodVxCounter = ibooker.book1D("I - good vertices vs lumi", "# Good vertices vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1261  goodVxCounter->setAxisTitle("Lumisection [#]",1);
1262  goodVxCounter->setAxisTitle("Good vertices [#]",2);
1263  goodVxCounter->getTH1()->SetOption("E1");
1264 
1265  statusCounter = ibooker.book1D("K - status vs lumi", "App. Status vs. Lumisection", nLumiXaxisRange, 0.5, ((double)nLumiXaxisRange)+0.5);
1266  statusCounter->setAxisTitle("Lumisection [#]",1);
1267  statusCounter->getTH1()->SetOption("E1");
1268  statusCounter->getTH1()->GetYaxis()->Set(11,-5.5,5.5);
1269  statusCounter->getTH1()->GetYaxis()->SetBinLabel(1, "Max Lumi.");
1270  statusCounter->getTH1()->GetYaxis()->SetBinLabel(2, "Neg. det.");
1271  statusCounter->getTH1()->GetYaxis()->SetBinLabel(3, "Infinite err.");
1272  statusCounter->getTH1()->GetYaxis()->SetBinLabel(4, "No vtx.");
1273  statusCounter->getTH1()->GetYaxis()->SetBinLabel(5, "Infinite EDM");
1274  statusCounter->getTH1()->GetYaxis()->SetBinLabel(6, "OK");
1275  statusCounter->getTH1()->GetYaxis()->SetBinLabel(7, "MINUIT stat.");
1276  statusCounter->getTH1()->GetYaxis()->SetBinLabel(8, "MINUIT stat.");
1277  statusCounter->getTH1()->GetYaxis()->SetBinLabel(9, "MINUIT stat.");
1278  statusCounter->getTH1()->GetYaxis()->SetBinLabel(10, "MINUIT stat.");
1279  statusCounter->getTH1()->GetYaxis()->SetBinLabel(11, "MINUIT stat.");
1280 
1281  fitResults = ibooker.book2D("A - fit results","Results of Beam Spot Fit", 2, 0., 2., 9, 0., 9.);
1282  fitResults->setAxisTitle("Ongoing: bootstrapping", 1);
1283  fitResults->setBinLabel(9, "X[cm]", 2);
1284  fitResults->setBinLabel(8, "Y[cm]", 2);
1285  fitResults->setBinLabel(7, "Z[cm]", 2);
1286  fitResults->setBinLabel(6, "#sigma_{Z}[cm]", 2);
1287  fitResults->setBinLabel(5, "#frac{dX}{dZ}[rad]", 2);
1288  fitResults->setBinLabel(4, "#frac{dY}{dZ}[rad]", 2);
1289  fitResults->setBinLabel(3, "#sigma_{X}[cm]", 2);
1290  fitResults->setBinLabel(2, "#sigma_{Y}[cm]", 2);
1291  fitResults->setBinLabel(1, "Vtx[#]", 2);
1292  fitResults->setBinLabel(1, "Value", 1);
1293  fitResults->setBinLabel(2, "Error (stat)", 1);
1294  fitResults->getTH1()->SetOption("text");
1295 
1296 
1297  ibooker.setCurrentFolder("BeamPixel/EventInfo");
1298 
1299  reportSummary = ibooker.bookFloat("reportSummary");
1300  reportSummary->Fill(-1);
1301  reportSummaryMap = ibooker.book2D("reportSummaryMap","Pixel-Vertices Beam Spot: % Good Fits", 1, 0., 1., 1, 0., 1.);
1302  reportSummaryMap->getTH1()->SetBinContent(1, 1, -1);
1303 
1304  ibooker.setCurrentFolder("BeamPixel/EventInfo/reportSummaryContents");
1305 
1306  // Convention for reportSummary and reportSummaryMap:
1307  // - -1% at the moment of creation of the histogram (i.e. white histogram)
1308  // - n% numberGoodFits / numberFits
1309 
1310 
1311  reset("scratch"); // Initialize histograms after creation
1312 }
MonitorElement * statusCounter
MonitorElement * dxdzlumi
MonitorElement * Vx_ZX
MonitorElement * Vx_Y_Cum
unsigned int nLumiXaxisRange
MonitorElement * Vx_X
void setBinLabel(int bin, const std::string &label, int axis=1)
set bin label for x, y or z axis (axis=1, 2, 3 respectively)
MonitorElement * mYlumi
MonitorElement * sYlumi
MonitorElement * reportSummaryMap
void Fill(long long x)
MonitorElement * Vx_XY
MonitorElement * sZlumi
MonitorElement * fitResults
MonitorElement * Vx_ZY
MonitorElement * reportSummary
MonitorElement * Vx_ZY_Cum
MonitorElement * goodVxCounter
MonitorElement * book1D(Args &&...args)
Definition: DQMStore.h:115
MonitorElement * dydzlumi
TH1 * getTH1(void) const
MonitorElement * Vx_ZX_Cum
MonitorElement * Vx_Z
MonitorElement * mXlumi
void reset(std::string ResetType)
MonitorElement * Vx_X_Cum
MonitorElement * mZlumi
MonitorElement * sXlumi
void setCurrentFolder(const std::string &fullpath)
Definition: DQMStore.cc:277
MonitorElement * book2D(Args &&...args)
Definition: DQMStore.h:133
MonitorElement * Vx_XY_Cum
MonitorElement * Vx_Z_Cum
MonitorElement * bookFloat(Args &&...args)
Definition: DQMStore.h:109
MonitorElement * hitCounter
void setAxisTitle(const std::string &title, int axis=1)
set x-, y- or z-axis title (axis=1, 2, 3 respectively)
MonitorElement * Vx_Y
void Vx3DHLTAnalyzer::endLuminosityBlock ( const edm::LuminosityBlock lumiBlock,
const edm::EventSetup iSetup 
)
overrideprivate

Definition at line 890 of file Vx3DHLTAnalyzer.cc.

References gather_cfg::cout, MillePedeFileConverter_cfg::e, edm::LuminosityBlockBase::endTime(), edm::service::formatTime(), mps_fire::i, edm::LuminosityBlockBase::luminosityBlock(), funct::pow(), reset(), convertSQLiteXML::runNumber, mathSSE::sqrt(), create_public_pileup_plots::vals, and edm::Timestamp::value().

