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sistrip::RawToDigiUnpacker Class Reference

#include <SiStripRawToDigiUnpacker.h>

List of all members.

Classes

class  Registry
 private class to register start and end index of digis in a collection More...

Public Types

typedef edm::DetSetVector
< SiStripDigi
Digis
typedef edm::DetSetVector
< SiStripRawDigi
RawDigis

Public Member Functions

void createDigis (const SiStripFedCabling &, const FEDRawDataCollection &, SiStripEventSummary &, RawDigis &scope_mode, RawDigis &virgin_raw, RawDigis &proc_raw, Digis &zero_suppr, DetIdCollection &, RawDigis &common_mode)
 creates digis
void doAPVEmulatorCheck (bool)
void doFullCorruptBufferChecks (bool)
void extractCm (bool)
void locateStartOfFedBuffer (const uint16_t &fed_id, const FEDRawData &input, FEDRawData &output)
 Removes any data appended prior to FED buffer and reorders 32-bit words if swapped.
void quiet (bool)
 verbosity
 RawToDigiUnpacker (int16_t appended_bytes, int16_t fed_buffer_dump_freq, int16_t fed_event_dump_freq, int16_t trigger_fed_id, bool using_fed_key, bool unpack_bad_channels, bool mark_missing_feds, const uint32_t errorThreshold)
 constructor
void triggerFed (const FEDRawDataCollection &, SiStripEventSummary &, const uint32_t &event)
 trigger info
void useDaqRegister (bool)
 EventSummary update request -> not yet implemented for FEDBuffer class.
 ~RawToDigiUnpacker ()
 default constructor

Private Member Functions

void cleanupWorkVectors ()
 method to clear registries and digi collections
void dumpRawData (uint16_t fed_id, const FEDRawData &, std::stringstream &)
 dumps raw data to stdout (NB: payload is byte-swapped,headers/trailer are not).
sistrip::FedBufferFormat fedBufferFormat (const uint16_t &register_value)
 returns buffer format
sistrip::FedReadoutMode fedReadoutMode (const uint16_t &register_value)
 returns buffer readout mode
void handleException (std::string method_name, std::string extra_info="")
 catches all possible exceptions and rethrows them as cms::Exceptions
void physicalOrder (uint16_t &readout_order, uint16_t &physical_order)
 order of strips
 RawToDigiUnpacker ()
 private default constructor
void readoutOrder (uint16_t &physical_order, uint16_t &readout_order)
 order of strips
void update (RawDigis &scope_mode, RawDigis &virgin_raw, RawDigis &proc_raw, Digis &zero_suppr, RawDigis &common_mode)
 fill DetSetVectors using registries
void updateEventSummary (const sistrip::FEDBuffer &, SiStripEventSummary &)
 sets the SiStripEventSummary -> not yet implemented for FEDBuffer class

Private Attributes

std::vector< SiStripRawDigicm_work_digis_
std::vector< Registrycm_work_registry_
bool doAPVEmulatorCheck_
bool doFullCorruptBufferChecks_
uint32_t errorThreshold_
uint32_t event_
 other values
bool extractCm_
int16_t fedBufferDumpFreq_
int16_t fedEventDumpFreq_
bool first_
int16_t headerBytes_
 configurables
bool markMissingFeds_
bool once_
std::vector< SiStripRawDigiproc_work_digis_
std::vector< Registryproc_work_registry_
bool quiet_
std::vector< SiStripRawDigiscope_work_digis_
std::vector< Registryscope_work_registry_
int16_t triggerFedId_
bool unpackBadChannels_
bool useDaqRegister_
bool useFedKey_
std::vector< SiStripRawDigivirgin_work_digis_
std::vector< Registryvirgin_work_registry_
std::vector< SiStripDigizs_work_digis_
 digi collections
std::vector< Registryzs_work_registry_
 registries

Friends

class RawToClustersLazyUnpacker

Detailed Description

Definition at line 29 of file SiStripRawToDigiUnpacker.h.


Member Typedef Documentation

Definition at line 35 of file SiStripRawToDigiUnpacker.h.

Definition at line 36 of file SiStripRawToDigiUnpacker.h.


Constructor & Destructor Documentation

sistrip::RawToDigiUnpacker::RawToDigiUnpacker ( int16_t  appended_bytes,
int16_t  fed_buffer_dump_freq,
int16_t  fed_event_dump_freq,
int16_t  trigger_fed_id,
bool  using_fed_key,
bool  unpack_bad_channels,
bool  mark_missing_feds,
const uint32_t  errorThreshold 
)

constructor

Definition at line 22 of file SiStripRawToDigiUnpacker.cc.

References edm::isDebugEnabled(), LogTrace, and unpackBadChannels_.

                                                                                                                                              :
    headerBytes_( appended_bytes ),
    fedBufferDumpFreq_( fed_buffer_dump_freq ),
    fedEventDumpFreq_( fed_event_dump_freq ),
    triggerFedId_( trigger_fed_id ),
    useFedKey_( using_fed_key ),
    unpackBadChannels_( unpack_bad_channels ),
    markMissingFeds_( mark_missing_feds ),
    event_(0),
    once_(true),
    first_(true),
    useDaqRegister_(false),
    quiet_(true),
    extractCm_(false),
    doFullCorruptBufferChecks_(false),
    doAPVEmulatorCheck_(true),
    errorThreshold_(errorThreshold)
  {
    if ( edm::isDebugEnabled() ) {
      LogTrace("SiStripRawToDigi")
        << "[sistrip::RawToDigiUnpacker::"<<__func__<<"]"
        <<" Constructing object...";
    }
    if (unpackBadChannels_) {
      edm::LogWarning("SiStripRawToDigi") << "Warning: Unpacking of bad channels enabled. Only enable this if you know what you are doing. " << std::endl;
    }
  }
sistrip::RawToDigiUnpacker::~RawToDigiUnpacker ( )

default constructor

Definition at line 51 of file SiStripRawToDigiUnpacker.cc.

References edm::isDebugEnabled(), and LogTrace.

                                        {
    if ( edm::isDebugEnabled() ) {
      LogTrace("SiStripRawToDigi")
        << "[sistrip::RawToDigiUnpacker::"<<__func__<<"]"
        << " Destructing object...";
    }
  }
sistrip::RawToDigiUnpacker::RawToDigiUnpacker ( ) [private]

private default constructor


Member Function Documentation

void sistrip::RawToDigiUnpacker::cleanupWorkVectors ( ) [private]

method to clear registries and digi collections

Definition at line 746 of file SiStripRawToDigiUnpacker.cc.

References cm_work_digis_, cm_work_registry_, proc_work_digis_, proc_work_registry_, scope_work_digis_, scope_work_registry_, virgin_work_digis_, virgin_work_registry_, zs_work_digis_, and zs_work_registry_.

Referenced by createDigis().

                                             {
    // Clear working areas and registries
    zs_work_registry_.clear();      zs_work_digis_.clear();
    virgin_work_registry_.clear();  virgin_work_digis_.clear();
    proc_work_registry_.clear();    proc_work_digis_.clear();
    scope_work_registry_.clear();   scope_work_digis_.clear();
    cm_work_registry_.clear();      cm_work_digis_.clear();
  }
void sistrip::RawToDigiUnpacker::createDigis ( const SiStripFedCabling cabling,
const FEDRawDataCollection buffers,
SiStripEventSummary summary,
RawDigis scope_mode,
RawDigis virgin_raw,
RawDigis proc_raw,
Digis zero_suppr,
DetIdCollection detids,
RawDigis common_mode 
)

creates digis

extract readout mode

FED channel

create unpacker

unpack -> add check to make sure strip < nstrips && strip > last strip......

create unpacker

unpack -> add check to make sure strip < nstrips && strip > last strip......

create unpacker

unpack -> add check to make sure strip < nstrips && strip > last strip......

create unpacker

unpack -> add check to make sure strip < nstrips && strip > last strip......

create unpacker

unpack -> add check to make sure strip < nstrips && strip > last strip......

create unpacker

unpack -> add check to make sure strip < nstrips && strip > last strip......

Definition at line 59 of file SiStripRawToDigiUnpacker.cc.

