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| // -*- C++ -*-
#include "Rivet/Analysis.hh"
#include "Rivet/Projections/Beam.hh"
#include "Rivet/Projections/FinalState.hh"
#include "Rivet/Projections/DISKinematics.hh"
#include "Rivet/Projections/DISFinalState.hh"
#include "Rivet/Projections/DISDiffHadron.hh"
#include "Rivet/Projections/FastJets.hh"
namespace Rivet {
namespace H1_2015_I1343110_PROJECTIONS {
/// Projection to find the largest gaps and the masses of the two
/// systems separated by the gap. Based on the HZTools gap-finding
/// method (hzhadgap.F). Note that gaps are found in the HCM frame.
///
/// @author Christine O. Rasmussen.
class RapidityGap : public Projection {
public:
/// Type of DIS boost to apply
enum Frame { HCM, LAB, XCM };
RapidityGap() {
setName("RapidityGap");
declare(DISKinematics(), "DISKIN");
declare(DISFinalState(DISFinalState::BoostFrame::HCM), "DISFS");
}
DEFAULT_RIVET_PROJ_CLONE(RapidityGap);
double M2X() const { return _M2X; }
double M2Y() const { return _M2Y; }
double t() const { return _t; }
double gap() const { return _gap; }
double gapUpp() const { return _gapUpp; }
double gapLow() const { return _gapLow; }
double EpPzX(Frame f) const {
if (f == LAB) return _ePpzX_LAB;
else if (f == XCM) return _ePpzX_XCM;
else return _ePpzX_HCM;
}
double EmPzX(Frame f) const {
if (f == LAB) return _eMpzX_LAB;
else if (f == XCM) return _eMpzX_XCM;
else return _eMpzX_HCM;
}
FourMomentum pX(Frame f) const {
if (f == LAB) return _momX_LAB;
else if (f == XCM) return _momX_XCM;
else return _momX_HCM;
}
FourMomentum pY(Frame f) const {
if (f == LAB) return _momY_LAB;
else if (f == XCM) return _momY_XCM;
else return _momY_HCM;
}
const Particles& systemX(Frame f) const {
if (f == LAB) return _pX_LAB;
else if (f == XCM) return _pX_XCM;
else return _pX_HCM;
}
const Particles& systemY(Frame f) const {
if (f == LAB) return _pY_LAB;
else if (f == XCM) return _pY_XCM;
else return _pY_HCM;
}
protected:
virtual CmpState compare(const Projection& p) const {
const RapidityGap& other = pcast<RapidityGap>(p);
return mkNamedPCmp(other, "DISKIN") || mkNamedPCmp(other, "DISFS");
}
virtual void project(const Event& e){
const DISKinematics& dk = apply<DISKinematics>(e, "DISKIN");
const Particles& p = apply<DISFinalState>(e, "DISFS").particles(cmpMomByEta);
findgap(p, dk);
}
void clearAll(){
_M2X = _M2Y = _t = _gap = 0.;
_gapUpp = _gapLow = -8.;
_ePpzX_HCM = _eMpzX_HCM =_ePpzX_LAB = _eMpzX_LAB = _ePpzX_XCM = _eMpzX_XCM = 0.;
_momX_HCM.setPE(0., 0., 0., 0.);
_momY_HCM.setPE(0., 0., 0., 0.);
_momX_XCM.setPE(0., 0., 0., 0.);
_momY_XCM.setPE(0., 0., 0., 0.);
_momX_LAB.setPE(0., 0., 0., 0.);
_momY_LAB.setPE(0., 0., 0., 0.);
_pX_HCM.clear();
_pY_HCM.clear();
_pX_XCM.clear();
_pY_XCM.clear();
_pX_LAB.clear();
_pY_LAB.clear();
}
void findgap(const Particles& particles, const DISKinematics& diskin){
clearAll();
// Begin by finding largest gap and gapedges between all final
// state particles in HCM frame.
int nP = particles.size();
int dir = diskin.orientation();
for (int i = 0; i < nP-1; ++i){
double tmpGap = abs(particles[i+1].eta() - particles[i].eta());
if (tmpGap > _gap) {
_gap = tmpGap;
_gapLow = (dir > 0) ? particles[i].eta() : dir * particles[i+1].eta();
_gapUpp = (dir > 0) ? particles[i+1].eta() : dir * particles[i].eta();
}
}
// Define the two systems X and Y.
