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#include "DQM/L1TMonitor/interface/L1TStage2MuonComp.h"
L1TStage2MuonComp::L1TStage2MuonComp(const edm::ParameterSet& ps)
: muonToken1(consumes<l1t::MuonBxCollection>(ps.getParameter<edm::InputTag>("muonCollection1"))),
muonToken2(consumes<l1t::MuonBxCollection>(ps.getParameter<edm::InputTag>("muonCollection2"))),
monitorDir(ps.getUntrackedParameter<std::string>("monitorDir")),
muonColl1Title(ps.getUntrackedParameter<std::string>("muonCollection1Title")),
muonColl2Title(ps.getUntrackedParameter<std::string>("muonCollection2Title")),
summaryTitle(ps.getUntrackedParameter<std::string>("summaryTitle")),
ignoreBin(ps.getUntrackedParameter<std::vector<int>>("ignoreBin")),
verbose(ps.getUntrackedParameter<bool>("verbose")),
enable2DComp(
ps.getUntrackedParameter<bool>("enable2DComp")), // When true eta-phi comparison plots are also produced
displacedQuantities_(ps.getUntrackedParameter<bool>("displacedQuantities")) {
if (displacedQuantities_) {
numErrBins_ += 2;
}
// First include all bins
for (int i = 1; i <= numErrBins_; i++) {
incBin[i] = true;
}
// Then check the list of bins to ignore
for (const auto& i : ignoreBin) {
if (i > 0 && i <= RIDX) {
incBin[i] = false;
}
}
}
L1TStage2MuonComp::~L1TStage2MuonComp() {}
void L1TStage2MuonComp::fillDescriptions(edm::ConfigurationDescriptions& descriptions) {
edm::ParameterSetDescription desc;
desc.add<edm::InputTag>("muonCollection1")->setComment("L1T Muon collection 1");
desc.add<edm::InputTag>("muonCollection2")->setComment("L1T Muon collection 2");
desc.addUntracked<std::string>("monitorDir", "")
->setComment("Target directory in the DQM file. Will be created if not existing.");
desc.addUntracked<std::string>("muonCollection1Title", "Muon collection 1")
->setComment("Histogram title for first collection.");
desc.addUntracked<std::string>("muonCollection2Title", "Muon collection 2")
->setComment("Histogram title for second collection.");
desc.addUntracked<std::string>("summaryTitle", "Summary")->setComment("Title of summary histogram.");
desc.addUntracked<std::vector<int>>("ignoreBin", std::vector<int>())->setComment("List of bins to ignore");
desc.addUntracked<bool>("verbose", false);
desc.addUntracked<bool>("enable2DComp", false);
desc.addUntracked<bool>("displacedQuantities", false);
descriptions.add("l1tStage2MuonComp", desc);
}
void L1TStage2MuonComp::bookHistograms(DQMStore::IBooker& ibooker, const edm::Run&, const edm::EventSetup&) {
// Subsystem Monitoring and Muon Output
ibooker.setCurrentFolder(monitorDir);
int numBins{16};
if (displacedQuantities_) {
numBins += 2;
}
summary = ibooker.book1D("summary", summaryTitle.c_str(), numBins, 1, numBins + 1); // range to match bin numbering
summary->setBinLabel(BXRANGEGOOD, "BX range match", 1);
summary->setBinLabel(BXRANGEBAD, "BX range mismatch", 1);
summary->setBinLabel(NMUONGOOD, "muon collection size match", 1);
summary->setBinLabel(NMUONBAD, "muon collection size mismatch", 1);
summary->setBinLabel(MUONALL, "# muons", 1);
summary->setBinLabel(MUONGOOD, "# matching muons", 1);
summary->setBinLabel(PTBAD, "p_{T} mismatch", 1);
