CSCDCCUnpacker Class Reference

Inheritance diagram for CSCDCCUnpacker:

Public Member Functions
	CSCDCCUnpacker (const edm::ParameterSet &pset)
	Constructor. More...
void	produce (edm::Event &e, const edm::EventSetup &c) override
	Produce digis out of raw data. More...
void	visual_raw (int hl, int id, int run, int event, bool fedshort, bool fDump, short unsigned int *buf) const
	Visualization of raw data in FED-less events (Robert Harr and Alexander Sakharov) More...
	~CSCDCCUnpacker () override
	Destructor. More...
Public Member Functions inherited from edm::stream::EDProducer<>
	EDProducer ()=default
	EDProducer (const EDProducer &)=delete
bool	hasAbilityToProduceInBeginLumis () const final
bool	hasAbilityToProduceInBeginProcessBlocks () const final
bool	hasAbilityToProduceInBeginRuns () const final
bool	hasAbilityToProduceInEndLumis () const final
bool	hasAbilityToProduceInEndProcessBlocks () const final
bool	hasAbilityToProduceInEndRuns () const final
const EDProducer &	operator= (const EDProducer &)=delete

Static Public Member Functions
static void	fillDescriptions (edm::ConfigurationDescriptions &descriptions)

Private Attributes
int	b904dmb
bool	b904Setup
int	b904vmecrate
edm::ESGetToken< CSCCrateMap, CSCCrateMapRcd >	crateToken
edm::ESGetToken< CSCChamberMap, CSCChamberMapRcd >	cscmapToken
bool	debug
bool	disableMappingCheck
unsigned int	errorMask
unsigned int	examinerMask
bool	formatedEventDump
bool	goodEvent
edm::EDGetTokenT< FEDRawDataCollection >	i_token
	Token for consumes interface & access to data. More...
bool	instantiateDQM
CSCMonitorInterface *	monitor
int	numOfEvents
bool	printEventNumber
bool	SuppressZeroLCT
	Suppress zeros LCTs. More...
bool	unpackStatusDigis
bool	useCSCShowers_
	option to unpack CSC shower data More...
bool	useExaminer
bool	useFormatStatus
bool	useGEMs_
	option to unpack GEM cluster data More...
bool	useRPCs_
	option to unpack RPC data More...
bool	useSelectiveUnpacking
bool	visualFEDInspect
	Visualization of raw data. More...
bool	visualFEDShort

Additional Inherited Members
Public Types inherited from edm::stream::EDProducer<>
using	CacheTypes = CacheContexts< T... >
using	GlobalCache = typename CacheTypes::GlobalCache
using	HasAbility = AbilityChecker< T... >
using	InputProcessBlockCache = typename CacheTypes::InputProcessBlockCache
using	LuminosityBlockCache = typename CacheTypes::LuminosityBlockCache
using	LuminosityBlockContext = LuminosityBlockContextT< LuminosityBlockCache, RunCache, GlobalCache >
using	LuminosityBlockSummaryCache = typename CacheTypes::LuminosityBlockSummaryCache
using	RunCache = typename CacheTypes::RunCache
using	RunContext = RunContextT< RunCache, GlobalCache >
using	RunSummaryCache = typename CacheTypes::RunSummaryCache

Detailed Description

Author

Alex Tumanov

Definition at line 67 of file CSCDCCUnpacker.cc.

Constructor & Destructor Documentation

CSCDCCUnpacker()

CSCDCCUnpacker::CSCDCCUnpacker

(

const edm::ParameterSet &

pset

)

Constructor.

Selective unpacking mode will skip only troublesome CSC blocks and not whole DCC/DDU block

Enable Format Status Digis

Visualization of raw data

Suppress zeros LCTs

Definition at line 116 of file CSCDCCUnpacker.cc.

References b904dmb, b904Setup, b904vmecrate, crateToken, cscmapToken, debug, disableMappingCheck, errorMask, examinerMask, formatedEventDump, i_token, instantiateDQM, monitor, Utilities::operator, printEventNumber, muonDTDigis_cfi::pset, CSCDCCEventData::setDebug(), CSCRPCData::setDebug(), CSCDDUEventData::setDebug(), CSCALCTHeader::setDebug(), CSCComparatorData::setDebug(), CSCTMBData::setDebug(), CSCEventData::setDebug(), CSCTMBHeader::setDebug(), CSCDDUEventData::setErrorMask(), SuppressZeroLCT, unpackStatusDigis, useCSCShowers_, useExaminer, useFormatStatus, useGEMs_, useRPCs_, useSelectiveUnpacking, visualFEDInspect, and visualFEDShort.

                                                          : numOfEvents(0) {
  // Tracked
  i_token = consumes<FEDRawDataCollection>(pset.getParameter<edm::InputTag>("InputObjects"));
  crateToken = esConsumes<CSCCrateMap, CSCCrateMapRcd>();
  cscmapToken = esConsumes<CSCChamberMap, CSCChamberMapRcd>();

  useExaminer = pset.getParameter<bool>("UseExaminer");
  examinerMask = pset.getParameter<unsigned int>("ExaminerMask");
  useSelectiveUnpacking = pset.getParameter<bool>("UseSelectiveUnpacking");
  errorMask = pset.getParameter<unsigned int>("ErrorMask");
  unpackStatusDigis = pset.getParameter<bool>("UnpackStatusDigis");
  useFormatStatus = pset.getParameter<bool>("UseFormatStatus");

  useRPCs_ = pset.getParameter<bool>("useRPCs");
  useGEMs_ = pset.getParameter<bool>("useGEMs");
  useCSCShowers_ = pset.getParameter<bool>("useCSCShowers");

  // Untracked
  printEventNumber = pset.getUntrackedParameter<bool>("PrintEventNumber", true);
  debug = pset.getUntrackedParameter<bool>("Debug", false);
  instantiateDQM = pset.getUntrackedParameter<bool>("runDQM", false);

  // Disable FED/DDU to chamber mapping inconsistency check
  disableMappingCheck = pset.getUntrackedParameter<bool>("DisableMappingCheck", false);
  // Make aware the unpacker that B904 test setup is used (disable mapping inconsistency check)
  b904Setup = pset.getUntrackedParameter<bool>("B904Setup", false);
  b904vmecrate = pset.getUntrackedParameter<int>("B904vmecrate", 1);
  b904dmb = pset.getUntrackedParameter<int>("B904dmb", 3);

  visualFEDInspect = pset.getUntrackedParameter<bool>("VisualFEDInspect", false);
  visualFEDShort = pset.getUntrackedParameter<bool>("VisualFEDShort", false);
  formatedEventDump = pset.getUntrackedParameter<bool>("FormatedEventDump", false);

  SuppressZeroLCT = pset.getUntrackedParameter<bool>("SuppressZeroLCT", true);

  if (instantiateDQM) {
    monitor = edm::Service<CSCMonitorInterface>().operator->();
  }

  produces<CSCWireDigiCollection>("MuonCSCWireDigi");
  produces<CSCStripDigiCollection>("MuonCSCStripDigi");
  produces<CSCComparatorDigiCollection>("MuonCSCComparatorDigi");
  produces<CSCALCTDigiCollection>("MuonCSCALCTDigi");
  produces<CSCCLCTDigiCollection>("MuonCSCCLCTDigi");
  produces<CSCCorrelatedLCTDigiCollection>("MuonCSCCorrelatedLCTDigi");

  if (unpackStatusDigis) {
    produces<CSCCFEBStatusDigiCollection>("MuonCSCCFEBStatusDigi");
    produces<CSCTMBStatusDigiCollection>("MuonCSCTMBStatusDigi");
    produces<CSCDMBStatusDigiCollection>("MuonCSCDMBStatusDigi");
    produces<CSCALCTStatusDigiCollection>("MuonCSCALCTStatusDigi");
    produces<CSCDDUStatusDigiCollection>("MuonCSCDDUStatusDigi");
    produces<CSCDCCStatusDigiCollection>("MuonCSCDCCStatusDigi");
  }

  if (useFormatStatus) {
    produces<CSCDCCFormatStatusDigiCollection>("MuonCSCDCCFormatStatusDigi");
  }

  if (useRPCs_) {
    produces<CSCRPCDigiCollection>("MuonCSCRPCDigi");
  }

  if (useGEMs_) {
    produces<GEMPadDigiClusterCollection>("MuonGEMPadDigiCluster");
  }

  if (useCSCShowers_) {
    produces<CSCShowerDigiCollection>("MuonCSCShowerDigi");
    produces<CSCShowerDigiCollection>("MuonCSCShowerDigiAnode");
    produces<CSCShowerDigiCollection>("MuonCSCShowerDigiCathode");
    produces<CSCShowerDigiCollection>("MuonCSCShowerDigiAnodeALCT");
  }

  //CSCAnodeData::setDebug(debug);
  CSCALCTHeader::setDebug(debug);
  CSCComparatorData::setDebug(debug);
  CSCEventData::setDebug(debug);
  CSCTMBData::setDebug(debug);
  CSCDCCEventData::setDebug(debug);
  CSCDDUEventData::setDebug(debug);
  CSCTMBHeader::setDebug(debug);
  CSCRPCData::setDebug(debug);
  CSCDDUEventData::setErrorMask(errorMask);
}

~CSCDCCUnpacker()

CSCDCCUnpacker::~CSCDCCUnpacker ( )

override

Destructor.

Definition at line 206 of file CSCDCCUnpacker.cc.

                                {
  //fill destructor here
}

Member Function Documentation

fillDescriptions()

void CSCDCCUnpacker::fillDescriptions ( edm::ConfigurationDescriptions &  descriptions )

static

Definition at line 210 of file CSCDCCUnpacker.cc.

References edm::ConfigurationDescriptions::add(), submitPVResolutionJobs::desc, ProducerED_cfi::InputTag, and edm::ConfigurationDescriptions::setComment().

