#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] |
DCCTBDataParser * | theParser_ |
enum EcalTBDaqFormatter::SMElectronics_t [private] |
kSamplesPerChannel | |
kSamplesPerPn | |
kChannelsPerTower | |
kStripsPerTower | |
kChannelsPerStrip | |
kPnPerTowerBlock | |
kTriggerTowersAndMem |
Definition at line 75 of file EcalTBDaqFormatter.h.
{ kSamplesPerChannel = 10, // Number of sample per channel, per event kSamplesPerPn = 50, // Number of sample per PN, per event kChannelsPerTower = 25, // Number of channels per trigger tower kStripsPerTower = 5, // Number of VFE cards per trigger tower kChannelsPerStrip = 5, // Number channels per VFE card kPnPerTowerBlock = 5, // Number Pn diodes pertaining to 1 tower block = 1/2 mem box kTriggerTowersAndMem = 70 // Number of trigger towers block including mems };
enum EcalTBDaqFormatter::SMGeom_t [private] |
kModules | |
kTriggerTowers | |
kTowersInPhi | |
kTowersInEta | |
kCrystals | |
kPns | |
kCrystalsInPhi | |
kCrystalsInEta | |
kCrystalsPerTower | |
kCardsPerTower | |
kChannelsPerCard |
Definition at line 61 of file EcalTBDaqFormatter.h.
{ kModules = 4, // Number of modules per supermodule kTriggerTowers = 68, // Number of trigger towers per supermodule kTowersInPhi = 4, // Number of trigger towers in phi kTowersInEta = 17, // Number of trigger towers in eta kCrystals = 1700, // Number of crystals per supermodule kPns = 10, // Number of PN laser monitoring diodes per supermodule kCrystalsInPhi = 20, // Number of crystals in phi kCrystalsInEta = 85, // Number of crystals in eta kCrystalsPerTower = 25, // Number of crystals per trigger tower kCardsPerTower = 5, // Number of VFE cards per trigger tower kChannelsPerCard = 5 // Number of channels per VFE card };
EcalTBDaqFormatter::EcalTBDaqFormatter | ( | ) |
Definition at line 33 of file EcalTBDaqFormatter.cc.
References LogDebug, Parameters::parameters, and theParser_.
{ LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter"; std::vector<uint32_t> parameters; parameters.push_back(10); // parameters[0] is the xtal samples parameters.push_back(1); // parameters[1] is the number of trigger time samples for TPG's parameters.push_back(68); // parameters[2] is the number of TT parameters.push_back(68); // parameters[3] is the number of SR Flags parameters.push_back(1); // parameters[4] is the dcc id parameters.push_back(1); // parameters[5] is the sr id parameters.push_back(1); // parameters[6] is the tcc1 id parameters.push_back(2); // parameters[7] is the tcc2 id parameters.push_back(3); // parameters[8] is the tcc3 id parameters.push_back(4); // parameters[9] is the tcc4 id theParser_ = new DCCTBDataParser(parameters); }
virtual EcalTBDaqFormatter::~EcalTBDaqFormatter | ( | ) | [inline, virtual] |
Definition at line 34 of file EcalTBDaqFormatter.h.
References LogDebug.
{LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter" << "\n"; };
std::pair< int, int > EcalTBDaqFormatter::cellIndex | ( | int | tower_id, |
int | strip, | ||
int | xtal | ||
) | [private] |
Definition at line 832 of file EcalTBDaqFormatter.cc.
References eta(), kCardsPerTower, kChannelsPerCard, kCrystalsPerTower, kTowersInPhi, phi, and rightTower().
Referenced by cryIc().
{ int xtal= (strip-1)*5+ch-1; // std::cout << " cellIndex input xtal " << xtal << std::endl; std::pair<int,int> ind; int eta = (tower_id - 1)/kTowersInPhi*kCardsPerTower; int phi = (tower_id - 1)%kTowersInPhi*kChannelsPerCard; if (rightTower(tower_id)) eta += xtal/kCardsPerTower; else eta += (kCrystalsPerTower - 1 - xtal)/kCardsPerTower; if ((rightTower(tower_id) && (xtal/kCardsPerTower)%2 == 1) || (!rightTower(tower_id) && (xtal/kCardsPerTower)%2 == 0)) phi += (kChannelsPerCard - 1 - xtal%kChannelsPerCard); else phi += xtal%kChannelsPerCard; ind.first =eta+1; ind.second=phi+1; // std::cout << " EcalTBDaqFormatter::cell_index eta " << ind.first << " phi " << ind.second << " " << std::endl; return ind; }
int EcalTBDaqFormatter::cryIc | ( | int | tower_id, |
int | strip, | ||
int | xtal | ||
) | [private] |
Definition at line 865 of file EcalTBDaqFormatter.cc.