References sistrip::FEDZSChannelUnpacker::adc(), sistrip::FEDRawChannelUnpacker::adc(), sistrip::APV_LATENCY, cleanupWorkVectors(), cm_work_digis_, cm_work_registry_, SiStripFedCabling::connections(), FEDRawData::data(), doAPVEmulatorCheck_, doFullCorruptBufferChecks_, dumpRawData(), alignCSCRings::e, errorThreshold_, event_, Exception, extractCm_, sistrip::FED_CABLING, fedBufferDumpFreq_, sistrip::FEDCH_PER_FEUNIT, FEDRawDataCollection::FEDData(), fedEventDumpFreq_, SiStripFedCabling::feds(), sistrip::FINE_DELAY, first_, sistrip::FEDRawChannelUnpacker::hasData(), sistrip::FEDZSChannelUnpacker::hasData(), i, collect_tpl::input, sistrip::invalid32_, sistrip::invalid_, edm::isDebugEnabled(), SiStripEventSummary::isSet(), combine::key, LogTrace, FEDNumbering::MAXSiStripFEDID, FEDNumbering::MINSiStripFEDID, sistrip::mlRawToDigi_, mode, n, proc_work_digis_, proc_work_registry_, sistrip::FEDRawChannelUnpacker::procRawModeUnpacker(), edm::EDCollection< T >::push_back(), quiet_, sistrip::READOUT_MODE_PROC_RAW, sistrip::READOUT_MODE_SCOPE, sistrip::READOUT_MODE_VIRGIN_RAW, sistrip::READOUT_MODE_ZERO_SUPPRESSED, sistrip::READOUT_MODE_ZERO_SUPPRESSED_LITE, readoutOrder(), edm::EDCollection< T >::reserve(), SiStripEventSummary::runType(), sistrip::FEDZSChannelUnpacker::sampleNumber(), scope_work_digis_, scope_work_registry_, sistrip::FEDRawChannelUnpacker::scopeModeUnpacker(), FEDRawData::size(), edm::EDCollection< T >::size(), triggerFedId_, unpackBadChannels_, update(), updateEventSummary(), useDaqRegister_, useFedKey_, SiStripEventSummary::valid(), virgin_work_digis_, virgin_work_registry_, sistrip::FEDRawChannelUnpacker::virginRawModeUnpacker(), cms::Exception::what(), sistrip::FEDZSChannelUnpacker::zeroSuppressedLiteModeUnpacker(), sistrip::FEDZSChannelUnpacker::zeroSuppressedModeUnpacker(), zs_work_digis_, and zs_work_registry_.

Referenced by sistrip::RawToDigiModule::produce().

                                                                                                                                                                                                                                                                            {

    // Clear working areas and registries
    cleanupWorkVectors();
    // Reserve space in bad module list
    detids.reserve(100);
  
    // Check if FEDs found in cabling map and event data
    if ( edm::isDebugEnabled() ) {
      if ( cabling.feds().empty() ) {
        edm::LogWarning(sistrip::mlRawToDigi_)
          << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
          << " No FEDs found in cabling map!";
        // Check which FED ids have non-zero size buffers
        std::vector<uint16_t> feds;
        for ( uint16_t ifed = FEDNumbering::MINSiStripFEDID; ifed < FEDNumbering::MAXSiStripFEDID; ifed++ ) {
          if ( ifed != triggerFedId_ && 
               buffers.FEDData( static_cast<int>(ifed) ).size() ) {
            feds.push_back(ifed);
          }
        }
        LogTrace("SiStripRawToDigi")
          << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
          << " Found " 
          << feds.size() 
          << " FED buffers with non-zero size!";
      }
    }

    // Flag for EventSummary update using DAQ register  
    bool first_fed = true;
  
    // Retrieve FED ids from cabling map and iterate through 
    std::vector<uint16_t>::const_iterator ifed = cabling.feds().begin();
    for ( ; ifed != cabling.feds().end(); ifed++ ) {

      // ignore trigger FED
      if ( *ifed == triggerFedId_ ) { continue;  }
    
      // Retrieve FED raw data for given FED 
      const FEDRawData& input = buffers.FEDData( static_cast<int>(*ifed) );
    
      // Some debug on FED buffer size
      if ( edm::isDebugEnabled() ) {
        if ( first_ && input.data() ) {
          std::stringstream ss;
          ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
             << " Found FED id " 
             << std::setw(4) << std::setfill(' ') << *ifed 
             << " in FEDRawDataCollection"
             << " with non-zero pointer 0x" 
             << std::hex
             << std::setw(8) << std::setfill('0') 
             << reinterpret_cast<uint32_t*>( const_cast<uint8_t*>(input.data()))
             << std::dec
             << " and size " 
             << std::setw(5) << std::setfill(' ') << input.size()
             << " chars";
          LogTrace("SiStripRawToDigi") << ss.str();
        }       
      }
    
      // Dump of FEDRawData to stdout
      if ( edm::isDebugEnabled() ) {
        if ( fedBufferDumpFreq_ && !(event_%fedBufferDumpFreq_) ) {
          std::stringstream ss;
          dumpRawData( *ifed, input, ss );
          edm::LogVerbatim(sistrip::mlRawToDigi_) << ss.str();
        }
      }
      
      // get the cabling connections for this FED
      const std::vector<FedChannelConnection>& conns = cabling.connections(*ifed);
    
      // Check on FEDRawData pointer
      if ( !input.data() ) {
        if ( edm::isDebugEnabled() ) {
          edm::LogWarning(sistrip::mlRawToDigi_)
            << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
            << " NULL pointer to FEDRawData for FED id " 
            << *ifed;
        }
        // Mark FED modules as bad
        detids.reserve(detids.size()+conns.size());
        std::vector<FedChannelConnection>::const_iterator iconn = conns.begin();
        for ( ; iconn != conns.end(); iconn++ ) {
          if ( !iconn->detId() || iconn->detId() == sistrip::invalid32_ ) continue;
          detids.push_back(iconn->detId()); //@@ Possible multiple entries (ok for Giovanni)
        }
        continue;
      } 
    
      // Check on FEDRawData size
      if ( !input.size() ) {
        if ( edm::isDebugEnabled() ) {
          edm::LogWarning(sistrip::mlRawToDigi_)
            << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
            << " FEDRawData has zero size for FED id " 
            << *ifed;
        }
        // Mark FED modules as bad
        detids.reserve(detids.size()+conns.size());
        std::vector<FedChannelConnection>::const_iterator iconn = conns.begin();
        for ( ; iconn != conns.end(); iconn++ ) {
          if ( !iconn->detId() || iconn->detId() == sistrip::invalid32_ ) continue;
          detids.push_back(iconn->detId()); //@@ Possible multiple entries (ok for Giovanni)
        }
        continue;
      }
      
      // construct FEDBuffer
      std::auto_ptr<sistrip::FEDBuffer> buffer;
      try {
        buffer.reset(new sistrip::FEDBuffer(input.data(),input.size()));
        if (!buffer->doChecks()) {
          if (!unpackBadChannels_ || !buffer->checkNoFEOverflows() )
            throw cms::Exception("FEDBuffer") << "FED Buffer check fails for FED ID " << *ifed << ".";
        }
        if (doFullCorruptBufferChecks_ && !buffer->doCorruptBufferChecks()) {
          throw cms::Exception("FEDBuffer") << "FED corrupt buffer check fails for FED ID " << *ifed << ".";
        }
      }
      catch (const cms::Exception& e) { 
        if ( edm::isDebugEnabled() ) {
          edm::LogWarning("sistrip::RawToDigiUnpacker") << "Exception caught when creating FEDBuffer object for FED " << *ifed << ": " << e.what();
        }
        // FED buffer is bad and should not be unpacked. Skip this FED and mark all modules as bad. 
        std::vector<FedChannelConnection>::const_iterator iconn = conns.begin();
        for ( ; iconn != conns.end(); iconn++ ) {
          if ( !iconn->detId() || iconn->detId() == sistrip::invalid32_ ) continue;
          detids.push_back(iconn->detId()); //@@ Possible multiple entries (ok for Giovanni)
        }
        continue;
      }

      // Check if EventSummary ("trigger FED info") needs updating
      if ( first_fed && useDaqRegister_ ) { updateEventSummary( *buffer, summary ); first_fed = false; }
    
      // Check to see if EventSummary info is set
      if ( edm::isDebugEnabled() ) {
        if ( !quiet_ && !summary.isSet() ) {
          std::stringstream ss;
          ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
             << " EventSummary is not set correctly!"
             << " Missing information from both \"trigger FED\" and \"DAQ registers\"!";
          edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
        }
      }
    