                                                                                {
  edm::ParameterSetDescription desc;
  desc.add<edm::InputTag>("InputObjects", edm::InputTag("rawDataCollector"))
      ->setComment("# Define input to the unpacker");
  desc.add<bool>("UseExaminer", true)
      ->setComment("# Use CSC examiner to check for corrupt or semi-corrupt data & avoid unpacker crashes");
  desc.add<unsigned int>("ExaminerMask", 535557110)->setComment("# This mask is needed by the examiner");
  desc.add<bool>("UseSelectiveUnpacking", true)
      ->setComment("# Use Examiner to unpack good chambers and skip only bad ones");
  desc.add<unsigned int>("ErrorMask", 0)->setComment("# This mask simply reduces error reporting");
  desc.add<bool>("UnpackStatusDigis", false)->setComment("# Unpack general status digis?");
  desc.add<bool>("UseFormatStatus", true)->setComment("# Unpack FormatStatus digi?");
  desc.add<bool>("useRPCs", false)->setComment("Unpack RPC data");
  desc.add<bool>("useGEMs", true)->setComment("Unpack GEM trigger data");
  desc.add<bool>("useCSCShowers", true)->setComment("Unpack CSCShower trigger data");
  desc.addUntracked<bool>("Debug", false)->setComment("# Turn on lots of output");
  desc.addUntracked<bool>("PrintEventNumber", false);
  desc.addUntracked<bool>("runDQM", false);
  desc.addUntracked<bool>("VisualFEDInspect", false)->setComment("# Visualization of raw data in corrupted events");
  desc.addUntracked<bool>("VisualFEDShort", false)->setComment("# Visualization of raw data in corrupted events");
  desc.addUntracked<bool>("FormatedEventDump", false);
  desc.addUntracked<bool>("SuppressZeroLCT", true);
  desc.addUntracked<bool>("DisableMappingCheck", false)
      ->setComment("# Disable FED/DDU to chamber mapping inconsistency check");
  desc.addUntracked<bool>("B904Setup", false)->setComment("# Make the unpacker aware of B904 test setup configuration");
  desc.addUntracked<int>("B904vmecrate", 1)->setComment("# Set vmecrate number for chamber used in B904 test setup");
  desc.addUntracked<int>("B904dmb", 3)->setComment("# Set dmb slot for chamber used in B904 test setup");
  descriptions.add("muonCSCDCCUnpacker", desc);
  descriptions.setComment(" This is the generic cfi file for CSC unpacking");
}

produce()

void CSCDCCUnpacker::produce ( edm::Event &  e, const edm::EventSetup &  c  )

override

Produce digis out of raw data.

access database for mapping

Get a handle to the FED data collection

create the collections of CSC digis

uncomment this for regional unpacking if (id!=SOME_ID) continue;
































Take a reference to this FED's data

if fed has data then unpack it

examine event for integrity

If we have DCC or only DDU FED by checking FED ID set examiner to uswe DCC or DDU mode

Visualization of raw data

get a pointer to data and pass it to constructor for unpacking

set default detid to that for E=+z, S=1, R=1, C=1, L=1

get a reference to dduData

DCC Trailer 2 added to dcc status product (to access TTS from DCC)

skip the DDU if its data has serious errors define a mask for serious errors






















DDU Trailer 0 added to ddu status product (to access TTS from DDU)

get a reference to chamber data

first process chamber-wide digis such as LCT

default value for all digis not related to cfebs

layer=0 flags entire chamber

For Post-LS1 readout only. Check Chamber->FED/DDU mapping consistency. Skip chambers (special case of data corruption), which report wrong ID and pose as different chamber
















Do not skip chamber data if mapping check is disabled or b904 setup data file is used

check alct data integrity

fill alct digi

fill Run3 anode HMT Shower digis anode shower digis vector per ALCT BX from ALCT data












check tmb data integrity

fill correlatedlct and clct digis

fill Run3 HMT Shower digis

(O)TMB Shower digi sent to MPC LCT trigger data

anode shower digis from OTMB header data

cathode shower digis from OTMB header data

fill CSC-RPC or CSC-GEMs digis

fill CSC-GEM GEMPadCluster digis

fill cfeb status digi

loop over status digis

fill dmb status digi

fill wire, strip and comparator digis...

set layer, dmb and vme are valid because already checked in line 240

Definition at line 241 of file CSCDCCUnpacker.cc.

References b904dmb, b904Setup, b904vmecrate, visDQMUpload::buf, HltBtagPostValidation_cff::c, RPCNoise_example::check, CSCDCCExaminer::check(), crateToken, CSCDCCExaminer::crcALCT(), CSCDCCExaminer::crcCFEB(), CSCDCCExaminer::crcTMB(), cscmapToken, FEDRawData::data(), data, CSCChamberMap::ddu(), debug, CSCCrateMap::detId(), disableMappingCheck, MillePedeFileConverter_cfg::e, CSCDCCExaminer::errName(), errorMask, CSCDCCExaminer::errors(), CSCDCCExaminer::errorsDetailed(), CSCDCCExaminer::errorsDetailedDDU(), examinerMask, FEDRawDataCollection::FEDData(), formatedEventDump, CSCDCCExaminer::getMask(), goodEvent, RecoTauValidation_cfi::header, mps_fire::i, i_token, l1ctLayer2EG_cff::id, hcalRecHitTable_cff::ieta, instantiateDQM, createfilelist::int, CSCShowerDigi::isValid(), sistrip::SpyUtilities::isValid(), nano_mu_digi_cff::layer, LogTrace, CSCConstants::MAX_CFEBS_RUN2, FEDNumbering::MAXCSCDDUFEDID, FEDNumbering::MAXCSCFEDID, CSCDetId::maxLayerId(), FEDNumbering::MINCSCDDUFEDID, FEDNumbering::MINCSCFEDID, CSCDetId::minLayerId(), CSCDCCExaminer::modeDDU(), monitor, eostools::move(), CSCDCCExaminer::nERRORS, numOfEvents, CSCDCCExaminer::payloadDetailed(), printEventNumber, CSCMonitorInterface::process(), edm::ESHandle< T >::product(), CSCDCCExaminer::setMask(), FEDRawData::size(), CSCDCCExaminer::statusDetailed(), SuppressZeroLCT, unpackStatusDigis, useCSCShowers_, useExaminer, useFormatStatus, useGEMs_, useRPCs_, useSelectiveUnpacking, visual_raw(), visualFEDInspect, and visualFEDShort.

                                                                {
  // Do we really have to do this every event???
  // ... Yes, because framework is more efficient than you are at caching :)
  // (But if you want to actually DO something specific WHEN the mapping changes, check out ESWatcher)
  edm::ESHandle<CSCCrateMap> hcrate = c.getHandle(crateToken);
  const CSCCrateMap* pcrate = hcrate.product();

  // Need access to CSCChamberMap for chamber<->FED/DDU mapping consistency checks
  edm::ESHandle<CSCChamberMap> cscmap = c.getHandle(cscmapToken);
  const CSCChamberMap* cscmapping = cscmap.product();

  if (printEventNumber)
    ++numOfEvents;

  edm::Handle<FEDRawDataCollection> rawdata;
  e.getByToken(i_token, rawdata);

  auto wireProduct = std::make_unique<CSCWireDigiCollection>();
  auto stripProduct = std::make_unique<CSCStripDigiCollection>();
  auto alctProduct = std::make_unique<CSCALCTDigiCollection>();
  auto clctProduct = std::make_unique<CSCCLCTDigiCollection>();
  auto comparatorProduct = std::make_unique<CSCComparatorDigiCollection>();
  auto rpcProduct = std::make_unique<CSCRPCDigiCollection>();
  auto corrlctProduct = std::make_unique<CSCCorrelatedLCTDigiCollection>();
  auto cfebStatusProduct = std::make_unique<CSCCFEBStatusDigiCollection>();
  auto dmbStatusProduct = std::make_unique<CSCDMBStatusDigiCollection>();
  auto tmbStatusProduct = std::make_unique<CSCTMBStatusDigiCollection>();
  auto dduStatusProduct = std::make_unique<CSCDDUStatusDigiCollection>();
  auto dccStatusProduct = std::make_unique<CSCDCCStatusDigiCollection>();
  auto alctStatusProduct = std::make_unique<CSCALCTStatusDigiCollection>();

  auto formatStatusProduct = std::make_unique<CSCDCCFormatStatusDigiCollection>();

  auto gemProduct = std::make_unique<GEMPadDigiClusterCollection>();

  auto lctShowerProduct =
      std::make_unique<CSCShowerDigiCollection>();  // HMT shower objects from OTMB/MPC LCT trigger data frames
  auto anodeShowerProductOTMB =
      std::make_unique<CSCShowerDigiCollection>();  // anode HMT shower objects from (O)TMB header data (matched at OTMB)
  auto cathodeShowerProductOTMB =
      std::make_unique<CSCShowerDigiCollection>();  // cathode HMT shower objects from (O)TMB header data
  auto anodeShowerProductALCT = std::make_unique<
      CSCShowerDigiCollection>();  // anode HMT shower objects from ALCT data (vector of HMT shower objects per ALCT BX)

  // If set selective unpacking mode
  // hardcoded examiner mask below to check for DCC and DDU level errors will be used first
  // then examinerMask for CSC level errors will be used during unpacking of each CSC block
  unsigned long dccBinCheckMask = 0x06080016;

  // Post-LS1 FED/DDU ID mapping fix
  const unsigned postLS1_map[] = {841, 842, 843, 844, 845, 846, 847, 848, 849, 831, 832, 833,
                                  834, 835, 836, 837, 838, 839, 861, 862, 863, 864, 865, 866,
                                  867, 868, 869, 851, 852, 853, 854, 855, 856, 857, 858, 859};

  // For new CSC readout layout, which wont include DCCs need to loop over DDU FED IDs. DCC IDs are included for backward compatibility with old data
  std::vector<unsigned int> cscFEDids;

  for (unsigned int id = FEDNumbering::MINCSCFEDID; id <= FEDNumbering::MAXCSCFEDID; ++id)  // loop over DCCs
  {
    cscFEDids.push_back(id);
  }

  for (unsigned int id = FEDNumbering::MINCSCDDUFEDID; id <= FEDNumbering::MAXCSCDDUFEDID; ++id)  // loop over DDUs
  {
    cscFEDids.push_back(id);
  }

  for (unsigned int i = 0; i < cscFEDids.size(); i++)  // loop over all CSC FEDs (DCCs and DDUs)
  {
    unsigned int id = cscFEDids[i];
    bool isDDU_FED = ((id >= FEDNumbering::MINCSCDDUFEDID) && (id <= FEDNumbering::MAXCSCDDUFEDID)) ? true : false;


    const FEDRawData& fedData = rawdata->FEDData(id);
    unsigned long length = fedData.size();

    if (length >= 32)  
    {
      CSCDCCExaminer* examiner = nullptr;
      goodEvent = true;
      if (useExaminer)  
      {
        // CSCDCCExaminer examiner;
        examiner = new CSCDCCExaminer();
        if (examinerMask & 0x40000)
          examiner->crcCFEB(true);
        if (examinerMask & 0x8000)
          examiner->crcTMB(true);
        if (examinerMask & 0x0400)
          examiner->crcALCT(true);
        examiner->setMask(examinerMask);

        if (isDDU_FED) {
          if (examiner != nullptr)
            examiner->modeDDU(true);
        }

        const short unsigned int* data = (short unsigned int*)fedData.data();

