#include <L1Trigger/L1RCTTPGProvider/src/L1RCTTPGProvider.cc>
Public Member Functions | |
L1RCTTPGProvider (const edm::ParameterSet &) | |
~L1RCTTPGProvider () | |
Private Member Functions | |
virtual void | endJob () |
virtual void | produce (edm::Event &, const edm::EventSetup &) |
Private Attributes | |
edm::InputTag | ecalTPG_ |
int | hbShift |
edm::InputTag | hcalTPG_ |
int | hfShift |
int | postSamples |
int | preSamples |
bool | useEcalCosmicTiming |
bool | useHcalCosmicTiming |
Description: <one line="" class="" summary>="">
Implementation: <Notes on="" implementation>="">
Definition at line 37 of file L1RCTTPGProvider.h.
L1RCTTPGProvider::L1RCTTPGProvider | ( | const edm::ParameterSet & | iConfig | ) | [explicit] |
Definition at line 5 of file L1RCTTPGProvider.cc.
References i, postSamples, and preSamples.
: ecalTPG_(iConfig.getParameter<edm::InputTag>("ecalTPGs")), hcalTPG_(iConfig.getParameter<edm::InputTag>("hcalTPGs")), useHcalCosmicTiming(iConfig.getParameter<bool>("useHCALCosmicTiming")), useEcalCosmicTiming(iConfig.getParameter<bool>("useECALCosmicTiming")), preSamples(iConfig.getParameter<int>("preSamples")), postSamples(iConfig.getParameter<int>("postSamples")), hfShift(iConfig.getParameter<int>("HFShift")), hbShift(iConfig.getParameter<int>("HBShift")) { //Output :The new manipulated TPGs //make it smart - to name the collections //correctly char ecal_label[200]; char hcal_label[200]; for(int i=preSamples;i>0;--i) { sprintf(ecal_label,"ECALBxminus%d",i); sprintf(hcal_label,"HCALBxminus%d",i); produces<EcalTrigPrimDigiCollection>(ecal_label); produces<HcalTrigPrimDigiCollection>(hcal_label); } produces<EcalTrigPrimDigiCollection>("ECALBx0"); produces<HcalTrigPrimDigiCollection>("HCALBx0"); for(int i=0;i<postSamples;++i) { sprintf(ecal_label,"ECALBxplus%d",i+1); sprintf(hcal_label,"HCALBxplus%d",i+1); produces<EcalTrigPrimDigiCollection>(ecal_label); produces<HcalTrigPrimDigiCollection>(hcal_label); } }
L1RCTTPGProvider::~L1RCTTPGProvider | ( | ) |
Definition at line 44 of file L1RCTTPGProvider.cc.
{ // do anything here that needs to be done at desctruction time // (e.g. close files, deallocate resources etc.) }
void L1RCTTPGProvider::endJob | ( | void | ) | [private, virtual] |
void L1RCTTPGProvider::produce | ( | edm::Event & | iEvent, |
const edm::EventSetup & | iSetup | ||
) | [private, virtual] |
Implements edm::EDProducer.
Definition at line 57 of file L1RCTTPGProvider.cc.
References patCandidatesForDimuonsSequences_cff::ecal, ecalTPG_, EcalTriggerTower, edm::Event::getByLabel(), hbShift, patCandidatesForDimuonsSequences_cff::hcal, hcalTPG_, hfShift, i, createXMLFile::iphi, j, postSamples, preSamples, edm::Event::put(), compare_using_db::sample, HcalTriggerPrimitiveDigi::setPresamples(), EcalTriggerPrimitiveDigi::setSample(), HcalTriggerPrimitiveDigi::setSample(), EcalTriggerPrimitiveDigi::setSize(), HcalTriggerPrimitiveDigi::setSize(), useEcalCosmicTiming, and useHcalCosmicTiming.