      // Check to see if event is to be analyzed according to EventSummary
      if ( !summary.valid() ) { 
        if ( edm::isDebugEnabled() ) {
          LogTrace("SiStripRawToDigi")
            << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
            << " EventSummary is not valid: skipping...";
        }
        continue; 
      }
    
      sistrip::FEDReadoutMode mode = buffer->readoutMode(); 

      // Retrive run type
      sistrip::RunType runType_ = summary.runType();
      if( runType_ == sistrip::APV_LATENCY || runType_ == sistrip::FINE_DELAY ) { useFedKey_ = false; } 
     
      // Dump of FED buffer
      if ( edm::isDebugEnabled() ) {
        if ( fedEventDumpFreq_ && !(event_%fedEventDumpFreq_) ) {
          std::stringstream ss;
          buffer->dump( ss );
          edm::LogVerbatim(sistrip::mlRawToDigi_) << ss.str();
        }
      }
    
      // Iterate through FED channels, extract payload and create Digis
      std::vector<FedChannelConnection>::const_iterator iconn = conns.begin();
      for ( ; iconn != conns.end(); iconn++ ) {

        uint16_t chan = iconn->fedCh();

        // Check if fed connection is valid
        if ( !iconn->isConnected() ) { continue; }
        
        // Check DetId is valid (if to be used as key)
        if ( !useFedKey_ && ( !iconn->detId() || iconn->detId() == sistrip::invalid32_ ) ) { continue; }
      
        // Check FED channel
        if (!buffer->channelGood(iconn->fedCh(),doAPVEmulatorCheck_)) {
          if (!unpackBadChannels_ || !(buffer->fePresent(iconn->fedCh()/FEDCH_PER_FEUNIT) && buffer->feEnabled(iconn->fedCh()/FEDCH_PER_FEUNIT)) ) {
            detids.push_back(iconn->detId()); //@@ Possible multiple entries (ok for Giovanni)
            continue;
          }
        }

        // Determine whether FED key is inferred from cabling or channel loop
        uint32_t fed_key = ( summary.runType() == sistrip::FED_CABLING ) ? ( ( *ifed & sistrip::invalid_ ) << 16 ) | ( chan & sistrip::invalid_ ) : ( ( iconn->fedId() & sistrip::invalid_ ) << 16 ) | ( iconn->fedCh() & sistrip::invalid_ );

        // Determine whether DetId or FED key should be used to index digi containers
        uint32_t key = ( useFedKey_ || mode == sistrip::READOUT_MODE_SCOPE ) ? fed_key : iconn->detId();
      
        // Determine APV std::pair number (needed only when using DetId)
        uint16_t ipair = ( useFedKey_ || mode == sistrip::READOUT_MODE_SCOPE ) ? 0 : iconn->apvPairNumber();
      

        if (mode == sistrip::READOUT_MODE_ZERO_SUPPRESSED ) { 
        
          Registry regItem(key, 0, zs_work_digis_.size(), 0);
        
          try {
            sistrip::FEDZSChannelUnpacker unpacker = sistrip::FEDZSChannelUnpacker::zeroSuppressedModeUnpacker(buffer->channel(iconn->fedCh()));
            
            
            while (unpacker.hasData()) {zs_work_digis_.push_back(SiStripDigi(unpacker.sampleNumber()+ipair*256,unpacker.adc()));unpacker++;}
          } catch (const cms::Exception& e) {
            if ( edm::isDebugEnabled() ) {
              edm::LogWarning(sistrip::mlRawToDigi_)
                << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
                << " Clusters are not ordered for FED "
                << *ifed << " channel " << iconn->fedCh()
                << ": " << e.what();
            }
            detids.push_back(iconn->detId()); //@@ Possible multiple entries (ok for Giovanni)
            continue;
          }
          
          regItem.length = zs_work_digis_.size() - regItem.index;
          if (regItem.length > 0) {
            regItem.first = zs_work_digis_[regItem.index].strip();
            zs_work_registry_.push_back(regItem);
          }

            
          // Common mode values
          if ( extractCm_ ) {
            try {
              Registry regItem2( key, 2*ipair, cm_work_digis_.size(), 2 );
              cm_work_digis_.push_back( SiStripRawDigi( buffer->channel(iconn->fedCh()).cmMedian(0) ) );
              cm_work_digis_.push_back( SiStripRawDigi( buffer->channel(iconn->fedCh()).cmMedian(1) ) );
              cm_work_registry_.push_back( regItem2 );
            } catch (const cms::Exception& e) {
              if ( edm::isDebugEnabled() ) {
                edm::LogWarning(sistrip::mlRawToDigi_)
                  << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
                  << " Problem extracting common modes for FED id "
                  << *ifed << " and channel " << iconn->fedCh()
                  << ": " << std::endl << e.what();
              }
            }
          }
          
        }

        else if (mode == sistrip::READOUT_MODE_ZERO_SUPPRESSED_LITE ) { 

          Registry regItem(key, 0, zs_work_digis_.size(), 0);
        
          try {
            sistrip::FEDZSChannelUnpacker unpacker = sistrip::FEDZSChannelUnpacker::zeroSuppressedLiteModeUnpacker(buffer->channel(iconn->fedCh()));
            
            while (unpacker.hasData()) {zs_work_digis_.push_back(SiStripDigi(unpacker.sampleNumber()+ipair*256,unpacker.adc()));unpacker++;}
          } catch (const cms::Exception& e) {
            if ( edm::isDebugEnabled() ) {
              edm::LogWarning(sistrip::mlRawToDigi_)
                << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
                << " Clusters are not ordered for FED "
                << *ifed << " channel " << iconn->fedCh()
                << ": " << e.what();
            }
            detids.push_back(iconn->detId()); //@@ Possible multiple entries (ok for Giovanni)
            continue;
          }  

          regItem.length = zs_work_digis_.size() - regItem.index;
          if (regItem.length > 0) {
            regItem.first = zs_work_digis_[regItem.index].strip();
            zs_work_registry_.push_back(regItem);
          }
          

        } 
     
        else if ( mode == sistrip::READOUT_MODE_VIRGIN_RAW ) {

          std::vector<uint16_t> samples; 

          sistrip::FEDRawChannelUnpacker unpacker = sistrip::FEDRawChannelUnpacker::virginRawModeUnpacker(buffer->channel(iconn->fedCh()));

          while (unpacker.hasData()) {samples.push_back(unpacker.adc());unpacker++;}

          if ( !samples.empty() ) { 
            Registry regItem(key, 256*ipair, virgin_work_digis_.size(), samples.size());
            uint16_t physical;
            uint16_t readout; 
            for ( uint16_t i = 0, n = samples.size(); i < n; i++ ) {
              physical = i%128;
              readoutOrder( physical, readout );                 // convert index from physical to readout order
              (i/128) ? readout=readout*2+1 : readout=readout*2; // un-multiplex data
              virgin_work_digis_.push_back(  SiStripRawDigi( samples[readout] ) );
            }
            virgin_work_registry_.push_back( regItem );
          }
        } 
    
        else if ( mode == sistrip::READOUT_MODE_PROC_RAW ) {
        
          std::vector<uint16_t> samples; 
        
          sistrip::FEDRawChannelUnpacker unpacker = sistrip::FEDRawChannelUnpacker::procRawModeUnpacker(buffer->channel(iconn->fedCh()));
        
          while (unpacker.hasData()) {samples.push_back(unpacker.adc());unpacker++;}
        
          if ( !samples.empty() ) { 
            Registry regItem(key, 256*ipair, proc_work_digis_.size(), samples.size());
            for ( uint16_t i = 0, n = samples.size(); i < n; i++ ) {
              proc_work_digis_.push_back(  SiStripRawDigi( samples[i] ) );
            }
            proc_work_registry_.push_back( regItem );
          }
        } 

        else if ( mode == sistrip::READOUT_MODE_SCOPE ) {
        
          std::vector<uint16_t> samples; 
        
          sistrip::FEDRawChannelUnpacker unpacker = sistrip::FEDRawChannelUnpacker::scopeModeUnpacker(buffer->channel(iconn->fedCh()));

