#include <DTDataIntegrityTask.h>
Public Member Functions | |
DTDataIntegrityTask (const edm::ParameterSet &ps, edm::ActivityRegistry ®) | |
bool | eventHasErrors () const |
void | fedEntry (int dduID) |
void | fedFatal (int dduID) |
void | fedNonFatal (int dduID) |
void | postBeginJob () |
void | postEndJob () |
void | preBeginLumi (const edm::LuminosityBlockID &ls, const edm::Timestamp &iTime) |
void | preEndLumi (const edm::LuminosityBlockID &ls, const edm::Timestamp &iTime) |
void | preProcessEvent (const edm::EventID &iEvtid, const edm::Timestamp &iTime) |
void | processFED (DTDDUData &dduData, const std::vector< DTROS25Data > &rosData, int dduID) |
void | processROS25 (DTROS25Data &data, int dduID, int ros) |
void | TimeHistos (std::string histoType) |
virtual | ~DTDataIntegrityTask () |
Private Member Functions | |
void | bookHistos (const int fedMin, const int fedMax) |
void | bookHistos (std::string folder, DTROChainCoding code) |
void | bookHistosROS25 (DTROChainCoding code) |
void | channelsInCEROS (int cerosId, int chMask, std::vector< int > &channels) |
void | channelsInROS (int cerosMask, std::vector< int > &channels) |
std::string | topFolder (bool isFEDIntegrity) const |
Private Attributes | |
DTROChainCoding | coding |
DQMStore * | dbe |
std::map< std::string, std::map< int, MonitorElement * > > | dduHistos |
std::map< std::string, std::map< int, DTTimeEvolutionHisto * > > | dduTimeHistos |
bool | doTimeHisto |
bool | eventErrorFlag |
std::set< int > | fedBXIds |
std::string | fedIntegrityFolder |
bool | getSCInfo |
MonitorElement * | hCorruptionSummary |
MonitorElement * | hFEDEntry |
MonitorElement * | hFEDFatal |
MonitorElement * | hFEDNonFatal |
MonitorElement * | hTTSSummary |
std::multimap< std::string, std::string >::iterator | it |
int | mode |
int | myPrevEv |
int | myPrevFifoVal [7] |
int | myPrevRosVal |
int | myPrevTtsVal |
std::multimap< std::string, std::string > | names |
MonitorElement * | nEventMonitor |
int | nevents |
int | neventsDDU |
int | nEventsLS |
int | neventsROS25 |
std::string | outputFile |
edm::ParameterSet | parameters |
double | rob_max [25] |
std::map< std::string, std::map< int, MonitorElement * > > | robHistos |
std::map< int, std::set< int > > | rosBxIdsPerFED |
std::map< std::string, std::map< int, MonitorElement * > > | rosHistos |
std::map< int, std::set< int > > | rosL1AIdsPerFED |
std::map< std::string, std::map< int, MonitorElement * > > | rosSHistos |
std::map< std::string, std::map< int, DTTimeEvolutionHisto * > > | rosTimeHistos |
float | trigger_counter |
Class for DT Data Integrity.
Definition at line 39 of file DTDataIntegrityTask.h.
DTDataIntegrityTask::DTDataIntegrityTask | ( | const edm::ParameterSet & | ps, |
edm::ActivityRegistry & | reg | ||
) | [explicit] |
Definition at line 37 of file DTDataIntegrityTask.cc.
References Exception, fedIntegrityFolder, getSCInfo, edm::ParameterSet::getUntrackedParameter(), LogTrace, mode, neventsDDU, neventsROS25, postBeginJob(), preBeginLumi(), preEndLumi(), preProcessEvent(), dtDQMClient_cfg::processingMode, edm::ActivityRegistry::watchPostBeginJob(), edm::ActivityRegistry::watchPreBeginLumi(), edm::ActivityRegistry::watchPreEndLumi(), and edm::ActivityRegistry::watchPreProcessEvent().
: nevents(0) , dbe(0) { // Register the methods that we want to schedule // reg.watchPostEndJob(this,&DTDataIntegrityTask::postEndJob); reg.watchPreBeginLumi(this,&DTDataIntegrityTask::preBeginLumi); reg.watchPreEndLumi(this,&DTDataIntegrityTask::preEndLumi); reg.watchPostBeginJob(this,&DTDataIntegrityTask::postBeginJob); reg.watchPreProcessEvent(this,&DTDataIntegrityTask::preProcessEvent); LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << "[DTDataIntegrityTask]: Constructor" <<endl; neventsDDU = 0; neventsROS25 = 0; // //If you want info VS time histos // doTimeHisto = ps.getUntrackedParameter<bool>("doTimeHisto", false); // Plot quantities about SC getSCInfo = ps.getUntrackedParameter<bool>("getSCInfo", false); fedIntegrityFolder = ps.getUntrackedParameter<string>("fedIntegrityFolder","DT/FEDIntegrity"); string processingMode = ps.getUntrackedParameter<string>("processingMode","Online"); // processing mode flag to select plots to be produced and basedirs CB vedi se farlo meglio... if (processingMode == "Online") { mode = 0; } else if(processingMode == "SM") { mode = 1; } else if (processingMode == "Offline") { mode = 2; } else if (processingMode == "HLT") { mode = 3; } else { throw cms::Exception("MissingParameter") << "[DTDataIntegrityTask]: processingMode :" << processingMode << " invalid! Must be Online, SM, Offline or HLT !" << endl; } }
DTDataIntegrityTask::~DTDataIntegrityTask | ( | ) | [virtual] |
Definition at line 81 of file DTDataIntegrityTask.cc.
References LogTrace, and neventsDDU.
{ LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") <<"[DTDataIntegrityTask]: Destructor. Analyzed "<< neventsDDU <<" events"<<endl; }
void DTDataIntegrityTask::bookHistos | ( | const int | fedMin, |
const int | fedMax | ||
) | [private] |
Definition at line 106 of file DTDataIntegrityTask.cc.
References DQMStore::book1D(), DQMStore::book2D(), DQMStore::bookFloat(), dbe, hCorruptionSummary, hFEDEntry, hFEDFatal, hFEDNonFatal, hTTSSummary, nEventMonitor, MonitorElement::setAxisTitle(), MonitorElement::setBinLabel(), DQMStore::setCurrentFolder(), and topFolder().
