BSCTrigger.cc

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// -*- C++ -*-
//
// Package:    BSCTrigger
// Class:      BSCTrigger
//
//
// Original Author:  Muriel VANDER DONCKT *:0
//         Created:  Wed Jul 16 16:11:05 CEST 2008
//
//
 
// system include files
#include <memory>
 
// user include files
#include "FWCore/Framework/interface/Frameworkfwd.h"
#include "FWCore/Framework/interface/global/EDProducer.h"
 
#include "FWCore/Framework/interface/Event.h"
#include "FWCore/Framework/interface/MakerMacros.h"
 
#include "FWCore/ParameterSet/interface/ParameterSet.h"
#include "SimDataFormats/TrackingHit/interface/PSimHitContainer.h"
#include "DataFormats/L1GlobalTrigger/interface/L1GtTechnicalTrigger.h"
#include "DataFormats/L1GlobalTrigger/interface/L1GtTechnicalTriggerRecord.h"
#include "FWCore/Utilities/interface/InputTag.h"
#include "FWCore/Utilities/interface/EDGetToken.h"
#include "FWCore/Utilities/interface/EDPutToken.h"
 
#include "SimDataFormats/CrossingFrame/interface/CrossingFrame.h"
#include "SimDataFormats/CrossingFrame/interface/MixCollection.h"
 
//
// class declaration
//
 
class BSCTrigger : public edm::global::EDProducer<> {
public:
  explicit BSCTrigger(const edm::ParameterSet&);
  ~BSCTrigger() override;
 
private:
  void produce(edm::StreamID, edm::Event&, const edm::EventSetup&) const override;
  int getBSCNum(int id, float z) const;
  bool isInner(int id) const;
  bool isZplus(int id) const;
  // ----------member data ---------------------------
  const std::vector<unsigned> ttBits_;
  const std::vector<std::string> names_;
  const double theCoincidence_;
  const double theResolution_;
  const edm::EDGetTokenT<CrossingFrame<PSimHit>> theHitsToken_;
  const edm::EDPutTokenT<L1GtTechnicalTriggerRecord> thePutToken_;
};
 
//
// constants, enums and typedefs
//
 
//
// static data member definitions
//
 
//
// constructors and destructor
//
BSCTrigger::BSCTrigger(const edm::ParameterSet& iConfig)
    : ttBits_{iConfig.getParameter<std::vector<unsigned>>("bitNumbers")},
      names_{iConfig.getParameter<std::vector<std::string>>("bitNames")},
      theCoincidence_{iConfig.getParameter<double>("coincidence")},
      theResolution_{iConfig.getParameter<double>("resolution")},
      theHitsToken_{consumes<CrossingFrame<PSimHit>>(iConfig.getParameter<edm::InputTag>("theHits"))},
      thePutToken_{produces<L1GtTechnicalTriggerRecord>()} {}
 
BSCTrigger::~BSCTrigger() {
  // do anything here that needs to be done at desctruction time
  // (e.g. close files, deallocate resources etc.)
}
 
//
// member functions
//
 
// ------------ method called to produce the data  ------------
void BSCTrigger::produce(edm::StreamID, edm::Event& iEvent, const edm::EventSetup& iSetup) const {
  std::vector<L1GtTechnicalTrigger> ttVec(ttBits_.size());
 
  edm::Handle<CrossingFrame<PSimHit>> cf;
  iEvent.getByToken(theHitsToken_, cf);
 
  if (!cf.failedToGet()) {
    std::vector<float> EnergyBX(32);
    std::vector<float> EnergyBXMinusDt(32);
 
    for (int c = 0; c < 32; ++c) {
      EnergyBX[c] = 0;
      EnergyBXMinusDt[c] = 0;
    }
    MixCollection<PSimHit> theBSCHitContainer(cf.product());
    const float dt1 = theCoincidence_ / 2 + theResolution_;
    const float dt2 = theCoincidence_ / 2 - theResolution_;
    if (edm::isDebugEnabled())
      LogDebug("BSCTrig") << " ----------------new event ---with " << theBSCHitContainer.size() << " hits in the BSC";
 