        LogTrace("badData") << "Length: " << length / 2;
        // Event data hex dump
        /*
              short unsigned * buf = (short unsigned int *)fedData.data();
                std::cout <<std::endl<<length/2<<" words of data:"<<std::endl;
                for (short unsigned int i=0;i<length/2;i++) {
                printf("%04x %04x %04x %04x\n",buf[i+3],buf[i+2],buf[i+1],buf[i]);
                i+=3;
                }
                      */

        int res = examiner->check(data, long(fedData.size() / 2));
        if (res < 0) {
          goodEvent = false;
        } else {
          if (useSelectiveUnpacking)
            goodEvent = !(examiner->errors() & dccBinCheckMask);
          else
            goodEvent = !(examiner->errors() & examinerMask);
        }

        /*
        std::cout << "FED" << std::dec << id << " size:" << fedData.size() << " good:" << goodEvent << " errs 0x"
              << std::hex << examiner->errors() << std::dec << std::endl;
         */

        // Fill Format status digis per FED
        // Remove examiner->errors() != 0 check if we need to put status digis for every event
        if (useFormatStatus && (examiner->errors() != 0))
          // formatStatusProduct->insertDigi(CSCDetId(1,1,1,1,1), CSCDCCFormatStatusDigi(id,examiner,dccBinCheckMask));
          formatStatusProduct->insertDigi(CSCDetId(1, 1, 1, 1, 1),
                                          CSCDCCFormatStatusDigi(id,
                                                                 dccBinCheckMask,
                                                                 examiner->getMask(),
                                                                 examiner->errors(),
                                                                 examiner->errorsDetailedDDU(),
                                                                 examiner->errorsDetailed(),
                                                                 examiner->payloadDetailed(),
                                                                 examiner->statusDetailed()));
      }

      if (visualFEDInspect || formatedEventDump) {
        if (!goodEvent || formatedEventDump) {
          short unsigned* buf = (short unsigned int*)fedData.data();
          visual_raw(length / 2, id, (int)e.id().run(), (int)e.id().event(), visualFEDShort, formatedEventDump, buf);
        }
      }

      if (goodEvent) {

        CSCDCCExaminer* ptrExaminer = examiner;
        if (!useSelectiveUnpacking)
          ptrExaminer = nullptr;

        std::vector<CSCDDUEventData> fed_Data;
        std::vector<CSCDDUEventData>* ptr_fedData = &fed_Data;

        CSCDetId layer(1, 1, 1, 1, 1);

        if (isDDU_FED)  // Use new DDU FED readout mode
        {
          CSCDDUEventData single_dduData((short unsigned int*)fedData.data(), ptrExaminer);
          fed_Data.push_back(single_dduData);

          // if(instantiateDQM) monitor->process(examiner, &single_dduData);

        } else  // Use old DCC FED readout mode
        {
          CSCDCCEventData dccData((short unsigned int*)fedData.data(), ptrExaminer);

          //std::cout << " DCC Size [UNPK] " << dccData.sizeInWords() << std::endl;

          if (instantiateDQM)
            monitor->process(examiner, &dccData);

          // const std::vector<CSCDDUEventData> & dduData = dccData.dduData();
          // ptr_fedData = &(dccData.dduData());
          fed_Data = dccData.dduData();

          if (unpackStatusDigis) {
            short unsigned* bufForDcc = (short unsigned int*)fedData.data();

            //std::cout << "FED Length: " << std::dec << length/2 <<
            //" Trailer 2: " << std::hex << bufForDcc[length/2-4] << std::endl;

            dccStatusProduct->insertDigi(layer,
                                         CSCDCCStatusDigi(dccData.dccHeader().data(),
                                                          dccData.dccTrailer().data(),
                                                          examiner->errors(),
                                                          bufForDcc[length / 2 - 4]));
          }
        }

        const std::vector<CSCDDUEventData>& dduData = *ptr_fedData;

        for (unsigned int iDDU = 0; iDDU < dduData.size(); ++iDDU)  // loop over DDUs
        {
          if (dduData[iDDU].trailer().errorstat() & errorMask) {
            LogTrace("CSCDCCUnpacker|CSCRawToDigi")
                << "FED ID" << id << " DDU# " << iDDU << " has serious error - no digis unpacked! " << std::hex
                << dduData[iDDU].trailer().errorstat();
            continue;  // to next iteration of DDU loop
          }

          if (unpackStatusDigis)
            dduStatusProduct->insertDigi(
                layer,
                CSCDDUStatusDigi(dduData[iDDU].header().data(),
                                 dduData[iDDU].trailer().data(),
                                 dduData[iDDU].trailer0()));

          const std::vector<CSCEventData>& cscData = dduData[iDDU].cscData();

          // if (cscData.size() != 0) std::cout << "FED" << id << " DDU Source ID: " << dduData[iDDU].header().source_id() << " firmware version: " << dduData[iDDU].header().format_version() << std::endl;

          for (unsigned int iCSC = 0; iCSC < cscData.size(); ++iCSC)  // loop over CSCs
          {

            int vmecrate = b904Setup ? b904vmecrate : cscData[iCSC].dmbHeader()->crateID();
            int dmb = b904Setup ? b904dmb : cscData[iCSC].dmbHeader()->dmbID();

            int icfeb = 0;   
            int ilayer = 0;  

            if (debug)
              LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "crate = " << vmecrate << "; dmb = " << dmb;

            if ((vmecrate >= 1) && (vmecrate <= 60) && (dmb >= 1) && (dmb <= 10) && (dmb != 6)) {
              layer = pcrate->detId(vmecrate, dmb, icfeb, ilayer);
            } else {
              LogTrace("CSCDCCUnpacker|CSCRawToDigi") << " detID input out of range!!! ";
              LogTrace("CSCDCCUnpacker|CSCRawToDigi") << " skipping chamber vme= " << vmecrate << " dmb= " << dmb;
              continue;  // to next iteration of iCSC loop
            }

            if (isDDU_FED) {
              unsigned int dduid = cscmapping->ddu(layer);
              if ((dduid >= 1) && (dduid <= 36)) {
                dduid = postLS1_map[dduid - 1];  // Fix for Post-LS1 FED/DDU IDs mappings
                // std::cout << "CSC " << layer << " -> " << id << ":" << dduid << ":" << vmecrate << ":" << dmb << std::endl;
              }

              if ((!disableMappingCheck) && (!b904Setup) && (id != dduid)) {
                LogTrace("CSCDDUUnpacker|CSCRawToDigi") << " CSC->FED/DDU mapping inconsistency!!! ";
                LogTrace("CSCDCCUnpacker|CSCRawToDigi")
                    << "readout FED/DDU ID=" << id << " expected ID=" << dduid << ", skipping chamber " << layer
                    << " vme= " << vmecrate << " dmb= " << dmb;
                continue;
              }
            }

            int nalct = cscData[iCSC].dmbHeader()->nalct();
            bool goodALCT = false;
            //if (nalct&&(cscData[iCSC].dataPresent>>6&0x1)==1) {
            if (nalct && cscData[iCSC].alctHeader()) {
              if (cscData[iCSC].alctHeader()->check()) {
                goodALCT = true;
              } else {
                LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "not storing ALCT digis; alct is bad or not present";
              }
            } else {
              if (debug)
                LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "nALCT==0 !!!";
            }

            if (goodALCT) {
              std::vector<CSCALCTDigi> alctDigis = cscData[iCSC].alctHeader()->ALCTDigis();
              if (SuppressZeroLCT) {
                std::vector<CSCALCTDigi> alctDigis_0;
                for (int unsigned i = 0; i < alctDigis.size(); ++i) {
                  if (alctDigis[i].isValid()) {
                    if (debug)
                      LogTrace("CSCDCCUnpacker|CSCRawToDigi") << alctDigis[i] << std::endl;
                    alctDigis_0.push_back(alctDigis[i]);
                  }
                }
                alctProduct->move(std::make_pair(alctDigis_0.begin(), alctDigis_0.end()), layer);
              } else
                alctProduct->move(std::make_pair(alctDigis.begin(), alctDigis.end()), layer);

              if (useCSCShowers_) {
                std::vector<CSCShowerDigi> anodeShowerDigisALCT = cscData[iCSC].alctHeader()->alctShowerDigis();
                anodeShowerProductALCT->move(std::make_pair(anodeShowerDigisALCT.begin(), anodeShowerDigisALCT.end()),
                                             layer);
              }
            }

            int nclct = cscData[iCSC].dmbHeader()->nclct();
            bool goodTMB = false;
            //      if (nclct&&(cscData[iCSC].dataPresent>>5&0x1)==1) {
            if (nclct && cscData[iCSC].tmbData()) {
              if (cscData[iCSC].tmbHeader()->check()) {
                if (cscData[iCSC].comparatorData()->check())
                  goodTMB = true;
              } else {
                LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "one of TMB checks failed! not storing TMB digis ";
              }
            } else {
              if (debug)
                LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "nCLCT==0 !!!";
            }

            if (goodTMB) {
              std::vector<CSCCorrelatedLCTDigi> correlatedlctDigis =
                  cscData[iCSC].tmbHeader()->CorrelatedLCTDigis(layer.rawId());
              if (SuppressZeroLCT) {
                std::vector<CSCCorrelatedLCTDigi> correlatedlctDigis_0;
                for (int unsigned i = 0; i < correlatedlctDigis.size(); ++i) {
                  if (correlatedlctDigis[i].isValid()) {
                    if (debug)
                      LogTrace("CSCDCCUnpacker|CSCRawToDigi") << correlatedlctDigis[i] << std::endl;
                    correlatedlctDigis_0.push_back(correlatedlctDigis[i]);
                  }
                }
                corrlctProduct->move(std::make_pair(correlatedlctDigis_0.begin(), correlatedlctDigis_0.end()), layer);
              } else
                corrlctProduct->move(std::make_pair(correlatedlctDigis.begin(), correlatedlctDigis.end()), layer);

              std::vector<CSCCLCTDigi> clctDigis = cscData[iCSC].tmbHeader()->CLCTDigis(layer.rawId());
              if (SuppressZeroLCT) {
                std::vector<CSCCLCTDigi> clctDigis_0;
                for (int unsigned i = 0; i < clctDigis.size(); ++i) {
                  if (clctDigis[i].isValid()) {
                    if (debug)
                      LogTrace("CSCDCCUnpacker|CSCRawToDigi") << clctDigis[i] << std::endl;
                    clctDigis_0.push_back(clctDigis[i]);
                  }
                }
                clctProduct->move(std::make_pair(clctDigis_0.begin(), clctDigis_0.end()), layer);
              } else
                clctProduct->move(std::make_pair(clctDigis.begin(), clctDigis.end()), layer);

              if (useCSCShowers_) {
                CSCShowerDigi lctShowerDigi = cscData[iCSC].tmbHeader()->showerDigi(layer.rawId());
                if (lctShowerDigi.isValid()) {
                  std::vector<CSCShowerDigi> lctShowerDigis;
                  lctShowerDigis.push_back(lctShowerDigi);
                  lctShowerProduct->move(std::make_pair(lctShowerDigis.begin(), lctShowerDigis.end()), layer);
                }