Particles tmp_pX, tmp_pY;
for (const Particle& ip : particles) {
if (dir * ip.eta() > _gapLow) tmp_pX.push_back(ip);
else tmp_pY.push_back(ip);
}
Particles pX, pY;
pX = (dir < 0) ? tmp_pY : tmp_pX;
pY = (dir < 0) ? tmp_pX : tmp_pY;
// Find variables related to HCM frame.
// Note that HCM has photon along +z, as opposed to
// H1 where proton is along +z. This results in a sign change
// as compared to H1 papers!
// X - side
FourMomentum momX;
for (const Particle& jp : pX) {
momX += jp.momentum();
_ePpzX_HCM += jp.E() - jp.pz(); // Sign + => -
_eMpzX_HCM += jp.E() + jp.pz(); // Sign - => +
}
_momX_HCM = momX;
_pX_HCM = pX;
_M2X = _momX_HCM.mass2();
// Y - side
FourMomentum momY;
for (const Particle& kp : pY) momY += kp.momentum();
_momY_HCM = momY;
_pY_HCM = pY;
_M2Y = _momY_HCM.mass2();
// Find variables related to LAB frame
const LorentzTransform hcmboost = diskin.boostHCM();
const LorentzTransform hcminverse = hcmboost.inverse();
_momX_LAB = hcminverse.transform(_momX_HCM);
_momY_LAB = hcminverse.transform(_momY_HCM);
// Find momenta in XCM frame. Note that it is HCM frame that is
// boosted, resulting in a sign change later!
const bool doXCM = (momX.betaVec().mod2() < 1.);
if (doXCM) {
const LorentzTransform xcmboost =
LorentzTransform::mkFrameTransformFromBeta(momX.betaVec());
_momX_XCM = xcmboost.transform(momX);
_momY_XCM = xcmboost.transform(momY);
}
for (const Particle& jp : pX) {
// Boost from HCM to LAB.
FourMomentum lab = hcminverse.transform(jp.momentum());
_ePpzX_LAB += lab.E() + dir * lab.pz();
_eMpzX_LAB += lab.E() - dir * lab.pz();
Particle plab = jp;
plab.setMomentum(lab);
_pX_LAB.push_back(plab);
// Set XCM. Note that since HCM frame is boosted to XCM frame,
// we have a sign change
if (doXCM) {
const LorentzTransform xcmboost =
LorentzTransform::mkFrameTransformFromBeta(_momX_HCM.betaVec());
FourMomentum xcm = xcmboost.transform(jp.momentum());
_ePpzX_XCM += xcm.E() - xcm.pz(); // Sign + => -
_eMpzX_XCM += xcm.E() + xcm.pz(); // Sign - => +
Particle pxcm = jp;
pxcm.setMomentum(xcm);
_pX_XCM.push_back(pxcm);
}
}
for (const Particle& jp : pY) {
// Boost from HCM to LAB
FourMomentum lab = hcminverse.transform(jp.momentum());
Particle plab = jp;
plab.setMomentum(lab);
_pY_LAB.push_back(plab);
// Boost from HCM to XCM
if (doXCM) {
const LorentzTransform xcmboost =
LorentzTransform::mkFrameTransformFromBeta(_momX_HCM.betaVec());
FourMomentum xcm = xcmboost.transform(jp.momentum());
Particle pxcm = jp;
pxcm.setMomentum(xcm);
_pY_XCM.push_back(pxcm);
}
}
// Find t: Currently can only handle gap on proton side.
// @TODO: Expand to also handle gap on photon side
// Boost p from LAB to HCM frame to find t.
const FourMomentum proton = hcmboost.transform(diskin.beamHadron().momentum());
FourMomentum pPom = proton - _momY_HCM;
_t = pPom * pPom;
}
private:
double _M2X, _M2Y, _t;
double _gap, _gapUpp, _gapLow;
double _ePpzX_LAB, _eMpzX_LAB, _ePpzX_HCM, _eMpzX_HCM, _ePpzX_XCM, _eMpzX_XCM;
FourMomentum _momX_HCM, _momY_HCM,_momX_LAB, _momY_LAB, _momX_XCM, _momY_XCM;
Particles _pX_HCM, _pY_HCM, _pX_LAB, _pY_LAB, _pX_XCM, _pY_XCM;
};
/// Projection to boost system X (photon+Pomeron) particles into its rest frame.