891 {
892  stringstream histTitle;
893  int goodData;
894 
895  if ((nLumiFit != 0) && (lumiCounter%nLumiFit == 0) && (beginTimeOfFit != 0) && (runNumber != 0))
896  {
897  endTimeOfFit = lumiBlock.endTime().value();
898  endLumiOfFit = lumiBlock.luminosityBlock();
900  vector<double> vals;
901 
902  hitCounter->getTH1()->SetBinContent(lastLumiOfFit, (double)totalHits);
903  hitCounter->getTH1()->SetBinError(lastLumiOfFit, (totalHits != 0 ? 1. : 0.)); // It's not sqrt(n) because we want to weight all entries in the same way for the fit
904 
905  if (dataFromFit == true)
906  {
907  vector<double> fitResults;
908 
909  fitResults.push_back(Vx_X->getTH1()->GetRMS()*Vx_X->getTH1()->GetRMS());
910  fitResults.push_back(Vx_Y->getTH1()->GetRMS()*Vx_Y->getTH1()->GetRMS());
911  fitResults.push_back(Vx_Z->getTH1()->GetRMS()*Vx_Z->getTH1()->GetRMS());
912  fitResults.push_back(0.0);
913  fitResults.push_back(0.0);
914  fitResults.push_back(0.0);
915  fitResults.push_back(Vx_X->getTH1()->GetMean());
916  fitResults.push_back(Vx_Y->getTH1()->GetMean());
917  fitResults.push_back(Vx_Z->getTH1()->GetMean());
918  for (unsigned int i = 0; i < nParams; i++) fitResults.push_back(0.0);
919 
920  if (internalDebug == true)
921  {
922  cout << "[Vx3DHLTAnalyzer]::\t@@@ Beam Spot parameters - prefit @@@" << endl;
923 
924  printFitParams(fitResults);
925 
926  cout << "Runnumber " << runNumber << endl;
927  cout << "BeginTimeOfFit " << formatTime(beginTimeOfFit >> 32) << " " << (beginTimeOfFit >> 32) << endl;
928  cout << "EndTimeOfFit " << formatTime(endTimeOfFit >> 32) << " " << (endTimeOfFit >> 32) << endl;
929  cout << "LumiRange " << beginLumiOfFit << " - " << endLumiOfFit << endl;
930  }
931 
932  goodData = MyFit(&fitResults);
933 
934  if (internalDebug == true)
935  {
936  cout << "[Vx3DHLTAnalyzer]::\t@@@ Beam Spot parameters - postfit @@@" << endl;
937 
938  printFitParams(fitResults);
939 
940  cout << "goodData --> " << goodData << endl;
941  cout << "Used vertices --> " << counterVx << endl;
942  }
943 
944  if (goodData == 0)
945  {
946  vals.push_back(fitResults[6]);
947  vals.push_back(fitResults[7]);
948  vals.push_back(fitResults[8]);
949  vals.push_back(std::sqrt(std::fabs(fitResults[2])));
950  vals.push_back(fitResults[5]);
951  vals.push_back(fitResults[4]);
952  vals.push_back(std::sqrt(std::fabs(fitResults[0])));
953  vals.push_back(std::sqrt(std::fabs(fitResults[1])));
954 
955  vals.push_back(std::pow(fitResults[6+nParams],2.));
956  vals.push_back(std::pow(fitResults[7+nParams],2.));
957  vals.push_back(std::pow(fitResults[8+nParams],2.));
958  vals.push_back(std::pow(std::fabs(fitResults[2+nParams]) / (2.*std::sqrt(std::fabs(fitResults[2]))),2.));
959  vals.push_back(std::pow(fitResults[5+nParams],2.));
960  vals.push_back(std::pow(fitResults[4+nParams],2.));
961  vals.push_back(std::pow(std::fabs(fitResults[0+nParams]) / (2.*std::sqrt(std::fabs(fitResults[0]))),2.));
962  vals.push_back(std::pow(std::fabs(fitResults[1+nParams]) / (2.*std::sqrt(std::fabs(fitResults[1]))),2.));
963  }
964  else for (unsigned int i = 0; i < (nParams-1)*2; i++) vals.push_back(0.0);
965 
966  fitResults.clear();
967  }
968  else
969  {
970  counterVx = Vx_X->getTH1F()->GetEntries();
971 
972  if (Vx_X->getTH1F()->GetEntries() >= minNentries)
973  {
974  goodData = 0;
975 
976  vals.push_back(Vx_X->getTH1F()->GetMean());
977  vals.push_back(Vx_Y->getTH1F()->GetMean());
978  vals.push_back(Vx_Z->getTH1F()->GetMean());
979  vals.push_back(Vx_Z->getTH1F()->GetRMS());
980  vals.push_back(0.0);
981  vals.push_back(0.0);
982  vals.push_back(Vx_X->getTH1F()->GetRMS());
983  vals.push_back(Vx_Y->getTH1F()->GetRMS());
984 
985  vals.push_back(std::pow(Vx_X->getTH1F()->GetMeanError(),2.));
986  vals.push_back(std::pow(Vx_Y->getTH1F()->GetMeanError(),2.));
987  vals.push_back(std::pow(Vx_Z->getTH1F()->GetMeanError(),2.));
988  vals.push_back(std::pow(Vx_Z->getTH1F()->GetRMSError(),2.));
989  vals.push_back(0.0);
990  vals.push_back(0.0);
991  vals.push_back(std::pow(Vx_X->getTH1F()->GetRMSError(),2.));
992  vals.push_back(std::pow(Vx_Y->getTH1F()->GetRMSError(),2.));
993  }
994  else
995  {
996  goodData = -2;
997  for (unsigned int i = 0; i < (nParams-1)*2; i++) vals.push_back(0.0);
998  }
999  }
1000 
1001  // vals[0] = X0
1002  // vals[1] = Y0
1003  // vals[2] = Z0
1004  // vals[3] = sigmaZ0
1005  // vals[4] = dxdz
1006  // vals[5] = dydz
1007  // vals[6] = BeamWidthX
1008  // vals[7] = BeamWidthY
1009 
1010  // vals[8] = err^2 X0
1011  // vals[9] = err^2 Y0
1012  // vals[10] = err^2 Z0
1013  // vals[11] = err^2 sigmaZ0
1014  // vals[12] = err^2 dxdz
1015  // vals[13] = err^2 dydz
1016  // vals[14] = err^2 BeamWidthX
1017  // vals[15] = err^2 BeamWidthY
1018 
1019  numberFits++;
1021  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tUsed vertices: " << counterVx << endl;
1022 
1023  statusCounter->getTH1()->SetBinContent(lastLumiOfFit, (double)goodData);
1024  statusCounter->getTH1()->SetBinError(lastLumiOfFit, 1e-3);
1025 
1026  if (goodData == 0)
1027  {
1028  numberGoodFits++;
1029 
1030  histTitle << "Ongoing: fitted lumis " << beginLumiOfFit << " - " << endLumiOfFit;
1031  reset("whole");
1032  }
1033  else
1034  {
1035  if (goodData == -2) histTitle << "Ongoing: not enough evts (" << lumiCounter << " - " << maxLumiIntegration << " lumis)";
1036  else histTitle << "Ongoing: temporary problems (" << lumiCounter << " - " << maxLumiIntegration << " lumis)";
1037 
1038  if (lumiCounter >= maxLumiIntegration)
1039  {
1040  statusCounter->getTH1()->SetBinContent(lastLumiOfFit, -5);
1041  statusCounter->getTH1()->SetBinError(lastLumiOfFit, 1e-3);
1042  reset("whole");
1043  }
1044  else reset("hitCounter");
1045  }
1046 
1047  reportSummary->Fill((numberFits != 0 ? ((double)numberGoodFits) / ((double)numberFits) : -1));
1048  reportSummaryMap->getTH1()->SetBinContent(1, 1, (numberFits != 0 ? ((double)numberGoodFits) / ((double)numberFits) : -1));
1049 
1050  fitResults->setAxisTitle(histTitle.str().c_str(), 1);
1051 
1052  fitResults->setBinContent(1, 9, vals[0]);
1053  fitResults->setBinContent(1, 8, vals[1]);
1054  fitResults->setBinContent(1, 7, vals[2]);
1055  fitResults->setBinContent(1, 6, vals[3]);
1056  fitResults->setBinContent(1, 5, vals[4]);
1057  fitResults->setBinContent(1, 4, vals[5]);
1058  fitResults->setBinContent(1, 3, vals[6]);
1059  fitResults->setBinContent(1, 2, vals[7]);
1060  fitResults->setBinContent(1, 1, counterVx);
1061 
1062  fitResults->setBinContent(2, 9, std::sqrt(vals[8]));
1063  fitResults->setBinContent(2, 8, std::sqrt(vals[9]));
1064  fitResults->setBinContent(2, 7, std::sqrt(vals[10]));
1065  fitResults->setBinContent(2, 6, std::sqrt(vals[11]));
1066  fitResults->setBinContent(2, 5, std::sqrt(vals[12]));
1067  fitResults->setBinContent(2, 4, std::sqrt(vals[13]));
1068  fitResults->setBinContent(2, 3, std::sqrt(vals[14]));
1069  fitResults->setBinContent(2, 2, std::sqrt(vals[15]));
1070  fitResults->setBinContent(2, 1, std::sqrt(counterVx));
1071 
1072  // Linear fit to the historical plots
1073  TF1* myLinFit = new TF1("myLinFit", "[0] + [1]*x", mXlumi->getTH1()->GetXaxis()->GetXmin(), mXlumi->getTH1()->GetXaxis()->GetXmax());
1074  myLinFit->SetLineColor(2);
1075  myLinFit->SetLineWidth(2);
1076  myLinFit->SetParName(0,"Inter.");
1077  myLinFit->SetParName(1,"Slope");
1078 
1079  mXlumi->getTH1()->SetBinContent(lastLumiOfFit, vals[0]);
1080  mXlumi->getTH1()->SetBinError(lastLumiOfFit, std::sqrt(vals[8]));
1081  myLinFit->SetParameter(0, mXlumi->getTH1()->GetMean(2));
1082  myLinFit->SetParameter(1, 0.0);
1083  mXlumi->getTH1()->Fit(myLinFit,"QR");
1084 
1085  mYlumi->getTH1()->SetBinContent(lastLumiOfFit, vals[1]);
1086  mYlumi->getTH1()->SetBinError(lastLumiOfFit, std::sqrt(vals[9]));
1087  myLinFit->SetParameter(0, mYlumi->getTH1()->GetMean(2));
1088  myLinFit->SetParameter(1, 0.0);
1089  mYlumi->getTH1()->Fit(myLinFit,"QR");
1090 
1091  mZlumi->getTH1()->SetBinContent(lastLumiOfFit, vals[2]);
1092  mZlumi->getTH1()->SetBinError(lastLumiOfFit, std::sqrt(vals[10]));
1093  myLinFit->SetParameter(0, mZlumi->getTH1()->GetMean(2));
1094  myLinFit->SetParameter(1, 0.0);
1095  mZlumi->getTH1()->Fit(myLinFit,"QR");
1096 
1097  sXlumi->getTH1()->SetBinContent(lastLumiOfFit, vals[6]);
1098  sXlumi->getTH1()->SetBinError(lastLumiOfFit, std::sqrt(vals[14]));
1099  myLinFit->SetParameter(0, sXlumi->getTH1()->GetMean(2));
1100  myLinFit->SetParameter(1, 0.0);
1101  sXlumi->getTH1()->Fit(myLinFit,"QR");
1102 
1103  sYlumi->getTH1()->SetBinContent(lastLumiOfFit, vals[7]);
1104  sYlumi->getTH1()->SetBinError(lastLumiOfFit, std::sqrt(vals[15]));
1105  myLinFit->SetParameter(0, sYlumi->getTH1()->GetMean(2));
1106  myLinFit->SetParameter(1, 0.0);
1107  sYlumi->getTH1()->Fit(myLinFit,"QR");
1108 
1109  sZlumi->getTH1()->SetBinContent(lastLumiOfFit, vals[3]);
1110  sZlumi->getTH1()->SetBinError(lastLumiOfFit, std::sqrt(vals[11]));
1111  myLinFit->SetParameter(0, sZlumi->getTH1()->GetMean(2));
1112  myLinFit->SetParameter(1, 0.0);
1113  sZlumi->getTH1()->Fit(myLinFit,"QR");
1114 
1115  dxdzlumi->getTH1()->SetBinContent(lastLumiOfFit, vals[4]);
1116  dxdzlumi->getTH1()->SetBinError(lastLumiOfFit, std::sqrt(vals[12]));
1117  myLinFit->SetParameter(0, dxdzlumi->getTH1()->GetMean(2));
1118  myLinFit->SetParameter(1, 0.0);
1119  dxdzlumi->getTH1()->Fit(myLinFit,"QR");
1120 
1121  dydzlumi->getTH1()->SetBinContent(lastLumiOfFit, vals[5]);
1122  dydzlumi->getTH1()->SetBinError(lastLumiOfFit, std::sqrt(vals[13]));
1123  myLinFit->SetParameter(0, dydzlumi->getTH1()->GetMean(2));
1124  myLinFit->SetParameter(1, 0.0);
1125  dydzlumi->getTH1()->Fit(myLinFit,"QR");
1126 
1127  myLinFit->SetParameter(0, hitCounter->getTH1()->GetMean(2));
1128  myLinFit->SetParameter(1, 0.0);
1129  hitCounter->getTH1()->Fit(myLinFit,"QR");
1130 
1131  goodVxCounter->getTH1()->SetBinContent(lastLumiOfFit, (double)counterVx);
1132  goodVxCounter->getTH1()->SetBinError(lastLumiOfFit, (counterVx != 0 ? 1. : 0.)); // It's not sqrt(n) because we want to weight all entries in the same way for the fit
1133  myLinFit->SetParameter(0, goodVxCounter->getTH1()->GetMean(2));
1134  myLinFit->SetParameter(1, 0.0);
1135  goodVxCounter->getTH1()->Fit(myLinFit,"QR");
1136 
1137  delete myLinFit;
1138  vals.clear();
1139  }
1140  else if ((nLumiFit != 0) && (lumiCounter%nLumiFit != 0) && (beginTimeOfFit != 0) && (runNumber != 0))
1141  {
1142  histTitle << "Ongoing: accumulating evts (" << lumiCounter%nLumiFit << " - " << nLumiFit << " in " << lumiCounter << " - " << maxLumiIntegration << " lumis)";
1143  fitResults->setAxisTitle(histTitle.str().c_str(), 1);
1144  if ((debugMode == true) && (outputDebugFile.is_open() == true))
1145  {
1146  outputDebugFile << "\n" << "Runnumber " << runNumber << endl;
1147  outputDebugFile << "BeginTimeOfFit " << formatTime(beginTimeOfFit >> 32) << " " << (beginTimeOfFit >> 32) << endl;
1148  outputDebugFile << "BeginLumiRange " << beginLumiOfFit << endl;
1149  outputDebugFile << histTitle.str().c_str() << "\n" << endl;
1150  }
1151  }
1152  else if ((nLumiFit == 0) || (beginTimeOfFit == 0) || (runNumber == 0))
1153  {
1154  histTitle << "Ongoing: no ongoing fits";
1155  fitResults->setAxisTitle(histTitle.str().c_str(), 1);
1156  if ((debugMode == true) && (outputDebugFile.is_open() == true)) outputDebugFile << histTitle.str().c_str() << "\n" << endl;
1157 
1158  endLumiOfFit = lumiBlock.luminosityBlock();
1159 
1160  hitCounter->getTH1()->SetBinContent(endLumiOfFit, (double)totalHits);
1161  hitCounter->getTH1()->SetBinError(endLumiOfFit, std::sqrt((double)totalHits));
1162 
1163  reset("whole");
1164  }
1165 
1166  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tHistogram title: " << histTitle.str() << endl;
1167 }
unsigned int lumiCounter
MonitorElement * statusCounter
MonitorElement * dxdzlumi
unsigned int totalHits
unsigned int maxLumiIntegration
unsigned int numberFits
unsigned int beginLumiOfFit
int MyFit(std::vector< double > *vals)
unsigned int minNentries
MonitorElement * Vx_X
MonitorElement * mYlumi
edm::TimeValue_t beginTimeOfFit
edm::TimeValue_t endTimeOfFit
MonitorElement * sYlumi
MonitorElement * reportSummaryMap
void writeToFile(std::vector< double > *vals, edm::TimeValue_t BeginTimeOfFit, edm::TimeValue_t EndTimeOfFit, unsigned int BeginLumiOfFit, unsigned int EndLumiOfFit, int dataType)
void Fill(long long x)
unsigned int nParams
MonitorElement * sZlumi
LuminosityBlockNumber_t luminosityBlock() const
MonitorElement * fitResults
unsigned int counterVx
std::string formatTime(const time_t &t)
unsigned int endLumiOfFit
unsigned int numberGoodFits
T sqrt(T t)
Definition: SSEVec.h:18
MonitorElement * reportSummary
Timestamp const & endTime() const
MonitorElement * goodVxCounter
std::ofstream outputDebugFile
MonitorElement * dydzlumi
TH1 * getTH1(void) const
MonitorElement * Vx_Z
MonitorElement * mXlumi
void reset(std::string ResetType)
MonitorElement * mZlumi
MonitorElement * sXlumi
unsigned int lastLumiOfFit
TH1F * getTH1F(void) const
void printFitParams(const std::vector< double > &fitResults)
unsigned int runNumber
unsigned int nLumiFit
MonitorElement * hitCounter
TimeValue_t value() const
Definition: Timestamp.h:56
Power< A, B >::type pow(const A &a, const B &b)
Definition: Power.h:40
MonitorElement * Vx_Y
string Vx3DHLTAnalyzer::formatTime ( const time_t &  t)
private