    // collect total deposited energy in BSC segments -> EnergyBX[segment id], in GeV units ---------------------------------------------------------------
    for (auto itHit = theBSCHitContainer.begin(); itHit != theBSCHitContainer.end(); ++itHit) {
      float zh = itHit->entryPoint().z() / 10;
      int id = getBSCNum(itHit->detUnitId(), zh);
      if (id > 31)
        continue;  // the small 2 paddles further from the IP
      float t = itHit->timeOfFlight();
 
      if (edm::isDebugEnabled()) {
        float rh = sqrt(itHit->entryPoint().x() * itHit->entryPoint().x() +
                        itHit->entryPoint().y() * itHit->entryPoint().y()) /
                   10;
        LogTrace("BSCTrig") << " BSC Num " << id << " z=" << zh << " isZplus=" << isZplus(id)
                            << " Hit DetId=" << getBSCNum(id, zh) << " r=" << rh << " isInner=" << isInner(id);
        LogTrace("BSCTrig") << " Hit time=" << t << " accepted range=[" << dt2 << "," << dt1 << "] from a "
                            << abs(itHit->particleType()) << " with energy " << itHit->energyLoss();
      }
      if (fabs(t) > dt1 || fabs(t) < dt2)
        continue;
      if (t > 0)
        EnergyBX[id] += itHit->energyLoss();
      else
        EnergyBXMinusDt[id] += itHit->energyLoss();
    }
 
    // count number of segments hit in inner/outer and +z, -z ---------------------------------------------------------------------------------------------
    int ZMinnerBX = 0, ZMouterBX = 0;
    int ZPinnerBX = 0, ZPouterBX = 0;
    int ZMinnerBXMinusDt = 0, ZMouterBXMinusDt = 0;
    int ZPinnerBXMinusDt = 0, ZPouterBXMinusDt = 0;
 
    constexpr float MipFraction = 0.5;
    constexpr float MipEnergy = 0.0027;
    constexpr float theThreshold = MipFraction * MipEnergy;
    for (unsigned int ipad = 0; ipad < 32; ipad++) {
      if (edm::isDebugEnabled())
        LogTrace("BSCTrig") << " EnergyBX[" << ipad << "]=" << EnergyBX[ipad];
      // hits after the bunch crossing
      if (EnergyBX[ipad] > theThreshold) {
        if (isZplus(ipad)) {
          if (isInner(ipad))
            ZPinnerBX++;
          else
            ZPouterBX++;
        } else {
          if (isInner(ipad))
            ZMinnerBX++;
          else
            ZMouterBX++;
        }
      }
      // hits before the bunch crossing
      if (EnergyBXMinusDt[ipad] > theThreshold) {
        if (isZplus(ipad)) {
          if (isInner(ipad))
            ZPinnerBXMinusDt++;
          else
            ZPouterBXMinusDt++;
        } else {
          if (isInner(ipad))
            ZMinnerBXMinusDt++;
          else
            ZMouterBXMinusDt++;
        }
      }
    }
 
    if (edm::isDebugEnabled())
      LogTrace("BSCTrig") << " Zplus I=" << ZPinnerBX << " Zminus I=" << ZMinnerBX << " Zplus O=" << ZPouterBX
                          << "  Zminus O=" << ZMouterBX;
 
    // minimum bias technical triggers that are also connected to 'external condition' triggers -----------------
    bool bit32 = false;  // min bias inner >=1
    if (ZPinnerBX >= 1 && ZMinnerBX >= 1)
      bit32 = true;
 
    bool bit33 = false;  // min bias inner >=2
    if (ZPinnerBX >= 2 && ZMinnerBX >= 2)
      bit33 = true;
 
    bool bit34 = false;  // min bias OR
    if (ZPinnerBX + ZMinnerBX + ZPouterBX + ZMouterBX >= 1)
      bit34 = true;
 
    bool bit35 = false;  // high multiplicity
    if (ZPinnerBX == 8 && ZMinnerBX == 8)
      bit35 = true;
 