          while (unpacker.hasData()) {samples.push_back(unpacker.adc());unpacker++;}
        
          if ( !samples.empty() ) { 
            Registry regItem(key, 0, scope_work_digis_.size(), samples.size());
            for ( uint16_t i = 0, n = samples.size(); i < n; i++ ) {
              scope_work_digis_.push_back(  SiStripRawDigi( samples[i] ) );
            }
            scope_work_registry_.push_back( regItem );
          }
        } 
        
        else { // Unknown readout mode! => assume scope mode

          if ( edm::isDebugEnabled() ) {
            std::stringstream ss;
            ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
               << " Unknown FED readout mode (" << mode
               << ")! Assuming SCOPE MODE..."; 
            edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
          }
        
          std::vector<uint16_t> samples; 
        
          sistrip::FEDRawChannelUnpacker unpacker = sistrip::FEDRawChannelUnpacker::scopeModeUnpacker(buffer->channel(iconn->fedCh()));
        
          while (unpacker.hasData()) {samples.push_back(unpacker.adc());unpacker++;}
        
          if ( !samples.empty() ) { 
            Registry regItem(key, 0, scope_work_digis_.size(), samples.size());
            for ( uint16_t i = 0, n = samples.size(); i < n; i++ ) {
              scope_work_digis_.push_back(  SiStripRawDigi( samples[i] ) );
            }
            scope_work_registry_.push_back( regItem );
          
            if ( edm::isDebugEnabled() ) {
              std::stringstream ss;
              ss << "Extracted " << samples.size() 
                 << " SCOPE MODE digis (samples[0] = " 
                 << samples[0] 
                 << ") from FED id/ch " 
                 << iconn->fedId() 
                 << "/" 
                 << iconn->fedCh();
              LogTrace("SiStripRawToDigi") << ss.str();
            }
          }
          else if ( edm::isDebugEnabled() ) {
            edm::LogWarning(sistrip::mlRawToDigi_)
              << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
              << " No SM digis found!"; 
          }
        } 
      } // channel loop
    } // fed loop

    // bad channels warning
    unsigned int detIdsSize = detids.size();
    if ( edm::isDebugEnabled() && detIdsSize ) {
      std::ostringstream ss;
      ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
         << " Problems were found in data and " << detIdsSize << " channels could not be unpacked. "
         << "See output of FED Hardware monitoring for more information. ";
      edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
    }
    if( (errorThreshold_ != 0) && (detIdsSize > errorThreshold_) ) {
      edm::LogError("TooManyErrors") << "Total number of errors = " << detIdsSize;
    }

    // update DetSetVectors
    update(scope_mode, virgin_raw, proc_raw, zero_suppr, cm_values);

    // increment event counter
    event_++;
  
    // no longer first event!
    if ( first_ ) { first_ = false; }
  
    // final cleanup, just in case
    cleanupWorkVectors();
  }
void sistrip::RawToDigiUnpacker::doAPVEmulatorCheck ( bool  do_APVEmulator_check) [inline]

Definition at line 186 of file SiStripRawToDigiUnpacker.h.

{ doAPVEmulatorCheck_ = do_APVEmulator_check; }
void sistrip::RawToDigiUnpacker::doFullCorruptBufferChecks ( bool  do_full_corrupt_buffer_checks) [inline]

Definition at line 184 of file SiStripRawToDigiUnpacker.h.

{ doFullCorruptBufferChecks_ = do_full_corrupt_buffer_checks; }
void sistrip::RawToDigiUnpacker::dumpRawData ( uint16_t  fed_id,
const FEDRawData buffer,
std::stringstream &  ss 
) [private]

dumps raw data to stdout (NB: payload is byte-swapped,headers/trailer are not).

Definition at line 1051 of file SiStripRawToDigiUnpacker.cc.

References FEDRawData::data(), relativeConstraints::empty, i, sistrip::invalid32_, and FEDRawData::size().

Referenced by createDigis(), and sistrip::RawToClustersLazyUnpacker::fill().

                                                                                                      {

    ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
       << " Dump of buffer for FED id " <<  fed_id << std::endl
       << " Buffer contains " << buffer.size()
       << " bytes (NB: payload is byte-swapped)" << std::endl;
    uint32_t* buffer_u32 = reinterpret_cast<uint32_t*>( const_cast<unsigned char*>( buffer.data() ) );
    unsigned int empty = 0;

    if ( 0 ) { 

      ss << "Byte->   4 5 6 7 0 1 2 3\n";
      for ( uint32_t i = 0; i < buffer.size()/8; i++ ) {
        unsigned int temp0 = buffer_u32[i*2] & sistrip::invalid32_;
        unsigned int temp1 = buffer_u32[i*2+1] & sistrip::invalid32_;
        if ( !temp0 && !temp1 ) { empty++; }
        else { 
          if ( empty ) { 
            ss << "        [ empty  words ]" << std::endl; 
            empty = 0; 
          }
          ss << std::dec
             << std::setfill(' ')  << std::setw(6) << i*8 << ": " 
             << std::hex 
             << std::setfill('0') << std::setw(8) << temp0 
             << std::setfill('0') << std::setw(8) << temp1 
             << std::dec
             << std::endl;
        }
      }

    } else {
    
      ss << "  Byte |  <---- Byte order ----<  | Byte" << std::endl;
      ss << "  cntr |  7  6  5  4  3  2  1  0  | cntr" << std::endl;
      for ( uint32_t i = 0; i < buffer.size()/8; i++ ) {
        //if ( i>=20 && ((i+4)<(buffer.size()/8)) ) { continue; }
        uint16_t tmp0 = buffer.data()[i*8+0] & 0xFF;
        uint16_t tmp1 = buffer.data()[i*8+1] & 0xFF;
        uint16_t tmp2 = buffer.data()[i*8+2] & 0xFF;
        uint16_t tmp3 = buffer.data()[i*8+3] & 0xFF;
        uint16_t tmp4 = buffer.data()[i*8+4] & 0xFF;
        uint16_t tmp5 = buffer.data()[i*8+5] & 0xFF;
        uint16_t tmp6 = buffer.data()[i*8+6] & 0xFF;
        uint16_t tmp7 = buffer.data()[i*8+7] & 0xFF;
//      if ( !tmp0 && !tmp1 && !tmp2 && !tmp3 &&
//           !tmp4 && !tmp5 && !tmp6 && !tmp7 ) { empty++; }
//      else { 
//        if ( empty ) { 
//          ss << "         [.." 
//             << std::dec << std::setfill('.') << std::setw(4) << empty 
//             << " null words....]" << std::endl; 
//          empty = 0; 
//        }
          ss << std::dec
             << std::setfill(' ')  << std::setw(6) << i*8+7 << " : " 
             << std::hex 
             << std::setfill('0') << std::setw(2) << tmp7 << " " 
             << std::setfill('0') << std::setw(2) << tmp6 << " " 
             << std::setfill('0') << std::setw(2) << tmp5 << " " 
             << std::setfill('0') << std::setw(2) << tmp4 << " " 
             << std::setfill('0') << std::setw(2) << tmp3 << " " 
             << std::setfill('0') << std::setw(2) << tmp2 << " " 
             << std::setfill('0') << std::setw(2) << tmp1 << " " 
             << std::setfill('0') << std::setw(2) << tmp0 
             << std::dec
             << " :" << std::setfill(' ')  << std::setw(6) << i*8 
             << std::endl;
//      }
      }

    }
    ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
       << " End of FED buffer";
  }
void sistrip::RawToDigiUnpacker::extractCm ( bool  extract_cm) [inline]

Definition at line 182 of file SiStripRawToDigiUnpacker.h.

{ extractCm_ = extract_cm; }
sistrip::FedBufferFormat sistrip::RawToDigiUnpacker::fedBufferFormat ( const uint16_t &  register_value) [inline, private]

returns buffer format

Definition at line 160 of file SiStripRawToDigiUnpacker.h.

References sistrip::APV_ERROR_FORMAT, sistrip::FULL_DEBUG_FORMAT, sistrip::UNDEFINED_FED_BUFFER_FORMAT, and sistrip::UNKNOWN_FED_BUFFER_FORMAT.