Definition at line 210 of file Vx3DHLTAnalyzer.cc.

211 {
212  char ts[25];
213  strftime(ts, sizeof(ts), "%Y.%m.%d %H:%M:%S %Z", gmtime(&t));
214 
215  string ts_string(ts);
216 
217  return ts_string;
218 }
double Vx3DHLTAnalyzer::Gauss3DFunc ( const double *  par)
protected

Definition at line 221 of file Vx3DHLTAnalyzer.cc.

References DIM, mps_fire::i, cmsBatch::log, pi, mathSSE::sqrt(), fftjetpfpileupcleaner_cfi::Vertices, and x().

Referenced by MyFit().

222 {
223  double K[DIM][DIM]; // Covariance Matrix
224  double M[DIM][DIM]; // K^-1
225  double det;
226  double sumlog = 0.;
227 
228 // par[0] = K(0,0) --> Var[X]
229 // par[1] = K(1,1) --> Var[Y]
230 // par[2] = K(2,2) --> Var[Z]
231 // par[3] = K(0,1) = K(1,0) --> Cov[X,Y]
232 // par[4] = K(1,2) = K(2,1) --> Cov[Y,Z] --> dy/dz
233 // par[5] = K(0,2) = K(2,0) --> Cov[X,Z] --> dx/dz
234 // par[6] = mean x
235 // par[7] = mean y
236 // par[8] = mean z
237 
238  counterVx = 0;
239  for (unsigned int i = 0; i < Vertices.size(); i++)
240  {
242  (std::fabs(Vertices[i].z-zPos) <= maxLongLength))
243  {
244  if (considerVxCovariance == true)
245  {
246  K[0][0] = std::fabs(par[0]) + VxErrCorr*VxErrCorr * std::fabs(Vertices[i].Covariance[0][0]);
247  K[1][1] = std::fabs(par[1]) + VxErrCorr*VxErrCorr * std::fabs(Vertices[i].Covariance[1][1]);
248  K[2][2] = std::fabs(par[2]) + VxErrCorr*VxErrCorr * std::fabs(Vertices[i].Covariance[2][2]);
249  K[0][1] = K[1][0] = par[3] + VxErrCorr*VxErrCorr * Vertices[i].Covariance[0][1];
250  K[1][2] = K[2][1] = par[4]*(std::fabs(par[2])-std::fabs(par[1])) - par[5]*par[3] + VxErrCorr*VxErrCorr * Vertices[i].Covariance[1][2];
251  K[0][2] = K[2][0] = par[5]*(std::fabs(par[2])-std::fabs(par[0])) - par[4]*par[3] + VxErrCorr*VxErrCorr * Vertices[i].Covariance[0][2];
252  }
253  else
254  {
255  K[0][0] = std::fabs(par[0]);
256  K[1][1] = std::fabs(par[1]);
257  K[2][2] = std::fabs(par[2]);
258  K[0][1] = K[1][0] = par[3];
259  K[1][2] = K[2][1] = par[4]*(std::fabs(par[2])-std::fabs(par[1])) - par[5]*par[3];
260  K[0][2] = K[2][0] = par[5]*(std::fabs(par[2])-std::fabs(par[0])) - par[4]*par[3];
261  }
262 
263  det = K[0][0]*(K[1][1]*K[2][2] - K[1][2]*K[1][2]) -
264  K[0][1]*(K[0][1]*K[2][2] - K[0][2]*K[1][2]) +
265  K[0][2]*(K[0][1]*K[1][2] - K[0][2]*K[1][1]);
266 
267  M[0][0] = (K[1][1]*K[2][2] - K[1][2]*K[1][2]) / det;
268  M[1][1] = (K[0][0]*K[2][2] - K[0][2]*K[0][2]) / det;
269  M[2][2] = (K[0][0]*K[1][1] - K[0][1]*K[0][1]) / det;
270  M[0][1] = M[1][0] = (K[0][2]*K[1][2] - K[0][1]*K[2][2]) / det;
271  M[1][2] = M[2][1] = (K[0][2]*K[0][1] - K[1][2]*K[0][0]) / det;
272  M[0][2] = M[2][0] = (K[0][1]*K[1][2] - K[0][2]*K[1][1]) / det;
273 
274  sumlog += double(DIM)*std::log(2.*pi) + std::log(std::fabs(det)) +
275  (M[0][0]*(Vertices[i].x-par[6])*(Vertices[i].x-par[6]) +
276  M[1][1]*(Vertices[i].y-par[7])*(Vertices[i].y-par[7]) +
277  M[2][2]*(Vertices[i].z-par[8])*(Vertices[i].z-par[8]) +
278  2.*M[0][1]*(Vertices[i].x-par[6])*(Vertices[i].y-par[7]) +
279  2.*M[1][2]*(Vertices[i].y-par[7])*(Vertices[i].z-par[8]) +
280  2.*M[0][2]*(Vertices[i].x-par[6])*(Vertices[i].z-par[8]));
281 
282  counterVx++;
283  }
284  }
285 
286  return sumlog;
287 }
unsigned int counterVx
T sqrt(T t)
Definition: SSEVec.h:18
std::vector< VertexType > Vertices
#define DIM
unsigned int Vx3DHLTAnalyzer::HitCounter ( const edm::Event iEvent)
private

Definition at line 196 of file Vx3DHLTAnalyzer.cc.

References edmNew::DetSetVector< T >::begin(), counter, edmNew::DetSetVector< T >::end(), and edm::Event::getByToken().

197 {
198  Handle<SiPixelRecHitCollection> rechitspixel;
199  iEvent.getByToken(pixelHitCollection, rechitspixel);
200 
201  unsigned int counter = 0;
202 
203  for (SiPixelRecHitCollection::const_iterator j = rechitspixel->begin(); j != rechitspixel->end(); j++)
204  for (edmNew::DetSet<SiPixelRecHit>::const_iterator h = j->begin(); h != j->end(); h++) counter += h->cluster()->size();
205 
206  return counter;
207 }
boost::transform_iterator< IterHelp, const_IdIter > const_iterator
const_iterator end(bool update=false) const
bool getByToken(EDGetToken token, Handle< PROD > &result) const
Definition: Event.h:460
edm::EDGetTokenT< SiPixelRecHitCollection > pixelHitCollection
data_type const * const_iterator
Definition: DetSetNew.h:30
static std::atomic< unsigned int > counter
const_iterator begin(bool update=false) const
int Vx3DHLTAnalyzer::MyFit ( std::vector< double > *  vals)
private

Definition at line 290 of file Vx3DHLTAnalyzer.cc.

References gather_cfg::cout, MillePedeFileConverter_cfg::e, Gauss3DFunc(), mps_fire::i, edm::isNotFinite(), hiDetachedTripletStep_cff::nSigmaZ, NULL, and mathSSE::sqrt().

