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EcalTBDaqFormatter Class Reference

#include <EcalTBDaqFormatter.h>

Public Member Functions

 EcalTBDaqFormatter ()
 
void interpretRawData (const FEDRawData &data, EBDigiCollection &digicollection, EcalPnDiodeDigiCollection &pndigicollection, EcalRawDataCollection &DCCheaderCollection, EBDetIdCollection &dccsizecollection, EcalElectronicsIdCollection &ttidcollection, EcalElectronicsIdCollection &blocksizecollection, EBDetIdCollection &chidcollection, EBDetIdCollection &gaincollection, EBDetIdCollection &gainswitchcollection, EcalElectronicsIdCollection &memttidcollection, EcalElectronicsIdCollection &memblocksizecollection, EcalElectronicsIdCollection &memgaincollection, EcalElectronicsIdCollection &memchidcollection, EcalTrigPrimDigiCollection &tpcollection)
 
virtual ~EcalTBDaqFormatter ()
 

Private Types

enum  SMElectronics_t {
  kSamplesPerChannel = 10, kSamplesPerPn = 50, kChannelsPerTower = 25, kStripsPerTower = 5,
  kChannelsPerStrip = 5, kPnPerTowerBlock = 5, kTriggerTowersAndMem = 70
}
 
enum  SMGeom_t {
  kModules = 4, kTriggerTowers = 68, kTowersInPhi = 4, kTowersInEta = 17,
  kCrystals = 1700, kPns = 10, kCrystalsInPhi = 20, kCrystalsInEta = 85,
  kCrystalsPerTower = 25, kCardsPerTower = 5, kChannelsPerCard = 5
}
 

Private Member Functions

std::pair< int, int > cellIndex (int tower_id, int strip, int xtal)
 
int cryIc (int tower_id, int strip, int xtal)
 
void DecodeMEM (DCCTBTowerBlock *towerblock, EcalPnDiodeDigiCollection &pndigicollection, EcalElectronicsIdCollection &memttidcollection, EcalElectronicsIdCollection &memblocksizecollection, EcalElectronicsIdCollection &memgaincollection, EcalElectronicsIdCollection &memchidcollection)
 
bool leftTower (int tower) const
 
bool rightTower (int tower) const
 

Private Attributes

unsigned _ExpectedTowers [71]
 
unsigned _expTowersIndex
 
unsigned _numExpectedTowers
 
int data_MEM [500]
 
int memRawSample_ [kStripsPerTower][kChannelsPerStrip][kSamplesPerChannel+1]
 
bool pnAllocated
 
bool pnIsOkInBlock [kPnPerTowerBlock]
 
DCCTBDataParsertheParser_
 

Detailed Description

Author
N. Marinelli IASA-Athens
G. Della Ricca
G. Franzoni
A. Ghezzi

Definition at line 26 of file EcalTBDaqFormatter.h.

Member Enumeration Documentation

Enumerator
kSamplesPerChannel 
kSamplesPerPn 
kChannelsPerTower 
kStripsPerTower 
kChannelsPerStrip 
kPnPerTowerBlock 
kTriggerTowersAndMem 

Definition at line 80 of file EcalTBDaqFormatter.h.

80  {
81  kSamplesPerChannel = 10, // Number of sample per channel, per event
82  kSamplesPerPn = 50, // Number of sample per PN, per event
83  kChannelsPerTower = 25, // Number of channels per trigger tower
84  kStripsPerTower = 5, // Number of VFE cards per trigger tower
85  kChannelsPerStrip = 5, // Number channels per VFE card
86  kPnPerTowerBlock = 5, // Number Pn diodes pertaining to 1 tower block = 1/2 mem box
87  kTriggerTowersAndMem = 70 // Number of trigger towers block including mems
88  };
Enumerator
kModules 
kTriggerTowers 
kTowersInPhi 
kTowersInEta 
kCrystals 
kPns 
kCrystalsInPhi 
kCrystalsInEta 
kCrystalsPerTower 
kCardsPerTower 
kChannelsPerCard 

Definition at line 66 of file EcalTBDaqFormatter.h.

66  {
67  kModules = 4, // Number of modules per supermodule
68  kTriggerTowers = 68, // Number of trigger towers per supermodule
69  kTowersInPhi = 4, // Number of trigger towers in phi
70  kTowersInEta = 17, // Number of trigger towers in eta
71  kCrystals = 1700, // Number of crystals per supermodule
72  kPns = 10, // Number of PN laser monitoring diodes per supermodule
73  kCrystalsInPhi = 20, // Number of crystals in phi
74  kCrystalsInEta = 85, // Number of crystals in eta
75  kCrystalsPerTower = 25, // Number of crystals per trigger tower
76  kCardsPerTower = 5, // Number of VFE cards per trigger tower
77  kChannelsPerCard = 5 // Number of channels per VFE card
78  };

Constructor & Destructor Documentation

EcalTBDaqFormatter::EcalTBDaqFormatter ( )

Definition at line 30 of file EcalTBDaqFormatter.cc.

References LogDebug, and theParser_.

30  {
31  LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter";
32  std::vector<uint32_t> parameters;
33  parameters.push_back(10); // parameters[0] is the xtal samples
34  parameters.push_back(1); // parameters[1] is the number of trigger time samples for TPG's
35  parameters.push_back(68); // parameters[2] is the number of TT
36  parameters.push_back(68); // parameters[3] is the number of SR Flags
37  parameters.push_back(1); // parameters[4] is the dcc id
38  parameters.push_back(1); // parameters[5] is the sr id
39  parameters.push_back(1); // parameters[6] is the tcc1 id
40  parameters.push_back(2); // parameters[7] is the tcc2 id
41  parameters.push_back(3); // parameters[8] is the tcc3 id
42  parameters.push_back(4); // parameters[9] is the tcc4 id
43 
44  theParser_ = new DCCTBDataParser(parameters);
45 }
DCCTBDataParser * theParser_
#define LogDebug(id)
virtual EcalTBDaqFormatter::~EcalTBDaqFormatter ( )
inlinevirtual

Definition at line 29 of file EcalTBDaqFormatter.h.

References LogDebug.