                CSCShowerDigi anodeShowerDigiOTMB = cscData[iCSC].tmbHeader()->anodeShowerDigi(layer.rawId());
                if (anodeShowerDigiOTMB.isValid()) {
                  std::vector<CSCShowerDigi> anodeShowerDigis;
                  anodeShowerDigis.push_back(anodeShowerDigiOTMB);
                  anodeShowerProductOTMB->move(std::make_pair(anodeShowerDigis.begin(), anodeShowerDigis.end()), layer);
                }

                CSCShowerDigi cathodeShowerDigiOTMB = cscData[iCSC].tmbHeader()->cathodeShowerDigi(layer.rawId());
                if (cathodeShowerDigiOTMB.isValid()) {
                  std::vector<CSCShowerDigi> cathodeShowerDigis;
                  cathodeShowerDigis.push_back(cathodeShowerDigiOTMB);
                  cathodeShowerProductOTMB->move(std::make_pair(cathodeShowerDigis.begin(), cathodeShowerDigis.end()),
                                                 layer);
                }
              }

              if (cscData[iCSC].tmbData()->checkSize()) {
                if (useRPCs_ && cscData[iCSC].tmbData()->hasRPC()) {
                  std::vector<CSCRPCDigi> rpcDigis = cscData[iCSC].tmbData()->rpcData()->digis();
                  rpcProduct->move(std::make_pair(rpcDigis.begin(), rpcDigis.end()), layer);
                }

                if (useGEMs_ && cscData[iCSC].tmbData()->hasGEM()) {
                  for (int unsigned igem = 0; igem < (int unsigned)(cscData[iCSC].tmbData()->gemData()->numGEMs());
                       ++igem) {
                    int gem_chamber = layer.chamber();
                    int gem_region = (layer.endcap() == 1) ? 1 : -1;
                    // Loop over GEM layer eta/rolls
                    for (unsigned ieta = 0; ieta < 8; ieta++) {
                      // GE11 eta/roll collection addressing according to GEMDetID definition is 1-8 (eta 8 being closest to beampipe)
                      GEMDetId gemid(gem_region, layer.ring(), layer.station(), igem + 1, gem_chamber, ieta + 1);
                      // GE11 trigger data format reports eta/rolls in 0-7 range (eta 0 being closest to beampipe)
                      // mapping agreement is that real data eta needs to be reversed from 0-7 to 8-1 for GEMDetId collection convention
                      std::vector<GEMPadDigiCluster> gemDigis = cscData[iCSC].tmbData()->gemData()->etaDigis(
                          igem, 7 - ieta, cscData[iCSC].tmbHeader()->ALCTMatchTime());
                      if (!gemDigis.empty()) {
                        gemProduct->move(std::make_pair(gemDigis.begin(), gemDigis.end()), gemid);
                      }
                    }
                  }
                }
              } else
                LogTrace("CSCDCCUnpacker|CSCRawToDigi") << " TMBData check size failed!";
            }

            if (unpackStatusDigis) {
              for (icfeb = 0; icfeb < CSCConstants::MAX_CFEBS_RUN2; ++icfeb)  
              {
                if (cscData[iCSC].cfebData(icfeb) != nullptr)
                  cfebStatusProduct->insertDigi(layer, cscData[iCSC].cfebData(icfeb)->statusDigi());
              }
              dmbStatusProduct->insertDigi(
                  layer, CSCDMBStatusDigi(cscData[iCSC].dmbHeader()->data(), cscData[iCSC].dmbTrailer()->data()));
              if (goodTMB)
                tmbStatusProduct->insertDigi(
                    layer,
                    CSCTMBStatusDigi(cscData[iCSC].tmbHeader()->data(), cscData[iCSC].tmbData()->tmbTrailer()->data()));
              if (goodALCT)
                alctStatusProduct->insertDigi(
                    layer, CSCALCTStatusDigi(cscData[iCSC].alctHeader()->data(), cscData[iCSC].alctTrailer()->data()));
            }

            for (int ilayer = CSCDetId::minLayerId(); ilayer <= CSCDetId::maxLayerId(); ++ilayer) {
              // (You have to be kidding. Line 240 in whose universe?)

              // Allocate all ME1/1 wire digis to ring 1
              layer = pcrate->detId(vmecrate, dmb, 0, ilayer);
              {
                std::vector<CSCWireDigi> wireDigis = cscData[iCSC].wireDigis(ilayer);
                wireProduct->move(std::make_pair(wireDigis.begin(), wireDigis.end()), layer);
              }

              for (icfeb = 0; icfeb < CSCConstants::MAX_CFEBS_RUN2; ++icfeb) {
                layer = pcrate->detId(vmecrate, dmb, icfeb, ilayer);
                if (cscData[iCSC].cfebData(icfeb) && cscData[iCSC].cfebData(icfeb)->check()) {
                  std::vector<CSCStripDigi> stripDigis;
                  cscData[iCSC].cfebData(icfeb)->digis(layer.rawId(), stripDigis);
                  stripProduct->move(std::make_pair(stripDigis.begin(), stripDigis.end()), layer);
                }
              }

              if (goodTMB && (cscData[iCSC].tmbHeader() != nullptr)) {
                int nCFEBs = cscData[iCSC].tmbHeader()->NCFEBs();
                for (icfeb = 0; icfeb < nCFEBs; ++icfeb) {
                  layer = pcrate->detId(vmecrate, dmb, icfeb, ilayer);
                  std::vector<CSCComparatorDigi> comparatorDigis =
                      cscData[iCSC].comparatorData()->comparatorDigis(layer.rawId(), icfeb);
                  // Set cfeb=0, so that ME1/a and ME1/b comparators go to
                  // ring 1.
                  layer = pcrate->detId(vmecrate, dmb, 0, ilayer);
                  comparatorProduct->move(std::make_pair(comparatorDigis.begin(), comparatorDigis.end()), layer);
                }
              }  // end of loop over cfebs
            }    // end of loop over layers
          }      // end of loop over chambers
        }        // endof loop over DDUs
      }          // end of good event
      else {
        LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "ERROR! Examiner rejected FED #" << id;
        if (examiner) {
          for (int i = 0; i < examiner->nERRORS; ++i) {
            if (((examinerMask & examiner->errors()) >> i) & 0x1)
              LogTrace("CSCDCCUnpacker|CSCRawToDigi") << examiner->errName(i);
          }
          if (debug) {
            LogTrace("CSCDCCUnpacker|CSCRawToDigi")
                << " Examiner errors:0x" << std::hex << examiner->errors() << " & 0x" << examinerMask << " = "
                << (examiner->errors() & examinerMask);
          }
        }

        // dccStatusProduct->insertDigi(CSCDetId(1,1,1,1,1), CSCDCCStatusDigi(examiner->errors()));
        // if(instantiateDQM)  monitor->process(examiner, NULL);
      }
      if (examiner != nullptr)
        delete examiner;
    }  // end of if fed has data
  }    // end of loop over DCCs
  // put into the event
  e.put(std::move(wireProduct), "MuonCSCWireDigi");
  e.put(std::move(stripProduct), "MuonCSCStripDigi");
  e.put(std::move(alctProduct), "MuonCSCALCTDigi");
  e.put(std::move(clctProduct), "MuonCSCCLCTDigi");
  e.put(std::move(comparatorProduct), "MuonCSCComparatorDigi");
  e.put(std::move(corrlctProduct), "MuonCSCCorrelatedLCTDigi");

  if (useFormatStatus)
    e.put(std::move(formatStatusProduct), "MuonCSCDCCFormatStatusDigi");

  if (unpackStatusDigis) {
    e.put(std::move(cfebStatusProduct), "MuonCSCCFEBStatusDigi");
    e.put(std::move(dmbStatusProduct), "MuonCSCDMBStatusDigi");
    e.put(std::move(tmbStatusProduct), "MuonCSCTMBStatusDigi");
    e.put(std::move(dduStatusProduct), "MuonCSCDDUStatusDigi");
    e.put(std::move(dccStatusProduct), "MuonCSCDCCStatusDigi");
    e.put(std::move(alctStatusProduct), "MuonCSCALCTStatusDigi");
  }

  if (useRPCs_) {
    e.put(std::move(rpcProduct), "MuonCSCRPCDigi");
  }
  if (useGEMs_) {
    e.put(std::move(gemProduct), "MuonGEMPadDigiCluster");
  }
  if (useCSCShowers_) {
    e.put(std::move(lctShowerProduct), "MuonCSCShowerDigi");
    e.put(std::move(anodeShowerProductOTMB), "MuonCSCShowerDigiAnode");
    e.put(std::move(cathodeShowerProductOTMB), "MuonCSCShowerDigiCathode");
    e.put(std::move(anodeShowerProductALCT), "MuonCSCShowerDigiAnodeALCT");
  }
  if (printEventNumber)
    LogTrace("CSCDCCUnpacker|CSCRawToDigi") << "[CSCDCCUnpacker]: " << numOfEvents << " events processed ";
}

visual_raw()

void CSCDCCUnpacker::visual_raw	(	int	hl,
		int	id,
		int	run,
		int	event,
		bool	fedshort,
		bool	fDump,
		short unsigned int *	buf
	)		const

Visualization of raw data in FED-less events (Robert Harr and Alexander Sakharov)

Visualization of raw data.