{ using namespace edm; //Declare handles Handle<EcalTrigPrimDigiCollection> ecal; Handle<HcalTrigPrimDigiCollection> hcal; //Declare vector of collection to send for output ! std::vector<EcalTrigPrimDigiCollection> ecalColl(preSamples+1+postSamples); std::vector<HcalTrigPrimDigiCollection> hcalColl(preSamples+1+postSamples); unsigned nSamples = preSamples + postSamples + 1; if(iEvent.getByLabel(ecalTPG_,ecal)) if (ecal.isValid()) { // loop through all ecal digis for (EcalTrigPrimDigiCollection::const_iterator ecal_it = ecal->begin(); ecal_it != ecal->end(); ecal_it++) { short zside = ecal_it->id().zside(); unsigned short ietaAbs = ecal_it->id().ietaAbs(); short iphi = ecal_it->id().iphi(); unsigned short digiSize = ecal_it->size(); unsigned short nSOI = (unsigned short) ( ecal_it->sampleOfInterest() ); if (digiSize < nSamples || nSOI < preSamples || ((int)(digiSize - nSOI) < (int)(nSamples - preSamples))) { unsigned short preLoopsZero = (unsigned short) (preSamples)- nSOI; // fill extra bx's at beginning with zeros for (int sample = 0; sample < preLoopsZero; sample++) { // fill first few with zeros EcalTriggerPrimitiveDigi ecalDigi(EcalTrigTowerDetId((int) zside, EcalTriggerTower, (int) ietaAbs, (int) iphi)); ecalDigi.setSize(1); ecalDigi.setSample(0, EcalTriggerPrimitiveSample(0,false,0)); ecalColl[sample].push_back(ecalDigi); } // loop through existing data for (int sample = preLoopsZero;sample < (preLoopsZero + digiSize); sample++) { // go through data EcalTriggerPrimitiveDigi ecalDigi(EcalTrigTowerDetId((int) zside, EcalTriggerTower, (int) ietaAbs, (int) iphi)); ecalDigi.setSize(1); if (useEcalCosmicTiming && iphi >= 1 && iphi <= 36) { if (nSOI < (preSamples + 1)) { edm::LogWarning ("TooLittleData") << "ECAL data needs at least one presample " << "more than the number requested " << "to use ecal cosmic timing mod! " << "reverting to useEcalCosmicTiming = false " << "for rest of job."; useEcalCosmicTiming = false; } else { ecalDigi.setSample(0, EcalTriggerPrimitiveSample (ecal_it->sample(nSOI + sample - preSamples - 1).raw())); } } //else if ((!useEcalCosmicTiming) || (iphi >=37 && iphi <= 72)) { ecalDigi.setSample(0, EcalTriggerPrimitiveSample (ecal_it->sample(nSOI + sample - preSamples).raw())); } ecalColl[sample].push_back(ecalDigi); } // fill extra bx's at end with zeros for (unsigned int sample = (preLoopsZero + digiSize); sample < nSamples; sample++) { // fill zeros! EcalTriggerPrimitiveDigi ecalDigi(EcalTrigTowerDetId((int) zside, EcalTriggerTower, (int) ietaAbs, (int) iphi)); ecalDigi.setSize(1); ecalDigi.setSample(0, EcalTriggerPrimitiveSample(0,false,0)); ecalColl[sample].push_back(ecalDigi); } } else { for (unsigned short sample = 0; sample < nSamples; sample++) { // put each time sample into its own digi short zside = ecal_it->id().zside(); unsigned short ietaAbs = ecal_it->id().ietaAbs(); short iphi = ecal_it->id().iphi(); EcalTriggerPrimitiveDigi ecalDigi(EcalTrigTowerDetId((int) zside, EcalTriggerTower, (int) ietaAbs, (int) iphi)); ecalDigi.setSize(1); if (useEcalCosmicTiming && iphi >= 1 && iphi <=36) { if (nSOI < (preSamples + 1)) { edm::LogWarning ("TooLittleData") << "ECAL data needs at least one presample " << "more than the number requested " << "to use ecal cosmic timing mod! " << "reverting to useEcalCosmicTiming = false " << "for rest