29  {
30  LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter"
31  << "\n";
32  };
#define LogDebug(id)

Member Function Documentation

std::pair< int, int > EcalTBDaqFormatter::cellIndex ( int  tower_id,
int  strip,
int  xtal 
)
private

Definition at line 723 of file EcalTBDaqFormatter.cc.

References PVValHelper::eta, kCardsPerTower, kChannelsPerCard, kCrystalsPerTower, kTowersInPhi, phi, and rightTower().

Referenced by cryIc().

723  {
724  int xtal = (strip - 1) * 5 + ch - 1;
725  // std::cout << " cellIndex input xtal " << xtal << std::endl;
726  std::pair<int, int> ind;
727 
728  int eta = (tower_id - 1) / kTowersInPhi * kCardsPerTower;
729  int phi = (tower_id - 1) % kTowersInPhi * kChannelsPerCard;
730 
731  if (rightTower(tower_id))
732  eta += xtal / kCardsPerTower;
733  else
734  eta += (kCrystalsPerTower - 1 - xtal) / kCardsPerTower;
735 
736  if ((rightTower(tower_id) && (xtal / kCardsPerTower) % 2 == 1) ||
737  (!rightTower(tower_id) && (xtal / kCardsPerTower) % 2 == 0))
738 
739  phi += (kChannelsPerCard - 1 - xtal % kChannelsPerCard);
740  else
741  phi += xtal % kChannelsPerCard;
742 
743  ind.first = eta + 1;
744  ind.second = phi + 1;
745 
746  // std::cout << " EcalTBDaqFormatter::cell_index eta " << ind.first << " phi " << ind.second << " " << std::endl;
747 
748  return ind;
749 }
bool rightTower(int tower) const
int EcalTBDaqFormatter::cryIc ( int  tower_id,
int  strip,
int  xtal 
)
private

Definition at line 751 of file EcalTBDaqFormatter.cc.

References cellIndex(), kCrystalsInPhi, and hgcalTowerProducer_cfi::tower.

Referenced by interpretRawData().

751  {
752  if (strip < 1 || 5 < strip || ch < 1 || 5 < ch || 68 < tower) {
753  edm::LogWarning("EcalTBRawToDigiChId") << "EcalTBDaqFormatter::interpretRawData (cryIc) "
754  << " wrong channel id, since out of range: "
755  << "\t strip: " << strip << "\t channel: " << ch << "\t in TT: " << tower;
756  return -1;
757  }
758 
759  std::pair<int, int> cellInd = EcalTBDaqFormatter::cellIndex(tower, strip, ch);
760  return cellInd.second + (cellInd.first - 1) * kCrystalsInPhi;
761 }
std::pair< int, int > cellIndex(int tower_id, int strip, int xtal)
Log< level::Warning, false > LogWarning
void EcalTBDaqFormatter::DecodeMEM ( DCCTBTowerBlock towerblock,
EcalPnDiodeDigiCollection pndigicollection,
EcalElectronicsIdCollection memttidcollection,
EcalElectronicsIdCollection memblocksizecollection,
EcalElectronicsIdCollection memgaincollection,
EcalElectronicsIdCollection memchidcollection 
)
private

Definition at line 525 of file EcalTBDaqFormatter.cc.

References _ExpectedTowers, _expTowersIndex, edm::EDCollection< T >::begin(), data_MEM, edm::EDCollection< T >::empty(), edm::EDCollection< T >::end(), cuy::ib, gpuClustering::id, kChannelsPerStrip, kChannelsPerTower, kPnPerTowerBlock, kSamplesPerChannel, kSamplesPerPn, kStripsPerTower, LogDebug, memRawSample_, pnIsOkInBlock, edm::EDCollection< T >::push_back(), edm::SortedCollection< T, SORT >::push_back(), makeMEIFBenchmarkPlots::sample, EcalPnDiodeDigi::setSample(), EcalPnDiodeDigi::setSize(), digitizers_cfi::strip, DCCTBTowerBlock::towerID(), and DCCTBTowerBlock::xtalBlocks().

Referenced by interpretRawData().