Referenced by bookHistosROS25(), and postBeginJob().
{ dbe->setCurrentFolder("DT/EventInfo/Counters"); nEventMonitor = dbe->bookFloat("nProcessedEventsDataIntegrity"); // Standard FED integrity histos dbe->setCurrentFolder(topFolder(true)); int nFED = (fedMax - fedMin)+1; hFEDEntry = dbe->book1D("FEDEntries","# entries per DT FED",nFED,fedMin,fedMax+1); hFEDFatal = dbe->book1D("FEDFatal","# fatal errors DT FED",nFED,fedMin,fedMax+1); hFEDNonFatal = dbe->book1D("FEDNonFatal","# NON fatal errors DT FED",nFED,fedMin,fedMax+1); dbe->setCurrentFolder(topFolder(false)); hTTSSummary = dbe->book2D("TTSSummary","Summary Status TTS",nFED,fedMin,fedMax+1,9,1,10); hTTSSummary->setAxisTitle("FED",1); hTTSSummary->setBinLabel(1,"ROS PAF",2); hTTSSummary->setBinLabel(2,"DDU PAF",2); hTTSSummary->setBinLabel(3,"ROS PAF",2); hTTSSummary->setBinLabel(4,"DDU PAF",2); hTTSSummary->setBinLabel(5,"DDU Full",2); hTTSSummary->setBinLabel(6,"L1A Mism.",2); hTTSSummary->setBinLabel(7,"ROS Error",2); hTTSSummary->setBinLabel(8,"BX Mism.",2); hTTSSummary->setBinLabel(9,"DDU Logic Err.",2); // bookkeeping of the hCorruptionSummary = dbe->book2D("DataCorruptionSummary", "Data Corruption Sources", nFED,fedMin,fedMax+1, 8, 1, 9); hCorruptionSummary->setAxisTitle("FED",1); hCorruptionSummary->setBinLabel(1,"Miss Ch.",2); hCorruptionSummary->setBinLabel(2,"ROS BX mism",2); hCorruptionSummary->setBinLabel(3,"DDU BX mism",2); hCorruptionSummary->setBinLabel(4,"ROS L1A mism",2); hCorruptionSummary->setBinLabel(5,"Miss Payload",2); hCorruptionSummary->setBinLabel(6,"FCRC bit",2); hCorruptionSummary->setBinLabel(7,"Header check",2); hCorruptionSummary->setBinLabel(8,"Triler Check",2); }
void DTDataIntegrityTask::bookHistos | ( | std::string | folder, |
DTROChainCoding | code | ||
) | [private] |
void DTDataIntegrityTask::bookHistosROS25 | ( | DTROChainCoding | code | ) | [private] |
Definition at line 528 of file DTDataIntegrityTask.cc.
References bookHistos(), getSCInfo, and mode.
Referenced by postBeginJob().
{ bookHistos( string("ROS"), code); // for(int robId = 0; robId != 25; ++robId) { // code.setROB(robId); // bookHistos( string("TDCError"), code); // } if(mode <= 1) if(getSCInfo) bookHistos( string("SC"), code); }
void DTDataIntegrityTask::channelsInCEROS | ( | int | cerosId, |
int | chMask, | ||
std::vector< int > & | channels | ||
) | [private] |
Definition at line 1186 of file DTDataIntegrityTask.cc.
Referenced by processROS25().
{ for (int iCh=0; iCh<6;++iCh) { if ((chMask >> iCh) & 0x1){ channels.push_back(cerosId*6+iCh); } } return; }
void DTDataIntegrityTask::channelsInROS | ( | int | cerosMask, |
std::vector< int > & | channels | ||
) | [private] |
Definition at line 1195 of file DTDataIntegrityTask.cc.
Referenced by processROS25().
{ for (int iCeros=0; iCeros<5;++iCeros) { if ((cerosMask >> iCeros) & 0x1){ for (int iCh=0; iCh<6;++iCh) { channels.push_back(iCeros*6+iCh); } } } return; }
bool DTDataIntegrityTask::eventHasErrors | ( | ) | const |
Definition at line 1150 of file DTDataIntegrityTask.cc.
References eventErrorFlag.
Referenced by DTDataErrorFilter::hltFilter().
{ return eventErrorFlag; }
void DTDataIntegrityTask::fedEntry | ( | int | dduID | ) | [virtual] |
Implements DTDataMonitorInterface.
Definition at line 1157 of file DTDataIntegrityTask.cc.
References MonitorElement::Fill(), and hFEDEntry.
void DTDataIntegrityTask::fedFatal | ( | int | dduID | ) | [virtual] |
Implements DTDataMonitorInterface.
Definition at line 1164 of file DTDataIntegrityTask.cc.
References MonitorElement::Fill(), and hFEDFatal.
void DTDataIntegrityTask::fedNonFatal | ( | int | dduID | ) | [virtual] |
Implements DTDataMonitorInterface.
Definition at line 1171 of file DTDataIntegrityTask.cc.
References MonitorElement::Fill(), and hFEDNonFatal.
{ hFEDNonFatal->Fill(dduID); }
void DTDataIntegrityTask::postBeginJob | ( | ) |
Definition at line 1264 of file DTDataIntegrityTask.cc.
References bookHistos(), bookHistosROS25(), dbe, LogTrace, FEDNumbering::MAXDTFEDID, FEDNumbering::MINDTFEDID, cppFunctionSkipper::operator, DTROChainCoding::setDDU(), and DTROChainCoding::setROS().
Referenced by DTDataIntegrityTask().
{ LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << "[DTDataIntegrityTask]: postBeginJob" <<endl; // get the DQMStore service if needed dbe = edm::Service<DQMStore>().operator->(); LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << "[DTDataIntegrityTask] Get DQMStore service" << endl; // Loop over the DT FEDs int FEDIDmin = FEDNumbering::MINDTFEDID; int FEDIDMax = FEDNumbering::MAXDTFEDID; LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " FEDS: " << FEDIDmin << " to " << FEDIDMax << " in the RO" << endl; // book FED integrity histos bookHistos(FEDIDmin, FEDIDMax); // static booking of the histograms for(int fed = FEDIDmin; fed <= FEDIDMax; ++fed) { // loop over the FEDs in the readout DTROChainCoding code; code.setDDU(fed); bookHistos( string("ROS_S"), code); bookHistos( string("DDU"), code); for(int ros = 1; ros <= 12; ++ros) {// loop over all ROS code.setROS(ros); bookHistosROS25(code); } } }
void DTDataIntegrityTask::postEndJob | ( | ) |
Definition at line 97 of file DTDataIntegrityTask.cc.