291 {
292  // ############################################
293  // # RETURN CODE: #
294  // # >0 == NO OK - fit status (MINUIT manual) #
295  // # 0 == OK #
296  // # -1 == NO OK - not finite edm #
297  // # -2 == NO OK - not enough "minNentries" #
298  // # -3 == NO OK - not finite errors #
299  // # -4 == NO OK - negative determinant #
300  // # -5 == NO OK - maxLumiIntegration reached #
301  // ############################################
302 
303  if ((vals != NULL) && (vals->size() == nParams*2))
304  {
305  double nSigmaXY = 10.;
306  double nSigmaZ = 10.;
307  double parDistanceXY = 1e-3; // Unit: [cm]
308  double parDistanceZ = 1e-2; // Unit: [cm]
309  double parDistanceddZ = 1e-3; // Unit: [rad]
310  double parDistanceCxy = 1e-5; // Unit: [cm^2]
311  double bestEdm;
312 
313  const unsigned int trials = 4;
314  double largerDist[trials] = {0.1, 5., 10., 100.};
315 
316  double covxz,covyz,det;
317  double deltaMean;
318  int bestMovementX = 1;
319  int bestMovementY = 1;
320  int bestMovementZ = 1;
321  int goodData;
322 
323  double edm;
324 
325  vector<double>::const_iterator it = vals->begin();
326 
327  ROOT::Math::Minimizer* Gauss3D = ROOT::Math::Factory::CreateMinimizer("Minuit2","Migrad");
328  Gauss3D->SetErrorDef(1.0);
329  if (internalDebug == true) Gauss3D->SetPrintLevel(3);
330  else Gauss3D->SetPrintLevel(0);
331 
332  ROOT::Math::Functor _Gauss3DFunc(this, &Vx3DHLTAnalyzer::Gauss3DFunc, nParams);
333  Gauss3D->SetFunction(_Gauss3DFunc);
334 
335  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\t@@@ START FITTING @@@" << endl;
336 
337  // @@@ Fit at X-deltaMean | X | X+deltaMean @@@
338  bestEdm = 1.;
339  for (int i = 0; i < 3; i++)
340  {
341  deltaMean = (double(i)-1.)*std::sqrt(*(it+0));
342  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tdeltaMean --> " << deltaMean << endl;
343 
344  Gauss3D->Clear();
345 
346  Gauss3D->SetVariable(0,"var x ", *(it+0), parDistanceXY * parDistanceXY);
347  Gauss3D->SetVariable(1,"var y ", *(it+1), parDistanceXY * parDistanceXY);
348  Gauss3D->SetVariable(2,"var z ", *(it+2), parDistanceZ * parDistanceZ);
349  Gauss3D->SetVariable(3,"cov xy", *(it+3), parDistanceCxy);
350  Gauss3D->SetVariable(4,"dydz ", *(it+4), parDistanceddZ);
351  Gauss3D->SetVariable(5,"dxdz ", *(it+5), parDistanceddZ);
352  Gauss3D->SetVariable(6,"mean x", *(it+6)+deltaMean, parDistanceXY);
353  Gauss3D->SetVariable(7,"mean y", *(it+7), parDistanceXY);
354  Gauss3D->SetVariable(8,"mean z", *(it+8), parDistanceZ);
355 
356  // Set the central positions of the centroid for vertex rejection
357  xPos = Gauss3D->X()[6];
358  yPos = Gauss3D->X()[7];
359  zPos = Gauss3D->X()[8];
360 
361  // Set dimensions of the centroid for vertex rejection
362  maxTransRadius = nSigmaXY * std::sqrt(std::fabs(Gauss3D->X()[0]) + std::fabs(Gauss3D->X()[1])) / 2.;
363  maxLongLength = nSigmaZ * std::sqrt(std::fabs(Gauss3D->X()[2]));
364 
365  Gauss3D->Minimize();
366  goodData = Gauss3D->Status();
367  edm = Gauss3D->Edm();
368 
369  if (counterVx < minNentries) goodData = -2;
370  else if (isNotFinite(edm) == true) { goodData = -1; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite edm !" << endl; }
371  else for (unsigned int j = 0; j < nParams; j++)
372  if (isNotFinite(Gauss3D->Errors()[j]) == true)
373  {
374  goodData = -3;
375  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite errors !" << endl;
376  break;
377  }
378  if (goodData == 0)
379  {
380  covyz = Gauss3D->X()[4]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[1])) - Gauss3D->X()[5]*Gauss3D->X()[3];
381  covxz = Gauss3D->X()[5]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[0])) - Gauss3D->X()[4]*Gauss3D->X()[3];
382 
383  det = std::fabs(Gauss3D->X()[0]) * (std::fabs(Gauss3D->X()[1])*std::fabs(Gauss3D->X()[2]) - covyz*covyz) -
384  Gauss3D->X()[3] * (Gauss3D->X()[3]*std::fabs(Gauss3D->X()[2]) - covxz*covyz) +
385  covxz * (Gauss3D->X()[3]*covyz - covxz*std::fabs(Gauss3D->X()[1]));
386  if (det < 0.) { goodData = -4; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNegative determinant !" << endl; }
387  }
388 
389  if ((goodData == 0) && (std::fabs(edm) < bestEdm)) { bestEdm = edm; bestMovementX = i; }
390  }
391  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tFound bestMovementX --> " << bestMovementX << endl;
392 
393  // @@@ Fit at Y-deltaMean | Y | Y+deltaMean @@@
394  bestEdm = 1.;
395  for (int i = 0; i < 3; i++)
396  {
397  deltaMean = (double(i)-1.)*std::sqrt(*(it+1));
398  if (internalDebug == true)
399  {
400  cout << "[Vx3DHLTAnalyzer]::\tdeltaMean --> " << deltaMean << endl;
401  cout << "[Vx3DHLTAnalyzer]::\tdeltaMean X --> " << (double(bestMovementX)-1.)*std::sqrt(*(it+0)) << endl;
402  }
403 
404  Gauss3D->Clear();
405 
406  Gauss3D->SetVariable(0,"var x ", *(it+0), parDistanceXY * parDistanceXY);
407  Gauss3D->SetVariable(1,"var y ", *(it+1), parDistanceXY * parDistanceXY);
408  Gauss3D->SetVariable(2,"var z ", *(it+2), parDistanceZ * parDistanceZ);
409  Gauss3D->SetVariable(3,"cov xy", *(it+3), parDistanceCxy);
410  Gauss3D->SetVariable(4,"dydz ", *(it+4), parDistanceddZ);
411  Gauss3D->SetVariable(5,"dxdz ", *(it+5), parDistanceddZ);
412  Gauss3D->SetVariable(6,"mean x", *(it+6)+(double(bestMovementX)-1.)*std::sqrt(*(it+0)), parDistanceXY);
413  Gauss3D->SetVariable(7,"mean y", *(it+7)+deltaMean, parDistanceXY);
414  Gauss3D->SetVariable(8,"mean z", *(it+8), parDistanceZ);
415 
416  // Set the central positions of the centroid for vertex rejection
417  xPos = Gauss3D->X()[6];
418  yPos = Gauss3D->X()[7];
419  zPos = Gauss3D->X()[8];
420 
421  // Set dimensions of the centroid for vertex rejection
422  maxTransRadius = nSigmaXY * std::sqrt(std::fabs(Gauss3D->X()[0]) + std::fabs(Gauss3D->X()[1])) / 2.;
423  maxLongLength = nSigmaZ * std::sqrt(std::fabs(Gauss3D->X()[2]));
424 
425  Gauss3D->Minimize();
426  goodData = Gauss3D->Status();
427  edm = Gauss3D->Edm();
428 
429  if (counterVx < minNentries) goodData = -2;
430  else if (isNotFinite(edm) == true) { goodData = -1; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite edm !" << endl; }
431  else for (unsigned int j = 0; j < nParams; j++)
432  if (isNotFinite(Gauss3D->Errors()[j]) == true)
433  {
434  goodData = -3;
435  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite errors !" << endl;
436  break;
437  }
438  if (goodData == 0)
439  {
440  covyz = Gauss3D->X()[4]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[1])) - Gauss3D->X()[5]*Gauss3D->X()[3];
441  covxz = Gauss3D->X()[5]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[0])) - Gauss3D->X()[4]*Gauss3D->X()[3];
442 
443  det = std::fabs(Gauss3D->X()[0]) * (std::fabs(Gauss3D->X()[1])*std::fabs(Gauss3D->X()[2]) - covyz*covyz) -
444  Gauss3D->X()[3] * (Gauss3D->X()[3]*std::fabs(Gauss3D->X()[2]) - covxz*covyz) +
445  covxz * (Gauss3D->X()[3]*covyz - covxz*std::fabs(Gauss3D->X()[1]));
446  if (det < 0.) { goodData = -4; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNegative determinant !" << endl; }
447  }
448 
449  if ((goodData == 0) && (std::fabs(edm) < bestEdm)) { bestEdm = edm; bestMovementY = i; }
450  }
451  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tFound bestMovementY --> " << bestMovementY << endl;
452 
453  // @@@ Fit at Z-deltaMean | Z | Z+deltaMean @@@
454  bestEdm = 1.;
455  for (int i = 0; i < 3; i++)
456  {
457  deltaMean = (double(i)-1.)*std::sqrt(*(it+2));
458  if (internalDebug == true)
459  {
460  cout << "[Vx3DHLTAnalyzer]::\tdeltaMean --> " << deltaMean << endl;
461  cout << "[Vx3DHLTAnalyzer]::\tdeltaMean X --> " << (double(bestMovementX)-1.)*std::sqrt(*(it+0)) << endl;
462  cout << "[Vx3DHLTAnalyzer]::\tdeltaMean Y --> " << (double(bestMovementY)-1.)*std::sqrt(*(it+1)) << endl;
463  }
464 
465  Gauss3D->Clear();
466 
467  Gauss3D->SetVariable(0,"var x ", *(it+0), parDistanceXY * parDistanceXY);
468  Gauss3D->SetVariable(1,"var y ", *(it+1), parDistanceXY * parDistanceXY);
469  Gauss3D->SetVariable(2,"var z ", *(it+2), parDistanceZ * parDistanceZ);
470  Gauss3D->SetVariable(3,"cov xy", *(it+3), parDistanceCxy);