530  {
531  LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::DecodeMEM"
532  << "in mem " << towerblock->towerID();
533 
534  int tower_id = towerblock->towerID();
535  int mem_id = tower_id - 69;
536 
537  // initializing container
538  for (int st_id = 0; st_id < kStripsPerTower; st_id++) {
539  for (int ch_id = 0; ch_id < kChannelsPerStrip; ch_id++) {
540  for (int sa = 0; sa < 11; sa++) {
541  memRawSample_[st_id][ch_id][sa] = -1;
542  }
543  }
544  }
545 
546  // check that tower block id corresponds to mem boxes
547  if (tower_id != 69 && tower_id != 70) {
548  edm::LogWarning("EcalTBRawToDigiTowerId") << "@SUB=EcalTBDaqFormatter:decodeMem"
549  << "DecodeMEM: this is not a mem box tower (" << tower_id << ")";
550  ++_expTowersIndex;
551  return;
552  }
553 
554  /******************************************************************************
555  // getting the raw hits from towerBlock while checking tt and ch data structure
556  ******************************************************************************/
557  std::vector<DCCTBXtalBlock*>& dccXtalBlocks = towerblock->xtalBlocks();
558  std::vector<DCCTBXtalBlock*>::iterator itXtal;
559 
560  // checking mem tower block fo size
561  if (dccXtalBlocks.size() != kChannelsPerTower) {
562  LogDebug("EcalTBRawToDigiDccBlockSize")
563  << "@SUB=EcalTBDaqFormatter:decodeMem"
564  << " wrong dccBlock size, namely: " << dccXtalBlocks.size() << ", for mem " << _ExpectedTowers[_expTowersIndex];
565 
566  // reporting mem-tt block size problem
567  // chosing channel 1 as representative as a dummy...
569  memblocksizecollection.push_back(id);
570 
571  ++_expTowersIndex;
572  return; // if mem tt block size not ok - do not build any Pn digis
573  }
574 
575  // loop on channels of the mem block
576  int cryCounter = 0;
577  int strip_id = 0;
578  int xtal_id = 0;
579 
580  for (itXtal = dccXtalBlocks.begin(); itXtal < dccXtalBlocks.end(); itXtal++) {
581  strip_id = (*itXtal)->getDataField("STRIP ID");
582  xtal_id = (*itXtal)->getDataField("XTAL ID");
583  int wished_strip_id = cryCounter / kStripsPerTower;
584  int wished_ch_id = cryCounter % kStripsPerTower;
585 
586  if ((wished_strip_id + 1) != ((int)strip_id) || (wished_ch_id + 1) != ((int)xtal_id)) {
587  LogDebug("EcalTBRawToDigiChId") << "@SUB=EcalTBDaqFormatter:decodeMem"
588  << " in mem " << towerblock->towerID() << ", expected:\t strip"
589  << (wished_strip_id + 1) << " cry " << (wished_ch_id + 1) << "\tfound: "
590  << " strip " << strip_id << " cry " << xtal_id;
591 
592  // report on crystal with unexpected indices
593  EcalElectronicsId id(1, (int)_ExpectedTowers[_expTowersIndex], wished_strip_id, wished_ch_id);
594  memchidcollection.push_back(id);
595  }
596 
597  // Accessing the 10 time samples per Xtal:
598  memRawSample_[wished_strip_id][wished_ch_id][1] = (*itXtal)->getDataField("ADC#1");
599  memRawSample_[wished_strip_id][wished_ch_id][2] = (*itXtal)->getDataField("ADC#2");
600  memRawSample_[wished_strip_id][wished_ch_id][3] = (*itXtal)->getDataField("ADC#3");
601  memRawSample_[wished_strip_id][wished_ch_id][4] = (*itXtal)->getDataField("ADC#4");
602  memRawSample_[wished_strip_id][wished_ch_id][5] = (*itXtal)->getDataField("ADC#5");
603  memRawSample_[wished_strip_id][wished_ch_id][6] = (*itXtal)->getDataField("ADC#6");
604  memRawSample_[wished_strip_id][wished_ch_id][7] = (*itXtal)->getDataField("ADC#7");
605  memRawSample_[wished_strip_id][wished_ch_id][8] = (*itXtal)->getDataField("ADC#8");
606  memRawSample_[wished_strip_id][wished_ch_id][9] = (*itXtal)->getDataField("ADC#9");
607  memRawSample_[wished_strip_id][wished_ch_id][10] = (*itXtal)->getDataField("ADC#10");
608 
609  cryCounter++;
610  } // end loop on crystals of mem dccXtalBlock
611 
612  // tower accepted and digi read from all 25 channels.
613  // Increase counter of expected towers before unpacking in the 5 PNs
614  ++_expTowersIndex;
615 
616  /************************************************************
617  // unpacking and 'cooking' the raw numbers to get PN sample
618  ************************************************************/
619  int tempSample = 0;
620  int memStoreIndex = 0;
621  int ipn = 0;
622  for (memStoreIndex = 0; memStoreIndex < 500; memStoreIndex++) {
623  data_MEM[memStoreIndex] = -1;
624  }
625 
626  for (int strip = 0; strip < kStripsPerTower; strip++) { // loop on strips
627  for (int channel = 0; channel < kChannelsPerStrip; channel++) { // loop on channels
628 
629  if (strip % 2 == 0) {
630  ipn = mem_id * 5 + channel;
631  } else {
632  ipn = mem_id * 5 + 4 - channel;
633  }
634 
635  for (int sample = 0; sample < kSamplesPerChannel; sample++) {
636  tempSample = memRawSample_[strip][channel][sample + 1];
637 
638  int new_data = 0;
639  if (strip % 2 == 1) {
640  // 1) if strip number is even, 14 bits are reversed in order
641  for (int ib = 0; ib < 14; ib++) {
642  new_data <<= 1;
643  new_data = new_data | (tempSample & 1);
644  tempSample >>= 1;
645  }
646  } else {
647  new_data = tempSample;
648  }
649 
650  // 2) flip 11th bit for AD9052 still there on MEM !
651  // 3) mask with 1 1111 1111 1111
652  new_data = (new_data ^ 0x800) & 0x3fff; // (new_data XOR 1000 0000 0000) & 11 1111 1111 1111
653  // new_data = (new_data ^ 0x800) & 0x1fff; // (new_data XOR 1000 0000 0000) & 1 1111 1111 1111
654 
655  //(Bit 12) == 1 -> Gain 16; (Bit 12) == 0 -> Gain 1
656  // gain in mem can be 1 or 16 encoded resp. with 0 ir 1 in the 13th bit.
657  // checking and reporting if there is any sample with gain==2,3
658  short sampleGain = (new_data & 0x3000) / 4096;
659  if (sampleGain == 2 || sampleGain == 3) {
661  memgaincollection.push_back(id);
662 
663  edm::LogWarning("EcalTBRawToDigiGainZero")
664  << "@SUB=EcalTBDaqFormatter:decodeMem"
665  << "in mem " << towerblock->towerID() << " :\t strip: " << (strip + 1) << " cry: " << (channel + 1)
666  << " has 14th bit non zero! Gain results: " << sampleGain << ".";
667 
668  continue;
669  } // end 'if gain is zero'
670 
671  memStoreIndex = ipn * 50 + strip * kSamplesPerChannel + sample;
672  // storing in data_MEM also the gain bits
673  data_MEM[memStoreIndex] = new_data & 0x3fff;
674 
675  } // loop on samples
676  } // loop on strips
677  } // loop on channels
678 
679  for (int pnId = 0; pnId < kPnPerTowerBlock; pnId++)
680  pnIsOkInBlock[pnId] = true;
681  // if anything was wrong with mem_tt_id or mem_tt_size: you would have already exited
682  // otherwise, if any problem with ch_gain or ch_id: must not produce digis for the pertaining Pn
683 
684  if (!(memgaincollection.empty() && memchidcollection.empty())) {
685  for (EcalElectronicsIdCollection::const_iterator idItr = memgaincollection.begin();
686  idItr != memgaincollection.end();
687  ++idItr) {
688  int ch = (*idItr).channelId();
689  ch = (ch - 1) / 5;
690  pnIsOkInBlock[ch] = false;
691  }
692 
693  for (EcalElectronicsIdCollection::const_iterator idItr = memchidcollection.begin();
694  idItr != memchidcollection.end();
695  ++idItr) {
696  int ch = (*idItr).channelId();
697  ch = (ch - 1) / 5;
698  pnIsOkInBlock[ch] = false;
699  }
700 
701  } // end: if any ch_gain or ch_id problems exclude the Pn's from digi production
702 
703  // looping on PN's of current mem box
704  for (int pnId = 1; pnId < (kPnPerTowerBlock + 1); pnId++) {
705  // if present Pn has any of its 5 channels with problems, do not produce digi for it
706  if (!pnIsOkInBlock[pnId - 1])
707  continue;
708 
709  // DccId set to 28 to be consistent with ism==1
710  EcalPnDiodeDetId PnId(1, 28, pnId + kPnPerTowerBlock * mem_id);
711  EcalPnDiodeDigi thePnDigi(PnId);
712 
713  thePnDigi.setSize(kSamplesPerPn);
714 
715  for (int sample = 0; sample < kSamplesPerPn; sample++) {
716  EcalFEMSample thePnSample(data_MEM[(mem_id)*250 + (pnId - 1) * kSamplesPerPn + sample]);
717  thePnDigi.setSample(sample, thePnSample);
718  }
719  pndigicollection.push_back(thePnDigi);
720  }
721 }
int ib
Definition: cuy.py:661
std::vector< DCCTBXtalBlock * > & xtalBlocks()
Definition: DCCTowerBlock.h:48
uint16_t *__restrict__ id
const_iterator end() const
Definition: EDCollection.h:122
Ecal readout channel identification [32:20] Unused (so far) [19:13] DCC id [12:6] tower [5:3] strip [...
void push_back(T const &t)
void push_back(T const &t)
Definition: EDCollection.h:60
bool empty() const
Definition: EDCollection.h:77
bool pnIsOkInBlock[kPnPerTowerBlock]
unsigned _ExpectedTowers[71]
const_iterator begin() const
Definition: EDCollection.h:117
int memRawSample_[kStripsPerTower][kChannelsPerStrip][kSamplesPerChannel+1]
Log< level::Warning, false > LogWarning
#define LogDebug(id)
std::vector< T >::const_iterator const_iterator
Definition: EDCollection.h:19
void EcalTBDaqFormatter::interpretRawData ( const FEDRawData data,
EBDigiCollection digicollection,
EcalPnDiodeDigiCollection pndigicollection,
EcalRawDataCollection DCCheaderCollection,
EBDetIdCollection dccsizecollection,
EcalElectronicsIdCollection ttidcollection,
EcalElectronicsIdCollection blocksizecollection,
EBDetIdCollection chidcollection,
EBDetIdCollection gaincollection,
EBDetIdCollection gainswitchcollection,
EcalElectronicsIdCollection memttidcollection,
EcalElectronicsIdCollection memblocksizecollection,
EcalElectronicsIdCollection memgaincollection,
EcalElectronicsIdCollection memchidcollection,
EcalTrigPrimDigiCollection tpcollection 
)

