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#include "DQM/HcalTasks/interface/ZDCTask.h"
#include <map>
using namespace hcaldqm;
using namespace hcaldqm::constants;
ZDCTask::ZDCTask(edm::ParameterSet const& ps) {
// tags
_tagQIE10 = ps.getUntrackedParameter<edm::InputTag>("tagQIE10", edm::InputTag("hcalDigis"));
_tokQIE10 = consumes<ZDCDigiCollection>(_tagQIE10);
// cuts
_cut = ps.getUntrackedParameter<double>("cut", 50.0);
_ped = ps.getUntrackedParameter<int>("ped", 4);
}
/* virtual */ void ZDCTask::bookHistograms(DQMStore::IBooker& ib, edm::Run const& r, edm::EventSetup const& es) {
//############################## hardcode manually the zdc mapping #############################
//############################# this follows from https://github.com/cms-sw/cmssw/blob/CMSSW_8_0_X/EventFilter/CastorRawToDigi/src/ZdcUnpacker.cc#L118
//##############################################################################################
//////ZDC MAP for NEW data (2015 PbPb are newer)
//PZDC
std::map<HcalElectronicsId, DetId> myEMap;
HcalElectronicsId eid = HcalElectronicsId(0, 1, 0, 3);
eid.setHTR(18, 8, 1);
myEMap[eid] = DetId(0x54000051); //PZDC EM1
eid = HcalElectronicsId(1, 1, 0, 3);
eid.setHTR(18, 8, 1);
myEMap[eid] = DetId(0x54000052); //PZDC EM2
eid = HcalElectronicsId(2, 1, 0, 3);
eid.setHTR(18, 8, 1);
myEMap[eid] = DetId(0x54000053); //PZDC EM3
eid = HcalElectronicsId(0, 2, 0, 3);
eid.setHTR(18, 8, 1);
myEMap[eid] = DetId(0x54000061); //PZDC HAD1
eid = HcalElectronicsId(1, 2, 0, 3);
eid.setHTR(18, 8, 1);
myEMap[eid] = DetId(0x54000054); //PZDC EM4
eid = HcalElectronicsId(2, 2, 0, 3);
eid.setHTR(18, 8, 1);
myEMap[eid] = DetId(0x54000055); //PZDC EM5
eid = HcalElectronicsId(0, 3, 0, 3);
eid.setHTR(18, 8, 1);
myEMap[eid] = DetId(0x54000062); //PZDC HAD2
eid = HcalElectronicsId(1, 3, 0, 3);
eid.setHTR(18, 8, 1);
myEMap[eid] = DetId(0x54000063); //PZDC HAD3
eid = HcalElectronicsId(2, 3, 0, 3);
eid.setHTR(18, 8, 1);
myEMap[eid] = DetId(0x54000064); //PZDC HAD4
//NZDC
eid = HcalElectronicsId(0, 1, 1, 3);
eid.setHTR(18, 8, 0);
myEMap[eid] = DetId(0x54000011); //NZDC EM1
eid = HcalElectronicsId(1, 1, 1, 3);
eid.setHTR(18, 8, 0);
myEMap[eid] = DetId(0x54000012); //NZDC EM2
eid = HcalElectronicsId(2, 1, 1, 3);
eid.setHTR(18, 8, 0);
myEMap[eid] = DetId(0x54000013); //NZDC EM3
eid = HcalElectronicsId(0, 2, 1, 3);
eid.setHTR(18, 8, 0);
myEMap[eid] = DetId(0x54000015); //NZDC EM5
eid = HcalElectronicsId(1, 2, 1, 3);
eid.setHTR(18, 8, 0);
myEMap[eid] = DetId(0x54000021); //NZDC HAD1
eid = HcalElectronicsId(2, 2, 1, 3);
eid.setHTR(18, 8, 0);
myEMap[eid] = DetId(0x54000014); //NZDC EM4
eid = HcalElectronicsId(0, 3, 1, 3);
eid.setHTR(18, 8, 0);
myEMap[eid] = DetId(0x54000022); //NZDC HAD2
eid = HcalElectronicsId(1, 3, 1, 3);
eid.setHTR(18, 8, 0);
myEMap[eid] = DetId(0x54000023); //NZDC HAD3
eid = HcalElectronicsId(2, 3, 1, 3);
eid.setHTR(18, 8, 0);
myEMap[eid] = DetId(0x54000024); //NZDC HAD4
//##################################### end hardcoding ###################################
ib.cd();
//quantities for axis
hcaldqm::quantity::ValueQuantity xAxisShape(hcaldqm::quantity::fTiming_TS);
hcaldqm::quantity::ValueQuantity yAxisShape(hcaldqm::quantity::ffC_10000);
hcaldqm::quantity::ValueQuantity xAxisADC(hcaldqm::quantity::fADC_128);
//book histos per channel