{
  if ( (register_value&0xF) == 0x1 ) { return sistrip::FULL_DEBUG_FORMAT; }
  else if ( (register_value&0xF) == 0x2 ) { return sistrip::APV_ERROR_FORMAT; }
  else if ( (register_value&0xF) == 0x0 ) { return sistrip::UNDEFINED_FED_BUFFER_FORMAT; }
  else { return sistrip::UNKNOWN_FED_BUFFER_FORMAT; }
}
sistrip::FedReadoutMode sistrip::RawToDigiUnpacker::fedReadoutMode ( const uint16_t &  register_value) [inline, private]

returns buffer readout mode

Definition at line 168 of file SiStripRawToDigiUnpacker.h.

References sistrip::FED_PROC_RAW, sistrip::FED_SCOPE_MODE, sistrip::FED_VIRGIN_RAW, sistrip::FED_ZERO_SUPPR, sistrip::FED_ZERO_SUPPR_LITE, and sistrip::UNKNOWN_FED_READOUT_MODE.

{
  if ( ((register_value>>1)&0x7) == 0x0 ) { return sistrip::FED_SCOPE_MODE; }
  else if ( ((register_value>>1)&0x7) == 0x1 ) { return sistrip::FED_VIRGIN_RAW; }
  else if ( ((register_value>>1)&0x7) == 0x3 ) { return sistrip::FED_PROC_RAW; }
  else if ( ((register_value>>1)&0x7) == 0x5 ) { return sistrip::FED_ZERO_SUPPR; }
  else if ( ((register_value>>1)&0x7) == 0x6 ) { return sistrip::FED_ZERO_SUPPR_LITE; }
  else { return sistrip::UNKNOWN_FED_READOUT_MODE; }
}
void sistrip::RawToDigiUnpacker::handleException ( std::string  method_name,
std::string  extra_info = "" 
) [private]

catches all possible exceptions and rethrows them as cms::Exceptions

Definition at line 1127 of file SiStripRawToDigiUnpacker.cc.

References alignCSCRings::e, exception, edm::isDebugEnabled(), and sistrip::mlRawToDigi_.

                                                                                       { 

    method_name = "sistrip::RawToDigiUnpacker::" + method_name;
    try {
      throw; // rethrow caught exception to be dealt with below
    } 
    catch ( const cms::Exception& e ) { 
      //throw e; // rethrow cms::Exception to be caught by framework
    }
    catch ( const std::exception& e ) {
      if ( edm::isDebugEnabled() ) {
        std::stringstream ss;
        ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
           << " Caught std::exception!" << std::endl;
        if ( extra_info != "" ) { 
          ss << " Information: " << extra_info << std::endl;
        }
        ss << " Caught std::exception in ["
           << method_name << "] with message:" << std::endl 
           << e.what();
        edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
      }
      //throw cms::Exception(sistrip::mlRawToDigi_) << ss.str();
    }
    catch (...) {
      if ( edm::isDebugEnabled() ) {
        std::stringstream ss;
        ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
           << " Caught unknown exception!" << std::endl;
        if ( extra_info != "" ) { 
          ss << " Information: " << extra_info << std::endl;
        }
        ss << "Caught unknown exception in ["
           << method_name << "]" << std::endl;
        edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
      }
      //throw cms::Exception(sistrip::mlRawToDigi_) << ss.str();
    }
  }
void sistrip::RawToDigiUnpacker::locateStartOfFedBuffer ( const uint16_t &  fed_id,
const FEDRawData input,
FEDRawData output 
)

Removes any data appended prior to FED buffer and reorders 32-bit words if swapped.

Definition at line 873 of file SiStripRawToDigiUnpacker.cc.

References FEDRawData::data(), newFWLiteAna::found, headerBytes_, edm::isDebugEnabled(), LogTrace, sistrip::mlRawToDigi_, evf::evtn::offset(), FEDRawData::resize(), and FEDRawData::size().

                                                                                                                      {
  
    // Check size of input buffer
    if ( input.size() < 24 ) { 
      output.resize( input.size() ); // Return UNadjusted buffer start position and size
      memcpy( output.data(), input.data(), input.size() );
      if ( edm::isDebugEnabled() ) {
        std::stringstream ss; 
        ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "] "
           << "Input FEDRawData with FED id " << fed_id 
           << " has size " << input.size();
        edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
      }
      return;
    } 
  
    // Iterator through buffer to find DAQ header 
    bool found = false;
    uint16_t ichar = 0;
    while ( ichar < input.size()-16 && !found ) {
      uint16_t offset = headerBytes_ < 0 ? ichar : headerBytes_; // Negative value means use "search mode" to find DAQ header
      uint32_t* input_u32   = reinterpret_cast<uint32_t*>( const_cast<unsigned char*>( input.data() ) + offset );
      uint32_t* fed_trailer = reinterpret_cast<uint32_t*>( const_cast<unsigned char*>( input.data() ) + input.size() - 8 );
    
      // see info on FED 32-bit swapping at end-of-file

      bool old_vme_header = ( input_u32[0] & 0xF0000000 ) == 0x50000000 && ( fed_trailer[0]  & 0xF0000000 ) == 0xA0000000 && ( (fed_trailer[0] & 0x00FFFFFF)*0x8 ) == (input.size() - offset);
    
      bool old_slink_header = ( input_u32[1] & 0xF0000000 ) == 0x50000000 && ( fed_trailer[1]  & 0xF0000000 ) == 0xA0000000 && ( (fed_trailer[1] & 0x00FFFFFF)*0x8 ) == (input.size() - offset);
    
      bool old_slink_payload = ( input_u32[3] & 0xFF000000 ) == 0xED000000;
    
      bool new_buffer_format = ( input_u32[2] & 0xFF000000 ) == 0xC5000000;
    
      if ( old_vme_header )  {
      
        // Found DAQ header at byte position 'offset'
        found = true;
        output.resize( input.size()-offset );
        memcpy( output.data(),         // target
                input.data()+offset,   // source
                input.size()-offset ); // nbytes
        if ( headerBytes_ < 0 ) {
          if ( edm::isDebugEnabled() ) {
            std::stringstream ss;
            ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]" 
               << " Buffer for FED id " << fed_id 
               << " has been found at byte position " << offset
               << " with a size of " << input.size()-offset << " bytes."
               << " Adjust the configurable 'AppendedBytes' to " << offset;
            LogTrace("SiStripRawToDigi") << ss.str();
          }
        }
      
      } else if ( old_slink_header ) {
      
        if ( old_slink_payload ) {
      
          // Found DAQ header (with MSB and LSB 32-bit words swapped) at byte position 'offset' 
          found = true;
          output.resize( input.size()-offset );
          uint32_t* output_u32 = reinterpret_cast<uint32_t*>( const_cast<unsigned char*>( output.data() ) );
          uint16_t iter = offset; 
          while ( iter < output.size() / sizeof(uint32_t) ) {
            output_u32[iter] = input_u32[iter+1];
            output_u32[iter+1] = input_u32[iter];
            iter+=2;
          }
          if ( headerBytes_ < 0 ) {
            if ( edm::isDebugEnabled() ) {
              std::stringstream ss;
              ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]" 
                 << " Buffer (with MSB and LSB 32-bit words swapped) for FED id " << fed_id 
                 << " has been found at byte position " << offset
                 << " with a size of " << output.size() << " bytes."
                 << " Adjust the configurable 'AppendedBytes' to " << offset;
              LogTrace("SiStripRawToDigi") << ss.str();
            }
          }

        } else if ( new_buffer_format ) {
        
          // Found DAQ header at byte position 'offset'
          found = true;
          output.resize( input.size()-offset );
          memcpy( output.data(),         // target
                  input.data()+offset,   // source
                  input.size()-offset ); // nbytes
          if ( headerBytes_ < 0 ) {
            if ( edm::isDebugEnabled() ) {
              std::stringstream ss;
              ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]" 
                 << " Buffer for FED id " << fed_id 
                 << " has been found at byte position " << offset
                 << " with a size of " << input.size()-offset << " bytes."
                 << " Adjust the configurable 'AppendedBytes' to " << offset;
              LogTrace("SiStripRawToDigi") << ss.str();
            }
          }
        
        } else { headerBytes_ < 0 ? found = false : found = true; }
      } else { headerBytes_ < 0 ? found = false : found = true; }
      ichar++;
    }      
  