Definition at line 47 of file EcalTBDaqFormatter.cc.

References _ExpectedTowers, _expTowersIndex, _numExpectedTowers, edm::DataFrameContainer::back(), edmScanValgrind::buffer, cryIc(), FEDRawData::data(), DCCTBDataParser::dccEvents(), EcalDCCTBHeaderRuntypeDecoder::Decode(), DecodeMEM(), EcalBarrel, l1tstage2_dqm_sourceclient-live_cfg::fedId, first, mps_fire::i, gpuClustering::id, kChannelsPerCard, kChannelsPerStrip, kChannelsPerTower, kCrystals, kPns, kStripsPerTower, kTowersInPhi, kTriggerTowers, kTriggerTowersAndMem, LogDebug, MAX_TCC_SIZE, MAX_TT_SIZE, DCCTBDataParser::parseBuffer(), pnAllocated, edm::DataFrameContainer::pop_back(), edm::EDCollection< T >::push_back(), EBDigiCollection::push_back(), edm::SortedCollection< T, SORT >::push_back(), edm::DataFrameContainer::reserve(), edm::SortedCollection< T, SORT >::reserve(), edm::second(), EcalDCCHeaderBlock::setBasicTriggerType(), EcalDCCHeaderBlock::setBX(), EcalDCCHeaderBlock::setErrors(), EcalDCCHeaderBlock::setFedId(), EcalDCCHeaderBlock::setFEStatus(), EcalDCCHeaderBlock::setId(), EcalDCCHeaderBlock::setLV1(), EcalDCCHeaderBlock::setOrbit(), EcalDCCHeaderBlock::setRunNumber(), EcalTriggerPrimitiveDigi::setSample(), EcalDataFrame::setSample(), EcalDCCHeaderBlock::setSelectiveReadout(), EcalTriggerPrimitiveDigi::setSize(), EcalDCCHeaderBlock::setSrpStatus(), EcalDCCHeaderBlock::setTccStatus(), EcalDCCHeaderBlock::setTestZeroSuppression(), EcalDCCHeaderBlock::setZeroSuppression(), FEDRawData::size(), AlCaHLTBitMon_QueryRunRegistry::string, digitizers_cfi::strip, theParser_, hgcalTowerProducer_cfi::tower, and findQualityFiles::v.

Referenced by EcalDCCTBUnpackingModule::produce().