    // beam halo technical triggers ----------------------------------------------------------------
    bool bit36 = false;  // beam 2 halo inner
    if (ZPinnerBX >= 1 && ZMinnerBXMinusDt >= 1)
      bit36 = true;
 
    bool bit37 = false;  // beam 2 halo outer
    if (ZPouterBX >= 1 && ZMouterBXMinusDt >= 1)
      bit37 = true;
 
    bool bit38 = false;  // beam 1 halo inner
    if (ZMinnerBX >= 1 && ZPinnerBXMinusDt >= 1)
      bit38 = true;
 
    bool bit39 = false;  // beam 1 halo outer
    if (ZMouterBX >= 1 && ZPouterBXMinusDt >= 1)
      bit39 = true;
 
    // minimum bias technical triggers ---------------------------------------------------------
    bool bit40 = false;  // min bias all >=1
    if (ZPinnerBX + ZPouterBX >= 1 && ZMinnerBX + ZMouterBX >= 1)
      bit40 = true;
 
    bool bit41 = false;  // min bias all >=2
    if (ZPinnerBX + ZPouterBX >= 2 && ZMinnerBX + ZMouterBX >= 2)
      bit41 = true;
 
    bool bit42 = false;  // beam 1 splash (-z)
    if (ZMinnerBX >= 2)
      bit42 = true;
 
    bool bit43 = false;  // beam 2 splash (+z)
    if (ZPinnerBX >= 2)
      bit43 = true;
 
    for (unsigned i = 0; i < ttBits_.size(); ++i) {
      bool bit = false;
      if (names_.at(i) == names_[0])
        bit = bit32;
      if (names_.at(i) == names_[1])
        bit = bit33;
      if (names_.at(i) == names_[2])
        bit = bit34;
      if (names_.at(i) == names_[3])
        bit = bit35;
      if (names_.at(i) == names_[4])
        bit = bit36;
      if (names_.at(i) == names_[5])
        bit = bit37;
      if (names_.at(i) == names_[6])
        bit = bit38;
      if (names_.at(i) == names_[7])
        bit = bit39;
      if (names_.at(i) == names_[8])
        bit = bit40;
      if (names_.at(i) == names_[9])
        bit = bit41;
      if (names_.at(i) == names_[10])
        bit = bit42;
      if (names_.at(i) == names_[11])
        bit = bit43;
      ttVec.at(i) = L1GtTechnicalTrigger(names_.at(i), ttBits_.at(i), 0, bit);
      if (edm::isDebugEnabled())
        LogTrace("AnaBsc") << "bit: " << ttBits_[i] << " VALUE:" << bit;
    }
  } else
    ttVec.clear();
  L1GtTechnicalTriggerRecord output;
  output.setGtTechnicalTrigger(ttVec);
  iEvent.emplace(thePutToken_, std::move(output));
}
int BSCTrigger::getBSCNum(int id, float z) const {
  int zside = 0;
  if (z > 0)
    zside = 1;
  if (edm::isDebugEnabled()) {
    int det = (id & 24) >> 3;
    int station = id & 7;
    LogTrace("BSCTrig") << "id=" << id << " zside=" << zside << " det=" << det << " station=" << station;
  }
  int BSCNum;
  if (id & 16)
    BSCNum = 32 + (id & 1) + (zside << 1);  // small paddles further from IP
  else
    BSCNum = (id & 15) + (zside << 4);  // the BSC on the HF
  return BSCNum;
}
 
bool BSCTrigger::isInner(int id) const { return ((id & 8) >> 3); }
 
bool BSCTrigger::isZplus(int id) const { return ((id & 16) >> 4); }
 
//define this as a plug-in
DEFINE_FWK_MODULE(BSCTrigger);