ALCT Header 1,2

Definition at line 772 of file CSCDCCUnpacker.cc.

References visDQMUpload::buf, gather_cfg::cout, formatedEventDump, mps_fire::i, dqmiolumiharvest::j, dqmdumpme::k, GetRecoTauVFromDQM_MC_cff::kk, writedatasetfile::run, and w().

Referenced by produce().

                                                                                                  {
  std::cout << std::endl << std::endl << std::endl;
  std::cout << "Run: " << run << " Event: " << event << std::endl;
  std::cout << std::endl << std::endl;
  if (formatedEventDump)
    std::cout << "FED-" << id << "  "
              << "(scroll down to see summary)" << std::endl;
  else
    std::cout << "Problem seems in FED-" << id << "  "
              << "(scroll down to see summary)" << std::endl;
  std::cout << "********************************************************************************" << std::endl;
  std::cout << hl << " words of data:" << std::endl;

  //================================================
  // FED codes in DCC
  std::vector<int> dcc_id;
  int dcc_h1_id = 0;
  // Current codes
  for (int i = 750; i < 758; i++)
    dcc_id.push_back(i);
  // Codes for upgrade
  for (int i = 830; i < 838; i++)
    dcc_id.push_back(i);

  char dcc_common[] = "DCC-";

  //================================================
  // DDU codes per FED
  std::vector<int> ddu_id;
  int ddu_h1_12_13 = 0;
  for (int i = 1; i < 37; i++)
    ddu_id.push_back(i);
  // For DDU Headers and tarailers
  char ddu_common[] = "DDU-";
  char ddu_header1[] = "Header 1";
  char ddu_header2[] = "Header 2";
  char ddu_header3[] = "Header 3";
  char ddu_trail1[] = "Trailer 1", ddu_trail2[] = "Trailer 2", ddu_trail3[] = "Trailer 3";
  // For Header 2
  char ddu_trailer1_bit[] = {'8', '0', '0', '0', 'f', 'f', 'f', 'f', '8', '0', '0', '0', '8', '0', '0', '0'};
  char ddu_trailer3_bit[] = {'a'};
  // Corrupted Trailers
  char ddu_tr1_err_common[] = "Incomplet";
  //====================================================

  //DMB
  char dmb_common[] = "DMB", dmb_header1[] = "Header 1", dmb_header2[] = "Header 2";
  char dmb_common_crate[] = "crate:", dmb_common_slot[] = "slot:";
  char dmb_common_l1a[] = "L1A:";
  char dmb_header1_bit[] = {'9', '9', '9', '9'};
  char dmb_header2_bit[] = {'a', 'a', 'a', 'a'};
  char dmb_tr1[] = "Trailer 1", dmb_tr2[] = "Trailer 2";
  char dmb_tr1_bit[] = {'f', 'f', 'f', 'f'}, dmb_tr2_bit[] = {'e', 'e', 'e', 'e'};

  //=====================================================

  // ALCT
  char alct_common[] = "ALCT", alct_header1[] = "Header 1", alct_header2[] = "Header 2";
  char alct_common_bxn[] = "BXN:";
  char alct_common_wcnt2[] = "| Actual word count:";
  char alct_common_wcnt1[] = "Expected word count:";
  char alct_header1_bit[] = {'d', 'd', 'd', 'd', 'b', '0', 'a'};
  char alct_header2_bit[] = {'0', '0', '0', '0'};
  char alct_tr1[] = "Trailer 1";

  //======================================================

  //TMB
  char tmb_common[] = "TMB", tmb_header1[] = "Header", tmb_tr1[] = "Trailer";
  char tmb_header1_bit[] = {'d', 'd', 'd', 'd', 'b', '0', 'c'};
  char tmb_tr1_bit[] = {'d', 'd', 'd', 'd', 'e', '0', 'f'};

  //======================================================

  //CFEB
  char cfeb_common[] = "CFEB", cfeb_tr1[] = "Trailer", cfeb_b[] = "B-word";
  char cfeb_common_sample[] = "sample:";

  //======================================================

  //Auxiliary variables

  // Bufers
  int word_lines = hl / 4;
  char tempbuf[80];
  char tempbuf1[130];
  char tempbuf_short[17];
  char sign1[] = "  --->| ";

  // Counters
  int word_numbering = 0;
  int ddu_inst_i = 0, ddu_inst_n = 0, ddu_inst_l1a = 0;
  int ddu_inst_bxn = 0;
  int dmb_inst_crate = 0, dmb_inst_slot = 0, dmb_inst_l1a = 0;
  int cfeb_sample = 0;
  int alct_inst_l1a = 0;
  int alct_inst_bxn = 0;
  int alct_inst_wcnt1 = 0;
  int alct_inst_wcnt2 = 0;
  int alct_start = 0;
  int alct_stop = 0;
  int tmb_inst_l1a = 0;
  int tmb_inst_wcnt1 = 0;
  int tmb_inst_wcnt2 = 0;
  int tmb_start = 0;
  int tmb_stop = 0;
  int dcc_h1_check = 0;

  //Flags
  int w = 0;

  //Logic variables
  const int sz1 = 5;
  bool dcc_check = false;
  bool ddu_h2_check[sz1] = {false};
  bool ddu_h1_check = false;
  bool dmb_h1_check[sz1] = {false};
  bool dmb_h2_check[sz1] = {false};
  bool ddu_h2_h1 = false;
  bool ddu_tr1_check[sz1] = {false};
  bool alct_h1_check[sz1] = {false};
  bool alct_h2_check[sz1] = {false};
  bool alct_tr1_check[sz1] = {false};
  bool dmb_tr1_check[sz1] = {false};
  bool dmb_tr2_check[sz1] = {false};
  bool tmb_h1_check[sz1] = {false};
  bool tmb_tr1_check[sz1] = {false};
  bool cfeb_tr1_check[sz1] = {false};
  bool cfeb_b_check[sz1] = {false};
  bool ddu_tr1_bad_check[sz1] = {false};
  bool extraction = fedshort;

  //Summary vectors
  //DDU
  std::vector<int> ddu_h1_coll;
  std::vector<int> ddu_h1_n_coll;
  std::vector<int> ddu_h2_coll;
  std::vector<int> ddu_h3_coll;
  std::vector<int> ddu_t1_coll;
  std::vector<int> ddu_t2_coll;
  std::vector<int> ddu_t3_coll;
  std::vector<int> ddu_l1a_coll;
  std::vector<int> ddu_bxn_coll;
  //DMB
  std::vector<int> dmb_h1_coll;
  std::vector<int> dmb_h2_coll;
  std::vector<int> dmb_t1_coll;
  std::vector<int> dmb_t2_coll;
  std::vector<int> dmb_crate_coll;
  std::vector<int> dmb_slot_coll;
  std::vector<int> dmb_l1a_coll;
  //ALCT
  std::vector<int> alct_h1_coll;
  std::vector<int> alct_h2_coll;
  std::vector<int> alct_t1_coll;
  std::vector<int> alct_l1a_coll;
  std::vector<int> alct_bxn_coll;
  std::vector<int> alct_wcnt1_coll;
  std::vector<int> alct_wcnt2_coll;
  std::vector<int> alct_wcnt2_id_coll;
  //TMB
  std::vector<int> tmb_h1_coll;
  std::vector<int> tmb_t1_coll;
  std::vector<int> tmb_l1a_coll;
  std::vector<int> tmb_wcnt1_coll;
  std::vector<int> tmb_wcnt2_coll;
  //CFEB
  std::vector<int> cfeb_t1_coll;

  //========================================================

  // DCC Header and Ttrailer information
  char dcc_header1[] = "DCC Header 1";
  char dcc_header2[] = "DCC Header 2";
  char dcc_trail1[] = "DCC Trailer 1", dcc_trail1_bit[] = {'e'};
  char dcc_trail2[] = "DCC Trailer 2", dcc_trail2_bit[] = {'a'};
  //=========================================================

  for (int i = 0; i < hl; i++) {
    ++word_numbering;
    for (int j = -1; j < 4; j++) {
      sprintf(tempbuf_short,
              "%04x%04x%04x%04x",
              buf[i + 4 * (j - 1) + 3],
              buf[i + 4 * (j - 1) + 2],
              buf[i + 4 * (j - 1) + 1],
              buf[i + 4 * (j - 1)]);

      // WARNING in 5_0_X for time being
      ddu_h2_check[j] = ((buf[i + 4 * (j - 1) + 1] == 0x8000) && (buf[i + 4 * (j - 1) + 2] == 0x0001) &&
                         (buf[i + 4 * (j - 1) + 3] == 0x8000));

      ddu_tr1_check[j] = ((tempbuf_short[0] == ddu_trailer1_bit[0]) && (tempbuf_short[1] == ddu_trailer1_bit[1]) &&
                          (tempbuf_short[2] == ddu_trailer1_bit[2]) && (tempbuf_short[3] == ddu_trailer1_bit[3]) &&
                          (tempbuf_short[4] == ddu_trailer1_bit[4]) && (tempbuf_short[5] == ddu_trailer1_bit[5]) &&
                          (tempbuf_short[6] == ddu_trailer1_bit[6]) && (tempbuf_short[7] == ddu_trailer1_bit[7]) &&
                          (tempbuf_short[8] == ddu_trailer1_bit[8]) && (tempbuf_short[9] == ddu_trailer1_bit[9]) &&
                          (tempbuf_short[10] == ddu_trailer1_bit[10]) && (tempbuf_short[11] == ddu_trailer1_bit[11]) &&
                          (tempbuf_short[12] == ddu_trailer1_bit[12]) && (tempbuf_short[13] == ddu_trailer1_bit[13]) &&
                          (tempbuf_short[14] == ddu_trailer1_bit[14]) && (tempbuf_short[15] == ddu_trailer1_bit[15]));

      dmb_h1_check[j] = ((tempbuf_short[0] == dmb_header1_bit[0]) && (tempbuf_short[4] == dmb_header1_bit[1]) &&
                         (tempbuf_short[8] == dmb_header1_bit[2]) && (tempbuf_short[12] == dmb_header1_bit[3]));