61  {
62  const unsigned char* pData = fedData.data();
63  int length = fedData.size();
64  bool shit = true;
65  unsigned int tower = 0;
66  int ch = 0;
67  int strip = 0;
68 
69  LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::interpretRawData"
70  << "size " << length;
71 
72  // mean + 3sigma estimation needed when switching to 0suppressed data
73  digicollection.reserve(kCrystals);
74  pnAllocated = false;
75 
76  theParser_->parseBuffer(reinterpret_cast<const uint32_t*>(pData), static_cast<uint32_t>(length), shit);
77 
78  std::vector<DCCTBEventBlock*>& dccEventBlocks = theParser_->dccEvents();
79 
80  // Access each DCCTB block
81  for (std::vector<DCCTBEventBlock*>::iterator itEventBlock = dccEventBlocks.begin();
82  itEventBlock != dccEventBlocks.end();
83  itEventBlock++) {
84  bool _displayParserMessages = false;
85  if ((*itEventBlock)->eventHasErrors() && _displayParserMessages) {
86  edm::LogWarning("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::interpretRawData"
87  << "errors found from parser... ";
88  edm::LogWarning("EcalTBRawToDigi") << (*itEventBlock)->eventErrorString();
89  edm::LogWarning("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::interpretRawData"
90  << "... errors from parser notified";
91  }
92 
93  // getting the fields of the DCC header
94  EcalDCCHeaderBlock theDCCheader;
95 
96  theDCCheader.setId(28); // tb unpacker: forced to 28 to get first geom slot in EB
97  int fedId = (*itEventBlock)->getDataField("FED/DCC ID");
98  theDCCheader.setFedId(fedId); // fed id as found in raw data (0... 35 at tb )
99 
100  theDCCheader.setRunNumber((*itEventBlock)->getDataField("RUN NUMBER"));
101  short trigger_type = (*itEventBlock)->getDataField("TRIGGER TYPE");
102  short zs = (*itEventBlock)->getDataField("ZS");
103  short tzs = (*itEventBlock)->getDataField("TZS");
104  short sr = (*itEventBlock)->getDataField("SR");
105  bool dataIsSuppressed;
106 
107  // if zs&&tzs the suppression algo is used in DCC, the data are not suppressed and zs-bits are set
108  if (zs && !(tzs))
109  dataIsSuppressed = true;
110  else
111  dataIsSuppressed = false;
112 
113  if (trigger_type > 0 && trigger_type < 5) {
114  theDCCheader.setBasicTriggerType(trigger_type);
115  } else {
116  edm::LogWarning("EcalTBRawToDigiTriggerType") << "@SUB=EcalTBDaqFormatter::interpretRawData"
117  << "unrecognized TRIGGER TYPE: " << trigger_type;
118  }
119  theDCCheader.setLV1((*itEventBlock)->getDataField("LV1"));
120  theDCCheader.setOrbit((*itEventBlock)->getDataField("ORBIT COUNTER"));
121  theDCCheader.setBX((*itEventBlock)->getDataField("BX"));
122  theDCCheader.setErrors((*itEventBlock)->getDataField("DCC ERRORS"));
123  theDCCheader.setSelectiveReadout(sr);
124  theDCCheader.setZeroSuppression(zs);
125  theDCCheader.setTestZeroSuppression(tzs);
126  theDCCheader.setSrpStatus((*itEventBlock)->getDataField("SR_CHSTATUS"));
127 
128  std::vector<short> theTCCs;
129  for (int i = 0; i < MAX_TCC_SIZE; i++) {
130  char TCCnum[20];
131  sprintf(TCCnum, "TCC_CHSTATUS#%d", i + 1);
132  std::string TCCnumS(TCCnum);
133  theTCCs.push_back((*itEventBlock)->getDataField(TCCnumS));
134  }
135  theDCCheader.setTccStatus(theTCCs);
136 
137  std::vector<DCCTBTCCBlock*> tccBlocks = (*itEventBlock)->tccBlocks();
138 
139  for (std::vector<DCCTBTCCBlock*>::iterator itTCCBlock = tccBlocks.begin(); itTCCBlock != tccBlocks.end();
140  itTCCBlock++) {
141  std::vector<std::pair<int, bool> > TpSamples = (*itTCCBlock)->triggerSamples();
142  // std::vector of 3 bits
143  std::vector<int> TpFlags = (*itTCCBlock)->triggerFlags();
144 
145  // there have always to be 68 primitives and flags, per FED
146  if (TpSamples.size() == 68 && TpFlags.size() == 68) {
147  for (int i = 0; i < ((int)TpSamples.size()); i++) {
148  int etaTT = (i) / kTowersInPhi + 1;
149  int phiTT = (i) % kTowersInPhi + 1;
150 
151  // follow HB convention in iphi
152  phiTT = 3 - phiTT;
153  if (phiTT <= 0)
154  phiTT = phiTT + 72;
155 
156  EcalTriggerPrimitiveSample theSample(TpSamples[i].first, TpSamples[i].second, TpFlags[i]);
157 
158  EcalTrigTowerDetId idtt(1, EcalBarrel, etaTT, phiTT, 0);
159 
160  EcalTriggerPrimitiveDigi thePrimitive(idtt);
161  thePrimitive.setSize(1); // hard coded
162  thePrimitive.setSample(0, theSample);
163 
164  tpcollection.push_back(thePrimitive);
165 
166  LogDebug("EcalTBRawToDigiTpg") << "@SUBS=EcalTBDaqFormatter::interpretRawData"
167  << "tower: " << (i + 1) << " primitive: " << TpSamples[i].first
168  << " flag: " << TpSamples[i].second;
169 
170  LogDebug("EcalTBRawToDigiTpg") << "@SUBS=EcalTBDaqFormatter::interpretRawData"
171  << "tower: " << (i + 1) << " flag: " << TpFlags[i];
172  } // end loop on tower primitives
173 
174  } // end if
175  else {
176  edm::LogWarning("EcalTBRawToDigiTpg")
177  << "68 elements not found for TpFlags or TpSamples, collection will be empty";
178  }
179  }
180 
181  short TowerStatus[MAX_TT_SIZE + 1];
182  char buffer[25];
183  std::vector<short> theTTstatus;
184  for (int i = 1; i < MAX_TT_SIZE + 1; i++) {
185  sprintf(buffer, "FE_CHSTATUS#%d", i);
186  std::string Tower(buffer);
187  TowerStatus[i] = (*itEventBlock)->getDataField(Tower);
188  theTTstatus.push_back(TowerStatus[i]);
189  //std::cout << "tower " << i << " has status " << TowerStatus[i] << std::endl;
190  }
191 
192  theDCCheader.setFEStatus(theTTstatus);
193 
194  EcalDCCTBHeaderRuntypeDecoder theRuntypeDecoder;
195  uint32_t DCCruntype = (*itEventBlock)->getDataField("RUN TYPE");
196  theRuntypeDecoder.Decode(DCCruntype, &theDCCheader);
197  //DCCHeader filled!
198  DCCheaderCollection.push_back(theDCCheader);
199 
200  std::vector<DCCTBTowerBlock*> dccTowerBlocks = (*itEventBlock)->towerBlocks();
201  LogDebug("EcalTBRawToDigi") << "@SUBS=EcalTBDaqFormatter::interpretRawData"
202  << "dccTowerBlocks size " << dccTowerBlocks.size();
203 
204  _expTowersIndex = 0;
205  _numExpectedTowers = 0;
206  for (int v = 0; v < 71; v++) {
207  _ExpectedTowers[v] = 99999;
208  }
209 
210  // note: these are the tower statuses handled at the moment - to be completed
211  // staus==0: tower expected;
212  // staus==9: Synk error LV1, tower expected;
213  // staus==10: Synk error BX, tower expected;
214  // status==1, 2, 3, 4, 5: tower not expected
215  for (int u = 1; u < (kTriggerTowersAndMem + 1); u++) {
216  if (TowerStatus[u] == 0 || TowerStatus[u] == 9 || TowerStatus[u] == 10) {
218  _expTowersIndex++;
220  }
221  }
222  // resetting counter of expected towers
223  _expTowersIndex = 0;
224 
225  // if number of dccEventBlocks NOT same as expected stop