for (std::map<HcalElectronicsId, DetId>::const_iterator itr = myEMap.begin(); itr != myEMap.end(); ++itr) {
char histoname[300];
sprintf(histoname,
"%d_%d_%d_%d",
itr->first.fiberChanId(),
itr->first.fiberIndex(),
itr->first.spigot(),
itr->first.dccid());
ib.setCurrentFolder("Hcal/ZDCTask/Shape_perChannel");
_cShape_EChannel[histoname] = ib.bookProfile(histoname,
histoname,
xAxisShape.nbins(),
xAxisShape.min(),
xAxisShape.max(),
yAxisShape.nbins(),
yAxisShape.min(),
yAxisShape.max());
_cShape_EChannel[histoname]->setAxisTitle("Timing", 1);
_cShape_EChannel[histoname]->setAxisTitle("fC QIE8", 2);
ib.setCurrentFolder("Hcal/ZDCTask/ADC_perChannel");
_cADC_EChannel[histoname] = ib.book1DD(histoname, histoname, xAxisADC.nbins(), xAxisADC.min(), xAxisADC.max());
_cADC_EChannel[histoname]->getTH1()->SetBit(
BIT(hcaldqm::constants::BIT_OFFSET + hcaldqm::quantity::AxisType::fYAxis));
_cADC_EChannel[histoname]->setAxisTitle("ADC QIE8", 1);
ib.setCurrentFolder("Hcal/ZDCTask/ADC_vs_TS_perChannel");
_cADC_vs_TS_EChannel[histoname] = ib.book2D(histoname,
histoname,
xAxisShape.nbins(),
xAxisShape.min(),
xAxisShape.max(),
xAxisADC.nbins(),
xAxisADC.min(),
xAxisADC.max());
_cADC_vs_TS_EChannel[histoname]->getTH1()->SetBit(
BIT(hcaldqm::constants::BIT_OFFSET + hcaldqm::quantity::AxisType::fYAxis));
_cADC_vs_TS_EChannel[histoname]->setAxisTitle("Timing", 1);
_cADC_vs_TS_EChannel[histoname]->setAxisTitle("ADC QIE8", 2);
}
//book global histos
ib.setCurrentFolder("Hcal/ZDCTask");
_cShape = ib.bookProfile("Shape",
"Shape",
xAxisShape.nbins(),
xAxisShape.min(),
xAxisShape.max(),
yAxisShape.nbins(),
yAxisShape.min(),
yAxisShape.max());
_cShape->setAxisTitle("Timing", 1);
_cShape->setAxisTitle("fC QIE8", 2);
_cADC = ib.book1DD("ADC", "ADC", xAxisADC.nbins(), xAxisADC.min(), xAxisADC.max());
_cADC->getTH1()->SetBit(BIT(hcaldqm::constants::BIT_OFFSET + hcaldqm::quantity::AxisType::fYAxis));
_cADC->setAxisTitle("ADC QIE8", 1);
_cADC_vs_TS = ib.book2D("ADC_vs_TS",
"ADC_vs_TS",
xAxisShape.nbins(),
xAxisShape.min(),
xAxisShape.max(),
xAxisADC.nbins(),
xAxisADC.min(),
xAxisADC.max());
_cADC_vs_TS->getTH1()->SetBit(BIT(hcaldqm::constants::BIT_OFFSET + hcaldqm::quantity::AxisType::fYAxis));
_cADC_vs_TS->setAxisTitle("Timing", 1);
_cADC_vs_TS->setAxisTitle("ADC QIE8", 2);
}
/* virtual */ void ZDCTask::analyze(edm::Event const& e, edm::EventSetup const&) {
edm::Handle<ZDCDigiCollection> cqie10;
if (!e.getByToken(_tokQIE10, cqie10))
edm::LogError("Collection ZDCDigiCollection isn't available" + _tagQIE10.label() + " " + _tagQIE10.instance());
for (uint32_t i = 0; i < cqie10->size(); i++) {
ZDCDataFrame frame = static_cast<ZDCDataFrame>((*cqie10)[i]);
HcalElectronicsId eid = frame.elecId();
char histoname[300];
sprintf(histoname, "%d_%d_%d_%d", eid.fiberChanId(), eid.fiberIndex(), eid.spigot(), eid.dccid());
// compute the signal, ped subracted
//double q = hcaldqm::utilities::sumQ_v10<ZDCDataFrame>(frame, constants::adc2fC[_ped], 0, frame.size()-1);
// iterate thru all TS and fill
for (int j = 0; j < frame.size(); j++) {
_cShape_EChannel[histoname]->Fill(j, frame[j].nominal_fC());
_cShape->Fill(j, frame[j].nominal_fC());
_cADC_EChannel[histoname]->Fill(frame[j].adc());
_cADC->Fill(frame[j].adc());
_cADC_vs_TS_EChannel[histoname]->Fill(j, frame[j].adc());
_cADC_vs_TS->Fill(j, frame[j].adc());
}
}
}
DEFINE_FWK_MODULE(ZDCTask);
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