      dmb_h2_check[j] = ((tempbuf_short[0] == dmb_header2_bit[0]) && (tempbuf_short[4] == dmb_header2_bit[1]) &&
                         (tempbuf_short[8] == dmb_header2_bit[2]) && (tempbuf_short[12] == dmb_header2_bit[3]));
      alct_h1_check[j] = ((tempbuf_short[0] == alct_header1_bit[0]) && (tempbuf_short[4] == alct_header1_bit[1]) &&
                          (tempbuf_short[8] == alct_header1_bit[2]) && (tempbuf_short[12] == alct_header1_bit[3]) &&
                          (tempbuf_short[13] == alct_header1_bit[4]) && (tempbuf_short[14] == alct_header1_bit[5]) &&
                          (tempbuf_short[15] == alct_header1_bit[6]));
      alct_h2_check[j] = (((tempbuf_short[0] == alct_header2_bit[0]) && (tempbuf_short[1] == alct_header2_bit[1]) &&
                           (tempbuf_short[2] == alct_header2_bit[2]) && (tempbuf_short[3] == alct_header2_bit[3])) ||
                          ((tempbuf_short[4] == alct_header2_bit[0]) && (tempbuf_short[5] == alct_header2_bit[1]) &&
                           (tempbuf_short[6] == alct_header2_bit[2]) && (tempbuf_short[7] == alct_header2_bit[3])) ||
                          ((tempbuf_short[8] == alct_header2_bit[0]) && (tempbuf_short[9] == alct_header2_bit[1]) &&
                           (tempbuf_short[10] == alct_header2_bit[2]) && (tempbuf_short[11] == alct_header2_bit[3])) ||
                          ((tempbuf_short[12] == alct_header2_bit[0]) && (tempbuf_short[13] == alct_header2_bit[1]) &&
                           (tempbuf_short[14] == alct_header2_bit[2]) && (tempbuf_short[15] == alct_header2_bit[3]))
                          //(tempbuf_short[4]==alct_header2_bit[4])&&(tempbuf_short[5]==alct_header2_bit[5])
      );
      // ALCT Trailers
      alct_tr1_check[j] =
          (((buf[i + 4 * (j - 1)] & 0xFFFF) == 0xDE0D) && ((buf[i + 4 * (j - 1) + 1] & 0xF800) == 0xD000) &&
           ((buf[i + 4 * (j - 1) + 2] & 0xF800) == 0xD000) && ((buf[i + 4 * (j - 1) + 3] & 0xF000) == 0xD000));
      // DMB Trailers
      dmb_tr1_check[j] = ((tempbuf_short[0] == dmb_tr1_bit[0]) && (tempbuf_short[4] == dmb_tr1_bit[1]) &&
                          (tempbuf_short[8] == dmb_tr1_bit[2]) && (tempbuf_short[12] == dmb_tr1_bit[3]));
      dmb_tr2_check[j] = ((tempbuf_short[0] == dmb_tr2_bit[0]) && (tempbuf_short[4] == dmb_tr2_bit[1]) &&
                          (tempbuf_short[8] == dmb_tr2_bit[2]) && (tempbuf_short[12] == dmb_tr2_bit[3]));
      // TMB
      tmb_h1_check[j] = ((tempbuf_short[0] == tmb_header1_bit[0]) && (tempbuf_short[4] == tmb_header1_bit[1]) &&
                         (tempbuf_short[8] == tmb_header1_bit[2]) && (tempbuf_short[12] == tmb_header1_bit[3]) &&
                         (tempbuf_short[13] == tmb_header1_bit[4]) && (tempbuf_short[14] == tmb_header1_bit[5]) &&
                         (tempbuf_short[15] == tmb_header1_bit[6]));
      tmb_tr1_check[j] = ((tempbuf_short[0] == tmb_tr1_bit[0]) && (tempbuf_short[4] == tmb_tr1_bit[1]) &&
                          (tempbuf_short[8] == tmb_tr1_bit[2]) && (tempbuf_short[12] == tmb_tr1_bit[3]) &&
                          (tempbuf_short[13] == tmb_tr1_bit[4]) && (tempbuf_short[14] == tmb_tr1_bit[5]) &&
                          (tempbuf_short[15] == tmb_tr1_bit[6]));
      // CFEB
      cfeb_tr1_check[j] =
          (((buf[i + 4 * (j - 1) + 1] & 0xF000) == 0x7000) && ((buf[i + 4 * (j - 1) + 2] & 0xF000) == 0x7000) &&
           ((buf[i + 4 * (j - 1) + 1] != 0x7FFF) || (buf[i + 4 * (j - 1) + 2] != 0x7FFF)) &&
           ((buf[i + 4 * (j - 1) + 3] == 0x7FFF) || ((buf[i + 4 * (j - 1) + 3] & buf[i + 4 * (j - 1)]) == 0x0 &&
                                                     (buf[i + 4 * (j - 1) + 3] + buf[i + 4 * (j - 1)] == 0x7FFF))));
      cfeb_b_check[j] =
          (((buf[i + 4 * (j - 1) + 3] & 0xF000) == 0xB000) && ((buf[i + 4 * (j - 1) + 2] & 0xF000) == 0xB000) &&
           ((buf[i + 4 * (j - 1) + 1] & 0xF000) == 0xB000) && ((buf[i + 4 * (j - 1)] = 3 & 0xF000) == 0xB000));
      // DDU Trailers with errors
      ddu_tr1_bad_check[j] =
          ((tempbuf_short[0] != ddu_trailer1_bit[0]) &&
           //(tempbuf_short[1]!=ddu_trailer1_bit[1])&&(tempbuf_short[2]!=ddu_trailer1_bit[2])&&
           //(tempbuf_short[3]==ddu_trailer1_bit[3])&&
           (tempbuf_short[4] != ddu_trailer1_bit[4]) &&
           //(tempbuf_short[5]==ddu_trailer1_bit[5])&&
           //(tempbuf_short[6]==ddu_trailer1_bit[6])&&(tempbuf_short[7]==ddu_trailer1_bit[7])&&
           (tempbuf_short[8] == ddu_trailer1_bit[8]) && (tempbuf_short[9] == ddu_trailer1_bit[9]) &&
           (tempbuf_short[10] == ddu_trailer1_bit[10]) && (tempbuf_short[11] == ddu_trailer1_bit[11]) &&
           (tempbuf_short[12] == ddu_trailer1_bit[12]) && (tempbuf_short[13] == ddu_trailer1_bit[13]) &&
           (tempbuf_short[14] == ddu_trailer1_bit[14]) && (tempbuf_short[15] == ddu_trailer1_bit[15]));
    }

    // DDU Header 2 next to Header 1
    ddu_h2_h1 = ddu_h2_check[2];

    sprintf(tempbuf_short, "%04x%04x%04x%04x", buf[i + 3], buf[i + 2], buf[i + 1], buf[i]);

    // Looking for DDU Header 1
    ddu_h1_12_13 = (buf[i] >> 8);
    for (int kk = 0; kk < 36; kk++) {
      if (((buf[i + 3] & 0xF000) == 0x5000) && (ddu_h1_12_13 == ddu_id[kk]) && ddu_h2_h1) {
        ddu_h1_coll.push_back(word_numbering);
        ddu_h1_n_coll.push_back(ddu_id[kk]);
        ddu_inst_l1a = ((buf[i + 2] & 0xFFFF) + ((buf[i + 3] & 0x00FF) << 16));
        ddu_l1a_coll.push_back(ddu_inst_l1a);
        ddu_inst_bxn = (buf[i + 1] & 0xFFF0) >> 4;
        ddu_bxn_coll.push_back(ddu_inst_bxn);
        sprintf(tempbuf1,
                "%6i    %04x %04x %04x %04x%s%s%i %s%s %s %i %s %i",
                word_numbering,
                buf[i + 3],
                buf[i + 2],
                buf[i + 1],
                buf[i],
                sign1,
                ddu_common,
                ddu_id[kk],
                ddu_header1,
                sign1,
                dmb_common_l1a,
                ddu_inst_l1a,
                alct_common_bxn,
                ddu_inst_bxn);
        std::cout << tempbuf1 << std::endl;
        w = 0;
        ddu_h1_check = true;
        cfeb_sample = 0;
      }
    }

    // Looking for DCC Header 1
    dcc_h1_id = (((buf[i + 1] << 12) & 0xF000) >> 4) + (buf[i] >> 8);
    for (int dcci = 0; dcci < 16; dcci++) {
      if ((dcc_id[dcci] == dcc_h1_id) && (((buf[i + 3] & 0xF000) == 0x5000) && (!ddu_h1_check))) {
        sprintf(tempbuf1,
                "%6i    %04x %04x %04x %04x%s%s%i %s",
                word_numbering,
                buf[i + 3],
                buf[i + 2],
                buf[i + 1],
                buf[i],
                sign1,
                dcc_common,
                dcc_h1_id,
                dcc_header1);
        dcc_h1_check = word_numbering;
        w = 0;
        dcc_check = true;
        std::cout << tempbuf1 << std::endl;
      }
    }