References cellIndex(), and kCrystalsInPhi.
Referenced by interpretRawData().
{ if ( strip < 1 || 5<strip || ch <1 || 5 < ch || 68<tower) { edm::LogWarning("EcalTBRawToDigiChId") << "EcalTBDaqFormatter::interpretRawData (cryIc) " << " wrong channel id, since out of range: " << "\t strip: " << strip << "\t channel: " << ch << "\t in TT: " << tower; return -1; } std::pair<int,int> cellInd= EcalTBDaqFormatter::cellIndex(tower, strip, ch); return cellInd.second + (cellInd.first-1)*kCrystalsInPhi; }
void EcalTBDaqFormatter::DecodeMEM | ( | DCCTBTowerBlock * | towerblock, |
EcalPnDiodeDigiCollection & | pndigicollection, | ||
EcalElectronicsIdCollection & | memttidcollection, | ||
EcalElectronicsIdCollection & | memblocksizecollection, | ||
EcalElectronicsIdCollection & | memgaincollection, | ||
EcalElectronicsIdCollection & | memchidcollection | ||
) | [private] |
Definition at line 603 of file EcalTBDaqFormatter.cc.
References _ExpectedTowers, _expTowersIndex, edm::EDCollection< T >::begin(), data_MEM, edm::EDCollection< T >::end(), kChannelsPerStrip, kChannelsPerTower, kPnPerTowerBlock, kSamplesPerChannel, kSamplesPerPn, kStripsPerTower, LogDebug, memRawSample_, pnIsOkInBlock, edm::SortedCollection< T, SORT >::push_back(), edm::EDCollection< T >::push_back(), compare_using_db::sample, EcalPnDiodeDigi::setSample(), EcalPnDiodeDigi::setSize(), edm::EDCollection< T >::size(), strip(), DCCTBTowerBlock::towerID(), and DCCTBTowerBlock::xtalBlocks().
Referenced by interpretRawData().
{ LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::DecodeMEM" << "in mem " << towerblock->towerID(); int tower_id = towerblock ->towerID() ; int mem_id = tower_id-69; // initializing container for (int st_id=0; st_id< kStripsPerTower; st_id++){ for (int ch_id=0; ch_id<kChannelsPerStrip; ch_id++){ for (int sa=0; sa<11; sa++){ memRawSample_[st_id][ch_id][sa] = -1;} } } // check that tower block id corresponds to mem boxes if(tower_id != 69 && tower_id != 70) { edm::LogWarning("EcalTBRawToDigiTowerId") << "@SUB=EcalTBDaqFormatter:decodeMem" << "DecodeMEM: this is not a mem box tower (" << tower_id << ")"; ++ _expTowersIndex; return; } /****************************************************************************** // getting the raw hits from towerBlock while checking tt and ch data structure ******************************************************************************/ std::vector<DCCTBXtalBlock *> & dccXtalBlocks = towerblock->xtalBlocks(); std::vector<DCCTBXtalBlock*>::iterator itXtal; // checking mem tower block fo size if (dccXtalBlocks.size() != kChannelsPerTower) { LogDebug("EcalTBRawToDigiDccBlockSize") << "@SUB=EcalTBDaqFormatter:decodeMem" << " wrong dccBlock size, namely: " << dccXtalBlocks.size() << ", for mem " << _ExpectedTowers[_expTowersIndex]; // reporting mem-tt block size problem // chosing channel 1 as representative as a dummy... EcalElectronicsId id(1, (int)_ExpectedTowers[_expTowersIndex], 1, 1); memblocksizecollection.push_back(id); ++ _expTowersIndex; return; // if mem tt block size not ok - do not build any Pn digis } // loop on channels of the mem block int cryCounter = 0; int strip_id = 0; int xtal_id = 0; for ( itXtal = dccXtalBlocks.begin(); itXtal < dccXtalBlocks.end(); itXtal++ ) { strip_id = (*itXtal) ->getDataField("STRIP ID"); xtal_id = (*itXtal) ->getDataField("XTAL ID"); int wished_strip_id = cryCounter/ kStripsPerTower; int wished_ch_id = cryCounter% kStripsPerTower; if( (wished_strip_id+1) != ((int)strip_id) || (wished_ch_id+1) != ((int)xtal_id) ) { LogDebug("EcalTBRawToDigiChId") << "@SUB=EcalTBDaqFormatter:decodeMem" << " in mem " << towerblock->towerID() << ", expected:\t strip" << (wished_strip_id+1) << " cry " << (wished_ch_id+1) << "\tfound: " << " strip " << strip_id << " cry " << xtal_id; // report on crystal with unexpected indices EcalElectronicsId id(1, (int)_ExpectedTowers[_expTowersIndex], wished_strip_id, wished_ch_id); memchidcollection.push_back(id); } // Accessing the 10 time samples per Xtal: memRawSample_[wished_strip_id][wished_ch_id][1] = (*itXtal)->getDataField("ADC#1"); memRawSample_[wished_strip_id][wished_ch_id][2] = (*itXtal)->getDataField("ADC#2"); memRawSample_[wished_strip_id][wished_ch_id][3] = (*itXtal)->getDataField("ADC#3"); memRawSample_[wished_strip_id][wished_ch_id][4] = (*itXtal)->getDataField("ADC#4"); memRawSample_[wished_strip_id][wished_ch_id][5] = (*itXtal)->getDataField("ADC#5"); memRawSample_[wished_strip_id][wished_ch_id][6] = (*itXtal)->getDataField("ADC#6"); memRawSample_[wished_strip_id][wished_ch_id][7] = (*itXtal)->getDataField("ADC#7"); memRawSample_[wished_strip_id][wished_ch_id][8] = (*itXtal)->getDataField("ADC#8"); memRawSample_[wished_strip_id][wished_ch_id][9] = (*itXtal)->getDataField("ADC#9"); memRawSample_[wished_strip_id][wished_ch_id][10] = (*itXtal)->getDataField("ADC#10"); cryCounter++; }// end loop on crystals of mem dccXtalBlock // tower accepted and digi read from all 25 channels. // Increase counter of expected towers before unpacking in the 5 PNs ++ _expTowersIndex; /************************************************************ // unpacking and 'cooking' the raw numbers to get PN sample ************************************************************/ int tempSample=0; int memStoreIndex=0; int ipn=0; for (memStoreIndex=0; memStoreIndex<500; memStoreIndex++) { data_MEM[memStoreIndex]= -1; } for(int strip=0; strip<kStripsPerTower; strip++) {// loop on strips for(int channel=0; channel<kChannelsPerStrip; channel++) {// loop on channels if(strip%2 == 0) {ipn= mem_id*5+channel;} else {ipn=mem_id*5+4-channel;} for(int sample=0;sample< kSamplesPerChannel ;sample++) { tempSample= memRawSample_[strip][channel][sample+1]; int new_data=0; if(strip%2 == 1) { // 1) if strip number is even, 14 bits are reversed in order for(int ib=0;ib<14;ib++) { new_data <<= 1; new_data=new_data | (tempSample&1); tempSample >>= 1; } } else { new_data=tempSample; } // 2) flip 11th bit for AD9052 still there on MEM ! // 3) mask with 1 1111 1111 1111 new_data = (new_data ^ 0x800) & 0x3fff; // (new_data XOR 1000 0000 0000) & 11 1111 1111 1111 // new_data = (new_data ^ 0x800) & 0x1fff; // (new_data XOR 1000 0000 0000) & 1 1111 1111 1111 //(Bit 12) == 1 -> Gain 16; (Bit 12) == 0 -> Gain 1 // gain in mem can be 1 or 16 encoded resp. with 0 ir 1 in the 13th bit. // checking and reporting if there is any sample with gain==2,3 short sampleGain = (new_data &0x3000)/4096; if ( sampleGain==2 || sampleGain==3) { EcalElectronicsId id(1, (int)_ExpectedTowers[_expTowersIndex], strip, channel); memgaincollection.push_back(id); edm::LogWarning("EcalTBRawToDigiGainZero") << "@SUB=EcalTBDaqFormatter:decodeMem" << "in mem " << towerblock->towerID() << " :\t strip: " << (strip +1) << " cry: " << (channel+1) << " has 14th bit non zero! Gain results: " << sampleGain << "."; continue; }// end 'if gain is zero' memStoreIndex= ipn*50+strip*kSamplesPerChannel+sample; // storing in data_MEM also the gain bits data_MEM[memStoreIndex]= new_data & 0x3fff; }// loop on samples }// loop on strips }// loop on channels for (int pnId=0; pnId<kPnPerTowerBlock; pnId++) pnIsOkInBlock[pnId]=true; // if anything was wrong with mem_tt_id or mem_tt_size: you would have already exited // otherwise, if any problem with ch_gain or ch_id: must not produce digis for the pertaining Pn if (! (memgaincollection.size()==0 && memchidcollection.size()==0) ) { for ( EcalElectronicsIdCollection::const_iterator idItr = memgaincollection.begin(); idItr != memgaincollection.end(); ++ idItr ) { int ch = (*idItr).channelId(); ch = (ch-1)/5; pnIsOkInBlock [ch] = false; } for ( EcalElectronicsIdCollection::const_iterator idItr = memchidcollection.begin(); idItr != memchidcollection.end(); ++ idItr ) { int ch = (*idItr).channelId(); ch = (ch-1)/5; pnIsOkInBlock [ch] = false; } }// end: if any ch_gain or ch_id problems exclude the Pn's from digi production // looping on PN's of current mem box for (int pnId = 1; pnId < (kPnPerTowerBlock+1); pnId++){ // if present Pn has any of its 5 channels with problems, do not produce digi for it if (! pnIsOkInBlock [pnId-1] ) continue; // DccId set to 28 to be consistent with ism==1 EcalPnDiodeDetId PnId(1, 28, pnId + kPnPerTowerBlock*mem_id); EcalPnDiodeDigi thePnDigi(PnId ); thePnDigi.setSize(kSamplesPerPn); for (int sample =0; sample<kSamplesPerPn; sample++) { EcalFEMSample thePnSample( data_MEM[(mem_id)*250 + (pnId-1)*kSamplesPerPn + sample ] ); thePnDigi.setSample(sample, thePnSample ); } pndigicollection.push_back(thePnDigi); } }
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 52 of file EcalTBDaqFormatter.cc.