471  Gauss3D->SetVariable(4,"dydz ", *(it+4), parDistanceddZ);
472  Gauss3D->SetVariable(5,"dxdz ", *(it+5), parDistanceddZ);
473  Gauss3D->SetVariable(6,"mean x", *(it+6)+(double(bestMovementX)-1.)*std::sqrt(*(it+0)), parDistanceXY);
474  Gauss3D->SetVariable(7,"mean y", *(it+7)+(double(bestMovementY)-1.)*std::sqrt(*(it+1)), parDistanceXY);
475  Gauss3D->SetVariable(8,"mean z", *(it+8)+deltaMean, parDistanceZ);
476 
477  // Set the central positions of the centroid for vertex rejection
478  xPos = Gauss3D->X()[6];
479  yPos = Gauss3D->X()[7];
480  zPos = Gauss3D->X()[8];
481 
482  // Set dimensions of the centroid for vertex rejection
483  maxTransRadius = nSigmaXY * std::sqrt(std::fabs(Gauss3D->X()[0]) + std::fabs(Gauss3D->X()[1])) / 2.;
484  maxLongLength = nSigmaZ * std::sqrt(std::fabs(Gauss3D->X()[2]));
485 
486  Gauss3D->Minimize();
487  goodData = Gauss3D->Status();
488  edm = Gauss3D->Edm();
489 
490  if (counterVx < minNentries) goodData = -2;
491  else if (isNotFinite(edm) == true) { goodData = -1; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite edm !" << endl; }
492  else for (unsigned int j = 0; j < nParams; j++)
493  if (isNotFinite(Gauss3D->Errors()[j]) == true)
494  {
495  goodData = -3;
496  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite errors !" << endl;
497  break;
498  }
499  if (goodData == 0)
500  {
501  covyz = Gauss3D->X()[4]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[1])) - Gauss3D->X()[5]*Gauss3D->X()[3];
502  covxz = Gauss3D->X()[5]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[0])) - Gauss3D->X()[4]*Gauss3D->X()[3];
503 
504  det = std::fabs(Gauss3D->X()[0]) * (std::fabs(Gauss3D->X()[1])*std::fabs(Gauss3D->X()[2]) - covyz*covyz) -
505  Gauss3D->X()[3] * (Gauss3D->X()[3]*std::fabs(Gauss3D->X()[2]) - covxz*covyz) +
506  covxz * (Gauss3D->X()[3]*covyz - covxz*std::fabs(Gauss3D->X()[1]));
507  if (det < 0.) { goodData = -4; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNegative determinant !" << endl; }
508  }
509 
510  if ((goodData == 0) && (std::fabs(edm) < bestEdm)) { bestEdm = edm; bestMovementZ = i; }
511  }
512  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tFound bestMovementZ --> " << bestMovementZ << endl;
513 
514  Gauss3D->Clear();
515 
516  // @@@ FINAL FIT @@@
517  Gauss3D->SetVariable(0,"var x ", *(it+0), parDistanceXY * parDistanceXY);
518  Gauss3D->SetVariable(1,"var y ", *(it+1), parDistanceXY * parDistanceXY);
519  Gauss3D->SetVariable(2,"var z ", *(it+2), parDistanceZ * parDistanceZ);
520  Gauss3D->SetVariable(3,"cov xy", *(it+3), parDistanceCxy);
521  Gauss3D->SetVariable(4,"dydz ", *(it+4), parDistanceddZ);
522  Gauss3D->SetVariable(5,"dxdz ", *(it+5), parDistanceddZ);
523  Gauss3D->SetVariable(6,"mean x", *(it+6)+(double(bestMovementX)-1.)*std::sqrt(*(it+0)), parDistanceXY);
524  Gauss3D->SetVariable(7,"mean y", *(it+7)+(double(bestMovementY)-1.)*std::sqrt(*(it+1)), parDistanceXY);
525  Gauss3D->SetVariable(8,"mean z", *(it+8)+(double(bestMovementZ)-1.)*std::sqrt(*(it+2)), parDistanceZ);
526 
527  // Set the central positions of the centroid for vertex rejection
528  xPos = Gauss3D->X()[6];
529  yPos = Gauss3D->X()[7];
530  zPos = Gauss3D->X()[8];
531 
532  // Set dimensions of the centroid for vertex rejection
533  maxTransRadius = nSigmaXY * std::sqrt(std::fabs(Gauss3D->X()[0]) + std::fabs(Gauss3D->X()[1])) / 2.;
534  maxLongLength = nSigmaZ * std::sqrt(std::fabs(Gauss3D->X()[2]));
535 
536  Gauss3D->Minimize();
537  goodData = Gauss3D->Status();
538  edm = Gauss3D->Edm();
539 
540  if (counterVx < minNentries) goodData = -2;
541  else if (isNotFinite(edm) == true) { goodData = -1; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite edm !" << endl; }
542  else for (unsigned int j = 0; j < nParams; j++)
543  if (isNotFinite(Gauss3D->Errors()[j]) == true)
544  {
545  goodData = -3;
546  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite errors !" << endl;
547  break;
548  }
549  if (goodData == 0)
550  {
551  covyz = Gauss3D->X()[4]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[1])) - Gauss3D->X()[5]*Gauss3D->X()[3];
552  covxz = Gauss3D->X()[5]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[0])) - Gauss3D->X()[4]*Gauss3D->X()[3];
553 
554  det = std::fabs(Gauss3D->X()[0]) * (std::fabs(Gauss3D->X()[1])*std::fabs(Gauss3D->X()[2]) - covyz*covyz) -
555  Gauss3D->X()[3] * (Gauss3D->X()[3]*std::fabs(Gauss3D->X()[2]) - covxz*covyz) +
556  covxz * (Gauss3D->X()[3]*covyz - covxz*std::fabs(Gauss3D->X()[1]));
557  if (det < 0.) { goodData = -4; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNegative determinant !" << endl; }
558  }
559 
560  // @@@ FIT WITH DIFFERENT PARAMETER DISTANCES @@@
561  for (unsigned int i = 0; i < trials; i++)
562  {
563  if ((goodData != 0) && (goodData != -2))
564  {
565  Gauss3D->Clear();
566 
567  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tFIT WITH DIFFERENT PARAMETER DISTANCES - STEP " << i+1 << endl;
568 
569  Gauss3D->SetVariable(0,"var x ", *(it+0), parDistanceXY * parDistanceXY * largerDist[i]);
570  Gauss3D->SetVariable(1,"var y ", *(it+1), parDistanceXY * parDistanceXY * largerDist[i]);
571  Gauss3D->SetVariable(2,"var z ", *(it+2), parDistanceZ * parDistanceZ * largerDist[i]);
572  Gauss3D->SetVariable(3,"cov xy", *(it+3), parDistanceCxy * largerDist[i]);
573  Gauss3D->SetVariable(4,"dydz ", *(it+4), parDistanceddZ * largerDist[i]);
574  Gauss3D->SetVariable(5,"dxdz ", *(it+5), parDistanceddZ * largerDist[i]);
575  Gauss3D->SetVariable(6,"mean x", *(it+6)+(double(bestMovementX)-1.)*std::sqrt(*(it+0)), parDistanceXY * largerDist[i]);
576  Gauss3D->SetVariable(7,"mean y", *(it+7)+(double(bestMovementY)-1.)*std::sqrt(*(it+1)), parDistanceXY * largerDist[i]);
577  Gauss3D->SetVariable(8,"mean z", *(it+8)+(double(bestMovementZ)-1.)*std::sqrt(*(it+2)), parDistanceZ * largerDist[i]);
578 
579  // Set the central positions of the centroid for vertex rejection
580  xPos = Gauss3D->X()[6];
581  yPos = Gauss3D->X()[7];
582  zPos = Gauss3D->X()[8];
583 
584  // Set dimensions of the centroid for vertex rejection
585  maxTransRadius = nSigmaXY * std::sqrt(std::fabs(Gauss3D->X()[0]) + std::fabs(Gauss3D->X()[1])) / 2.;
586  maxLongLength = nSigmaZ * std::sqrt(std::fabs(Gauss3D->X()[2]));
587 
588  Gauss3D->Minimize();
589  goodData = Gauss3D->Status();
590  edm = Gauss3D->Edm();
591 
592  if (counterVx < minNentries) goodData = -2;
593  else if (isNotFinite(edm) == true) { goodData = -1; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite edm !" << endl; }
594  else for (unsigned int j = 0; j < nParams; j++)
595  if (isNotFinite(Gauss3D->Errors()[j]) == true)
596  {
597  goodData = -3;
598  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNot finite errors !" << endl;
599  break;
600  }
601  if (goodData == 0)
602  {
603  covyz = Gauss3D->X()[4]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[1])) - Gauss3D->X()[5]*Gauss3D->X()[3];
604  covxz = Gauss3D->X()[5]*(std::fabs(Gauss3D->X()[2])-std::fabs(Gauss3D->X()[0])) - Gauss3D->X()[4]*Gauss3D->X()[3];
605 
606  det = std::fabs(Gauss3D->X()[0]) * (std::fabs(Gauss3D->X()[1])*std::fabs(Gauss3D->X()[2]) - covyz*covyz) -
607  Gauss3D->X()[3] * (Gauss3D->X()[3]*std::fabs(Gauss3D->X()[2]) - covxz*covyz) +
608  covxz * (Gauss3D->X()[3]*covyz - covxz*std::fabs(Gauss3D->X()[1]));
609  if (det < 0.) { goodData = -4; if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tNegative determinant !" << endl; }
610  }
611  } else break;
612  }
613 
614  if (goodData == 0)
615  for (unsigned int i = 0; i < nParams; i++)
616  {
617  vals->operator[](i) = Gauss3D->X()[i];
618  vals->operator[](i+nParams) = Gauss3D->Errors()[i];
619  }
620 
621  delete Gauss3D;
622  return goodData;
623  }
624 
625  return -1;
626 }
unsigned int minNentries
#define NULL
Definition: scimark2.h:8
double Gauss3DFunc(const double *par)
unsigned int nParams
bool isNotFinite(T x)
Definition: isFinite.h:10
unsigned int counterVx
T sqrt(T t)
Definition: SSEVec.h:18
HLT enums.
void Vx3DHLTAnalyzer::printFitParams ( const std::vector< double > &  fitResults)
private