References LogTrace.
{ LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << "[DTDataIntegrityTask]: postEndJob called!" <<endl; // if(doTimeHisto) TimeHistos("Event_word_vs_time"); }
void DTDataIntegrityTask::preBeginLumi | ( | const edm::LuminosityBlockID & | ls, |
const edm::Timestamp & | iTime | ||
) |
Definition at line 1232 of file DTDataIntegrityTask.cc.
References nEventsLS.
Referenced by DTDataIntegrityTask().
{ nEventsLS = 0; }
void DTDataIntegrityTask::preEndLumi | ( | const edm::LuminosityBlockID & | ls, |
const edm::Timestamp & | iTime | ||
) |
Definition at line 1238 of file DTDataIntegrityTask.cc.
References dduTimeHistos, edm::LuminosityBlockID::luminosityBlock(), nEventsLS, and rosTimeHistos.
Referenced by DTDataIntegrityTask().
{ int lumiBlock = ls.luminosityBlock(); map<std::string, map<int, DTTimeEvolutionHisto*> >::iterator dduIt = dduTimeHistos.begin(); map<std::string, map<int, DTTimeEvolutionHisto*> >::iterator dduEnd = dduTimeHistos.end(); for(; dduIt!=dduEnd; ++dduIt) { map<int, DTTimeEvolutionHisto*>::iterator histoIt = dduIt->second.begin(); map<int, DTTimeEvolutionHisto*>::iterator histoEnd = dduIt->second.end(); for(; histoIt!=histoEnd; ++histoIt) { histoIt->second->updateTimeSlot(lumiBlock,nEventsLS); } } map<std::string, map<int, DTTimeEvolutionHisto*> >::iterator rosIt = rosTimeHistos.begin(); map<std::string, map<int, DTTimeEvolutionHisto*> >::iterator rosEnd = rosTimeHistos.end(); for(; rosIt!=rosEnd; ++rosIt) { map<int, DTTimeEvolutionHisto*>::iterator histoIt = rosIt->second.begin(); map<int, DTTimeEvolutionHisto*>::iterator histoEnd = rosIt->second.end(); for(; histoIt!=histoEnd; ++histoIt) { histoIt->second->updateTimeSlot(lumiBlock,nEventsLS); } } }
void DTDataIntegrityTask::preProcessEvent | ( | const edm::EventID & | iEvtid, |
const edm::Timestamp & | iTime | ||
) |
Definition at line 1206 of file DTDataIntegrityTask.cc.
References eventErrorFlag, fedBXIds, MonitorElement::Fill(), LogTrace, nEventMonitor, nevents, nEventsLS, rosBxIdsPerFED, and rosL1AIdsPerFED.
Referenced by DTDataIntegrityTask().
{ nevents++; nEventMonitor->Fill(nevents); nEventsLS++; LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << "[DTDataIntegrityTask]: preProcessEvent" <<endl; // clear the set of BXids from the ROSs for(map<int, set<int> >::iterator rosBxIds = rosBxIdsPerFED.begin(); rosBxIds != rosBxIdsPerFED.end(); ++rosBxIds) { (*rosBxIds).second.clear(); } fedBXIds.clear(); for(map<int, set<int> >::iterator rosL1AIds = rosL1AIdsPerFED.begin(); rosL1AIds != rosL1AIdsPerFED.end(); ++rosL1AIds) { (*rosL1AIds).second.clear(); } // reset the error flag eventErrorFlag = false; }
void DTDataIntegrityTask::processFED | ( | DTDDUData & | dduData, |
const std::vector< DTROS25Data > & | rosData, | ||
int | dduID | ||
) | [virtual] |
Implements DTDataMonitorInterface.
Definition at line 863 of file DTDataIntegrityTask.cc.
References DTDDUSecondStatusWord::busyROSPAF(), FEDHeader::bxID(), DTDDUSecondStatusWord::bxIDError(), FEDTrailer::check(), FEDHeader::check(), DTDDUData::crcErrorBit(), dduHistos, dduTimeHistos, fedBXIds, DTDDUSecondStatusWord::fifoAlmostFull(), DTDDUSecondStatusWord::fifoFull(), MonitorElement::Fill(), DTDDUData::getDDUHeader(), DTROChainCoding::getDDUID(), DTDDUData::getDDUTrailer(), DTDDUData::getFirstStatusWord(), DTDDUData::getSecondStatusWord(), hCorruptionSummary, hFEDEntry, hFEDFatal, hTTSSummary, i, DTDDUSecondStatusWord::inputFifoAlmostFull(), DTDDUSecondStatusWord::inputFifoFull(), DTDDUSecondStatusWord::l1AIDError(), FEDTrailer::lenght(), LogTrace, FEDHeader::lvl1ID(), mode, neventsDDU, DTDDUSecondStatusWord::outOfSynchROSError(), DTDDUSecondStatusWord::outputFifoAlmostFull(), DTDDUSecondStatusWord::outputFifoFull(), rosBxIdsPerFED, rosL1AIdsPerFED, DTDDUSecondStatusWord::rosList(), DTROChainCoding::setDDU(), FEDHeader::triggerType(), FEDTrailer::ttsBits(), and DTDDUSecondStatusWord::warningROSPAF().