226  if (!(dccTowerBlocks.size() == _numExpectedTowers)) {
227  // we probably always want to know if this happens
228  edm::LogWarning("EcalTBRawToDigiNumTowerBlocks")
229  << "@SUB=EcalTBDaqFormatter::interpretRawData"
230  << "number of TowerBlocks found (" << dccTowerBlocks.size() << ") differs from expected ("
231  << _numExpectedTowers << ") skipping event";
232 
233  EBDetId idsm(1, 1);
234  dccsizecollection.push_back(idsm);
235 
236  return;
237  }
238 
239  // Access the Tower block
240  for (std::vector<DCCTBTowerBlock*>::iterator itTowerBlock = dccTowerBlocks.begin();
241  itTowerBlock != dccTowerBlocks.end();
242  itTowerBlock++) {
243  tower = (*itTowerBlock)->towerID();
244 
245  // checking if tt in data is the same as tt expected
246  // else skip tower and increment problem counter
247 
248  // compute eta/phi in order to have iTT = _ExpectedTowers[_expTowersIndex]
249  // for the time being consider only zside>0
250 
252 
253  if (!(tower == _ExpectedTowers[_expTowersIndex])) {
254  if (_ExpectedTowers[_expTowersIndex] <= 68) {
255  edm::LogWarning("EcalTBRawToDigiTowerId")
256  << "@SUBS=EcalTBDaqFormatter::interpretRawData"
257  << "TTower id found (=" << tower << ") different from expected (=" << _ExpectedTowers[_expTowersIndex]
258  << ") " << (_expTowersIndex + 1) << "-th tower checked";
259 
260  // report on failed tt_id for regular tower block
261  ttidcollection.push_back(idtt);
262  } else {
263  edm::LogWarning("EcalTBRawToDigiTowerId")
264  << "@SUB=EcalTBDaqFormatter:interpretRawData"
265  << "DecodeMEM: tower " << tower << " is not the same as expected "
266  << ((int)_ExpectedTowers[_expTowersIndex]) << " (according to DCC header channel status)";
267 
268  // report on failed tt_id for mem tower block
269  // chosing channel 1 as representative
270  EcalElectronicsId id(1, (int)_ExpectedTowers[_expTowersIndex], 1, 1);
271  memttidcollection.push_back(id);
272  }
273 
274  ++_expTowersIndex;
275  continue;
276  } // if TT id found different than expected
277 
278  /*********************************
279  // tt: 1 ... 68: crystal data
280  *********************************/
281  if (0 < (*itTowerBlock)->towerID() && (*itTowerBlock)->towerID() < (kTriggerTowers + 1)) {
282  std::vector<DCCTBXtalBlock*>& xtalDataBlocks = (*itTowerBlock)->xtalBlocks();
283 
284  // if there is no zero suppression, tower block must have have 25 channels in it
285  if ((!dataIsSuppressed) && (xtalDataBlocks.size() != kChannelsPerTower)) {
286  edm::LogWarning("EcalTBRawToDigiTowerSize")
287  << "EcalTBDaqFormatter::interpretRawData, no zero suppression "
288  << "wrong tower block size is: " << xtalDataBlocks.size() << " at LV1 "
289  << (*itEventBlock)->getDataField("LV1") << " for TT " << _ExpectedTowers[_expTowersIndex];
290  // report on wrong tt block size
291  blocksizecollection.push_back(idtt);
292 
293  ++_expTowersIndex;
294  continue;
295  }
296 
297  short cryInTower = 0;
298 
299  short expStripInTower;
300  short expCryInStrip;
301  short expCryInTower = 0;
302 
303  // Access the Xstal data
304  for (std::vector<DCCTBXtalBlock*>::iterator itXtalBlock = xtalDataBlocks.begin();
305  itXtalBlock != xtalDataBlocks.end();
306  itXtalBlock++) { //loop on crys of a tower
307 
308  strip = (*itXtalBlock)->stripID();
309  ch = (*itXtalBlock)->xtalID();
310  cryInTower = (strip - 1) * kChannelsPerCard + (ch - 1);
311 
312  expStripInTower = expCryInTower / 5 + 1;
313  expCryInStrip = expCryInTower % 5 + 1;
314 
315  // FIXME: waiting for geometry to do (TT, strip,chNum) <--> (SMChId)
316  // short abscissa = (_ExpectedTowers[_expTowersIndex]-1) /4;
317  // short ordinate = (_ExpectedTowers[_expTowersIndex]-1) %4;
318  // temporarily choosing central crystal in trigger tower
319  // int cryIdInSM = 45 + ordinate*5 + abscissa * 100;
320 
321  // in case of 0 zuppressed data, check that cryInTower constantly grows
322  if (dataIsSuppressed) {
323  if (strip < 1 || 5 < strip || ch < 1 || 5 < ch) {
324  int sm = 1; // hardcoded because of test beam
325  for (int StripInTower_ = 1; StripInTower_ < 6; StripInTower_++) {
326  for (int CryInStrip_ = 1; CryInStrip_ < 6; CryInStrip_++) {
327  int ic = cryIc(tower, StripInTower_, CryInStrip_);
328  EBDetId idExp(sm, ic, 1);
329  chidcollection.push_back(idExp);
330  }
331  }
332 
333  edm::LogWarning("EcalTBRawToDigiChId")
334  << "EcalTBDaqFormatter::interpretRawData with zero suppression, "
335  << " wrong channel id, since out of range: "
336  << "\t strip: " << strip << "\t channel: " << ch << "\t in TT: " << _ExpectedTowers[_expTowersIndex]
337  << "\t at LV1 : " << (*itEventBlock)->getDataField("LV1");
338 
339  expCryInTower++;
340  continue;
341  }
342 
343  // correct ordering
344  if (cryInTower >= expCryInTower) {
345  expCryInTower = cryInTower + 1;
346  }
347 
348  // cry_id wrong because of incorrect ordering within trigger tower
349  else {
350  edm::LogWarning("EcalTBRawToDigiChId")
351  << "EcalTBDaqFormatter::interpretRawData with zero suppression, "
352  << " based on ch ordering within tt, wrong channel id: "
353  << "\t strip: " << strip << "\t channel: " << ch << "\t cryInTower " << cryInTower
354  << "\t expCryInTower: " << expCryInTower << "\t in TT: " << _ExpectedTowers[_expTowersIndex]
355  << "\t at LV1: " << (*itEventBlock)->getDataField("LV1");
356 
357  int sm = 1; // hardcoded because of test beam
358  for (int StripInTower_ = 1; StripInTower_ < 6; StripInTower_++) {
359  for (int CryInStrip_ = 1; CryInStrip_ < 6; CryInStrip_++) {
360  int ic = cryIc(tower, StripInTower_, CryInStrip_);
361  EBDetId idExp(sm, ic, 1);
362  chidcollection.push_back(idExp);
363  }
364  }
365 
366  // chennel with id which does not follow correct odering
367  expCryInTower++;
368  continue;
369 
370  } // end 'ch_id does not respect growing order'
371 
372  } // end if zero supression
373 
374  else {
375  // checking that ch and strip are within range and cryInTower is as expected
376  if (cryInTower != expCryInTower || strip < 1 || kStripsPerTower < strip || ch < 1 ||
377  kChannelsPerStrip < ch) {
378  int ic = cryIc(tower, expStripInTower, expCryInStrip);
379  int sm = 1; // hardcoded because of test beam
380  EBDetId idExp(sm, ic, 1);
381 
382  edm::LogWarning("EcalTBRawToDigiChId")
383  << "EcalTBDaqFormatter::interpretRawData no zero suppression "
384  << " wrong channel id for channel: " << expCryInStrip << "\t strip: " << expStripInTower
385  << "\t in TT: " << _ExpectedTowers[_expTowersIndex]
386  << "\t at LV1: " << (*itEventBlock)->getDataField("LV1")