Definition at line 862 of file Vx3DHLTAnalyzer.cc.

References gather_cfg::cout.

863 {
864  cout << "var x --> " << fitResults[0] << " +/- " << fitResults[0+nParams] << endl;
865  cout << "var y --> " << fitResults[1] << " +/- " << fitResults[1+nParams] << endl;
866  cout << "var z --> " << fitResults[2] << " +/- " << fitResults[2+nParams] << endl;
867  cout << "cov xy --> " << fitResults[3] << " +/- " << fitResults[3+nParams] << endl;
868  cout << "dydz --> " << fitResults[4] << " +/- " << fitResults[4+nParams] << endl;
869  cout << "dxdz --> " << fitResults[5] << " +/- " << fitResults[5+nParams] << endl;
870  cout << "mean x --> " << fitResults[6] << " +/- " << fitResults[6+nParams] << endl;
871  cout << "mean y --> " << fitResults[7] << " +/- " << fitResults[7+nParams] << endl;
872  cout << "mean z --> " << fitResults[8] << " +/- " << fitResults[8+nParams] << endl;
873 }
unsigned int nParams
MonitorElement * fitResults
void Vx3DHLTAnalyzer::reset ( std::string  ResetType)
private

Definition at line 629 of file Vx3DHLTAnalyzer.cc.

References gather_cfg::cout, edm::service::formatTime(), convertSQLiteXML::runNumber, and fftjetpfpileupcleaner_cfi::Vertices.