{ neventsDDU++; if (neventsDDU%1000 == 0) LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << "[DTDataIntegrityTask]: " << neventsDDU << " events analyzed by processFED" << endl; DTROChainCoding code; code.setDDU(ddu); hFEDEntry->Fill(code.getDDUID()); FEDTrailer trailer = data.getDDUTrailer(); FEDHeader header = data.getDDUHeader(); // check consistency of header and trailer if(!header.check()) { // error code 7 hFEDFatal->Fill(code.getDDUID()); hCorruptionSummary->Fill(code.getDDUID(), 7); } if(!trailer.check()) { // error code 8 hFEDFatal->Fill(code.getDDUID()); hCorruptionSummary->Fill(code.getDDUID(), 8); } // check CRC error bit set by DAQ before sending data on SLink if(data.crcErrorBit()) { // error code 6 hFEDFatal->Fill(code.getDDUID()); hCorruptionSummary->Fill(code.getDDUID(), 6); } DTDDUSecondStatusWord secondWord = data.getSecondStatusWord(); // Fill the status summary of the TTS //1D HISTO WITH TTS VALUES form trailer (7 bins = 7 values) int ttsCodeValue = -1; int ttsSummaryBin = -1; switch(trailer.ttsBits()) { case 0:{ //disconnected ttsCodeValue = 0; break; } case 1:{ //warning overflow ttsCodeValue = 1; if(secondWord.warningROSPAF()) { // ROS PAF ttsSummaryBin = 1; } else { // DDU PAF ttsSummaryBin = 2; } break; } case 2:{ //out of sinch ttsCodeValue = 2; bool knownOrigin = false; if(secondWord.outOfSynchROSError()) {// ROS Error ttsSummaryBin = 7; knownOrigin = true; } if(secondWord.l1AIDError()) {// L1A Mism. ttsSummaryBin = 6; knownOrigin = true; } if(secondWord.bxIDError()) {// BX Mism. ttsSummaryBin = 8; knownOrigin = true; } if(secondWord.outputFifoFull() || secondWord.inputFifoFull() || secondWord.fifoFull()) { // DDU Full ttsSummaryBin = 5; knownOrigin = true; } if(!knownOrigin) ttsSummaryBin = 9; // Error in DDU logic break; } case 4:{ //busy ttsCodeValue = 3; bool knownOrigin = false; if(secondWord.busyROSPAF()) { // ROS PAF ttsSummaryBin = 3; knownOrigin = true; } if(secondWord.outputFifoAlmostFull() || secondWord.inputFifoAlmostFull() || secondWord.fifoAlmostFull() ){ // DDU PAF ttsSummaryBin = 4; knownOrigin = true; } if(!knownOrigin) ttsSummaryBin = 9; // Error in DDU logic break; } case 8:{ //ready ttsCodeValue = 4; break; } case 12:{ //error ttsCodeValue = 5; break; } case 16:{ //disconnected ttsCodeValue = 6; break; } default:{ LogError("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") <<"[DTDataIntegrityTask] DDU control: wrong TTS value "<<trailer.ttsBits()<<endl; ttsCodeValue = 7; } } if(mode <= 1) dduHistos["TTSValues"][code.getDDUID()]->Fill(ttsCodeValue); if(ttsSummaryBin != -1) { hTTSSummary->Fill(ddu, ttsSummaryBin); } //2D HISTO: ROS VS STATUS (8 BIT = 8 BIN) from 1st-2nd status words (9th BIN FROM LIST OF ROS in 2nd status word) MonitorElement* hROSStatus = dduHistos["ROSStatus"][code.getDDUID()]; //1D HISTO: NUMBER OF ROS IN THE EVENTS from 2nd status word int rosList = secondWord.rosList(); set<int> rosPositions; for(int i=0;i<12;i++) { if(rosList & 0x1) { rosPositions.insert(i); //9th BIN FROM LIST OF ROS in 2nd status word if(mode <= 2) hROSStatus->Fill(8,i,1); } rosList >>= 1; } int channel=0; for (vector<DTDDUFirstStatusWord>::const_iterator fsw_it = data.getFirstStatusWord().begin(); fsw_it != data.getFirstStatusWord().end(); fsw_it++) { // assuming association one-to-one between DDU channel and ROS if(mode <= 2) { hROSStatus->Fill(0,channel,(*fsw_it).channelEnabled()); hROSStatus->Fill(1,channel,(*fsw_it).timeout()); hROSStatus->Fill(2,channel,(*fsw_it).eventTrailerLost()); hROSStatus->Fill(3,channel,(*fsw_it).opticalFiberSignalLost()); hROSStatus->Fill(4,channel,(*fsw_it).tlkPropagationError()); hROSStatus->Fill(5,channel,(*fsw_it).tlkPatternError()); hROSStatus->Fill(6,channel,(*fsw_it).tlkSignalLost()); hROSStatus->Fill(7,channel,(*fsw_it).errorFromROS()); } // check that the enabled channel was also in the read-out if((*fsw_it).channelEnabled() == 1 && rosPositions.find(channel) == rosPositions.end()) { if(mode <= 2) hROSStatus->Fill(9,channel,1); // error code 1 hFEDFatal->Fill(code.getDDUID()); hCorruptionSummary->Fill(code.getDDUID(), 1); } channel++; } // --------------------------------------------------------------------- // cross checks between FED and ROS data // check the BX ID against the ROSs set<int> rosBXIds = rosBxIdsPerFED[ddu]; if((rosBXIds.size() > 1 || rosBXIds.find(header.bxID()) == rosBXIds.end()) && rosBXIds.size() != 0) { // in this case look for faulty ROSs for(vector<DTROS25Data>::const_iterator rosControlData = rosData.begin(); rosControlData != rosData.end(); ++rosControlData) { // loop over the ROS data for (vector<DTROSDebugWord>::const_iterator debug_it = (*rosControlData).getROSDebugs().begin(); debug_it != (*rosControlData).getROSDebugs().end(); debug_it++) { // Loop over ROS debug words if ((*debug_it).debugType() == 0 && (*debug_it).debugMessage() != header.bxID()) { // check the BX int ros = (*rosControlData).getROSID(); // fill the error bin if(mode <= 2) hROSStatus->Fill(11,ros-1); // error code 2 hFEDFatal->Fill(code.getDDUID()); hCorruptionSummary->Fill(code.getDDUID(), 2); } } } } // check the BX ID against other FEDs fedBXIds.insert(header.bxID()); if(fedBXIds.size() != 1) { LogWarning("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << "ERROR: FED " << ddu << " BX ID different from other feds: " << header.bxID() << endl; // error code 3 hFEDFatal->Fill(code.getDDUID()); hCorruptionSummary->Fill(code.getDDUID(), 3); } // check the L1A ID against the ROSs set<int> rosL1AIds = rosL1AIdsPerFED[ddu]; if((rosL1AIds.size() > 1 || rosL1AIds.find(header.lvl1ID()-1) == rosL1AIds.end()) && rosL1AIds.size() != 0) { // in this case look for faulty ROSs //If L1A_ID error identify which ROS has wrong L1A for (vector<DTROS25Data>::const_iterator rosControlData = rosData.begin(); rosControlData != rosData.end(); rosControlData++) { // loop over the ROS data int ROSHeader_TTCCount = ((*rosControlData).getROSHeader().TTCEventCounter() + 1) % 0x1000000; // fix comparison in case of last counting bin in ROS /first one in DDU if( ROSHeader_TTCCount != header.lvl1ID() ) { int ros = (*rosControlData).getROSID(); if(mode <= 2) hROSStatus->Fill(10,ros-1); // error code 4 hFEDFatal->Fill(code.getDDUID()); hCorruptionSummary->Fill(code.getDDUID(), 4); } } } //1D HISTOS: EVENT LENGHT from trailer int fedEvtLenght = trailer.lenght()*8; // if(fedEvtLenght > 16000) fedEvtLenght = 16000; // overflow bin dduHistos["EventLenght"][code.getDDUID()]->Fill(fedEvtLenght); if(mode > 1) return; dduTimeHistos["FEDAvgEvLenghtvsLumi"][code.getDDUID()]->accumulateValueTimeSlot(fedEvtLenght); // size of the list of ROS in the Read-Out dduHistos["ROSList"][code.getDDUID()]->Fill(rosPositions.size()); //2D HISTO: FIFO STATUS from 2nd status word MonitorElement *hFIFOStatus = dduHistos["FIFOStatus"][code.getDDUID()]; int inputFifoFull = secondWord.inputFifoFull(); int inputFifoAlmostFull = secondWord.inputFifoAlmostFull(); int fifoFull = secondWord.fifoFull(); int fifoAlmostFull = secondWord.fifoAlmostFull(); int outputFifoFull = secondWord.outputFifoFull(); int outputFifoAlmostFull = secondWord.outputFifoAlmostFull(); for(int i=0;i<3;i++){ if(inputFifoFull & 0x1){ hFIFOStatus->Fill(i,0); } if(inputFifoAlmostFull & 0x1){ hFIFOStatus->Fill(i,1); } if(fifoFull & 0x1){ hFIFOStatus->Fill(3+i,0); } if(fifoAlmostFull & 0x1){ hFIFOStatus->Fill(3+i,1); } if(!(inputFifoFull & 0x1) && !(inputFifoAlmostFull & 0x1)){ hFIFOStatus->Fill(i,2); } if(!(fifoFull & 0x1) && !(fifoAlmostFull & 0x1)){ hFIFOStatus->Fill(3+i,2); } inputFifoFull >>= 1; inputFifoAlmostFull >>= 1; fifoFull >>= 1; fifoAlmostFull >>= 1; } if(outputFifoFull){ hFIFOStatus->Fill(6,0); } if(outputFifoAlmostFull){ hFIFOStatus->Fill(6,1); } if(!outputFifoFull && !outputFifoAlmostFull){ hFIFOStatus->Fill(6,2); } //1D HISTO: EVENT TYPE from header dduHistos["EventType"][code.getDDUID()]->Fill(header.triggerType()); // fill the distribution of the BX ids dduHistos["BXID"][code.getDDUID()]->Fill(header.bxID()); }
void DTDataIntegrityTask::processROS25 | ( | DTROS25Data & | data, |
int | dduID, | ||
int | ros | ||
) | [virtual] |
Implements DTDataMonitorInterface.
Definition at line 540 of file DTDataIntegrityTask.cc.
References DTROBHeaderWord::bunchID(), channelsInCEROS(), channelsInROS(), eventErrorFlag, DTROSTrailerWord::EventWordCount(), MonitorElement::Fill(), FirstRos, DTROChainCoding::getDDUID(), DTROChainCoding::getROB(), DTROS25Data::getROBHeaders(), DTROS25Data::getROBTrailers(), DTROChainCoding::getROS(), DTROS25Data::getROSDebugs(), DTROS25Data::getROSErrors(), DTROS25Data::getROSHeader(), DTROChainCoding::getROSID(), DTROS25Data::getROSTrailer(), DTROChainCoding::getSCID(), getSCInfo, DTROS25Data::getSCPrivHeader(), DTROS25Data::getSCTrailer(), DTROS25Data::getTDCData(), DTROS25Data::getTDCError(), DTROSTrailerWord::l1AFifoOccupancy(), LogTrace, mode, nevents, neventsROS25, DTLocalTriggerSectorCollectorHeaderWord::NumberOf16bitWords(), DTTDCMeasurementWord::PC(), ResetCount_unfolded, DTROBHeaderWord::robID(), rosBxIdsPerFED, rosHistos, rosL1AIdsPerFED, rosSHistos, rosTimeHistos, ROSWords_t(), DTROChainCoding::setDDU(), DTROChainCoding::setROB(), DTROChainCoding::setROS(), DTROSTrailerWord::TPX(), DTROSHeaderWord::TTCEventCounter(), and DTLocalTriggerTrailerWord::wordCount().