summary->setBinLabel(ETABAD, "#eta mismatch", 1);
summary->setBinLabel(PHIBAD, "#phi mismatch", 1);
summary->setBinLabel(ETAATVTXBAD, "#eta at vertex mismatch", 1);
summary->setBinLabel(PHIATVTXBAD, "#phi at vertex mismatch", 1);
summary->setBinLabel(CHARGEBAD, "charge mismatch", 1);
summary->setBinLabel(CHARGEVALBAD, "charge valid mismatch", 1);
summary->setBinLabel(QUALBAD, "quality mismatch", 1);
summary->setBinLabel(ISOBAD, "iso mismatch", 1);
summary->setBinLabel(IDXBAD, "index mismatch", 1);
if (displacedQuantities_) {
summary->setBinLabel(PTUNCONSTRBAD, "p_{T} unconstrained mismatch", 1);
summary->setBinLabel(DXYBAD, "dXY mismatch", 1);
}
errorSummaryNum = ibooker.book1D(
"errorSummaryNum", summaryTitle.c_str(), numErrBins_, 1, numErrBins_ + 1); // range to match bin numbering
errorSummaryNum->setBinLabel(RBXRANGE, "BX range mismatch", 1);
errorSummaryNum->setBinLabel(RNMUON, "muon collection size mismatch", 1);
errorSummaryNum->setBinLabel(RMUON, "mismatching muons", 1);
errorSummaryNum->setBinLabel(RPT, "p_{T} mismatch", 1);
errorSummaryNum->setBinLabel(RETA, "#eta mismatch", 1);
errorSummaryNum->setBinLabel(RPHI, "#phi mismatch", 1);
errorSummaryNum->setBinLabel(RETAATVTX, "#eta at vertex mismatch", 1);
errorSummaryNum->setBinLabel(RPHIATVTX, "#phi at vertex mismatch", 1);
errorSummaryNum->setBinLabel(RCHARGE, "charge mismatch", 1);
errorSummaryNum->setBinLabel(RCHARGEVAL, "charge valid mismatch", 1);
errorSummaryNum->setBinLabel(RQUAL, "quality mismatch", 1);
errorSummaryNum->setBinLabel(RISO, "iso mismatch", 1);
errorSummaryNum->setBinLabel(RIDX, "index mismatch", 1);
if (displacedQuantities_) {
errorSummaryNum->setBinLabel(RPTUNCONSTR, "p_{T} unconstrained mismatch", 1);
errorSummaryNum->setBinLabel(RDXY, "dXY mismatch", 1);
}
// Change the label for those bins that will be ignored
for (unsigned int i = 1; i <= RIDX; i++) {
if (incBin[i] == false) {
errorSummaryNum->setBinLabel(i, "Ignored", 1);
}
}
// Setting canExtend to false is needed to get the correct behaviour when running multithreaded.
// Otherwise, when merging the histgrams of the threads, TH1::Merge sums bins that have the same label in one bin.
// This needs to come after the calls to setBinLabel.
errorSummaryNum->getTH1F()->GetXaxis()->SetCanExtend(false);
errorSummaryDen = ibooker.book1D(
"errorSummaryDen", "denominators", numErrBins_, 1, numErrBins_ + 1); // range to match bin numbering
errorSummaryDen->setBinLabel(RBXRANGE, "# events", 1);
errorSummaryDen->setBinLabel(RNMUON, "# muon collections", 1);
for (int i = RMUON; i <= numErrBins_; ++i) {
errorSummaryDen->setBinLabel(i, "# muons", 1);
}
// Needed for correct histogram summing in multithreaded running.
errorSummaryDen->getTH1F()->GetXaxis()->SetCanExtend(false);
muColl1BxRange = ibooker.book1D("muBxRangeColl1", (muonColl1Title + " mismatching BX range").c_str(), 5, -2.5, 2.5);
muColl1BxRange->setAxisTitle("BX range", 1);
muColl1nMu = ibooker.book1D("nMuColl1", (muonColl1Title + " mismatching muon multiplicity").c_str(), 9, -0.5, 8.5);
muColl1nMu->setAxisTitle("Muon multiplicity", 1);