///
/// @author Ilkka Helenius
class BoostedXSystem : public FinalState {
public:
BoostedXSystem(const FinalState& fs) {
setName("BoostedXSystem");
declare(fs,"FS");
declare(RapidityGap(), "RAPGAP");
}
// Return the boost to XCM frame.
const LorentzTransform& boost() const { return _boost; }
DEFAULT_RIVET_PROJ_CLONE(BoostedXSystem);
protected:
// Apply the projection on the supplied event.
void project(const Event& e){
const RapidityGap& rg = apply<RapidityGap>(e, "RAPGAP");
// Total momentum of the system X.
const FourMomentum pX = rg.pX(RapidityGap::HCM);
// Reset the boost. Is there a separate method for this?
_boost = combine(_boost, _boost.inverse());
// Define boost only when numerically safe, otherwise negligible.
if (pX.betaVec().mod2() < 1.)
_boost = LorentzTransform::mkFrameTransformFromBeta(pX.betaVec());
// Boost the particles from system X.
_theParticles.clear();
_theParticles.reserve(rg.systemX(RapidityGap::HCM).size());
for (const Particle& p : rg.systemX(RapidityGap::HCM)) {
Particle temp = p;
temp.setMomentum(_boost.transform(temp.momentum()));
_theParticles.push_back(temp);
}
}
// Compare projections.
CmpState compare(const Projection& p) const {
const BoostedXSystem& other = pcast<BoostedXSystem>(p);
return mkNamedPCmp(other, "RAPGAP") || mkNamedPCmp(other, "FS");
}
private:
LorentzTransform _boost;
};
}
/// @brief H1 diffractive dijets
///
/// Diffractive dijets H1 with 920 GeV p and 27.5 GeV e
/// Tagged protons & jets found in gamma*p rest frame.
///
/// @author Christine O. Rasmussen
class H1_2015_I1343110 : public Analysis {
public:
/// Constructor
RIVET_DEFAULT_ANALYSIS_CTOR(H1_2015_I1343110);
typedef H1_2015_I1343110_PROJECTIONS::RapidityGap RapidityGap;
typedef H1_2015_I1343110_PROJECTIONS::BoostedXSystem BoostedXSystem;
/// @name Analysis methods
//@{
// Book projections and histograms
void init() {
declare(DISKinematics(), "Kinematics");
const DISFinalState& disfs = declare(DISFinalState(DISFinalState::BoostFrame::HCM), "DISFS");
const BoostedXSystem& disfsXcm = declare( BoostedXSystem(disfs), "BoostedXFS");
declare(FastJets(disfsXcm, fastjet::JetAlgorithm::kt_algorithm, fastjet::RecombinationScheme::pt_scheme, 1.0,
JetAlg::Muons::ALL, JetAlg::Invisibles::NONE, nullptr), "DISFSJets");
declare(DISDiffHadron(), "Hadron");
declare(RapidityGap(), "RapidityGap");
// Book histograms from REF data
book(_h_PHO_sig_sqrts, 1, 1, 1);
book(_h_DIS_sig_sqrts, 2, 1, 1);
book(_h_PHODIS_sqrts, 3, 1, 1);
book(_h_DIS_dsigdz, 4, 1, 1);
book(_h_DIS_dsigdxPom, 5, 1, 1);
book(_h_DIS_dsigdy, 6, 1, 1);
book(_h_DIS_dsigdQ2, 7, 1, 1);
book(_h_DIS_dsigdEtj1, 8, 1, 1);
book(_h_DIS_dsigdMX, 9, 1, 1);
book(_h_DIS_dsigdDeltaEta, 10, 1, 1);
book(_h_DIS_dsigdAvgEta, 11, 1, 1);
book(_h_PHO_dsigdz, 12, 1, 1);
book(_h_PHO_dsigdxPom, 13, 1, 1);
book(_h_PHO_dsigdy, 14, 1, 1);
book(_h_PHO_dsigdxGam, 15, 1, 1);
book(_h_PHO_dsigdEtj1, 16, 1, 1);
book(_h_PHO_dsigdMX, 17, 1, 1);
book(_h_PHO_dsigdDeltaEta, 18, 1, 1);
book(_h_PHO_dsigdAvgEta, 19, 1, 1);
book(_h_PHODIS_deltaEta, 20, 1, 1);
book(_h_PHODIS_y, 21, 1, 1);