References _ExpectedTowers, _expTowersIndex, _numExpectedTowers, edm::DataFrameContainer::back(), cryIc(), FEDRawData::data(), DCCTBDataParser::dccEvents(), EcalDCCTBHeaderRuntypeDecoder::Decode(), DecodeMEM(), EcalBarrel, first, i, kChannelsPerCard, kChannelsPerStrip, kChannelsPerTower, kCrystals, kPns, kStripsPerTower, kTowersInPhi, kTriggerTowers, kTriggerTowersAndMem, LogDebug, MAX_TCC_SIZE, MAX_TT_SIZE, DCCTBDataParser::parseBuffer(), pnAllocated, edm::DataFrameContainer::pop_back(), edm::DataFrameContainer::push_back(), edm::SortedCollection< T, SORT >::push_back(), edm::EDCollection< T >::push_back(), edm::SortedCollection< T, SORT >::reserve(), edm::DataFrameContainer::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, strip(), theParser_, and v.
Referenced by EcalDCCTBUnpackingModule::produce().
{ const unsigned char * pData = fedData.data(); int length = fedData.size(); bool shit=true; unsigned int tower=0; int ch=0; int strip=0; LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::interpretRawData" << "size " << length; // mean + 3sigma estimation needed when switching to 0suppressed data digicollection.reserve(kCrystals); pnAllocated = false; theParser_->parseBuffer( reinterpret_cast<uint32_t*>(const_cast<unsigned char*>(pData)), static_cast<uint32_t>(length), shit ); std::vector< DCCTBEventBlock * > & dccEventBlocks = theParser_->dccEvents(); // Access each DCCTB block for( std::vector< DCCTBEventBlock * >::iterator itEventBlock = dccEventBlocks.begin(); itEventBlock != dccEventBlocks.end(); itEventBlock++){ bool _displayParserMessages = false; if( (*itEventBlock)->eventHasErrors() && _displayParserMessages) { edm::LogWarning("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::interpretRawData" << "errors found from parser... "; edm::LogWarning("EcalTBRawToDigi") << (*itEventBlock)->eventErrorString(); edm::LogWarning("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::interpretRawData" << "... errors from parser notified"; } // getting the fields of the DCC header EcalDCCHeaderBlock theDCCheader; theDCCheader.setId(28); // tb unpacker: forced to 28 to get first geom slot in EB int fedId = (*itEventBlock)->getDataField("FED/DCC ID"); theDCCheader.setFedId( fedId ); // fed id as found in raw data (0... 35 at tb ) theDCCheader.setRunNumber((*itEventBlock)->getDataField("RUN NUMBER")); short trigger_type = (*itEventBlock)->getDataField("TRIGGER TYPE"); short zs = (*itEventBlock)->getDataField("ZS"); short tzs = (*itEventBlock)->getDataField("TZS"); short sr = (*itEventBlock)->getDataField("SR"); bool dataIsSuppressed; // if zs&&tzs the suppression algo is used in DCC, the data are not suppressed and zs-bits are set if ( zs && !(tzs) ) dataIsSuppressed = true; else dataIsSuppressed = false; if(trigger_type >0 && trigger_type <5){theDCCheader.setBasicTriggerType(trigger_type);} else{ edm::LogWarning("EcalTBRawToDigiTriggerType") << "@SUB=EcalTBDaqFormatter::interpretRawData" << "unrecognized TRIGGER TYPE: "<<trigger_type;} theDCCheader.setLV1((*itEventBlock)->getDataField("LV1")); theDCCheader.setOrbit((*itEventBlock)->getDataField("ORBIT COUNTER")); theDCCheader.setBX((*itEventBlock)->getDataField("BX")); theDCCheader.setErrors((*itEventBlock)->getDataField("DCC ERRORS")); theDCCheader.setSelectiveReadout( sr ); theDCCheader.setZeroSuppression( zs ); theDCCheader.setTestZeroSuppression( tzs ); theDCCheader.setSrpStatus((*itEventBlock)->getDataField("SR_CHSTATUS")); std::vector<short> theTCCs; for(int i=0; i<MAX_TCC_SIZE; i++){ char TCCnum[20]; sprintf(TCCnum,"TCC_CHSTATUS#%d",i+1); std::string TCCnumS(TCCnum); theTCCs.push_back ((*itEventBlock)->getDataField(TCCnumS) ); } theDCCheader.setTccStatus(theTCCs); std::vector< DCCTBTCCBlock * > tccBlocks = (*itEventBlock)->tccBlocks(); for( std::vector< DCCTBTCCBlock * >::iterator itTCCBlock = tccBlocks.begin(); itTCCBlock != tccBlocks.end(); itTCCBlock ++) { std::vector< std::pair<int,bool> > TpSamples = (* itTCCBlock) -> triggerSamples() ; // std::vector of 3 bits std::vector<int> TpFlags = (* itTCCBlock) -> triggerFlags() ; // there have always to be 68 primitives and flags, per FED if (TpSamples.size()==68 && TpFlags.size()==68) { for(int i=0; i<((int)TpSamples.size()); i++) { int etaTT = (i) / kTowersInPhi +1; int phiTT = (i) % kTowersInPhi +1; // follow HB convention in iphi phiTT=3-phiTT; if(phiTT<=0)phiTT=phiTT+72; EcalTriggerPrimitiveSample theSample(TpSamples[i].first, TpSamples[i].second, TpFlags[i]); EcalTrigTowerDetId idtt(1, EcalBarrel, etaTT, phiTT, 0); EcalTriggerPrimitiveDigi thePrimitive(idtt); thePrimitive.setSize(1); // hard coded thePrimitive.setSample(0, theSample); tpcollection.push_back(thePrimitive); LogDebug("EcalTBRawToDigiTpg") << "@SUBS=EcalTBDaqFormatter::interpretRawData" << "tower: " << (i+1) << " primitive: " << TpSamples[i].first << " flag: " << TpSamples[i].second; LogDebug("EcalTBRawToDigiTpg") << "@SUBS=EcalTBDaqFormatter::interpretRawData"<< "tower: " << (i+1) << " flag: " << TpFlags[i]; }// end loop on tower primitives }// end if else { edm::LogWarning("EcalTBRawToDigiTpg") << "68 elements not found for TpFlags or TpSamples, collection will be empty"; } } short TowerStatus[MAX_TT_SIZE+1]; char buffer[20]; std::vector<short> theTTstatus; for(int i=1;i<MAX_TT_SIZE+1;i++) { sprintf(buffer, "FE_CHSTATUS#%d", i); std::string Tower(buffer); TowerStatus[i]= (*itEventBlock)->getDataField(Tower); theTTstatus.push_back(TowerStatus[i]); //std::cout << "tower " << i << " has status " << TowerStatus[i] << std::endl; } theDCCheader.setFEStatus(theTTstatus); EcalDCCTBHeaderRuntypeDecoder theRuntypeDecoder; uint32_t DCCruntype = (*itEventBlock)->getDataField("RUN TYPE"); theRuntypeDecoder.Decode(DCCruntype, &theDCCheader); //DCCHeader filled! DCCheaderCollection.push_back(theDCCheader); std::vector< DCCTBTowerBlock * > dccTowerBlocks = (*itEventBlock)->towerBlocks(); LogDebug("EcalTBRawToDigi") << "@SUBS=EcalTBDaqFormatter::interpretRawData" << "dccTowerBlocks size " << dccTowerBlocks.size(); _expTowersIndex=0;_numExpectedTowers=0; for (int v=0; v<71; v++){ _ExpectedTowers[v]=99999; } // note: these are the tower statuses handled at the moment - to be completed // staus==0: tower expected; // staus==9: Synk error LV1, tower expected; // staus==10: Synk error BX, tower expected; // status==1, 2, 3, 4, 5: tower not expected for (int u=1; u< (kTriggerTowersAndMem+1); u++) { if( TowerStatus[u] ==0 || TowerStatus[u] ==9 || TowerStatus[u] ==10 ) {_ExpectedTowers[_expTowersIndex]=u; _expTowersIndex++; _numExpectedTowers++; } } // resetting counter of expected towers _expTowersIndex=0; // if number of dccEventBlocks NOT same as expected stop if (! (dccTowerBlocks.size() == _numExpectedTowers) ) { // we probably always want to know if this happens edm::LogWarning("EcalTBRawToDigiNumTowerBlocks") << "@SUB=EcalTBDaqFormatter::interpretRawData" << "number of TowerBlocks found (" << dccTowerBlocks.size() << ") differs from expected (" << _numExpectedTowers << ") skipping event"; EBDetId idsm(1, 1); dccsizecollection.push_back(idsm); return; } // Access the Tower block for( std::vector< DCCTBTowerBlock * >::iterator itTowerBlock = dccTowerBlocks.begin(); itTowerBlock!