muColl1hwPt = ibooker.book1D("muHwPtColl1", (muonColl1Title + " mismatching muon p_{T}").c_str(), 512, -0.5, 511.5);
muColl1hwPt->setAxisTitle("Hardware p_{T}", 1);
muColl1hwEta =
ibooker.book1D("muHwEtaColl1", (muonColl1Title + " mismatching muon #eta").c_str(), 461, -230.5, 230.5);
muColl1hwEta->setAxisTitle("Hardware #eta", 1);
muColl1hwPhi = ibooker.book1D("muHwPhiColl1", (muonColl1Title + " mismatching muon #phi").c_str(), 576, -0.5, 575.5);
muColl1hwPhi->setAxisTitle("Hardware #phi", 1);
muColl1hwEtaAtVtx = ibooker.book1D(
"muHwEtaAtVtxColl1", (muonColl1Title + " mismatching muon #eta at vertex").c_str(), 461, -230.5, 230.5);
muColl1hwEtaAtVtx->setAxisTitle("Hardware #eta at vertex", 1);
muColl1hwPhiAtVtx = ibooker.book1D(
"muHwPhiAtVtxColl1", (muonColl1Title + " mismatching muon #phi at vertex").c_str(), 576, -0.5, 575.5);
muColl1hwPhiAtVtx->setAxisTitle("Hardware #phi at vertex", 1);
muColl1hwCharge =
ibooker.book1D("muHwChargeColl1", (muonColl1Title + " mismatching muon charge").c_str(), 2, -0.5, 1.5);
muColl1hwCharge->setAxisTitle("Hardware charge", 1);
muColl1hwChargeValid =
ibooker.book1D("muHwChargeValidColl1", (muonColl1Title + " mismatching muon charge valid").c_str(), 2, -0.5, 1.5);
muColl1hwChargeValid->setAxisTitle("Hardware charge valid", 1);
muColl1hwQual =
ibooker.book1D("muHwQualColl1", (muonColl1Title + " mismatching muon quality").c_str(), 16, -0.5, 15.5);
muColl1hwQual->setAxisTitle("Hardware quality", 1);
muColl1hwIso = ibooker.book1D("muHwIsoColl1", (muonColl1Title + " mismatching muon isolation").c_str(), 4, -0.5, 3.5);
muColl1hwIso->setAxisTitle("Hardware isolation", 1);
muColl1Index =
ibooker.book1D("muIndexColl1", (muonColl1Title + " mismatching Input muon index").c_str(), 108, -0.5, 107.5);
muColl1Index->setAxisTitle("Index", 1);
if (displacedQuantities_) {
muColl1hwPtUnconstrained = ibooker.book1D("muHwPtUnconstrainedColl1",
(muonColl1Title + " mismatching muon p_{T} unconstrained").c_str(),
512,
-0.5,
511.5);
muColl1hwPtUnconstrained->setAxisTitle("Hardware p_{T} unconstrained", 1);
muColl1hwDXY =
ibooker.book1D("muHwDXYColl1", (muonColl1Title + " mismatching impact parameter").c_str(), 4, -0.5, 3.5);
muColl1hwDXY->setAxisTitle("Hardware dXY", 1);
}
// if enable2DComp variable is True, book also the eta-phi map
if (enable2DComp) {
muColl1EtaPhimap = ibooker.book2D(
"muEtaPhimapColl1", (muonColl1Title + " mismatching muon #eta-#phi map").c_str(), 25, -2.5, 2.5, 25, -3.2, 3.2);
muColl1EtaPhimap->setAxisTitle("#eta", 1);
muColl1EtaPhimap->setAxisTitle("#phi", 2);
}
muColl2BxRange = ibooker.book1D("muBxRangeColl2", (muonColl2Title + " mismatching BX range").c_str(), 5, -2.5, 2.5);
muColl2BxRange->setAxisTitle("BX range", 1);
muColl2nMu = ibooker.book1D("nMuColl2", (muonColl2Title + " mismatching muon multiplicity").c_str(), 9, -0.5, 8.5);
muColl2nMu->setAxisTitle("Muon multiplicity", 1);
muColl2hwPt = ibooker.book1D("muHwPtColl2", (muonColl2Title + " mismatching muon p_{T}").c_str(), 512, -0.5, 511.5);
muColl2hwPt->setAxisTitle("Hardware p_{T}", 1);
muColl2hwEta =
ibooker.book1D("muHwEtaColl2", (muonColl2Title + " mismatching muon #eta").c_str(), 461, -230.5, 230.5);