book(_h_PHODIS_z, 22, 1, 1);
book(_h_PHODIS_Etj1, 23, 1, 1);
isPHO = false;
nVeto1 = 0;
nVeto2 = 0;
nVeto3 = 0;
nVeto4 = 0;
nVeto5 = 0;
nVeto6 = 0;
nPHO = 0;
nDIS = 0;
}
// Do the analysis
void analyze(const Event& event) {
// Event weight
isPHO = false;
// Projections - special handling of events where no proton found:
const RapidityGap& rg = apply<RapidityGap>(event, "RapidityGap");
const DISKinematics& kin = apply<DISKinematics>(event, "Kinematics");
const BoostedXSystem& disfsXcm = apply<BoostedXSystem>( event, "BoostedXFS");
Particle hadronOut;
Particle hadronIn;
try {
const DISDiffHadron& diffhadr = apply<DISDiffHadron>(event, "Hadron");
hadronOut = diffhadr.out();
hadronIn = diffhadr.in();
} catch (const Error& e){
vetoEvent;
}
// Determine kinematics: H1 has +z = proton direction
int dir = kin.orientation();
double y = kin.y();
double Q2 = kin.Q2();
// Separate into DIS and PHO regimes else veto
if (Q2 < 2.*GeV2 && inRange(y, 0.2, 0.70)) {
isPHO = true;
++nPHO;
} else if (inRange(Q2, 4.0*GeV2, 80.*GeV2) && inRange(y, 0.2, 0.7)) {
isPHO = false;
++nDIS;
} else vetoEvent;
++nVeto1;
// Find diffractive variables as defined in paper.
// Note tagged protons in VFPS => smaller allowed xPom range
// xPom = 1 - E'/E, M2X from hadrons, t = (P-P')^2
const double M2X = rg.M2X();
const double abst = abs(rg.t());
const double xPom = 1. - hadronOut.energy() / hadronIn.energy();
//cout << "\nhadout=" << hadronOut.energy() << ", hadin=" << hadronIn.energy() << endl;
//cout << "xPomH1=" << (Q2+M2X) / (y * sqr(sqrtS())) << endl;
//cout << "|t|=" << abst << ", xPom=" << xPom << endl;
// Veto if outside allowed region
if (abst > 0.6 * GeV2) vetoEvent;
++nVeto2;
if (!inRange(xPom, 0.010, 0.024)) vetoEvent;
++nVeto3;
// Jet selection. Note jets are found in XCM frame, but
// eta cut is applied in lab frame!
Cut jetcuts = Cuts::Et > 4.* GeV;
Jets jets = apply<FastJets>(event, "DISFSJets").jets(jetcuts, cmpMomByEt);
// Veto if not dijets and if Et_j1 < 5.5
if (jets.size() < 2) vetoEvent;
if (jets[0].Et() < 5.5 * GeV) vetoEvent;
++nVeto4;
// Find Et_jet1 in XCM frame
double EtJet1 = jets[0].Et() * GeV;
//cout << "gamma*p frame:" << endl;
//cout << "Et1=" << jets[0].Et() << ", E1=" << jets[0].E() << ", pz1=" << jets[0].pz() << ", m1=" << jets[0].mass() << endl;
//cout << "Et2=" << jets[1].Et() << ", E2=" << jets[1].E() << ", pz2=" << jets[1].pz() << ", m2=" << jets[1].mass() << endl;
// Transform from XCM to HCM
const LorentzTransform xcmboost = disfsXcm.boost();
for (int i = 0; i < 2; ++i) jets[i].transformBy(xcmboost.inverse());
// Find mass of jets and EpPz, EmPz of jets in HCM frame.
FourMomentum momJets = jets[0].momentum() + jets[1].momentum();
double M2jets = momJets.mass2();
double EpPzJets = 0.;
double EmPzJets = 0.;
// Note sign change wrt. H1 because photon is in +z direction
for (int i = 0; i < 2; ++i){
EpPzJets += jets[i].E() - jets[i].pz(); // Sign: + => -
EmPzJets += jets[i].E() + jets[i].pz(); // Sign: - => +
}
// Transform the jets from HCM to LAB frame where eta cut is
// applied for photoproduction.