{ neventsROS25++; // FIXME: implement a counter which makes sense // if (neventsROS25%1000 == 0) LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << "[DTDataIntegrityTask]: " << neventsROS25 << " events analyzed by processROS25" << endl; // The ID of the RO board (used to map the histos) DTROChainCoding code; code.setDDU(ddu); code.setROS(ros); MonitorElement* ROSSummary = rosSHistos["ROSSummary"][code.getDDUID()]; // Summary of all ROB errors MonitorElement* ROSError = 0; if(mode <= 2) ROSError = rosHistos["ROSError"][code.getROSID()]; if ( (mode<=2) && (!ROSError) ) { LogError("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << "Trying to access non existing ME at ROSID " << code.getROSID() << std::endl; return; } // L1A ids to be checked against FED one rosL1AIdsPerFED[ddu].insert(data.getROSHeader().TTCEventCounter()); // ROS errors // check for TPX errors if (data.getROSTrailer().TPX() != 0) { LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " TXP error en ROS " << code.getROS() << endl; ROSSummary->Fill(9,code.getROS()); } // L1 Buffer almost full (non-critical error!) if(data.getROSTrailer().l1AFifoOccupancy() > 31) { ROSSummary->Fill(10,code.getROS()); } // FIXME: what is this about??? if (neventsROS25 == 1) FirstRos = code.getROSID(); if (code.getROSID() == FirstRos) nevents++ ; for (vector<DTROSErrorWord>::const_iterator error_it = data.getROSErrors().begin(); error_it != data.getROSErrors().end(); error_it++) { // Loop over ROS error words LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " Error in ROS " << code.getROS() << " ROB Id " << (*error_it).robID() << " Error type " << (*error_it).errorType() << endl; // Fill the ROSSummary (1 per FED) histo ROSSummary->Fill((*error_it).errorType(), code.getROS()); if((*error_it).errorType() <= 11) { // set error flag eventErrorFlag = true; } if(mode <= 2) { // Fill the ROB Summary (1 per ROS) histo if ((*error_it).robID() != 31) { ROSError->Fill((*error_it).errorType(),(*error_it).robID()); } else if ((*error_it).errorType() == 4) { vector<int> channelBins; channelsInROS((*error_it).cerosID(),channelBins); vector<int>::const_iterator channelIt = channelBins.begin(); vector<int>::const_iterator channelEnd = channelBins.end(); for(;channelIt!=channelEnd;++channelIt) { ROSError->Fill(4,(*channelIt)); } } } } int ROSDebug_BunchNumber = -1; int ROSDebug_BcntResCntLow = 0; int ROSDebug_BcntResCntHigh = 0; int ROSDebug_BcntResCnt = 0; for (vector<DTROSDebugWord>::const_iterator debug_it = data.getROSDebugs().begin(); debug_it != data.getROSDebugs().end(); debug_it++) { // Loop over ROS debug words int debugROSSummary = 0; int debugROSError = 0; vector<int> debugBins; bool hasEvIdMis = false; vector<int> evIdMisBins; if ((*debug_it).debugType() == 0 ) { ROSDebug_BunchNumber = (*debug_it).debugMessage(); } else if ((*debug_it).debugType() == 1 ) { ROSDebug_BcntResCntLow = (*debug_it).debugMessage(); } else if ((*debug_it).debugType() == 2 ) { ROSDebug_BcntResCntHigh = (*debug_it).debugMessage(); } else if ((*debug_it).debugType() == 3) { if ((*debug_it).dontRead()){ debugROSSummary = 11; debugROSError = 8; if (mode <= 2) channelsInCEROS((*debug_it).cerosIdCerosStatus(),(*debug_it).dontRead(),debugBins); } if ((*debug_it).evIdMis()){ hasEvIdMis = true; if (mode <= 2) channelsInCEROS((*debug_it).cerosIdCerosStatus(),(*debug_it).evIdMis(),evIdMisBins); } } else if ((*debug_it).debugType() == 4 && (*debug_it).cerosIdRosStatus()){ debugROSSummary = 13; debugROSError = 10; if (mode <= 2) channelsInROS((*debug_it).cerosIdRosStatus(),debugBins); } if (debugROSSummary) { ROSSummary->Fill(debugROSSummary,code.getROS()); if (mode <= 2) { vector<int>::const_iterator channelIt = debugBins.begin(); vector<int>::const_iterator channelEnd = debugBins.end(); for (;channelIt!=channelEnd;++channelIt) { ROSError->Fill(debugROSError,(*channelIt)); } } } if (hasEvIdMis) { ROSSummary->Fill(12,code.getROS()); if (mode <= 2) { vector<int>::const_iterator channelIt = evIdMisBins.begin(); vector<int>::const_iterator channelEnd = evIdMisBins.end(); for (;channelIt!=channelEnd;++channelIt) { ROSError->Fill(9,(*channelIt)); } } } } ROSDebug_BcntResCnt = (ROSDebug_BcntResCntHigh << 15) + ROSDebug_BcntResCntLow; // LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") // << " ROS: " << code.getROS() << " ROSDebug_BunchNumber " << ROSDebug_BunchNumber // << " ROSDebug_BcntResCnt " << ROSDebug_BcntResCnt << endl; // Event words vs time // FIXME: what is this doing??? ROSWords_t(ResetCount_unfolded,code.getROS(),ROSDebug_BcntResCnt,nevents); // fill hists it here // histoType = "Event_word_vs_time"; // if (rosHistos[histoType].find(code.getROSID()) != rosHistos[histoType].end()){ // (rosHistos.find(histoType)->second).find(code.getROSID())->second-> // Fill((ResetCount_unfolded),data.getROSTrailer().EventWordCount()); // (rosHistos.find(histoType)->second).find(code.getROSID())->second->setAxisTitle("Time(s)",1); // } // else { // (rosHistos.find(histoType)->second).find(code.getROSID())->second-> // Fill((ResetCount_unfolded),data.getROSTrailer().EventWordCount());} // ROB Group Header // Check the BX of the ROB headers against the BX of the ROS for (vector<DTROBHeader>::const_iterator rob_it = data.getROBHeaders().begin(); rob_it != data.getROBHeaders().end(); rob_it++) { // loop over ROB headers code.setROB((*rob_it).first); DTROBHeaderWord robheader = (*rob_it).second; rosBxIdsPerFED[ddu].insert(ROSDebug_BunchNumber); if (robheader.bunchID() != ROSDebug_BunchNumber) { // fill ROS Summary plot ROSSummary->Fill(8,code.getROS()); eventErrorFlag = true; // fill ROB Summary plot for that particular ROS if(mode <= 2) ROSError->Fill(7,robheader.robID()); } } if(mode <= 