muColl2hwEta->setAxisTitle("Hardware #eta", 1);
muColl2hwPhi = ibooker.book1D("muHwPhiColl2", (muonColl2Title + " mismatching muon #phi").c_str(), 576, -0.5, 575.5);
muColl2hwPhi->setAxisTitle("Hardware #phi", 1);
muColl2hwEtaAtVtx = ibooker.book1D(
"muHwEtaAtVtxColl2", (muonColl2Title + " mismatching muon #eta at vertex").c_str(), 461, -230.5, 230.5);
muColl2hwEtaAtVtx->setAxisTitle("Hardware #eta at vertex", 1);
muColl2hwPhiAtVtx = ibooker.book1D(
"muHwPhiAtVtxColl2", (muonColl2Title + " mismatching muon #phi at vertex").c_str(), 576, -0.5, 575.5);
muColl2hwPhiAtVtx->setAxisTitle("Hardware #phi at vertex", 1);
muColl2hwCharge =
ibooker.book1D("muHwChargeColl2", (muonColl2Title + " mismatching muon charge").c_str(), 2, -0.5, 1.5);
muColl2hwCharge->setAxisTitle("Hardware charge", 1);
muColl2hwChargeValid =
ibooker.book1D("muHwChargeValidColl2", (muonColl2Title + " mismatching muon charge valid").c_str(), 2, -0.5, 1.5);
muColl2hwChargeValid->setAxisTitle("Hardware charge valid", 1);
muColl2hwQual =
ibooker.book1D("muHwQualColl2", (muonColl2Title + " mismatching muon quality").c_str(), 16, -0.5, 15.5);
muColl2hwQual->setAxisTitle("Hardware quality", 1);
muColl2hwIso = ibooker.book1D("muHwIsoColl2", (muonColl2Title + " mismatching muon isolation").c_str(), 4, -0.5, 3.5);
muColl2hwIso->setAxisTitle("Hardware isolation", 1);
muColl2Index =
ibooker.book1D("muIndexColl2", (muonColl2Title + " mismatching Input muon index").c_str(), 108, -0.5, 107.5);
muColl2Index->setAxisTitle("Index", 1);
if (displacedQuantities_) {
muColl2hwPtUnconstrained = ibooker.book1D("muHwPtUnconstrainedColl2",
(muonColl2Title + " mismatching muon p_{T} unconstrained").c_str(),
512,
-0.5,
511.5);
muColl2hwPtUnconstrained->setAxisTitle("Hardware p_{T} unconstrained", 1);
muColl2hwDXY =
ibooker.book1D("muHwDXYColl2", (muonColl2Title + " mismatching impact parameter").c_str(), 4, -0.5, 3.5);
muColl2hwDXY->setAxisTitle("Hardware dXY", 1);
}
// if enable2DdeMu variable is True, book also the eta-phi map
if (enable2DComp) {
muColl2EtaPhimap = ibooker.book2D(
"muEtaPhimapColl2", (muonColl2Title + " mismatching muon #eta-#phi map").c_str(), 25, -2.5, 2.5, 25, -3.2, 3.2);
muColl2EtaPhimap->setAxisTitle("#eta", 1);
muColl2EtaPhimap->setAxisTitle("#phi", 2);
}
}
void L1TStage2MuonComp::analyze(const edm::Event& e, const edm::EventSetup& c) {
if (verbose)
edm::LogInfo("L1TStage2MuonComp") << "L1TStage2MuonComp: analyze..." << std::endl;
edm::Handle<l1t::MuonBxCollection> muonBxColl1;
edm::Handle<l1t::MuonBxCollection> muonBxColl2;
e.getByToken(muonToken1, muonBxColl1);
e.getByToken(muonToken2, muonBxColl2);
errorSummaryDen->Fill(RBXRANGE);
int bxRange1 = muonBxColl1->getLastBX() - muonBxColl1->getFirstBX() + 1;
int bxRange2 = muonBxColl2->getLastBX() - muonBxColl2->getFirstBX() + 1;
if (bxRange1 != bxRange2) {
summary->Fill(BXRANGEBAD);
if (incBin[RBXRANGE])
errorSummaryNum->Fill(RBXRANGE);
int bx;
for (bx = muonBxColl1->getFirstBX(); bx <= muonBxColl1->getLastBX(); ++bx) {
muColl1BxRange->Fill(bx);
}
for (bx = muonBxColl2->getFirstBX(); bx <= muonBxColl2->getLastBX(); ++bx) {
muColl2BxRange->Fill(bx);
}
} else {
summary->Fill(BXRANGEGOOD);