    // Looking for DCC Header 2 and trailers
    if (((word_numbering - 1) == dcc_h1_check) && ((buf[i + 3] & 0xFF00) == 0xD900)) {
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              dcc_header2);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    } else if ((word_numbering == word_lines - 1) && (tempbuf_short[0] == dcc_trail1_bit[0])) {
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              dcc_trail1);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    } else if ((word_numbering == word_lines) && (tempbuf_short[0] == dcc_trail2_bit[0])) {
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              dcc_trail2);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    // DDU Header 2
    else if (ddu_h2_check[1]) {
      ddu_inst_i = ddu_h1_n_coll.size();  //ddu_inst_n=ddu_h1_n_coll[0];
      if (ddu_inst_i > 0) {
        ddu_inst_n = ddu_h1_n_coll[ddu_inst_i - 1];
      }
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s%i %s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              ddu_common,
              ddu_inst_n,
              ddu_header2);
      ddu_h2_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    // DDU Header 3 (either between DDU Header 2 DMB Header or DDU Header 2 DDU Trailer1)
    else if ((ddu_h2_check[0] && dmb_h1_check[2]) || (ddu_h2_check[0] && ddu_tr1_check[2])) {
      ddu_inst_i = ddu_h1_n_coll.size();
      if (ddu_inst_i > 0) {
        ddu_inst_n = ddu_h1_n_coll[ddu_inst_i - 1];
      }
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s%i %s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              ddu_common,
              ddu_inst_n,
              ddu_header3);
      ddu_h3_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    // DMB Header 1,2

    else if (dmb_h1_check[1]) {
      dmb_inst_crate = 0;
      dmb_inst_slot = 0;
      dmb_inst_l1a = ((buf[i] & 0x0FFF) + ((buf[i + 1] & 0xFFF) << 12));
      dmb_l1a_coll.push_back(dmb_inst_l1a);
      if (dmb_h2_check[2]) {
        dmb_inst_crate = ((buf[i + 4 + 1] >> 4) & 0xFF);
        dmb_inst_slot = (buf[i + 4 + 1] & 0xF);
        dmb_crate_coll.push_back(dmb_inst_crate);
        dmb_slot_coll.push_back(dmb_inst_slot);
      }
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s%s%s %i %s %i %s %i",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              dmb_common,
              dmb_header1,
              sign1,
              dmb_common_crate,
              dmb_inst_crate,
              dmb_common_slot,
              dmb_inst_slot,
              dmb_common_l1a,
              dmb_inst_l1a);
      dmb_h1_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    else if (dmb_h2_check[1]) {
      dmb_inst_crate = ((buf[i + 1] >> 4) & 0xFF);
      dmb_inst_slot = (buf[i + 1] & 0xF);
      dmb_h2_coll.push_back(word_numbering);
      if (dmb_h1_check[0])
        dmb_inst_l1a = ((buf[i - 4] & 0x0FFF) + ((buf[i - 4 + 1] & 0xFFF) << 12));
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s%s%s %i %s %i %s %i",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              dmb_common,
              dmb_header2,
              sign1,
              dmb_common_crate,
              dmb_inst_crate,
              dmb_common_slot,
              dmb_inst_slot,
              dmb_common_l1a,
              dmb_inst_l1a);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    //DDU Trailer 1

    else if (ddu_tr1_check[1]) {
      ddu_inst_i = ddu_h1_n_coll.size();
      if (ddu_inst_i > 0) {
        ddu_inst_n = ddu_h1_n_coll[ddu_inst_i - 1];
      }
      //ddu_inst_n=ddu_h1_n_coll[ddu_inst_i-1];
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s%i %s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              ddu_common,
              ddu_inst_n,
              ddu_trail1);
      ddu_t1_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    else if (alct_h1_check[1]) {
      alct_start = word_numbering;
      alct_inst_l1a = (buf[i + 2] & 0x0FFF);
      alct_l1a_coll.push_back(alct_inst_l1a);
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s%s %s %i",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              alct_common,
              alct_header1,
              sign1,
              dmb_common_l1a,
              alct_inst_l1a);
      alct_h1_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    else if ((alct_h1_check[0]) && (alct_h2_check[2])) {
      alct_inst_bxn = (buf[i] & 0x0FFF);
      alct_bxn_coll.push_back(alct_inst_bxn);
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s%s%s %i",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              alct_common,
              alct_header2,
              sign1,
              alct_common_bxn,
              alct_inst_bxn);
      alct_h2_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    //ALCT Trailer 1
    else if (alct_tr1_check[1]) {
      alct_stop = word_numbering;
      if ((alct_start != 0) && (alct_stop != 0) && (alct_stop > alct_start)) {
        alct_inst_wcnt2 = 4 * (alct_stop - alct_start + 1);
        alct_wcnt2_coll.push_back(alct_inst_wcnt2);
        alct_wcnt2_id_coll.push_back(alct_start);
      }
      alct_inst_wcnt1 = (buf[i + 3] & 0x7FF);
      alct_wcnt1_coll.push_back(alct_inst_wcnt1);
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s%s%s %i %s %i",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              alct_common,
              alct_tr1,
              sign1,
              alct_common_wcnt1,
              alct_inst_wcnt1,
              alct_common_wcnt2,
              alct_inst_wcnt2);
      alct_t1_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
      alct_inst_wcnt2 = 0;
    }

    //DDU Trailer 3

    //      else if ((ddu_tr1_check[-1])&&(tempbuf_short[0]==ddu_trailer3_bit[0])) { // !!! TO FIX: negative index
    else if ((ddu_h2_h1) && (tempbuf_short[0] == ddu_trailer3_bit[0])) {
      //&&(tempbuf_short[0]==ddu_trailer3_bit[0])){
      ddu_inst_i = ddu_h1_n_coll.size();
      if (ddu_inst_i > 0) {
        ddu_inst_n = ddu_h1_n_coll[ddu_inst_i - 1];
      }
      //ddu_inst_n=ddu_h1_n_coll[ddu_inst_i-1];
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s%i %s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              ddu_common,
              ddu_inst_n,
              ddu_trail3);
      ddu_t3_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }
    //DDU Trailer 2
    else if ((ddu_tr1_check[0]) && (tempbuf_short[0] != ddu_trailer3_bit[0])) {
      //&&(tempbuf_short[0]==ddu_trailer3_bit[0])){
      ddu_inst_i = ddu_h1_n_coll.size();
      if (ddu_inst_i > 0) {
        ddu_inst_n = ddu_h1_n_coll[ddu_inst_i - 1];
      }
      //ddu_inst_n=ddu_h1_n_coll[ddu_inst_i-1];
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s%i %s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              ddu_common,
              ddu_inst_n,
              ddu_trail2);
      ddu_t2_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    //DMB Trailer 1,2
    else if (dmb_tr1_check[1]) {
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              dmb_common,
              dmb_tr1);
      dmb_t1_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
      cfeb_sample = 0;
    }

    else if (dmb_tr2_check[1]) {
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              dmb_common,
              dmb_tr2);
      dmb_t2_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }
    // TMB
    else if (tmb_h1_check[1]) {
      tmb_start = word_numbering;
      tmb_inst_l1a = (buf[i + 2] & 0x000F);
      tmb_l1a_coll.push_back(tmb_inst_l1a);
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s%s%s %i",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              tmb_common,
              tmb_header1,
              sign1,
              dmb_common_l1a,
              tmb_inst_l1a);
      tmb_h1_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    } else if (tmb_tr1_check[1]) {
      tmb_stop = word_numbering;
      if ((tmb_start != 0) && (tmb_stop != 0) && (tmb_stop > tmb_start)) {
        tmb_inst_wcnt2 = 4 * (tmb_stop - tmb_start + 1);
        tmb_wcnt2_coll.push_back(tmb_inst_wcnt2);
      }
      tmb_inst_wcnt1 = (buf[i + 3] & 0x7FF);
      tmb_wcnt1_coll.push_back(tmb_inst_wcnt1);
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s%s%s %i %s %i",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              tmb_common,
              tmb_tr1,
              sign1,
              alct_common_wcnt1,
              tmb_inst_wcnt1,
              alct_common_wcnt2,
              tmb_inst_wcnt2);
      tmb_t1_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
      tmb_inst_wcnt2 = 0;
    }
    // CFEB
    else if (cfeb_tr1_check[1]) {
      ++cfeb_sample;
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s%s %s %i",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              cfeb_common,
              cfeb_tr1,
              sign1,
              cfeb_common_sample,
              cfeb_sample);
      cfeb_t1_coll.push_back(word_numbering);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    } else if (cfeb_b_check[1]) {
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s %s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              cfeb_common,
              cfeb_b);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    //ERRORS ddu_tr1_bad_check

    else if (ddu_tr1_bad_check[1]) {
      ddu_inst_i = ddu_h1_n_coll.size();
      ddu_inst_n = ddu_h1_n_coll[ddu_inst_i - 1];
      sprintf(tempbuf1,
              "%6i    %04x %04x %04x %04x%s%s%i %s %s",
              word_numbering,
              buf[i + 3],
              buf[i + 2],
              buf[i + 1],
              buf[i],
              sign1,
              ddu_common,
              ddu_inst_n,
              ddu_trail1,
              ddu_tr1_err_common);
      std::cout << tempbuf1 << std::endl;
      w = 0;
    }

    else if (extraction && (!ddu_h1_check) && (!dcc_check)) {
      if (w < 3) {
        sprintf(tempbuf, "%6i    %04x %04x %04x %04x", word_numbering, buf[i + 3], buf[i + 2], buf[i + 1], buf[i]);
        std::cout << tempbuf << std::endl;
        w++;
      }
      if (w == 3) {
        std::cout << "..................................................." << std::endl;
        w++;
      }
    }

    else if ((!ddu_h1_check) && (!dcc_check)) {
      sprintf(tempbuf, "%6i    %04x %04x %04x %04x", word_numbering, buf[i + 3], buf[i + 2], buf[i + 1], buf[i]);
      std::cout << tempbuf << std::endl;
    }

    i += 3;
    ddu_h1_check = false;
    dcc_check = false;
  }
  //char sign[30]; //WARNING 5_0_X
  std::cout << "********************************************************************************" << std::endl
            << std::endl;
  if (fedshort)
    std::cout << "For complete output turn off VisualFEDShort in muonCSCDigis configuration file." << std::endl;
  std::cout << "********************************************************************************" << std::endl
            << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << "            Summary                " << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << ddu_h1_coll.size() << "  " << ddu_common << "  " << ddu_header1 << "  "
            << "found" << std::endl;
  /*
  std::cout << ddu_h1_coll.size() << " " << ddu_h1_n_coll.size() << " " << ddu_l1a_coll.size() <<
  " " << ddu_bxn_coll.size() << std::endl;
  */
  for (unsigned int k = 0; k < ddu_h1_coll.size(); ++k) {
    /*
      sprintf(sign,"%s%6i%5s %s%i %s %i %s %i","Line: ",
      ddu_h1_coll[k],sign1,ddu_common,ddu_h1_n_coll[k],dmb_common_l1a,ddu_l1a_coll[k],
      alct_common_bxn,ddu_bxn_coll[k]);
      */
    std::cout << "Line: "
              << "    " << ddu_h1_coll[k] << " " << sign1 << " " << ddu_common << " " << ddu_h1_n_coll[k] << " "
              << dmb_common_l1a << " " << ddu_l1a_coll[k] << " " << alct_common_bxn << " " << ddu_bxn_coll[k]
              << std::endl;
  }