    // Check size of output buffer
    if ( output.size() == 0 ) { 
    
      // Did not find DAQ header after search => return buffer with null size
      output.resize( 0 ); //@@ NULL SIZE
      memcpy( output.data(), input.data(), 0 ); //@@ NULL SIZE
      if ( edm::isDebugEnabled() ) {
        std::stringstream ss;
        if ( headerBytes_ < 0 ) {
          ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
             << " DAQ header not found within buffer for FED id: " << fed_id;
        } else {
          uint32_t* input_u32 = reinterpret_cast<uint32_t*>( const_cast<unsigned char*>( input.data() ) );
          ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
             << " DAQ header not found at expected location for FED id: " << fed_id << std::endl
             << " First 64-bit word of buffer is 0x"
             << std::hex 
             << std::setfill('0') << std::setw(8) << input_u32[0] 
             << std::setfill('0') << std::setw(8) << input_u32[1] 
             << std::dec << std::endl
             << " Adjust 'AppendedBytes' configurable to '-1' to activate 'search mode'";
        }
        edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
      }
    
    } else if ( output.size() < 24 ) { // Found DAQ header after search, but too few words
    
      if ( edm::isDebugEnabled() ) {
        std::stringstream ss; 
        ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
           << " Unexpected buffer size! FEDRawData with FED id " << fed_id 
           << " has size " << output.size();
        edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
      }
    }   
  }
void sistrip::RawToDigiUnpacker::physicalOrder ( uint16_t &  readout_order,
uint16_t &  physical_order 
) [inline, private]

order of strips

Definition at line 155 of file SiStripRawToDigiUnpacker.h.

{
  physical_order = ( (32 * (readout_order%4)) + (8 * static_cast<uint16_t>(static_cast<float>(readout_order)/4.0)) - (31 * static_cast<uint16_t>(static_cast<float>(readout_order)/16.0)) );
}
void sistrip::RawToDigiUnpacker::quiet ( bool  quiet) [inline]

verbosity

Definition at line 178 of file SiStripRawToDigiUnpacker.h.

{ quiet_ = quiet; }
void sistrip::RawToDigiUnpacker::readoutOrder ( uint16_t &  physical_order,
uint16_t &  readout_order 
) [inline, private]

order of strips

Definition at line 150 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

{
  readout_order = ( 4*((static_cast<uint16_t>((static_cast<float>(physical_order)/8.0)))%4) + static_cast<uint16_t>(static_cast<float>(physical_order)/32.0) + 16*(physical_order%8) );
}
void sistrip::RawToDigiUnpacker::triggerFed ( const FEDRawDataCollection buffers,
SiStripEventSummary summary,
const uint32_t &  event 
)

trigger info

Definition at line 755 of file SiStripRawToDigiUnpacker.cc.

References SiStripEventSummary::bx(), SiStripEventSummary::commissioningInfo(), fedt_struct::conscheck, FEDRawData::data(), SiStripEventSummary::event(), FEDRawDataCollection::FEDData(), TFHeaderDescription::getBunchCrossing(), TFHeaderDescription::getFedEventNumber(), edm::isDebugEnabled(), SiStripEventSummary::isSet(), FEDNumbering::lastFEDId(), LogTrace, sistrip::mlRawToDigi_, once_, FEDRawData::size(), summarizeEdmComparisonLogfiles::summary, groupFilesInBlocks::temp, SiStripEventSummary::triggerFed(), and triggerFedId_.

Referenced by sistrip::RawToDigiModule::produce().

                                                                                                                               {
  
    // Pointer to data (recast as 32-bit words) and number of 32-bit words
    uint32_t* data_u32 = 0;
    uint32_t  size_u32 = 0;
  
    // Search mode
    if ( triggerFedId_ < 0 ) { 
    
      uint16_t ifed = 0;
      while ( triggerFedId_ < 0 && 
              ifed < 1 + FEDNumbering::lastFEDId() ) {
        const FEDRawData& trigger_fed = buffers.FEDData( ifed );
        if ( trigger_fed.data() && trigger_fed.size() ) {
          uint8_t*  temp = const_cast<uint8_t*>( trigger_fed.data() );
          data_u32 = reinterpret_cast<uint32_t*>( temp ) + sizeof(fedh_t)/sizeof(uint32_t) + 1;
          size_u32 = trigger_fed.size()/sizeof(uint32_t) - sizeof(fedh_t)/sizeof(uint32_t) - 1;
          fedt_t* fed_trailer = reinterpret_cast<fedt_t*>( temp + trigger_fed.size() - sizeof(fedt_t) );
          if ( fed_trailer->conscheck == 0xDEADFACE ) { 
            triggerFedId_ = ifed; 
            if ( edm::isDebugEnabled() ) {
              std::stringstream ss;
              ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
                 << " Search mode for 'trigger FED' activated!"
                 << " Found 'trigger FED' info with id " << triggerFedId_;
              LogTrace("SiStripRawToDigi") << ss.str();
            }
          }
        }
        ifed++;
      }
      if ( triggerFedId_ < 0 ) {
        triggerFedId_ = 0;
        if ( edm::isDebugEnabled() ) {
          std::stringstream ss;
          ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
             << " Search mode for 'trigger FED' activated!"
             << " 'Trigger FED' info not found!";
          edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
        }
      }  
    } 

    // "Trigger FED" id given in .cfg file
    else if ( triggerFedId_ > 0 ) { 
    
      const FEDRawData& trigger_fed = buffers.FEDData( triggerFedId_ );
      if ( trigger_fed.data() && trigger_fed.size() ) {
        uint8_t*  temp = const_cast<uint8_t*>( trigger_fed.data() );
        data_u32 = reinterpret_cast<uint32_t*>( temp ) + sizeof(fedh_t)/sizeof(uint32_t) + 1;
        size_u32 = trigger_fed.size()/sizeof(uint32_t) - sizeof(fedh_t)/sizeof(uint32_t) - 1;
        fedt_t* fed_trailer = reinterpret_cast<fedt_t*>( temp + trigger_fed.size() - sizeof(fedt_t) );
        if ( fed_trailer->conscheck != 0xDEADFACE ) { 
          if ( edm::isDebugEnabled() ) {
            edm::LogWarning(sistrip::mlRawToDigi_) 
              << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
              << " Unexpected stamp found in DAQ trailer (ie, not 0xDEADFACE)!"
              << " Buffer appears not to contain 'trigger FED' data!";
          }
          triggerFedId_ = 0; 
        }
      }
      
    } else { 
      triggerFedId_ = 0; 
      data_u32 = 0;
      size_u32 = 0;
    }
  
    // Populate summary object with commissioning information
    if ( triggerFedId_ > 0 ) { 

      // Some checks
      if ( !data_u32 ) {
        if ( edm::isDebugEnabled() ) {
          std::stringstream ss;
          ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
             << " NULL pointer to 'trigger FED' data";
          edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
        }
        return;
      } 
      if ( size_u32 < sizeof(TFHeaderDescription)/sizeof(uint32_t) ) {
        if ( edm::isDebugEnabled() ) {
          std::stringstream ss;
          ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
             << " Unexpected 'Trigger FED' data size [32-bit words]: " << size_u32;
          edm::LogWarning(sistrip::mlRawToDigi_) << ss.str();
        }
        return;
      }
    
      // Write event-specific data to event
      TFHeaderDescription* header = (TFHeaderDescription*) data_u32;
      summary.event( static_cast<uint32_t>( header->getFedEventNumber()) );
      summary.bx( static_cast<uint32_t>( header->getBunchCrossing()) );
    
      // Write commissioning information to event 
      uint32_t hsize = sizeof(TFHeaderDescription)/sizeof(uint32_t);
      uint32_t* head = &data_u32[hsize];
      summary.commissioningInfo( head, event );
      summary.triggerFed( triggerFedId_ );
    
    }

    // Some debug
    if ( summary.isSet() && once_ ) {
      if ( edm::isDebugEnabled() ) {
        std::stringstream ss;
        ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
           << " EventSummary built from \"trigger FED\":" 
           << std::endl << summary;
        LogTrace("SiStripRawToDigi") << ss.str();
      }
      once_ = false;
    }
  }
void sistrip::RawToDigiUnpacker::update ( RawDigis scope_mode,
RawDigis virgin_raw,
RawDigis proc_raw,
Digis zero_suppr,
RawDigis common_mode 
) [private]

fill DetSetVectors using registries

Definition at line 480 of file SiStripRawToDigiUnpacker.cc.