const LorentzTransform hcmboost = kin.boostHCM();
for (int i = 0; i < 2; ++i) jets[i].transformBy(hcmboost.inverse());
double etaLabJet1 = dir * jets[0].eta();
double etaLabJet2 = dir * jets[1].eta();
if (!inRange(etaLabJet1, -1., 2.5)) vetoEvent;
if (!inRange(etaLabJet2, -1., 2.5)) vetoEvent;
++nVeto5;
// Pseudorapidity distributions are examined in lab frame:
double deltaEtaJets = abs(dir * jets[0].eta() - dir * jets[1].eta());
double avgEtaJets = 0.5 * (dir * jets[0].eta() + dir * jets[1].eta());
// Evaluate observables
double zPomJets, xGamJets = 0.;
if (isPHO){
zPomJets = EpPzJets / rg.EpPzX(RapidityGap::HCM);
xGamJets = EmPzJets / rg.EmPzX(RapidityGap::HCM);
//cout << "xGamJets=" << xGamJets << endl;
} else {
zPomJets = (Q2 + M2jets) / (Q2 + M2X);
}
//cout << "lab frame:" << endl;
//cout << "Et1=" << jets[0].Et() << ", E1=" << jets[0].E() << ", pz1=" << jets[0].pz() << ", m1=" << jets[0].mass() << endl;
//cout << "Et2=" << jets[1].Et() << ", E2=" << jets[1].E() << ", pz2=" << jets[1].pz() << ", m2=" << jets[1].mass() << endl;
//cout << "EpPzJets=" << EpPzJets << ", EmPzJets=" << EmPzJets << endl;
//cout << "Et*exp(eta)=" << jets[0].Et()*exp(etaLabJet1) + jets[1].Et()*exp(etaLabJet2) << endl;
//cout << "Et*exp(-eta)=" << jets[0].Et()*exp(-etaLabJet1) + jets[1].Et()*exp(-etaLabJet2) << endl;
//cout << "EpPz=" << rg.EpPzX(RapidityGap::HCM) << ", EmPz=" << rg.EmPzX(RapidityGap::HCM) << endl;
//cout << "2 xPom Ep=" << 2. * xPom * kin.beamHadron().E() << ", 2 y Ee=" << 2. * y * kin.beamLepton().E() << endl;
//cout << "xGam=" << xGamJets << ", zPom=" << zPomJets << endl;
//cout << "M12=" << M2jets << ", deltaEta=" << deltaEtaJets << ", avgEta=" << avgEtaJets << endl;
// Veto events with zPom > 0.8
if (zPomJets > 0.8) vetoEvent;
++nVeto6;
// Now fill histograms
if (isPHO){
_h_PHO_sig_sqrts ->fill(sqrtS()/GeV);
_h_PHO_dsigdz ->fill(zPomJets);
_h_PHO_dsigdxPom ->fill(xPom);
_h_PHO_dsigdy ->fill(y);
_h_PHO_dsigdxGam ->fill(xGamJets);
_h_PHO_dsigdEtj1 ->fill(EtJet1);
_h_PHO_dsigdMX ->fill(sqrt(M2X)/GeV);
_h_PHO_dsigdDeltaEta ->fill(deltaEtaJets);
_h_PHO_dsigdAvgEta ->fill(avgEtaJets);
} else {
_h_DIS_sig_sqrts ->fill(sqrtS()/GeV);
_h_DIS_dsigdz ->fill(zPomJets);
_h_DIS_dsigdxPom ->fill(xPom);
_h_DIS_dsigdy ->fill(y);
_h_DIS_dsigdQ2 ->fill(Q2);
_h_DIS_dsigdEtj1 ->fill(EtJet1);
_h_DIS_dsigdMX ->fill(sqrt(M2X)/GeV);
_h_DIS_dsigdDeltaEta ->fill(deltaEtaJets);
_h_DIS_dsigdAvgEta ->fill(avgEtaJets);
}
}
// Finalize
void finalize() {
// Normalise to cross section
// Remember to manually scale the cross section afterwards with
// the number of rejected events.