1) { // produce only when not in HLT // ROB Trailer for (vector<DTROBTrailerWord>::const_iterator robt_it = data.getROBTrailers().begin(); robt_it != data.getROBTrailers().end(); robt_it++) { // loop over ROB trailers float wCount = (*robt_it).wordCount()<100. ? (*robt_it).wordCount() : 99.9; rosHistos["ROB_mean"][code.getROSID()]->Fill((*robt_it).robID(),wCount); } // // Trigger frequency // double frequency = 0; // // FIXME: how is the frequency computed // ROS_L1A_Frequency(code.getROS(),ROSDebug_BcntResCnt,neventsROS25,frequency,trigger_counter); // rosHistos["Trigger_frequency"][code.getROSID()]->Fill(frequency); // Plot the event lenght //NOHLT int rosEventLenght = data.getROSTrailer().EventWordCount()*4; rosTimeHistos["ROSAvgEventLenghtvsLumi"][code.getROSID()]->accumulateValueTimeSlot(rosEventLenght); if(rosEventLenght > 1600) rosEventLenght = 1600; rosHistos["ROSEventLenght"][code.getROSID()]->Fill(rosEventLenght); } // TDC Data for (vector<DTTDCData>::const_iterator tdc_it = data.getTDCData().begin(); tdc_it != data.getTDCData().end(); tdc_it++) { // loop over TDC data DTTDCMeasurementWord tdcDatum = (*tdc_it).second; if ( tdcDatum.PC() !=0) { LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " PC error in ROS " << code.getROS() << " TDC " << (*tdc_it).first << endl; // fill ROS Summary plot ROSSummary->Fill(7,code.getROS()); eventErrorFlag = true; // fill ROB Summary plot for that particular ROS if(mode <= 2) ROSError->Fill(6,(*tdc_it).first); } } // TDC Error for (vector<DTTDCError>::const_iterator tdc_it = data.getTDCError().begin(); tdc_it != data.getTDCError().end(); tdc_it++) { // loop over TDC errors code.setROB((*tdc_it).first); int tdcError_ROSSummary = 0; int tdcError_ROSError = 0; int tdcError_TDCHisto = 0; if(((*tdc_it).second).tdcError() & 0x4000 ) { LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " ROS " << code.getROS() << " ROB " << code.getROB() << " Internal fatal Error 4000 in TDC " << (*tdc_it).first << endl; tdcError_ROSSummary = 14; tdcError_ROSError = 11; tdcError_TDCHisto = 0; } else if ( ((*tdc_it).second).tdcError() & 0x0249 ) { LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " ROS " << code.getROS() << " ROB " << code.getROB() << " TDC FIFO overflow in TDC " << (*tdc_it).first << endl; tdcError_ROSSummary = 15; tdcError_ROSError = 12; tdcError_TDCHisto = 1; } else if ( ((*tdc_it).second).tdcError() & 0x0492 ) { LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " ROS " << code.getROS() << " ROB " << code.getROB() << " TDC L1 buffer overflow in TDC " << (*tdc_it).first << endl; tdcError_ROSSummary = 16; tdcError_ROSError = 13; tdcError_TDCHisto = 2; } else if ( ((*tdc_it).second).tdcError() & 0x2000 ) { LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " ROS " << code.getROS() << " ROB " << code.getROB() << " TDC L1A FIFO overflow in TDC " << (*tdc_it).first << endl; tdcError_ROSSummary = 17; tdcError_ROSError = 14; tdcError_TDCHisto = 3; } else if ( ((*tdc_it).second).tdcError() & 0x0924 ) { LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " ROS " << code.getROS() << " ROB " << code.getROB() << " TDC hit error in TDC " << (*tdc_it).first << endl; tdcError_ROSSummary = 18; tdcError_ROSError = 15; tdcError_TDCHisto = 4; } else if ( ((*tdc_it).second).tdcError() & 0x1000 ) { LogTrace("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " ROS " << code.getROS() << " ROB " << code.getROB() << " TDC hit rejected in TDC " << (*tdc_it).first << endl; tdcError_ROSSummary = 19; tdcError_ROSError = 16; tdcError_TDCHisto = 5; } else { LogWarning("DTRawToDigi|DTDQM|DTMonitorModule|DTDataIntegrityTask") << " TDC error code not known " << ((*tdc_it).second).tdcError() << endl; } ROSSummary->Fill(tdcError_ROSSummary,code.getROS()); if(tdcError_ROSSummary <= 15) { eventErrorFlag = true; } if(mode <= 2) { ROSError->Fill(tdcError_ROSError,(*tdc_it).first); if(mode <= 1) rosHistos["TDCError"][code.getROSID()]->Fill(tdcError_TDCHisto+6*((*tdc_it).second).tdcID(),(*tdc_it).first); } } // Read SC data if (mode <= 1 && getSCInfo) { // SC Data // NumberOf16bitWords counts the # of words + 1 subheader // the SC includes the SC "private header" and the ROS header and trailer (= NumberOf16bitWords +3) rosHistos["SCSizeVsROSSize"][code.getSCID()]->Fill(ros,data.getSCPrivHeader().NumberOf16bitWords()+3-data.getSCTrailer().wordCount()); } }
void DTDataIntegrityTask::TimeHistos | ( | std::string | histoType | ) |
Definition at line 492 of file DTDataIntegrityTask.cc.
References newFWLiteAna::bin, dbe, DQMStore::get(), MonitorElement::getBinContent(), MonitorElement::getNbinsX(), MonitorElement::getNbinsY(), it, j, names, and MonitorElement::setAxisRange().
{ if(histoType == "Event_word_vs_time"){ for (it = names.begin(); it != names.end(); it++) { if ((*it).first==histoType){ MonitorElement * h1 =dbe->get((*it).second); int first_bin = -1, last_bin=-1; for( int bin=1; bin < h1->getNbinsX()+1; bin++ ){ for( int j=1; j < h1->getNbinsY(); j++ ){ if( h1->getBinContent(bin,j) > 0 ) { if( first_bin == -1 ) { first_bin = bin; } last_bin = bin; } } } if( first_bin > 1 ) { first_bin -= 1; } if( last_bin < h1-> getNbinsX() ){ last_bin += 1; } h1->setAxisRange(0,last_bin,1); } } } }
std::string DTDataIntegrityTask::topFolder | ( | bool | isFEDIntegrity | ) | const [private] |
Definition at line 1175 of file DTDataIntegrityTask.cc.
References fedIntegrityFolder, and mode.
Referenced by bookHistos().
{ string folder = isFEDIntegrity ? fedIntegrityFolder : "DT/00-DataIntegrity"; if (!isFEDIntegrity) folder += (mode==1) ? "_SM/" : (mode==3) ? "_EvF/" : "/"; return folder; }
DTROChainCoding DTDataIntegrityTask::coding [private] |
Definition at line 93 of file DTDataIntegrityTask.h.