630 {
631  if ((debugMode == true) && (outputDebugFile.is_open() == true))
632  {
633  outputDebugFile << "Runnumber " << runNumber << endl;
634  outputDebugFile << "BeginTimeOfFit " << formatTime(beginTimeOfFit >> 32) << " " << (beginTimeOfFit >> 32) << endl;
635  outputDebugFile << "BeginLumiRange " << beginLumiOfFit << endl;
636  outputDebugFile << "EndTimeOfFit " << formatTime(endTimeOfFit >> 32) << " " << (endTimeOfFit >> 32) << endl;
637  outputDebugFile << "EndLumiRange " << endLumiOfFit << endl;
638  outputDebugFile << "LumiCounter " << lumiCounter << endl;
639  outputDebugFile << "LastLumiOfFit " << lastLumiOfFit << endl;
640  }
641 
642 
643  if (ResetType.compare("scratch") == 0)
644  {
645  runNumber = 0;
646  numberGoodFits = 0;
647  numberFits = 0;
648  lastLumiOfFit = 0;
649 
650  Vx_X->Reset();
651  Vx_Y->Reset();
652  Vx_Z->Reset();
653 
654  Vx_ZX->Reset();
655  Vx_ZY->Reset();
656  Vx_XY->Reset();
657 
658  Vx_X_Cum->Reset();
659  Vx_Y_Cum->Reset();
660  Vx_Z_Cum->Reset();
661 
662  Vx_ZX_Cum->Reset();
663  Vx_ZY_Cum->Reset();
664  Vx_XY_Cum->Reset();
665 
666  mXlumi->Reset();
667  mYlumi->Reset();
668  mZlumi->Reset();
669 
670  sXlumi->Reset();
671  sYlumi->Reset();
672  sZlumi->Reset();
673 
674  dxdzlumi->Reset();
675  dydzlumi->Reset();
676 
677  hitCounter->Reset();
678  goodVxCounter->Reset();
679  statusCounter->Reset();
680  fitResults->Reset();
681 
682  reportSummary->Fill(-1);
683  reportSummaryMap->getTH1()->SetBinContent(1, 1, -1);
684 
685  Vertices.clear();
686 
687  lumiCounter = 0;
688  totalHits = 0;
689  beginTimeOfFit = 0;
690  endTimeOfFit = 0;
691  beginLumiOfFit = 0;
692  endLumiOfFit = 0;
693 
694  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tReset issued: scratch" << endl;
695  if ((debugMode == true) && (outputDebugFile.is_open() == true)) outputDebugFile << "Reset -scratch- issued\n" << endl;
696  }
697  else if (ResetType.compare("whole") == 0)
698  {
699  Vx_X->Reset();
700  Vx_Y->Reset();
701  Vx_Z->Reset();
702 
703  Vx_ZX->Reset();
704  Vx_ZY->Reset();
705  Vx_XY->Reset();
706 
707  Vertices.clear();
708 
709  lumiCounter = 0;
710  totalHits = 0;
711  beginTimeOfFit = 0;
712  endTimeOfFit = 0;
713  beginLumiOfFit = 0;
714  endLumiOfFit = 0;
715 
716  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tReset issued: whole" << endl;
717  if ((debugMode == true) && (outputDebugFile.is_open() == true)) outputDebugFile << "Reset -whole- issued\n" << endl;
718  }
719  else if (ResetType.compare("hitCounter") == 0)
720  {
721  totalHits = 0;
722 
723  if (internalDebug == true) cout << "[Vx3DHLTAnalyzer]::\tReset issued: hitCounter" << endl;
724  if ((debugMode == true) && (outputDebugFile.is_open() == true)) outputDebugFile << "Reset -hitCounter- issued\n" << endl;
725  }
726 }
unsigned int lumiCounter
MonitorElement * statusCounter
MonitorElement * dxdzlumi
MonitorElement * Vx_ZX
unsigned int totalHits
unsigned int numberFits
MonitorElement * Vx_Y_Cum
unsigned int beginLumiOfFit
MonitorElement * Vx_X
MonitorElement * mYlumi
edm::TimeValue_t beginTimeOfFit
edm::TimeValue_t endTimeOfFit
MonitorElement * sYlumi
MonitorElement * reportSummaryMap
void Fill(long long x)
MonitorElement * Vx_XY
MonitorElement * sZlumi
MonitorElement * fitResults
MonitorElement * Vx_ZY
std::string formatTime(const time_t &t)
unsigned int endLumiOfFit
unsigned int numberGoodFits
MonitorElement * reportSummary
MonitorElement * Vx_ZY_Cum
MonitorElement * goodVxCounter
std::ofstream outputDebugFile
MonitorElement * dydzlumi
TH1 * getTH1(void) const
MonitorElement * Vx_ZX_Cum
MonitorElement * Vx_Z
MonitorElement * mXlumi
MonitorElement * Vx_X_Cum
std::vector< VertexType > Vertices
MonitorElement * mZlumi
MonitorElement * sXlumi
unsigned int lastLumiOfFit
MonitorElement * Vx_XY_Cum
unsigned int runNumber
MonitorElement * Vx_Z_Cum
MonitorElement * hitCounter
void Reset(void)
reset ME (ie. contents, errors, etc)
MonitorElement * Vx_Y
void Vx3DHLTAnalyzer::writeToFile ( std::vector< double > *  vals,
edm::TimeValue_t  BeginTimeOfFit,
edm::TimeValue_t  EndTimeOfFit,
unsigned int  BeginLumiOfFit,
unsigned int  EndLumiOfFit,
int  dataType 
)
private

Definition at line 729 of file Vx3DHLTAnalyzer.cc.

References MillePedeFileConverter_cfg::fileName, edm::service::formatTime(), NULL, MillePedeFileConverter_cfg::out, download_sqlite_cfg::outputFile, convertSQLiteXML::runNumber, and mathSSE::sqrt().