const double norm = crossSection()/picobarn/sumOfWeights();
scale(_h_PHO_sig_sqrts, norm);
scale(_h_PHO_dsigdz, norm);
scale(_h_PHO_dsigdxPom, norm);
scale(_h_PHO_dsigdy, norm);
scale(_h_PHO_dsigdxGam, norm);
scale(_h_PHO_dsigdEtj1, norm);
scale(_h_PHO_dsigdMX, norm);
scale(_h_PHO_dsigdDeltaEta, norm);
scale(_h_PHO_dsigdAvgEta, norm);
scale(_h_DIS_sig_sqrts, norm);
scale(_h_DIS_dsigdz, norm);
scale(_h_DIS_dsigdxPom, norm);
scale(_h_DIS_dsigdy, norm);
scale(_h_DIS_dsigdQ2, norm);
scale(_h_DIS_dsigdEtj1, norm);
scale(_h_DIS_dsigdMX, norm);
scale(_h_DIS_dsigdDeltaEta, norm);
scale(_h_DIS_dsigdAvgEta, norm);
if (_h_DIS_sig_sqrts->numEntries() != 0)
divide(_h_PHO_sig_sqrts, _h_DIS_sig_sqrts, _h_PHODIS_sqrts);
if (_h_DIS_dsigdDeltaEta->numEntries() != 0)
divide(_h_PHO_dsigdDeltaEta, _h_DIS_dsigdDeltaEta, _h_PHODIS_deltaEta);
if (_h_DIS_dsigdy->numEntries() != 0)
divide(_h_PHO_dsigdy, _h_DIS_dsigdy, _h_PHODIS_y);
if (_h_DIS_dsigdz->numEntries() != 0)
divide(_h_PHO_dsigdz, _h_DIS_dsigdz, _h_PHODIS_z);
if (_h_DIS_dsigdEtj1->numEntries() != 0)
divide(_h_PHO_dsigdEtj1, _h_DIS_dsigdEtj1, _h_PHODIS_Etj1);
const double dPHO = nPHO;
MSG_INFO("H1_2015_I1343110");
MSG_INFO("Cross section = " << crossSection()/picobarn << " pb");
MSG_INFO("Number of events = " << numEvents() << ", sumW = " << sumOfWeights());
MSG_INFO("Number of PHO = " << nPHO << ", number of DIS = " << nDIS);
MSG_INFO("Events passing electron veto = " << nVeto1 << " (" << nVeto1/dPHO * 100. << "%)" );
MSG_INFO("Events passing t veto = " << nVeto2 << " (" << nVeto2/dPHO * 100. << "%)" );
MSG_INFO("Events passing xPom = " << nVeto3 << " (" << nVeto3/dPHO * 100. << "%)" );
MSG_INFO("Events passing jet Et veto = " << nVeto4 << " (" << nVeto4/dPHO * 100. << "%)" );
MSG_INFO("Events passing jet eta veto = " << nVeto5 << " (" << nVeto5/dPHO * 100. << "%)" );
MSG_INFO("Events passing zPom veto = " << nVeto6 << " (" << nVeto6/dPHO * 100. << "%)" );
}
//@}
private:
/// @name Histograms
//@{
// Book histograms from REF data
Histo1DPtr _h_PHO_sig_sqrts;
Histo1DPtr _h_DIS_sig_sqrts;
Scatter2DPtr _h_PHODIS_sqrts;
Histo1DPtr _h_DIS_dsigdz;
Histo1DPtr _h_DIS_dsigdxPom;
Histo1DPtr _h_DIS_dsigdy;
Histo1DPtr _h_DIS_dsigdQ2;
Histo1DPtr _h_DIS_dsigdEtj1;
Histo1DPtr _h_DIS_dsigdMX;
Histo1DPtr _h_DIS_dsigdDeltaEta;
Histo1DPtr _h_DIS_dsigdAvgEta;
Histo1DPtr _h_PHO_dsigdz;
Histo1DPtr _h_PHO_dsigdxPom;
Histo1DPtr _h_PHO_dsigdy;
Histo1DPtr _h_PHO_dsigdxGam;
Histo1DPtr _h_PHO_dsigdEtj1;
Histo1DPtr _h_PHO_dsigdMX;
Histo1DPtr _h_PHO_dsigdDeltaEta;
Histo1DPtr _h_PHO_dsigdAvgEta;
Scatter2DPtr _h_PHODIS_deltaEta;
Scatter2DPtr _h_PHODIS_y;
Scatter2DPtr _h_PHODIS_z;
Scatter2DPtr _h_PHODIS_Etj1;
//@}
bool isPHO;
int nVeto1, nVeto2, nVeto3, nVeto4, nVeto5, nVeto6;
int nPHO, nDIS;
};
RIVET_DECLARE_PLUGIN(H1_2015_I1343110);
}
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