of job."; useEcalCosmicTiming = false; } else { ecalDigi.setSample(0, EcalTriggerPrimitiveSample (ecal_it->sample (ecal_it->sampleOfInterest() + sample - preSamples - 1).raw())); } } //else if ((!useEcalCosmicTiming) || (iphi >=37 && iphi <= 72)) { ecalDigi.setSample(0, EcalTriggerPrimitiveSample (ecal_it->sample (ecal_it->sampleOfInterest() + sample - preSamples).raw())); } // push back each digi into correct "time sample" of coll ecalColl[sample].push_back(ecalDigi); } } } } if(iEvent.getByLabel(hcalTPG_,hcal)) if (hcal.isValid()) { // loop through all hcal digis for (HcalTrigPrimDigiCollection::const_iterator hcal_it = hcal->begin(); hcal_it != hcal->end(); hcal_it++) { short ieta = hcal_it->id().ieta(); short iphi = hcal_it->id().iphi(); // loop through time samples for each digi unsigned short digiSize = hcal_it->size(); // (size of each digi must be no less than nSamples) unsigned short nSOI = (unsigned short) (hcal_it->presamples()); if (digiSize < nSamples || nSOI < preSamples || ((int)(digiSize - nSOI) < (int)(nSamples - preSamples))) { unsigned short preLoopsZero = (unsigned short) (preSamples) - nSOI; // fill extra bx's at beginning with zeros for (int sample = 0; sample < preLoopsZero; sample++) { // fill first few with zeros HcalTriggerPrimitiveDigi hcalDigi(HcalTrigTowerDetId((int) ieta, (int) iphi)); hcalDigi.setSize(1); hcalDigi.setPresamples(0); hcalDigi.setSample(0, HcalTriggerPrimitiveSample(0,false,0,0)); hcalColl[sample].push_back(hcalDigi); } // loop through existing data for (int sample = preLoopsZero; sample < (preLoopsZero + digiSize); sample++) { // go through data HcalTriggerPrimitiveDigi hcalDigi(HcalTrigTowerDetId((int) ieta, (int) iphi)); hcalDigi.setSize(1); hcalDigi.setPresamples(0); if (useHcalCosmicTiming && iphi >= 1 && iphi <= 36) { if (nSOI < (preSamples + 1)) { edm::LogWarning ("TooLittleData") << "HCAL data needs at least one presample " << "more than the number requested " << "to use hcal cosmic timing mod! " << "reverting to useHcalCosmicTiming = false " << "for rest of job."; useHcalCosmicTiming = false; } else { hcalDigi.setSample(0, HcalTriggerPrimitiveSample (hcal_it->sample(hcal_it-> presamples() + sample - preSamples - 1).raw())); } } //else if ((!useHcalCosmicTiming) || (iphi >= 37 && iphi <= 72)) { hcalDigi.setSample(0, HcalTriggerPrimitiveSample (hcal_it->sample(hcal_it-> presamples() + sample - preSamples).raw())); } hcalColl[sample].push_back(hcalDigi); } // fill extra bx's at end with zeros for (unsigned int sample = (preLoopsZero + digiSize); sample < nSamples; sample++) { // fill zeros! HcalTriggerPrimitiveDigi hcalDigi(HcalTrigTowerDetId((int) ieta, (int) iphi)); hcalDigi.setSize(1); hcalDigi.setPresamples(0); hcalDigi.setSample(0, HcalTriggerPrimitiveSample(0,false,0,0)); hcalColl[sample].push_back(hcalDigi); } } else { for (unsigned short sample = 0; sample < nSamples; sample++) { // put each (relevant) time sample into its own digi HcalTriggerPrimitiveDigi hcalDigi(HcalTrigTowerDetId((int) ieta, (int) iphi)); hcalDigi.setSize(1); hcalDigi.setPresamples(0); if (useHcalCosmicTiming && iphi >= 1 && iphi <= 36) { if (nSOI < (preSamples + 1)) { edm::LogWarning ("TooLittleData") << "HCAL data needs at least one presample " << "more than the number requested " << "to use hcal cosmic timing mod! " << "reverting