387  << "\t (in the data, found channel: " << ch << "\t strip: " << strip << " ).";
388 
389  // report on wrong channel id
390  chidcollection.push_back(idExp);
391 
392  // there has been unexpected crystal id, dataframe not to go to the Event
393  expCryInTower++;
394  continue;
395 
396  } // if channel in data does not equal expected channel
397 
398  expCryInTower++;
399 
400  } // end 'not zero suppression'
401 
402  // data to be stored in EBDataFrame, identified by EBDetId
403  int ic = cryIc(tower, strip, ch);
404  int sm = 1;
405  EBDetId id(sm, ic, 1);
406 
407  // here data frame go into the Event
408  // removed later on (with a pop_back()) if gain==0 or if forbidden-gain-switch
409  digicollection.push_back(id);
410  EBDataFrame theFrame(digicollection.back());
411  std::vector<int> xtalDataSamples = (*itXtalBlock)->xtalDataSamples();
412  //theFrame.setSize(xtalDataSamples.size()); // if needed, to be changed when constructing digicollection
413 
414  // gain cannot be 0, checking for that
415  bool gainIsOk = true;
416  unsigned gain_mask = 12288; //12th and 13th bit
417  std::vector<int> xtalGain;
418 
419  for (unsigned short i = 0; i < xtalDataSamples.size(); ++i) {
420  theFrame.setSample(i, xtalDataSamples[i]);
421 
422  if ((xtalDataSamples[i] & gain_mask) == 0) {
423  gainIsOk = false;
424  }
425 
426  xtalGain.push_back(0);
427  xtalGain[i] |= (xtalDataSamples[i] >> 12);
428  }
429 
430  if (!gainIsOk) {
431  edm::LogWarning("EcalTBRawToDigiGainZero")
432  << "@SUB=EcalTBDaqFormatter::interpretRawData"
433  << " gain==0 for strip: " << expStripInTower << "\t channel: " << expCryInStrip
434  << "\t in TT: " << _ExpectedTowers[_expTowersIndex] << "\t ic: " << ic
435  << "\t at LV1: " << (*itEventBlock)->getDataField("LV1");
436  // report on gain==0
437  gaincollection.push_back(id);
438 
439  // there has been a gain==0, dataframe not to go to the Event
440  digicollection.pop_back();
441  continue; // expCryInTower already incremented
442  }
443 
444  // looking for forbidden gain transitions
445 
446  short firstGainWrong = -1;
447  short numGainWrong = 0;
448 
449  for (unsigned short i = 0; i < xtalGain.size(); i++) {
450  if (i > 0 && xtalGain[i - 1] > xtalGain[i]) {
451  numGainWrong++; // counting forbidden gain transitions
452 
453  if (firstGainWrong == -1) {
454  firstGainWrong = i;
455  edm::LogWarning("EcalTBRawToDigiGainSwitch")
456  << "@SUB=EcalTBDaqFormatter::interpretRawData"
457  << "channelHasGainSwitchProblem: crystal eta = " << id.ieta() << " phi = " << id.iphi();
458  }
459  edm::LogWarning("EcalTBRawToDigiGainSwitch")
460  << "@SUB=EcalTBDaqFormatter::interpretRawData"
461  << "channelHasGainSwitchProblem: sample = " << (i - 1) << " gain: " << xtalGain[i - 1]
462  << " sample: " << i << " gain: " << xtalGain[i];
463  }
464  }
465 
466  if (numGainWrong > 0) {
467  gainswitchcollection.push_back(id);
468 
469  edm::LogWarning("EcalTBRawToDigiGainSwitch") << "@SUB=EcalTBDaqFormatter:interpretRawData"
470  << "channelHasGainSwitchProblem: more than 1 wrong transition";
471 
472  for (unsigned short i1 = 0; i1 < xtalDataSamples.size(); ++i1) {
473  int countADC = 0x00000FFF;
474  countADC &= xtalDataSamples[i1];
475  LogDebug("EcalTBRawToDigi") << "Sample " << i1 << " ADC " << countADC << " Gain " << xtalGain[i1];
476  }
477 
478  // there has been a forbidden gain transition, dataframe not to go to the Event
479  digicollection.pop_back();
480  continue; // expCryInTower already incremented
481 
482  } // END of: 'if there is a forbidden gain transition'
483 
484  } // end loop on crystals within a tower block
485 
486  _expTowersIndex++;
487  } // end: tt1 ... tt68, crystal data
488 
489  /******************************************************************
490  // tt 69 and 70: two mem boxes, holding PN0 ... PN9
491  ******************************************************************/
492  else if ((*itTowerBlock)->towerID() == 69 || (*itTowerBlock)->towerID() == 70) {
493  LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::interpretRawData"
494  << "processing mem box num: " << (*itTowerBlock)->towerID();
495 
496  // if tt 69 or 70 found, allocate Pn digi collection
497  if (!pnAllocated) {
498  pndigicollection.reserve(kPns);
499  pnAllocated = true;
500  }
501 
502  DecodeMEM((*itTowerBlock),
503  pndigicollection,
504  memttidcollection,
505  memblocksizecollection,
506  memgaincollection,
507  memchidcollection);
508 
509  } // end of < if it is a mem box>
510 
511  // wrong tt id
512  else {
513  edm::LogWarning("EcalTBRawToDigiTowerId")
514  << "@SUB=EcalTBDaqFormatter::interpretRawData"
515  << " processing tt with ID not existing ( " << (*itTowerBlock)->towerID() << ")";
516  ++_expTowersIndex;
517  continue;
518  } // end: tt id error
519 
520  } // end loop on trigger towers
521 
522  } // end loop on events
523 }
void push_back(const Digi &digi)
bool Decode(unsigned long headerWord, EcalDCCHeaderBlock *theHeader)
void setSelectiveReadout(const bool &selectiveReadout)
uint16_t *__restrict__ id
void setFedId(const int &fedId)
DCCTBDataParser * theParser_
Ecal readout channel identification [32:20] Unused (so far) [19:13] DCC id [12:6] tower [5:3] strip [...
void setBasicTriggerType(const short &triggerType)
int cryIc(int tower_id, int strip, int xtal)
void push_back(T const &t)
void push_back(T const &t)
Definition: EDCollection.h:60
std::vector< DCCTBEventBlock * > & dccEvents()
void DecodeMEM(DCCTBTowerBlock *towerblock, EcalPnDiodeDigiCollection &pndigicollection, EcalElectronicsIdCollection &memttidcollection, EcalElectronicsIdCollection &memblocksizecollection, EcalElectronicsIdCollection &memgaincollection, EcalElectronicsIdCollection &memchidcollection)
void setFEStatus(const std::vector< short > &feStatus)
void setRunNumber(const int &run)
U second(std::pair< T, U > const &p)
void setZeroSuppression(const bool &zeroSuppression)
void setTestZeroSuppression(const bool &testZeroSuppression)
void setTccStatus(const std::vector< short > &tccStatus)
void reserve(size_t isize)
unsigned _ExpectedTowers[71]
void setErrors(const int &dccErrors)
void setSrpStatus(const short &srpStatus)
void setOrbit(const int &orbit)
void setSample(int i, EcalMGPASample sam)
Definition: EcalDataFrame.h:43
#define MAX_TCC_SIZE
void reserve(size_type n)
void setId(const int &dccId)
void setLV1(const int &LV1)
void setBX(const int &BX)
Log< level::Warning, false > LogWarning
void parseBuffer(const uint32_t *buffer, uint32_t bufferSize, bool singleEvent=false)
#define MAX_TT_SIZE
#define LogDebug(id)
bool EcalTBDaqFormatter::leftTower ( int  tower) const
private