}
for (int iBx = muonBxColl1->getFirstBX(); iBx <= muonBxColl1->getLastBX(); ++iBx) {
// don't analyse if this BX does not exist in the second collection
if (iBx < muonBxColl2->getFirstBX() || iBx > muonBxColl2->getLastBX())
continue;
l1t::MuonBxCollection::const_iterator muonIt1;
l1t::MuonBxCollection::const_iterator muonIt2;
errorSummaryDen->Fill(RNMUON);
// check number of muons
if (muonBxColl1->size(iBx) != muonBxColl2->size(iBx)) {
summary->Fill(NMUONBAD);
if (incBin[RNMUON])
errorSummaryNum->Fill(RNMUON);
muColl1nMu->Fill(muonBxColl1->size(iBx));
muColl2nMu->Fill(muonBxColl2->size(iBx));
if (muonBxColl1->size(iBx) > muonBxColl2->size(iBx)) {
muonIt1 = muonBxColl1->begin(iBx) + muonBxColl2->size(iBx);
for (; muonIt1 != muonBxColl1->end(iBx); ++muonIt1) {
muColl1hwPt->Fill(muonIt1->hwPt());
muColl1hwEta->Fill(muonIt1->hwEta());
muColl1hwPhi->Fill(muonIt1->hwPhi());
muColl1hwEtaAtVtx->Fill(muonIt1->hwEtaAtVtx());
muColl1hwPhiAtVtx->Fill(muonIt1->hwPhiAtVtx());
muColl1hwCharge->Fill(muonIt1->hwCharge());
muColl1hwChargeValid->Fill(muonIt1->hwChargeValid());
muColl1hwQual->Fill(muonIt1->hwQual());
muColl1hwIso->Fill(muonIt1->hwIso());
muColl1Index->Fill(muonIt1->tfMuonIndex());
if (enable2DComp) {
muColl1EtaPhimap->Fill(muonIt1->eta(), muonIt1->phi());
}
if (displacedQuantities_) {
muColl1hwPtUnconstrained->Fill(muonIt1->hwPtUnconstrained());
muColl1hwDXY->Fill(muonIt1->hwDXY());
}
}
} else {
muonIt2 = muonBxColl2->begin(iBx) + muonBxColl1->size(iBx);
for (; muonIt2 != muonBxColl2->end(iBx); ++muonIt2) {
muColl2hwPt->Fill(muonIt2->hwPt());
muColl2hwEta->Fill(muonIt2->hwEta());
muColl2hwPhi->Fill(muonIt2->hwPhi());
muColl2hwEtaAtVtx->Fill(muonIt2->hwEtaAtVtx());
muColl2hwPhiAtVtx->Fill(muonIt2->hwPhiAtVtx());
muColl2hwCharge->Fill(muonIt2->hwCharge());
muColl2hwChargeValid->Fill(muonIt2->hwChargeValid());
muColl2hwQual->Fill(muonIt2->hwQual());
muColl2hwIso->Fill(muonIt2->hwIso());
muColl2Index->Fill(muonIt2->tfMuonIndex());
if (enable2DComp) {
muColl2EtaPhimap->Fill(muonIt2->eta(), muonIt2->phi());
}
if (displacedQuantities_) {
muColl2hwPtUnconstrained->Fill(muonIt2->hwPtUnconstrained());
muColl2hwDXY->Fill(muonIt2->hwDXY());
}
}
}
} else {
summary->Fill(NMUONGOOD);
}
muonIt1 = muonBxColl1->begin(iBx);
muonIt2 = muonBxColl2->begin(iBx);
while (muonIt1 != muonBxColl1->end(iBx) && muonIt2 != muonBxColl2->end(iBx)) {
summary->Fill(MUONALL);
for (int i = RMUON; i <= numErrBins_; ++i) {
errorSummaryDen->Fill(i);
}
bool muonMismatch = false; // All muon mismatches
bool muonSelMismatch = false; // Muon mismatches excluding ignored bins
if (muonIt1->hwPt() != muonIt2->hwPt()) {
muonMismatch = true;
summary->Fill(PTBAD);
if (incBin[RPT]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RPT);
}
}
if (displacedQuantities_) {
if (muonIt1->hwPtUnconstrained() != muonIt2->hwPtUnconstrained()) {
muonMismatch = true;
summary->Fill(PTUNCONSTRBAD);
if (incBin[RPTUNCONSTR]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RPTUNCONSTR);
}
}
if (muonIt1->hwDXY() != muonIt2->hwDXY()) {
muonMismatch = true;
summary->Fill(DXYBAD);
if (incBin[RDXY]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RDXY);