DQMStore* DTDataIntegrityTask::dbe [private] |
Definition at line 91 of file DTDataIntegrityTask.h.
Referenced by bookHistos(), postBeginJob(), and TimeHistos().
std::map<std::string, std::map<int, MonitorElement*> > DTDataIntegrityTask::dduHistos [private] |
Definition at line 98 of file DTDataIntegrityTask.h.
Referenced by processFED().
std::map<std::string, std::map<int, DTTimeEvolutionHisto*> > DTDataIntegrityTask::dduTimeHistos [private] |
Definition at line 116 of file DTDataIntegrityTask.h.
Referenced by preEndLumi(), and processFED().
bool DTDataIntegrityTask::doTimeHisto [private] |
Definition at line 84 of file DTDataIntegrityTask.h.
bool DTDataIntegrityTask::eventErrorFlag [private] |
Definition at line 137 of file DTDataIntegrityTask.h.
Referenced by eventHasErrors(), preProcessEvent(), and processROS25().
std::set<int> DTDataIntegrityTask::fedBXIds [private] |
Definition at line 140 of file DTDataIntegrityTask.h.
Referenced by preProcessEvent(), and processFED().
std::string DTDataIntegrityTask::fedIntegrityFolder [private] |
Definition at line 145 of file DTDataIntegrityTask.h.
Referenced by DTDataIntegrityTask(), and topFolder().
bool DTDataIntegrityTask::getSCInfo [private] |
Definition at line 86 of file DTDataIntegrityTask.h.
Referenced by bookHistosROS25(), DTDataIntegrityTask(), and processROS25().
Definition at line 110 of file DTDataIntegrityTask.h.
Referenced by bookHistos(), and processFED().
MonitorElement* DTDataIntegrityTask::hFEDEntry [private] |
Definition at line 107 of file DTDataIntegrityTask.h.
Referenced by bookHistos(), fedEntry(), and processFED().
MonitorElement* DTDataIntegrityTask::hFEDFatal [private] |
Definition at line 108 of file DTDataIntegrityTask.h.
Referenced by bookHistos(), fedFatal(), and processFED().
MonitorElement* DTDataIntegrityTask::hFEDNonFatal [private] |
Definition at line 109 of file DTDataIntegrityTask.h.
Referenced by bookHistos(), and fedNonFatal().
MonitorElement* DTDataIntegrityTask::hTTSSummary [private] |
Definition at line 113 of file DTDataIntegrityTask.h.
Referenced by bookHistos(), and processFED().
std::multimap<std::string, std::string>::iterator DTDataIntegrityTask::it [private] |
Definition at line 79 of file DTDataIntegrityTask.h.
Referenced by TimeHistos().
int DTDataIntegrityTask::mode [private] |
Definition at line 144 of file DTDataIntegrityTask.h.
Referenced by bookHistosROS25(), DTDataIntegrityTask(), processFED(), processROS25(), and topFolder().
int DTDataIntegrityTask::myPrevEv [private] |
Definition at line 128 of file DTDataIntegrityTask.h.
int DTDataIntegrityTask::myPrevFifoVal[7] [private] |
Definition at line 133 of file DTDataIntegrityTask.h.
int DTDataIntegrityTask::myPrevRosVal [private] |
Definition at line 132 of file DTDataIntegrityTask.h.
int DTDataIntegrityTask::myPrevTtsVal [private] |
Definition at line 131 of file DTDataIntegrityTask.h.
std::multimap<std::string, std::string> DTDataIntegrityTask::names [private] |
Definition at line 78 of file DTDataIntegrityTask.h.
Referenced by TimeHistos().
MonitorElement* DTDataIntegrityTask::nEventMonitor [private] |
Definition at line 96 of file DTDataIntegrityTask.h.
Referenced by bookHistos(), and preProcessEvent().
int DTDataIntegrityTask::nevents [private] |
Definition at line 88 of file DTDataIntegrityTask.h.
Referenced by preProcessEvent(), and processROS25().
int DTDataIntegrityTask::neventsDDU [private] |
Definition at line 121 of file DTDataIntegrityTask.h.
Referenced by DTDataIntegrityTask(), processFED(), and ~DTDataIntegrityTask().
int DTDataIntegrityTask::nEventsLS [private] |
Definition at line 119 of file DTDataIntegrityTask.h.
Referenced by preBeginLumi(), preEndLumi(), and preProcessEvent().
int DTDataIntegrityTask::neventsROS25 [private] |
Definition at line 122 of file DTDataIntegrityTask.h.
Referenced by DTDataIntegrityTask(), and processROS25().
std::string DTDataIntegrityTask::outputFile [private] |
Definition at line 124 of file DTDataIntegrityTask.h.
Definition at line 81 of file DTDataIntegrityTask.h.
double DTDataIntegrityTask::rob_max[25] [private] |
Definition at line 125 of file DTDataIntegrityTask.h.
std::map<std::string, std::map<int, MonitorElement*> > DTDataIntegrityTask::robHistos [private] |
Definition at line 104 of file DTDataIntegrityTask.h.
std::map<int, std::set<int> > DTDataIntegrityTask::rosBxIdsPerFED [private] |
Definition at line 139 of file DTDataIntegrityTask.h.
Referenced by preProcessEvent(), processFED(), and processROS25().
std::map<std::string, std::map<int, MonitorElement*> > DTDataIntegrityTask::rosHistos [private] |
Definition at line 102 of file DTDataIntegrityTask.h.
Referenced by processROS25().
std::map<int, std::set<int> > DTDataIntegrityTask::rosL1AIdsPerFED [private] |
Definition at line 141 of file DTDataIntegrityTask.h.
Referenced by preProcessEvent(), processFED(), and processROS25().
std::map<std::string, std::map<int, MonitorElement*> > DTDataIntegrityTask::rosSHistos [private] |
Definition at line 100 of file DTDataIntegrityTask.h.
Referenced by processROS25().
std::map<std::string, std::map<int, DTTimeEvolutionHisto*> > DTDataIntegrityTask::rosTimeHistos [private] |
Definition at line 117 of file DTDataIntegrityTask.h.
Referenced by preEndLumi(), and processROS25().
float DTDataIntegrityTask::trigger_counter [private] |
Definition at line 123 of file DTDataIntegrityTask.h.