735 {
736  stringstream BufferString;
737  BufferString.precision(5);
738 
739  outputFile.open(fileName.c_str(), ios::out);
740 
741  if ((outputFile.is_open() == true) && (vals != NULL) && (vals->size() == (nParams-1)*2))
742  {
743  vector<double>::const_iterator it = vals->begin();
744 
745  outputFile << "Runnumber " << runNumber << endl;
746  outputFile << "BeginTimeOfFit " << formatTime(beginTimeOfFit >> 32) << " " << (beginTimeOfFit >> 32) << endl;
747  outputFile << "EndTimeOfFit " << formatTime(endTimeOfFit >> 32) << " " << (endTimeOfFit >> 32) << endl;
748  outputFile << "LumiRange " << beginLumiOfFit << " - " << endLumiOfFit << endl;
749  outputFile << "Type " << dataType << endl;
750  // 3D Vertexing with Pixel Tracks:
751  // Good data = Type 3
752  // Bad data = Type -1
753 
754  BufferString << *(it+0);
755  outputFile << "X0 " << BufferString.str().c_str() << endl;
756  BufferString.str("");
757 
758  BufferString << *(it+1);
759  outputFile << "Y0 " << BufferString.str().c_str() << endl;
760  BufferString.str("");
761 
762  BufferString << *(it+2);
763  outputFile << "Z0 " << BufferString.str().c_str() << endl;
764  BufferString.str("");
765 
766  BufferString << *(it+3);
767  outputFile << "sigmaZ0 " << BufferString.str().c_str() << endl;
768  BufferString.str("");
769 
770  BufferString << *(it+4);
771  outputFile << "dxdz " << BufferString.str().c_str() << endl;
772  BufferString.str("");
773 
774  BufferString << *(it+5);
775  outputFile << "dydz " << BufferString.str().c_str() << endl;
776  BufferString.str("");
777 
778  BufferString << *(it+6);
779  outputFile << "BeamWidthX " << BufferString.str().c_str() << endl;
780  BufferString.str("");
781 
782  BufferString << *(it+7);
783  outputFile << "BeamWidthY " << BufferString.str().c_str() << endl;
784  BufferString.str("");
785 
786  outputFile << "Cov(0,j) " << *(it+8) << " 0.0 0.0 0.0 0.0 0.0 0.0" << endl;
787  outputFile << "Cov(1,j) 0.0 " << *(it+9) << " 0.0 0.0 0.0 0.0 0.0" << endl;
788  outputFile << "Cov(2,j) 0.0 0.0 " << *(it+10) << " 0.0 0.0 0.0 0.0" << endl;
789  outputFile << "Cov(3,j) 0.0 0.0 0.0 " << *(it+11) << " 0.0 0.0 0.0" << endl;
790  outputFile << "Cov(4,j) 0.0 0.0 0.0 0.0 " << *(it+12) << " 0.0 0.0" << endl;
791  outputFile << "Cov(5,j) 0.0 0.0 0.0 0.0 0.0 " << *(it+13) << " 0.0" << endl;
792  outputFile << "Cov(6,j) 0.0 0.0 0.0 0.0 0.0 0.0 " << ((*(it+14)) + (*(it+15)) + 2.*std::sqrt((*(it+14))*(*(it+15)))) / 4. << endl;
793 
794  outputFile << "EmittanceX 0.0" << endl;
795  outputFile << "EmittanceY 0.0" << endl;
796  outputFile << "BetaStar 0.0" << endl;
797  }
798  outputFile.close();
799 
800  if ((debugMode == true) && (outputDebugFile.is_open() == true) && (vals != NULL) && (vals->size() == (nParams-1)*2))
801  {
802  vector<double>::const_iterator it = vals->begin();
803 
804  outputDebugFile << "Runnumber " << runNumber << endl;
805  outputDebugFile << "BeginTimeOfFit " << formatTime(beginTimeOfFit >> 32) << " " << (beginTimeOfFit >> 32) << endl;
806  outputDebugFile << "EndTimeOfFit " << formatTime(endTimeOfFit >> 32) << " " << (endTimeOfFit >> 32) << endl;
807  outputDebugFile << "LumiRange " << beginLumiOfFit << " - " << endLumiOfFit << endl;
808  outputDebugFile << "Type " << dataType << endl;
809  // 3D Vertexing with Pixel Tracks:
810  // Good data = Type 3
811  // Bad data = Type -1
812 
813  BufferString << *(it+0);
814  outputDebugFile << "X0 " << BufferString.str().c_str() << endl;
815  BufferString.str("");
816 
817  BufferString << *(it+1);
818  outputDebugFile << "Y0 " << BufferString.str().c_str() << endl;
819  BufferString.str("");
820 
821  BufferString << *(it+2);
822  outputDebugFile << "Z0 " << BufferString.str().c_str() << endl;
823  BufferString.str("");
824 
825  BufferString << *(it+3);
826  outputDebugFile << "sigmaZ0 " << BufferString.str().c_str() << endl;
827  BufferString.str("");
828 
829  BufferString << *(it+4);
830  outputDebugFile << "dxdz " << BufferString.str().c_str() << endl;
831  BufferString.str("");
832 
833  BufferString << *(it+5);
834  outputDebugFile << "dydz " << BufferString.str().c_str() << endl;
835  BufferString.str("");
836 
837  BufferString << *(it+6);
838  outputDebugFile << "BeamWidthX " << BufferString.str().c_str() << endl;
839  BufferString.str("");
840 
841  BufferString << *(it+7);
842  outputDebugFile << "BeamWidthY " << BufferString.str().c_str() << endl;
843  BufferString.str("");
844 
845  outputDebugFile << "Cov(0,j) " << *(it+8) << " 0.0 0.0 0.0 0.0 0.0 0.0" << endl;
846  outputDebugFile << "Cov(1,j) 0.0 " << *(it+9) << " 0.0 0.0 0.0 0.0 0.0" << endl;
847  outputDebugFile << "Cov(2,j) 0.0 0.0 " << *(it+10) << " 0.0 0.0 0.0 0.0" << endl;
848  outputDebugFile << "Cov(3,j) 0.0 0.0 0.0 " << *(it+11) << " 0.0 0.0 0.0" << endl;
849  outputDebugFile << "Cov(4,j) 0.0 0.0 0.0 0.0 " << *(it+12) << " 0.0 0.0" << endl;
850  outputDebugFile << "Cov(5,j) 0.0 0.0 0.0 0.0 0.0 " << *(it+13) << " 0.0" << endl;
851  outputDebugFile << "Cov(6,j) 0.0 0.0 0.0 0.0 0.0 0.0 " << ((*(it+14)) + (*(it+15)) + 2.*std::sqrt((*(it+14))*(*(it+15)))) / 4. << endl;
852 
853  outputDebugFile << "EmittanceX 0.0" << endl;
854  outputDebugFile << "EmittanceY 0.0" << endl;
855  outputDebugFile << "BetaStar 0.0" << endl;
856 
857  outputDebugFile << "\n" << "Used vertices: " << counterVx << "\n" << endl;
858  }
859 }
unsigned int beginLumiOfFit
#define NULL
Definition: scimark2.h:8
edm::TimeValue_t beginTimeOfFit
edm::TimeValue_t endTimeOfFit
unsigned int nParams
unsigned int counterVx
std::string fileName
std::string formatTime(const time_t &t)
unsigned int endLumiOfFit
T sqrt(T t)
Definition: SSEVec.h:18
std::ofstream outputDebugFile
std::ofstream outputFile
unsigned int runNumber

Member Data Documentation

unsigned int Vx3DHLTAnalyzer::beginLumiOfFit
private

Definition at line 153 of file Vx3DHLTAnalyzer.h.

edm::TimeValue_t Vx3DHLTAnalyzer::beginTimeOfFit
private

Definition at line 146 of file Vx3DHLTAnalyzer.h.

bool Vx3DHLTAnalyzer::considerVxCovariance
private

Definition at line 160 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::counterVx
private

Definition at line 161 of file Vx3DHLTAnalyzer.h.

bool Vx3DHLTAnalyzer::dataFromFit
private

Definition at line 84 of file Vx3DHLTAnalyzer.h.

bool Vx3DHLTAnalyzer::debugMode
private

Definition at line 83 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::dxdzlumi
private

Definition at line 112 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::dydzlumi
private

Definition at line 113 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::endLumiOfFit
private

Definition at line 154 of file Vx3DHLTAnalyzer.h.

edm::TimeValue_t Vx3DHLTAnalyzer::endTimeOfFit
private

Definition at line 147 of file Vx3DHLTAnalyzer.h.

std::string Vx3DHLTAnalyzer::fileName
private

Definition at line 98 of file Vx3DHLTAnalyzer.h.

Referenced by readConfig.fileINI::read().

MonitorElement* Vx3DHLTAnalyzer::fitResults
private

Definition at line 138 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::goodVxCounter
private

Definition at line 131 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::hitCounter
private

Definition at line 132 of file Vx3DHLTAnalyzer.h.

bool Vx3DHLTAnalyzer::internalDebug
private

Definition at line 157 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::lastLumiOfFit
private

Definition at line 155 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::lumiCounter
private

Definition at line 149 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::maxLongLength
private

Definition at line 163 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::maxLumiIntegration
private

Definition at line 86 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::maxTransRadius
private

Definition at line 162 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::minNentries
private

Definition at line 88 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::minVxDoF
private

Definition at line 96 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::minVxWgt
private

Definition at line 97 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::mXlumi
private

Definition at line 104 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::mYlumi
private

Definition at line 105 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::mZlumi
private

Definition at line 106 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::nLumiFit
private

Definition at line 85 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::nLumiXaxisRange
private

Definition at line 87 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::nParams
private

Definition at line 156 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::numberFits
private

Definition at line 152 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::numberGoodFits
private

Definition at line 151 of file Vx3DHLTAnalyzer.h.

std::ofstream Vx3DHLTAnalyzer::outputDebugFile
private

Definition at line 145 of file Vx3DHLTAnalyzer.h.

std::ofstream Vx3DHLTAnalyzer::outputFile
private

Definition at line 144 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::pi
private

Definition at line 165 of file Vx3DHLTAnalyzer.h.

edm::EDGetTokenT<SiPixelRecHitCollection> Vx3DHLTAnalyzer::pixelHitCollection
private

Definition at line 82 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::reportSummary
private

Definition at line 135 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::reportSummaryMap
private

Definition at line 136 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::runNumber
private

Definition at line 148 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::statusCounter
private

Definition at line 133 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::sXlumi
private

Definition at line 108 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::sYlumi
private

Definition at line 109 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::sZlumi
private

Definition at line 110 of file Vx3DHLTAnalyzer.h.

unsigned int Vx3DHLTAnalyzer::totalHits
private

Definition at line 150 of file Vx3DHLTAnalyzer.h.

edm::EDGetTokenT<reco::VertexCollection> Vx3DHLTAnalyzer::vertexCollection
private

Definition at line 81 of file Vx3DHLTAnalyzer.h.

std::vector<VertexType> Vx3DHLTAnalyzer::Vertices
private

Definition at line 159 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_X
private

Definition at line 115 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_X_Cum
private

Definition at line 123 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_XY
private

Definition at line 121 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_XY_Cum
private

Definition at line 129 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_Y
private

Definition at line 116 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_Y_Cum
private

Definition at line 124 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_Z
private

Definition at line 117 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_Z_Cum
private

Definition at line 125 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_ZX
private

Definition at line 119 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_ZX_Cum
private

Definition at line 127 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_ZY
private

Definition at line 120 of file Vx3DHLTAnalyzer.h.

MonitorElement* Vx3DHLTAnalyzer::Vx_ZY_Cum
private

Definition at line 128 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::VxErrCorr
private

Definition at line 95 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::xPos
private

Definition at line 164 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::xRange
private

Definition at line 89 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::xStep
private

Definition at line 90 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::yPos
private

Definition at line 164 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::yRange
private

Definition at line 91 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::yStep
private

Definition at line 92 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::zPos
private

Definition at line 164 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::zRange
private

Definition at line 93 of file Vx3DHLTAnalyzer.h.

double Vx3DHLTAnalyzer::zStep
private

Definition at line 94 of file Vx3DHLTAnalyzer.h.