}
}
}
if (muonIt1->hwEta() != muonIt2->hwEta()) {
muonMismatch = true;
summary->Fill(ETABAD);
if (incBin[RETA]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RETA);
}
}
if (muonIt1->hwPhi() != muonIt2->hwPhi()) {
muonMismatch = true;
summary->Fill(PHIBAD);
if (incBin[RPHI]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RPHI);
}
}
if (muonIt1->hwEtaAtVtx() != muonIt2->hwEtaAtVtx()) {
muonMismatch = true;
summary->Fill(ETAATVTXBAD);
if (incBin[RETAATVTX]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RETAATVTX);
}
}
if (muonIt1->hwPhiAtVtx() != muonIt2->hwPhiAtVtx()) {
muonMismatch = true;
summary->Fill(PHIATVTXBAD);
if (incBin[RPHIATVTX]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RPHIATVTX);
}
}
if (muonIt1->hwCharge() != muonIt2->hwCharge()) {
muonMismatch = true;
summary->Fill(CHARGEBAD);
if (incBin[RCHARGE]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RCHARGE);
}
}
if (muonIt1->hwChargeValid() != muonIt2->hwChargeValid()) {
muonMismatch = true;
summary->Fill(CHARGEVALBAD);
if (incBin[RCHARGEVAL]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RCHARGEVAL);
}
}
if (muonIt1->hwQual() != muonIt2->hwQual()) {
muonMismatch = true;
summary->Fill(QUALBAD);
if (incBin[RQUAL]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RQUAL);
}
}
if (muonIt1->hwIso() != muonIt2->hwIso()) {
muonMismatch = true;
summary->Fill(ISOBAD);
if (incBin[RISO]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RISO);
}
}
if (muonIt1->tfMuonIndex() != muonIt2->tfMuonIndex()) {
muonMismatch = true;
summary->Fill(IDXBAD);
if (incBin[RIDX]) {
muonSelMismatch = true;
errorSummaryNum->Fill(RIDX);
}
}
if (incBin[RMUON] && muonSelMismatch) {
errorSummaryNum->Fill(RMUON);
}
if (muonMismatch) {
muColl1hwPt->Fill(muonIt1->hwPt());
if (displacedQuantities_) {
muColl1hwPtUnconstrained->Fill(muonIt1->hwPtUnconstrained());
muColl1hwDXY->Fill(muonIt1->hwDXY());
}
muColl1hwEta->Fill(muonIt1->hwEta());
muColl1hwPhi->Fill(muonIt1->hwPhi());
muColl1hwEtaAtVtx->Fill(muonIt1->hwEtaAtVtx());
muColl1hwPhiAtVtx->Fill(muonIt1->hwPhiAtVtx());
muColl1hwCharge->Fill(muonIt1->hwCharge());
muColl1hwChargeValid->Fill(muonIt1->hwChargeValid());
muColl1hwQual->Fill(muonIt1->hwQual());
muColl1hwIso->Fill(muonIt1->hwIso());
muColl1Index->Fill(muonIt1->tfMuonIndex());
if (enable2DComp)
muColl1EtaPhimap->Fill(muonIt1->eta(), muonIt1->phi());
muColl2hwPt->Fill(muonIt2->hwPt());
if (displacedQuantities_) {
muColl2hwPtUnconstrained->Fill(muonIt2->hwPtUnconstrained());
muColl2hwDXY->Fill(muonIt2->hwDXY());
}
muColl2hwEta->Fill(muonIt2->hwEta());
muColl2hwPhi->Fill(muonIt2->hwPhi());
muColl2hwEtaAtVtx->Fill(muonIt2->hwEtaAtVtx());
muColl2hwPhiAtVtx->Fill(muonIt2->hwPhiAtVtx());
muColl2hwCharge->Fill(muonIt2->hwCharge());
muColl2hwChargeValid->Fill(muonIt2->hwChargeValid());
muColl2hwQual->Fill(muonIt2->hwQual());
muColl2hwIso->Fill(muonIt2->hwIso());
muColl2Index->Fill(muonIt2->tfMuonIndex());
if (enable2DComp) {
muColl2EtaPhimap->Fill(muonIt2->eta(), muonIt2->phi());
}
} else {
summary->Fill(MUONGOOD);
}
++muonIt1;
++muonIt2;
}
}
}
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