Definition at line 771 of file EcalTBDaqFormatter.cc.

References rightTower().

771 { return !rightTower(tower); }
bool rightTower(int tower) const
bool EcalTBDaqFormatter::rightTower ( int  tower) const
private

Definition at line 763 of file EcalTBDaqFormatter.cc.

Referenced by cellIndex(), and leftTower().

763  {
764  if ((tower > 12 && tower < 21) || (tower > 28 && tower < 37) || (tower > 44 && tower < 53) ||
765  (tower > 60 && tower < 69))
766  return true;
767  else
768  return false;
769 }

Member Data Documentation

unsigned EcalTBDaqFormatter::_ExpectedTowers[71]
private

Definition at line 92 of file EcalTBDaqFormatter.h.

Referenced by DecodeMEM(), and interpretRawData().

unsigned EcalTBDaqFormatter::_expTowersIndex
private

Definition at line 93 of file EcalTBDaqFormatter.h.

Referenced by DecodeMEM(), and interpretRawData().

unsigned EcalTBDaqFormatter::_numExpectedTowers
private

Definition at line 91 of file EcalTBDaqFormatter.h.

Referenced by interpretRawData().

int EcalTBDaqFormatter::data_MEM[500]
private

Definition at line 97 of file EcalTBDaqFormatter.h.

Referenced by DecodeMEM().

int EcalTBDaqFormatter::memRawSample_[kStripsPerTower][kChannelsPerStrip][kSamplesPerChannel+1]
private

Definition at line 96 of file EcalTBDaqFormatter.h.

Referenced by DecodeMEM().

bool EcalTBDaqFormatter::pnAllocated
private

Definition at line 98 of file EcalTBDaqFormatter.h.

Referenced by interpretRawData().

bool EcalTBDaqFormatter::pnIsOkInBlock[kPnPerTowerBlock]
private

Definition at line 99 of file EcalTBDaqFormatter.h.

Referenced by DecodeMEM().

DCCTBDataParser* EcalTBDaqFormatter::theParser_
private

Definition at line 64 of file EcalTBDaqFormatter.h.

Referenced by EcalTBDaqFormatter(), and interpretRawData().