References cm_work_digis_, cm_work_registry_, filterCSVwithJSON::copy, cond::rpcobgas::detid, end, Exception, extractCm_, min, proc_work_digis_, proc_work_registry_, scope_work_digis_, scope_work_registry_, python::multivaluedict::sort(), edm::DetSetVector< T >::swap(), virgin_work_digis_, virgin_work_registry_, zs_work_digis_, and zs_work_registry_.

Referenced by createDigis().

                                                                                                                                           {
  
    if ( ! zs_work_registry_.empty() ) {
      std::sort( zs_work_registry_.begin(), zs_work_registry_.end() );
      std::vector< edm::DetSet<SiStripDigi> > sorted_and_merged;
      sorted_and_merged.reserve(  std::min(zs_work_registry_.size(), size_t(17000)) );
    
      bool errorInData = false;
      std::vector<Registry>::iterator it = zs_work_registry_.begin(), it2 = it+1, end = zs_work_registry_.end();
      while (it < end) {
        sorted_and_merged.push_back( edm::DetSet<SiStripDigi>(it->detid) );
        std::vector<SiStripDigi> & digis = sorted_and_merged.back().data;
        // first count how many digis we have
        size_t len = it->length;
        for (it2 = it+1; (it2 != end) && (it2->detid == it->detid); ++it2) { len += it2->length; }
        // reserve memory 
        digis.reserve(len);
        // push them in
        for (it2 = it+0; (it2 != end) && (it2->detid == it->detid); ++it2) {
          digis.insert( digis.end(), & zs_work_digis_[it2->index], & zs_work_digis_[it2->index + it2->length] );
        }
        it = it2;
      }
    
      // check sorting
      if (!__gnu_cxx::is_sorted( sorted_and_merged.begin(), sorted_and_merged.end() )) {
        // this is an error in the code: i DID sort it already!
        throw cms::Exception("Bug Found") 
          << "Container must be already sorted!\nat " 
          << __FILE__ 
          << ", line " 
          << __LINE__ 
          <<"\n";
      }
    
      std::vector< edm::DetSet<SiStripDigi> >::iterator iii = sorted_and_merged.begin();
      std::vector< edm::DetSet<SiStripDigi> >::iterator jjj = sorted_and_merged.end();
      for ( ; iii != jjj; ++iii ) { 
        if ( ! __gnu_cxx::is_sorted( iii->begin(), iii->end() ) ) {
          // this might be an error in the data, if the raws from one FED are not sorted
          iii->clear(); 
          errorInData = true;
        }
      } 
    
      // output error
      if (errorInData) edm::LogWarning("CorruptData") << "Some modules contained corrupted ZS raw data, and have been skipped in unpacking\n";
    
      // make output DetSetVector
      edm::DetSetVector<SiStripDigi> zero_suppr_dsv( sorted_and_merged, true ); 
      zero_suppr.swap( zero_suppr_dsv );
    } 
  
    // Populate final DetSetVector container with VR data 
    if ( !virgin_work_registry_.empty() ) {

      std::sort( virgin_work_registry_.begin(), virgin_work_registry_.end() );
    
      std::vector< edm::DetSet<SiStripRawDigi> > sorted_and_merged;
      sorted_and_merged.reserve( std::min(virgin_work_registry_.size(), size_t(17000)) );
    
      bool errorInData = false;
      std::vector<Registry>::iterator it = virgin_work_registry_.begin(), it2, end = virgin_work_registry_.end();
      while (it < end) {
        sorted_and_merged.push_back( edm::DetSet<SiStripRawDigi>(it->detid) );
        std::vector<SiStripRawDigi> & digis = sorted_and_merged.back().data;
      
        bool isDetOk = true; 
        // first count how many digis we have
        int maxFirstStrip = it->first;
        for (it2 = it+1; (it2 != end) && (it2->detid == it->detid); ++it2) { 
          // duplicated APV or data corruption. DO NOT 'break' here!
          if (it2->first <= maxFirstStrip) { isDetOk = false; continue; } 
          maxFirstStrip = it2->first;                           
        }
        if (!isDetOk) { errorInData = true; it = it2; continue; } // skip whole det
      
        // make room for 256 * (max_apv_pair + 1) Raw Digis
        digis.resize(maxFirstStrip + 256);
        // push them in
        for (it2 = it+0; (it2 != end) && (it2->detid == it->detid); ++it2) {
          // data corruption. DO NOT 'break' here
          if (it->length != 256)  { isDetOk = false; continue; } 
          std::copy( & virgin_work_digis_[it2->index], & virgin_work_digis_[it2->index + it2->length], & digis[it2->first] );
        }
        if (!isDetOk) { errorInData = true; digis.clear(); it = it2; continue; } // skip whole det
        it = it2;
      }
    
      // output error
      if (errorInData) edm::LogWarning("CorruptData") << "Some modules contained corrupted virgin raw data, and have been skipped in unpacking\n"; 
    
      // check sorting
      if ( !__gnu_cxx::is_sorted( sorted_and_merged.begin(), sorted_and_merged.end()  ) ) {
        // this is an error in the code: i DID sort it already!
        throw cms::Exception("Bug Found") 
          << "Container must be already sorted!\nat " 
          << __FILE__ 
          << ", line " 
          << __LINE__ 
          <<"\n";
      }
    
      // make output DetSetVector
      edm::DetSetVector<SiStripRawDigi> virgin_raw_dsv( sorted_and_merged, true ); 
      virgin_raw.swap( virgin_raw_dsv );
    }
  
    // Populate final DetSetVector container with VR data 
    if ( !proc_work_registry_.empty() ) {
      std::sort( proc_work_registry_.begin(), proc_work_registry_.end() );
    
      std::vector< edm::DetSet<SiStripRawDigi> > sorted_and_merged;
      sorted_and_merged.reserve( std::min(proc_work_registry_.size(), size_t(17000)) );
    
      bool errorInData = false;
      std::vector<Registry>::iterator it = proc_work_registry_.begin(), it2, end = proc_work_registry_.end();
      while (it < end) {
        sorted_and_merged.push_back( edm::DetSet<SiStripRawDigi>(it->detid) );
        std::vector<SiStripRawDigi> & digis = sorted_and_merged.back().data;
      
        bool isDetOk = true; 
        // first count how many digis we have
        int maxFirstStrip = it->first;
        for (it2 = it+1; (it2 != end) && (it2->detid == it->detid); ++it2) { 
          // duplicated APV or data corruption. DO NOT 'break' here!
          if (it2->first <= maxFirstStrip) { isDetOk = false; continue; } 
          maxFirstStrip = it2->first;                           
        }
        // skip whole det
        if (!isDetOk) { errorInData = true; it = it2; continue; } 
      
        // make room for 256 * (max_apv_pair + 1) Raw Digis
        digis.resize(maxFirstStrip + 256);
        // push them in
        for (it2 = it+0; (it2 != end) && (it2->detid == it->detid); ++it2) {
          // data corruption. DO NOT 'break' here
          if (it->length != 256)  { isDetOk = false; continue; } 
          std::copy( & proc_work_digis_[it2->index], & proc_work_digis_[it2->index + it2->length], & digis[it2->first] );
        }
        // skip whole det
        if (!isDetOk) { errorInData = true; digis.clear(); it = it2; continue; } 
        it = it2;
      }
    
      // output error
      if (errorInData) edm::LogWarning("CorruptData") << "Some modules contained corrupted proc raw data, and have been skipped in unpacking\n";
    
      // check sorting
      if ( !__gnu_cxx::is_sorted( sorted_and_merged.begin(), sorted_and_merged.end()  ) ) {
        // this is an error in the code: i DID sort it already!
        throw cms::Exception("Bug Found") 
          << "Container must be already sorted!\nat " 
          << __FILE__ 
          << ", line " 
          << __LINE__ 
          <<"\n";
      }
    
      // make output DetSetVector
      edm::DetSetVector<SiStripRawDigi> proc_raw_dsv( sorted_and_merged, true ); 
      proc_raw.swap( proc_raw_dsv );
    }
  