  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << ddu_h2_coll.size() << "  " << ddu_common << "  " << ddu_header2 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < ddu_h2_coll.size(); ++k)
    std::cout << "Line:  " << ddu_h2_coll[k] << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << ddu_h3_coll.size() << "  " << ddu_common << "  " << ddu_header3 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < ddu_h3_coll.size(); ++k)
    std::cout << "Line:  " << ddu_h3_coll[k] << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << ddu_t1_coll.size() << "  " << ddu_common << "  " << ddu_trail1 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < ddu_t1_coll.size(); ++k)
    std::cout << "Line:  " << ddu_t1_coll[k] << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << ddu_t2_coll.size() << "  " << ddu_common << "  " << ddu_trail2 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < ddu_t2_coll.size(); ++k)
    std::cout << "Line:  " << ddu_t2_coll[k] << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << ddu_t3_coll.size() << "  " << ddu_common << "  " << ddu_trail3 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < ddu_t3_coll.size(); ++k)
    std::cout << "Line:  " << ddu_t3_coll[k] << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << dmb_h1_coll.size() << "  " << dmb_common << "  " << dmb_header1 << "  "
            << "found" << std::endl;

  for (unsigned int k = 0; k < dmb_h1_coll.size(); ++k) {
    /*
      sprintf(sign,"%s%6i%5s %s %s %i %s %i %s %i","Line: ",
      dmb_h1_coll[k],sign1,dmb_common,dmb_common_crate,dmb_crate_coll[k],dmb_common_slot,
      dmb_slot_coll[k],dmb_common_l1a,dmb_l1a_coll[k]);
      */
    std::cout << "Line: "
              << "    " << dmb_h1_coll[k] << " " << sign1 << dmb_common << " " << dmb_common_crate << " "
              << dmb_crate_coll[k] << " " << dmb_common_slot << " " << dmb_slot_coll[k] << " " << dmb_common_l1a << " "
              << dmb_l1a_coll[k] << std::endl;
  }
  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << dmb_h2_coll.size() << "  " << dmb_common << "  " << dmb_header2 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < dmb_h2_coll.size(); ++k)
    std::cout << "Line:  " << dmb_h2_coll[k] << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << dmb_t1_coll.size() << "  " << dmb_common << "  " << dmb_tr1 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < dmb_t1_coll.size(); ++k)
    std::cout << "Line:  " << dmb_t1_coll[k] << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << dmb_t2_coll.size() << "  " << dmb_common << "  " << dmb_tr2 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < dmb_t2_coll.size(); ++k)
    std::cout << "Line:  " << dmb_t2_coll[k] << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << alct_h1_coll.size() << "  " << alct_common << "  " << alct_header1 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < alct_h1_coll.size(); ++k) {
    /*
      sprintf(sign,"%s%6i%5s %s %s %i","Line: ",
      alct_h1_coll[k],sign1,alct_common,
      dmb_common_l1a,alct_l1a_coll[k]);
      std::cout << sign << std::endl;
      */
    std::cout << "Line: "
              << "    " << alct_h1_coll[k] << " " << sign1 << " " << alct_common << " " << dmb_common_l1a << " "
              << alct_l1a_coll[k] << std::endl;
  }

  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << alct_h2_coll.size() << "  " << alct_common << "  " << alct_header2 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < alct_h2_coll.size(); ++k) {
    /*
      sprintf(sign,"%s%6i%5s %s %s %i","Line: ",
      alct_h1_coll[k],sign1,alct_common,
      alct_common_bxn,alct_bxn_coll[k]);
      std::cout << sign << std::endl;
      */
    std::cout << "Line: "
              << "    " << alct_h1_coll[k] << " " << sign1 << " " << alct_common << " " << alct_common_bxn << " "
              << alct_bxn_coll[k] << std::endl;
  }

  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << alct_t1_coll.size() << "  " << alct_common << "  " << alct_tr1 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < alct_t1_coll.size(); ++k) {
    /*
         sprintf(sign,"%s%6i%5s %s %s %i %s %i","Line: ",
         alct_t1_coll[k],sign1,alct_common,
         alct_common_wcnt1,alct_wcnt1_coll[k],alct_common_wcnt2,alct_wcnt2_coll[k]);
         std::cout << sign << std::endl;
       */
    std::cout << "Line: "
              << "    " << alct_t1_coll[k] << " " << sign1 << " " << alct_common << " " << alct_common_wcnt1 << " "
              << alct_wcnt1_coll[k] << " " << alct_common_wcnt2 << " ";
    if (!alct_wcnt2_coll.empty()) {
      std::cout << alct_wcnt2_coll[k] << std::endl;
    } else {
      std::cout << "Undefined (ALCT Header is not found) " << std::endl;
    }
  }

  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << tmb_h1_coll.size() << "  " << tmb_common << "  " << tmb_header1 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < tmb_h1_coll.size(); ++k) {
    /*
      sprintf(sign,"%s%6i%5s %s %s %i","Line: ",
      tmb_h1_coll[k],sign1,tmb_common,
      dmb_common_l1a,tmb_l1a_coll[k]);
      std::cout << sign << std::endl;
      */
    std::cout << "Line: "
              << "    " << tmb_h1_coll[k] << " " << sign1 << " " << tmb_common << " " << dmb_common_l1a << " "
              << tmb_l1a_coll[k] << std::endl;
  }

  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << tmb_t1_coll.size() << "  " << tmb_common << "  " << tmb_tr1 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < tmb_t1_coll.size(); ++k) {
    /*
      sprintf(sign,"%s%6i%5s %s %s %i %s %i","Line: ",
      tmb_t1_coll[k],sign1,tmb_common,
      alct_common_wcnt1,tmb_wcnt1_coll[k],alct_common_wcnt2,tmb_wcnt2_coll[k]);
      std::cout << sign << std::endl;
      */
    std::cout << "Line: "
              << "    " << tmb_t1_coll[k] << " " << sign1 << " " << tmb_common << " " << alct_common_wcnt1 << " "
              << tmb_wcnt1_coll[k] << " " << alct_common_wcnt2 << " " << tmb_wcnt2_coll[k] << std::endl;
  }

  std::cout << std::endl << std::endl;
  std::cout << "||||||||||||||||||||" << std::endl;
  std::cout << std::endl << std::endl;
  std::cout << cfeb_t1_coll.size() << "  " << cfeb_common << "  " << cfeb_tr1 << "  "
            << "found" << std::endl;
  for (unsigned int k = 0; k < cfeb_t1_coll.size(); ++k)
    std::cout << "Line:  " << cfeb_t1_coll[k] << std::endl;
  std::cout << "********************************************************************************" << std::endl;
}

Member Data Documentation

b904dmb

int CSCDCCUnpacker::b904dmb

private

Definition at line 106 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

b904Setup

bool CSCDCCUnpacker::b904Setup

private

Definition at line 105 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

b904vmecrate

int CSCDCCUnpacker::b904vmecrate

private

Definition at line 106 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

crateToken

edm::ESGetToken<CSCCrateMap, CSCCrateMapRcd> CSCDCCUnpacker::crateToken

private

Definition at line 112 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

cscmapToken

edm::ESGetToken<CSCChamberMap, CSCChamberMapRcd> CSCDCCUnpacker::cscmapToken

private

Definition at line 113 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

debug

bool CSCDCCUnpacker::debug

private

Definition at line 84 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), rrapi.RRApi::dprint(), util.rrapi.RRApi::dprint(), pkg.AbstractPkg::generate(), util.rrapi.RRApi::get(), rrapi.RRApi::get(), pkg.AbstractPkg::get_kwds(), runTauIdMVA.TauIDEmbedder::loadMVA_WPs_run2_2017(), produce(), runTauIdMVA.TauIDEmbedder::runTauID(), and pkg.AbstractPkg::write().

disableMappingCheck

bool CSCDCCUnpacker::disableMappingCheck

private

Definition at line 105 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

errorMask

unsigned int CSCDCCUnpacker::errorMask

private

Definition at line 102 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

examinerMask

unsigned int CSCDCCUnpacker::examinerMask

private

Definition at line 102 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

formatedEventDump

bool CSCDCCUnpacker::formatedEventDump

private

Definition at line 97 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), produce(), and visual_raw().

goodEvent

bool CSCDCCUnpacker::goodEvent

private

Definition at line 84 of file CSCDCCUnpacker.cc.

Referenced by produce().

i_token

edm::EDGetTokenT<FEDRawDataCollection> CSCDCCUnpacker::i_token

private

Token for consumes interface & access to data.

Definition at line 111 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

instantiateDQM

bool CSCDCCUnpacker::instantiateDQM

private

Definition at line 103 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

monitor

CSCMonitorInterface* CSCDCCUnpacker::monitor

private

Definition at line 108 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), produce(), and production_tasks.MonitorJobs::run().

numOfEvents

int CSCDCCUnpacker::numOfEvents

private

Definition at line 101 of file CSCDCCUnpacker.cc.

Referenced by produce().

printEventNumber

bool CSCDCCUnpacker::printEventNumber

private

Definition at line 84 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

SuppressZeroLCT

bool CSCDCCUnpacker::SuppressZeroLCT

private

Suppress zeros LCTs.

Definition at line 99 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

unpackStatusDigis

bool CSCDCCUnpacker::unpackStatusDigis

private

Definition at line 84 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

useCSCShowers_

bool CSCDCCUnpacker::useCSCShowers_

private

option to unpack CSC shower data

Definition at line 94 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

useExaminer

bool CSCDCCUnpacker::useExaminer

private

Definition at line 84 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

useFormatStatus

bool CSCDCCUnpacker::useFormatStatus

private

Definition at line 85 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

useGEMs_

bool CSCDCCUnpacker::useGEMs_

private

option to unpack GEM cluster data

Definition at line 91 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

useRPCs_

bool CSCDCCUnpacker::useRPCs_

private

option to unpack RPC data

Definition at line 88 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

useSelectiveUnpacking

bool CSCDCCUnpacker::useSelectiveUnpacking

private

Definition at line 85 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

visualFEDInspect

bool CSCDCCUnpacker::visualFEDInspect

private

Visualization of raw data.

Definition at line 97 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().

visualFEDShort

bool CSCDCCUnpacker::visualFEDShort

private

Definition at line 97 of file CSCDCCUnpacker.cc.

Referenced by CSCDCCUnpacker(), and produce().