= dccTowerBlocks.end(); itTowerBlock++){ tower=(*itTowerBlock)->towerID(); // checking if tt in data is the same as tt expected // else skip tower and increment problem counter // compute eta/phi in order to have iTT = _ExpectedTowers[_expTowersIndex] // for the time being consider only zside>0 EcalElectronicsId idtt(28, _ExpectedTowers[_expTowersIndex], 1, 1); if ( !(tower == _ExpectedTowers[_expTowersIndex]) ) { if (_ExpectedTowers[_expTowersIndex] <= 68){ edm::LogWarning("EcalTBRawToDigiTowerId") << "@SUBS=EcalTBDaqFormatter::interpretRawData" << "TTower id found (=" << tower << ") different from expected (=" << _ExpectedTowers[_expTowersIndex] << ") " << (_expTowersIndex+1) << "-th tower checked"; // report on failed tt_id for regular tower block ttidcollection.push_back(idtt); } else { edm::LogWarning("EcalTBRawToDigiTowerId") << "@SUB=EcalTBDaqFormatter:interpretRawData" << "DecodeMEM: tower " << tower << " is not the same as expected " << ((int)_ExpectedTowers[_expTowersIndex]) << " (according to DCC header channel status)"; // report on failed tt_id for mem tower block // chosing channel 1 as representative EcalElectronicsId id(1, (int)_ExpectedTowers[_expTowersIndex], 1, 1); memttidcollection.push_back(id); } ++ _expTowersIndex; continue; }// if TT id found different than expected /********************************* // tt: 1 ... 68: crystal data *********************************/ if ( 0< (*itTowerBlock)->towerID() && (*itTowerBlock)->towerID() < (kTriggerTowers+1) ) { std::vector<DCCTBXtalBlock * > & xtalDataBlocks = (*itTowerBlock)->xtalBlocks(); // if there is no zero suppression, tower block must have have 25 channels in it if ( (!dataIsSuppressed) && (xtalDataBlocks.size() != kChannelsPerTower) ) { edm::LogWarning("EcalTBRawToDigiTowerSize") << "EcalTBDaqFormatter::interpretRawData, no zero suppression " << "wrong tower block size is: " << xtalDataBlocks.size() << " at LV1 " << (*itEventBlock)->getDataField("LV1") << " for TT " << _ExpectedTowers[_expTowersIndex]; // report on wrong tt block size blocksizecollection.push_back(idtt); ++ _expTowersIndex; continue; } short cryInTower =0; short expStripInTower; short expCryInStrip; short expCryInTower =0; // Access the Xstal data for( std::vector< DCCTBXtalBlock * >::iterator itXtalBlock = xtalDataBlocks.begin(); itXtalBlock!= xtalDataBlocks.end(); itXtalBlock++){ //loop on crys of a tower strip =(*itXtalBlock)->stripID(); ch =(*itXtalBlock)->xtalID(); cryInTower =(strip-1)* kChannelsPerCard + (ch -1); expStripInTower = expCryInTower/5 +1; expCryInStrip = expCryInTower%5 +1; // FIXME: waiting for geometry to do (TT, strip,chNum) <--> (SMChId) // short abscissa = (_ExpectedTowers[_expTowersIndex]-1) /4; // short ordinate = (_ExpectedTowers[_expTowersIndex]-1) %4; // temporarily choosing central crystal in trigger tower // int cryIdInSM = 45 + ordinate*5 + abscissa * 100; // in case of 0 zuppressed data, check that cryInTower constantly grows if (dataIsSuppressed) { if ( strip < 1 || 5<strip || ch <1 || 5 < ch) { int sm = 1; // hardcoded because of test beam for (int StripInTower_ =1; StripInTower_ < 6; StripInTower_++){ for (int CryInStrip_ =1; CryInStrip_ < 6; CryInStrip_++){ int ic = cryIc(tower, StripInTower_, CryInStrip_) ; EBDetId idExp(sm, ic,1); chidcollection.push_back(idExp); } } edm::LogWarning("EcalTBRawToDigiChId") << "EcalTBDaqFormatter::interpretRawData with zero suppression, " << " wrong channel id, since out of range: " << "\t strip: " << strip << "\t channel: " << ch << "\t in TT: " << _ExpectedTowers[_expTowersIndex] << "\t at LV1 : " << (*itEventBlock)->getDataField("LV1"); expCryInTower++; continue; } // correct ordering if( cryInTower >= expCryInTower ){ expCryInTower = cryInTower +1; } // cry_id wrong because of incorrect ordering within trigger tower else { edm::LogWarning("EcalTBRawToDigiChId") << "EcalTBDaqFormatter::interpretRawData with zero suppression, " << " based on ch ordering within tt, wrong channel id: " << "\t strip: " << strip << "\t channel: " << ch << "\t cryInTower " << cryInTower << "\t expCryInTower: " << expCryInTower << "\t in TT: " << _ExpectedTowers[_expTowersIndex] << "\t at LV1: " << (*itEventBlock)->getDataField("LV1"); int sm = 1; // hardcoded because of test beam for (int StripInTower_ =1; StripInTower_ < 6; StripInTower_++){ for (int CryInStrip_ =1; CryInStrip_ < 6; CryInStrip_++){ int ic = cryIc(tower, StripInTower_, CryInStrip_) ; EBDetId idExp(sm, ic,1); chidcollection.push_back(idExp); } } // chennel with id which does not follow correct odering expCryInTower++; continue; }// end 'ch_id does not respect growing order' }// end if zero supression else { // checking that ch and strip are within range and cryInTower is as expected if( cryInTower != expCryInTower || strip < 1 || kStripsPerTower <strip || ch <1 || kChannelsPerStrip < ch ) { int ic = cryIc(tower, expStripInTower, expCryInStrip) ; int sm = 1; // hardcoded because of test beam EBDetId idExp(sm, ic,1); edm::LogWarning("EcalTBRawToDigiChId") << "EcalTBDaqFormatter::interpretRawData no zero suppression " << " wrong channel id for channel: " << expCryInStrip << "\t strip: " << expStripInTower << "\t in TT: " << _ExpectedTowers[_expTowersIndex] << "\t at LV1: " << (*itEventBlock)->getDataField("LV1") << "\t (in the data, found channel: " << ch << "\t strip: " << strip << " )."; // report on wrong channel id chidcollection.push_back(idExp); // there has been unexpected crystal id, dataframe not to go to the Event expCryInTower++; continue; } // if channel in data does not equal expected channel expCryInTower++; } // end 'not zero suppression' // data to be stored in EBDataFrame, identified by EBDetId int ic = cryIc(tower, strip, ch) ; int sm = 1; EBDetId id(sm, ic,1); // here data frame go into the Event // removed later on (with a pop_back()) if gain==0 or if forbidden-gain-switch digicollection.push_back( id ); EBDataFrame theFrame ( digicollection.back() ); std::vector<int> xtalDataSamples = (*itXtalBlock)->xtalDataSamples(); //theFrame.setSize(xtalDataSamples.size()); // if needed, to be changed when constructing digicollection // gain cannot be 0, checking for that bool gainIsOk =true; unsigned gain_mask = 12288; //12th and 13th bit std::vector <int> xtalGain; for (unsigned short i=0; i<xtalDataSamples.size(); ++i ) { theFrame.setSample (i, xtalDataSamples[i] ); if((xtalDataSamples[i] & gain_mask) == 0){gainIsOk =false;} xtalGain.push_back(0); xtalGain[i] |= (xtalDataSamples[i] >> 12); } if (! gainIsOk) { edm::LogWarning("EcalTBRawToDigiGainZero") << "@SUB=EcalTBDaqFormatter::interpretRawData" << " gain==0 for strip: " << expStripInTower << "\t channel: " << expCryInStrip << "\t in TT: " << _ExpectedTowers[_expTowersIndex] << "\t ic: " << ic << "\t at LV1: " << (*itEventBlock)->getDataField("LV1"); // report on gain==0 gaincollection.push_back(id); // there has been a gain==0, dataframe not to go to the Event digicollection.pop_back(); continue; // expCryInTower already incremented } // looking for forbidden gain transitions short firstGainWrong=-1; short numGainWrong=0; for (unsigned short i=0; i<xtalGain.size(); i++ ) { if (i>0 && xtalGain[i-1]>xtalGain[i]) { numGainWrong++;// counting forbidden gain transitions if (firstGainWrong == -1) { firstGainWrong=i; edm::LogWarning("EcalTBRawToDigiGainSwitch") << "@SUB=EcalTBDaqFormatter::interpretRawData" << "channelHasGainSwitchProblem: crystal eta = " << id.ieta() << " phi = " << id.iphi(); } edm::LogWarning("EcalTBRawToDigiGainSwitch") << "@SUB=EcalTBDaqFormatter::interpretRawData" << "channelHasGainSwitchProblem: sample = " << (i-1) << " gain: " << xtalGain[i-1] << " sample: " << i << " gain: " << xtalGain[i]; } } if (numGainWrong>0) { gainswitchcollection.push_back(id); edm::LogWarning("EcalTBRawToDigiGainSwitch") << "@SUB=EcalTBDaqFormatter:interpretRawData" << "channelHasGainSwitchProblem: more than 1 wrong transition"; for (unsigned short i1=0; i1<xtalDataSamples.size(); ++i1 ) { int countADC = 0x00000FFF; countADC &= xtalDataSamples[i1]; LogDebug("EcalTBRawToDigi") << "Sample " << i1 << " ADC " << countADC << " Gain " << xtalGain[i1]; } // there has been a forbidden gain transition, dataframe not to go to the Event digicollection.pop_back(); continue; // expCryInTower already incremented }// END of: 'if there is a forbidden gain transition' }// end loop on crystals within a tower block _expTowersIndex++; }// end: tt1 ... tt68, crystal data /****************************************************************** // tt 69 and 70: two mem boxes, holding PN0 ... PN9 ******************************************************************/ else if ( (*itTowerBlock)->towerID() == 69 || (*itTowerBlock)->towerID() == 70 ) { LogDebug("EcalTBRawToDigi") << "@SUB=EcalTBDaqFormatter::interpretRawData" << "processing mem box num: " << (*itTowerBlock)->towerID(); // if tt 69 or 70 found, allocate Pn digi collection if(! pnAllocated) { pndigicollection.reserve(kPns); pnAllocated = true; } DecodeMEM( (*itTowerBlock), pndigicollection , memttidcollection, memblocksizecollection, memgaincollection, memchidcollection); }// end of < if it is a mem box> // wrong tt id else { edm::LogWarning("EcalTBRawToDigiTowerId") <<"@SUB=EcalTBDaqFormatter::interpretRawData" << " processing tt with ID not existing ( " << (*itTowerBlock)->towerID() << ")"; ++ _expTowersIndex;continue; }// end: tt id error }// end loop on trigger towers }// end loop on events }
bool EcalTBDaqFormatter::leftTower | ( | int | tower | ) | const [private] |
Definition at line 893 of file EcalTBDaqFormatter.cc.
References rightTower().
{ return !rightTower(tower); }
bool EcalTBDaqFormatter::rightTower | ( | int | tower | ) | const [private] |
Definition at line 882 of file EcalTBDaqFormatter.cc.
Referenced by cellIndex(), and leftTower().
{ if ((tower>12 && tower<21) || (tower>28 && tower<37) || (tower>44 && tower<53) || (tower>60 && tower<69)) return true; else return false; }
unsigned EcalTBDaqFormatter::_ExpectedTowers[71] [private] |
Definition at line 87 of file EcalTBDaqFormatter.h.
Referenced by DecodeMEM(), and interpretRawData().
unsigned EcalTBDaqFormatter::_expTowersIndex [private] |
Definition at line 88 of file EcalTBDaqFormatter.h.
Referenced by DecodeMEM(), and interpretRawData().
unsigned EcalTBDaqFormatter::_numExpectedTowers [private] |
Definition at line 86 of file EcalTBDaqFormatter.h.
Referenced by interpretRawData().
int EcalTBDaqFormatter::data_MEM[500] [private] |
Definition at line 92 of file EcalTBDaqFormatter.h.
Referenced by DecodeMEM().
int EcalTBDaqFormatter::memRawSample_[kStripsPerTower][kChannelsPerStrip][kSamplesPerChannel+1] [private] |
Definition at line 91 of file EcalTBDaqFormatter.h.
Referenced by DecodeMEM().
bool EcalTBDaqFormatter::pnAllocated [private] |
Definition at line 93 of file EcalTBDaqFormatter.h.
Referenced by interpretRawData().
bool EcalTBDaqFormatter::pnIsOkInBlock[kPnPerTowerBlock] [private] |
Definition at line 94 of file EcalTBDaqFormatter.h.
Referenced by DecodeMEM().
DCCTBDataParser* EcalTBDaqFormatter::theParser_ [private] |
Definition at line 59 of file EcalTBDaqFormatter.h.
Referenced by EcalTBDaqFormatter(), and interpretRawData().