to useHcalCosmicTiming = false " << "for rest of job."; useHcalCosmicTiming = false; } else { hcalDigi.setSample(0, HcalTriggerPrimitiveSample (hcal_it->sample(hcal_it-> presamples() + sample - preSamples - 1).raw())); } } //else if ((!useHcalCosmicTiming) || (iphi >= 37 && iphi <= 72)) { if(ieta>-29 && ieta<29) hcalDigi.setSample(0, HcalTriggerPrimitiveSample (hcal_it->sample(hcal_it-> presamples() + sample - preSamples+hbShift).raw())); if(ieta<=-29 || ieta>=29) hcalDigi.setSample(0, HcalTriggerPrimitiveSample (hcal_it->sample(hcal_it-> presamples() + sample - preSamples+hfShift).raw())); } hcalColl[sample].push_back(hcalDigi); } } } } //Now put the events back to file for(int i=0;i<preSamples;++i) { char ecal_label[200]; char hcal_label[200]; sprintf(ecal_label,"ECALBxminus%d",preSamples-i); sprintf(hcal_label,"HCALBxminus%d",preSamples-i); std::auto_ptr<EcalTrigPrimDigiCollection> ecalIn(new EcalTrigPrimDigiCollection); std::auto_ptr<HcalTrigPrimDigiCollection> hcalIn(new HcalTrigPrimDigiCollection); for(unsigned int j=0;j<ecalColl[i].size();++j) { ecalIn->push_back((ecalColl[i])[j]); } for(unsigned int j=0;j<hcalColl[i].size();++j) hcalIn->push_back((hcalColl[i])[j]); iEvent.put(ecalIn,ecal_label); iEvent.put(hcalIn,hcal_label); } std::auto_ptr<EcalTrigPrimDigiCollection> ecal0(new EcalTrigPrimDigiCollection); std::auto_ptr<HcalTrigPrimDigiCollection> hcal0(new HcalTrigPrimDigiCollection); for(unsigned int j=0;j<ecalColl[preSamples].size();++j) ecal0->push_back((ecalColl[preSamples])[j]); for(unsigned int j=0;j<hcalColl[preSamples].size();++j) hcal0->push_back((hcalColl[preSamples])[j]); iEvent.put(ecal0,"ECALBx0"); iEvent.put(hcal0,"HCALBx0"); for(int i=preSamples+1;i<preSamples+postSamples+1;++i) { char ecal_label[200]; char hcal_label[200]; sprintf(ecal_label,"ECALBxplus%d",i-preSamples); sprintf(hcal_label,"HCALBxplus%d",i-preSamples); std::auto_ptr<EcalTrigPrimDigiCollection> ecalIn2(new EcalTrigPrimDigiCollection); std::auto_ptr<HcalTrigPrimDigiCollection> hcalIn2(new HcalTrigPrimDigiCollection); for(unsigned int j=0;j<ecalColl[i].size();++j) ecalIn2->push_back((ecalColl[i])[j]); for(unsigned int j=0;j<hcalColl[i].size();++j) hcalIn2->push_back((hcalColl[i])[j]); iEvent.put(ecalIn2,ecal_label); iEvent.put(hcalIn2,hcal_label); } }
edm::InputTag L1RCTTPGProvider::ecalTPG_ [private] |
Definition at line 47 of file L1RCTTPGProvider.h.
Referenced by produce().
int L1RCTTPGProvider::hbShift [private] |
Definition at line 54 of file L1RCTTPGProvider.h.
Referenced by produce().
edm::InputTag L1RCTTPGProvider::hcalTPG_ [private] |
Definition at line 48 of file L1RCTTPGProvider.h.
Referenced by produce().
int L1RCTTPGProvider::hfShift [private] |
Definition at line 53 of file L1RCTTPGProvider.h.
Referenced by produce().
int L1RCTTPGProvider::postSamples [private] |
Definition at line 52 of file L1RCTTPGProvider.h.
Referenced by L1RCTTPGProvider(), and produce().
int L1RCTTPGProvider::preSamples [private] |
Definition at line 51 of file L1RCTTPGProvider.h.
Referenced by L1RCTTPGProvider(), and produce().
bool L1RCTTPGProvider::useEcalCosmicTiming [private] |
Definition at line 50 of file L1RCTTPGProvider.h.
Referenced by produce().
bool L1RCTTPGProvider::useHcalCosmicTiming [private] |
Definition at line 49 of file L1RCTTPGProvider.h.
Referenced by produce().