    // Populate final DetSetVector container with SM data 
    if ( !scope_work_registry_.empty() ) {
      std::sort( scope_work_registry_.begin(), scope_work_registry_.end() );
    
      std::vector< edm::DetSet<SiStripRawDigi> > sorted_and_merged;
      sorted_and_merged.reserve( scope_work_registry_.size() );
    
      bool errorInData = false;
      std::vector<Registry>::iterator it, end;
      for (it = scope_work_registry_.begin(), end = scope_work_registry_.end() ; it != end; ++it) {
        sorted_and_merged.push_back( edm::DetSet<SiStripRawDigi>(it->detid) );
        std::vector<SiStripRawDigi> & digis = sorted_and_merged.back().data;
        digis.insert( digis.end(), & scope_work_digis_[it->index], & scope_work_digis_[it->index + it->length] );
      
        if ( (it +1 != end) && (it->detid == (it+1)->detid) ) {
          errorInData = true; 
          // let's skip *all* the detsets for that key, as we don't know which is the correct one!
          do { ++it; } while ( ( it+1 != end) && (it->detid == (it+1)->detid) );
        }
      }

      // output error
      if (errorInData) edm::LogWarning("CorruptData") << "Some fed keys contained corrupted scope mode data, and have been skipped in unpacking\n"; 

      // check sorting
      if ( !__gnu_cxx::is_sorted( sorted_and_merged.begin(), sorted_and_merged.end()  ) ) {
        // this is an error in the code: i DID sort it already!
        throw cms::Exception("Bug Found") 
          << "Container must be already sorted!\nat " 
          << __FILE__ 
          << ", line " 
          << __LINE__ 
          <<"\n";
      }

      // make output DetSetVector
      edm::DetSetVector<SiStripRawDigi> scope_mode_dsv( sorted_and_merged, true ); 
      scope_mode.swap( scope_mode_dsv );
    }

    // Populate DetSetVector with Common Mode values 
    if ( extractCm_ ) {

      // Populate final DetSetVector container with VR data 
      if ( !cm_work_registry_.empty() ) {

        std::sort( cm_work_registry_.begin(), cm_work_registry_.end() );
    
        std::vector< edm::DetSet<SiStripRawDigi> > sorted_and_merged;
        sorted_and_merged.reserve( std::min(cm_work_registry_.size(), size_t(17000)) );
    
        bool errorInData = false;
        std::vector<Registry>::iterator it = cm_work_registry_.begin(), it2, end = cm_work_registry_.end();
        while (it < end) {
          sorted_and_merged.push_back( edm::DetSet<SiStripRawDigi>(it->detid) );
          std::vector<SiStripRawDigi> & digis = sorted_and_merged.back().data;
      
          bool isDetOk = true; 
          // first count how many digis we have
          int maxFirstStrip = it->first;
          for (it2 = it+1; (it2 != end) && (it2->detid == it->detid); ++it2) { 
            // duplicated APV or data corruption. DO NOT 'break' here!
            if (it2->first <= maxFirstStrip) { isDetOk = false; continue; } 
            maxFirstStrip = it2->first;                           
          }
          if (!isDetOk) { errorInData = true; it = it2; continue; } // skip whole det
          
          // make room for 2 * (max_apv_pair + 1) Common mode values
          digis.resize(maxFirstStrip + 2);
          // push them in
          for (it2 = it+0; (it2 != end) && (it2->detid == it->detid); ++it2) {
            // data corruption. DO NOT 'break' here
            if (it->length != 2)  { isDetOk = false; continue; } 
            std::copy( & cm_work_digis_[it2->index], & cm_work_digis_[it2->index + it2->length], & digis[it2->first] );
          }
          if (!isDetOk) { errorInData = true; digis.clear(); it = it2; continue; } // skip whole det
          it = it2;
        }
    
        // output error
        if (errorInData) edm::LogWarning("CorruptData") << "Some modules contained corrupted common mode data, and have been skipped in unpacking\n"; 
    
        // check sorting
        if ( !__gnu_cxx::is_sorted( sorted_and_merged.begin(), sorted_and_merged.end()  ) ) {
          // this is an error in the code: i DID sort it already!
          throw cms::Exception("Bug Found") 
            << "Container must be already sorted!\nat " 
            << __FILE__ 
            << ", line " 
            << __LINE__ 
            <<"\n";
        }
    
        // make output DetSetVector
        edm::DetSetVector<SiStripRawDigi> common_mode_dsv( sorted_and_merged, true ); 
        common_mode.swap( common_mode_dsv );
      }
      
    }
    
  }
void sistrip::RawToDigiUnpacker::updateEventSummary ( const sistrip::FEDBuffer fed,
SiStripEventSummary summary 
) [private]

sets the SiStripEventSummary -> not yet implemented for FEDBuffer class

Definition at line 1015 of file SiStripRawToDigiUnpacker.cc.

References SiStripEventSummary::commissioningInfo(), sistrip::FEDBufferBase::daqEventType(), sistrip::FEDFullDebugHeader::daqRegister(), sistrip::FEDFullDebugHeader::daqRegister2(), SiStripEventSummary::fedReadoutMode(), sistrip::FEDBuffer::feHeader(), sistrip::HEADER_TYPE_FULL_DEBUG, sistrip::FEDBufferBase::headerType(), sistrip::invalid32_, edm::isDebugEnabled(), SiStripEventSummary::isSet(), LogTrace, once_, summarizeEdmComparisonLogfiles::summary, SiStripEventSummary::triggerFed(), and triggerFedId_.

Referenced by createDigis().

                                                                                                        {
  
    // Retrieve contents of DAQ registers

    sistrip::FEDDAQEventType readout_mode = fed.daqEventType(); 
    uint32_t daq1 = sistrip::invalid32_;
    uint32_t daq2 = sistrip::invalid32_;

    if (fed.headerType() == sistrip::HEADER_TYPE_FULL_DEBUG) {
      const sistrip::FEDFullDebugHeader* header = 0;
      header = dynamic_cast<const sistrip::FEDFullDebugHeader*>(fed.feHeader());
      daq1 = static_cast<uint32_t>( header->daqRegister() ); 
      daq2 = static_cast<uint32_t>( header->daqRegister2() ); 
    }

  
    // If FED DAQ registers contain info, update (and possibly overwrite) EventSummary 
    if ( daq1 != 0 && daq1 != sistrip::invalid32_ ) {
    
      summary.triggerFed( triggerFedId_ );
      summary.fedReadoutMode( readout_mode );
      summary.commissioningInfo( daq1, daq2 );
    
      if ( summary.isSet() && once_ ) {
        if ( edm::isDebugEnabled() ) {
          std::stringstream ss;
          ss << "[sistrip::RawToDigiUnpacker::" << __func__ << "]"
             << " EventSummary built from FED DAQ registers:"
             << std::endl << summary;
          LogTrace("SiStripRawToDigi") << ss.str();
        }
        once_ = false;
      }
    }
  }
void sistrip::RawToDigiUnpacker::useDaqRegister ( bool  use) [inline]

EventSummary update request -> not yet implemented for FEDBuffer class.

Definition at line 180 of file SiStripRawToDigiUnpacker.h.

{ useDaqRegister_ =  use; }

Friends And Related Function Documentation

friend class RawToClustersLazyUnpacker [friend]

Definition at line 31 of file SiStripRawToDigiUnpacker.h.


Member Data Documentation

Definition at line 145 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().

Definition at line 138 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().

Definition at line 130 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

Definition at line 129 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

Definition at line 131 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

other values

Definition at line 123 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

Definition at line 128 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis(), and update().

Definition at line 115 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

Definition at line 116 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

Definition at line 125 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

configurables

Definition at line 114 of file SiStripRawToDigiUnpacker.h.

Referenced by locateStartOfFedBuffer().

Definition at line 120 of file SiStripRawToDigiUnpacker.h.

Definition at line 124 of file SiStripRawToDigiUnpacker.h.

Referenced by triggerFed(), and updateEventSummary().

Definition at line 144 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().

Definition at line 137 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().

Definition at line 127 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

Definition at line 143 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().

Definition at line 136 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().

Definition at line 117 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis(), triggerFed(), and updateEventSummary().

Definition at line 119 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis(), and RawToDigiUnpacker().

Definition at line 126 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

Definition at line 118 of file SiStripRawToDigiUnpacker.h.

Referenced by createDigis().

Definition at line 142 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().

Definition at line 135 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().

digi collections

Definition at line 141 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().

registries

Definition at line 134 of file SiStripRawToDigiUnpacker.h.

Referenced by cleanupWorkVectors(), createDigis(), and update().