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#include "CondCore/Utilities/interface/PayloadInspectorModule.h"
#include "CondCore/Utilities/interface/PayloadInspector.h"
#include "CondCore/CondDB/interface/Time.h"
#include "DataFormats/EcalDetId/interface/EBDetId.h"
#include "DataFormats/EcalDetId/interface/EEDetId.h"
#include "CondCore/EcalPlugins/plugins/EcalDrawUtils.h"
#include "CondCore/EcalPlugins/plugins/EcalFloatCondObjectContainerUtils.h"
// the data format of the condition to be inspected
#include "CondFormats/EcalObjects/interface/EcalIntercalibConstantsMC.h"
#include "TH2F.h"
#include "TCanvas.h"
#include "TStyle.h"
#include "TLine.h"
#include "TLatex.h"
#include <memory>
#include <sstream>
#include <array>
namespace {
enum { kEBChannels = 61200, kEEChannels = 14648 };
enum {
MIN_IETA = 1,
MIN_IPHI = 1,
MAX_IETA = 85,
MAX_IPHI = 360,
EBhistEtaMax = 171
}; // barrel lower and upper bounds on eta and phi
enum {
IX_MIN = 1,
IY_MIN = 1,
IX_MAX = 100,
IY_MAX = 100,
EEhistXMax = 220
}; // endcaps lower and upper bounds on x and y
/*******************************************************
2d histogram of ECAL barrel Intercalib Constants MC of 1 IOV
*******************************************************/
// inherit from one of the predefined plot class: Histogram2D
class EcalIntercalibConstantsMCEBMap : public cond::payloadInspector::Histogram2D<EcalIntercalibConstantsMC> {
public:
EcalIntercalibConstantsMCEBMap()
: cond::payloadInspector::Histogram2D<EcalIntercalibConstantsMC>("ECAL Barrel Intercalib Constants MC- map ",
"iphi",
MAX_IPHI,
MIN_IPHI,
MAX_IPHI + 1,
"ieta",
EBhistEtaMax,
-MAX_IETA,
MAX_IETA + 1) {
Base::setSingleIov(true);
}
// Histogram2D::fill (virtual) needs be overridden - the implementation should use fillWithValue
bool fill() override {
auto tag = PlotBase::getTag<0>();
for (auto const& iov : tag.iovs) {
std::shared_ptr<EcalIntercalibConstantsMC> payload = Base::fetchPayload(std::get<1>(iov));
if (payload.get()) {
// looping over the EB channels, via the dense-index, mapped into EBDetId's
if (payload->barrelItems().empty())
return false;
// set to 1 for ieta 0 (no crystal)
for (int iphi = MIN_IPHI; iphi < MAX_IPHI + 1; iphi++)
fillWithValue(iphi, 0, 1);
for (int cellid = EBDetId::MIN_HASH; cellid < EBDetId::kSizeForDenseIndexing; ++cellid) {
uint32_t rawid = EBDetId::unhashIndex(cellid);
// check the existence of ECAL Intercalib Constants, for a given ECAL barrel channel
EcalFloatCondObjectContainer::const_iterator value_ptr = payload->find(rawid);
if (value_ptr == payload->end())
continue; // cell absent from payload
float weight = (float)(*value_ptr);
// fill the Histogram2D here
fillWithValue((EBDetId(rawid)).iphi(), (EBDetId(rawid)).ieta(), weight);
} // loop over cellid
} // if payload.get()
} // loop over IOV's (1 in this case)
return true;
} //fill method
};
/*******************************************************
2d histogram of ECAL EndCaps Intercalib Constants MC of 1 IOV
*******************************************************/
class EcalIntercalibConstantsMCEEMap : public cond::payloadInspector::Histogram2D<EcalIntercalibConstantsMC> {
private:
int EEhistSplit = 20;
public:
EcalIntercalibConstantsMCEEMap()
: cond::payloadInspector::Histogram2D<EcalIntercalibConstantsMC>("ECAL Endcap Intercalib Constants MC- map ",
"ix",
EEhistXMax,
IX_MIN,
EEhistXMax + 1,
"iy",
IY_MAX,
IY_MIN,
IY_MAX + 1) {
Base::setSingleIov(true);
}
bool fill() override {
auto tag = PlotBase::getTag<0>();
for (auto const& iov : tag.iovs) {
std::shared_ptr<EcalIntercalibConstantsMC> payload = Base::fetchPayload(std::get<1>(iov));
if (payload.get()) {
if (payload->endcapItems().empty())
return false;
// set to 0 everywhwere
for (int ix = IX_MIN; ix < EEhistXMax + 1; ix++)
for (int iy = IY_MIN; iy < IY_MAX + 1; iy++)
fillWithValue(ix, iy, 0);
for (int cellid = 0; cellid < EEDetId::kSizeForDenseIndexing; ++cellid) { // loop on EE cells
if (EEDetId::validHashIndex(cellid)) {
uint32_t rawid = EEDetId::unhashIndex(cellid);
EcalFloatCondObjectContainer::const_iterator value_ptr = payload->find(rawid);
if (value_ptr == payload->end())
continue; // cell absent from payload
float weight = (float)(*value_ptr);
EEDetId myEEId(rawid);
if (myEEId.zside() == -1)
fillWithValue(myEEId.ix(), myEEId.iy(), weight);
else
fillWithValue(myEEId.ix() + IX_MAX + EEhistSplit, myEEId.iy(), weight);
} // validDetId
} // loop over cellid
} // payload
} // loop over IOV's (1 in this case)
return true;
} // fill method
};
/*************************************************
2d plot of ECAL IntercalibConstantsMC of 1 IOV
*************************************************/
class EcalIntercalibConstantsMCPlot : public cond::payloadInspector::PlotImage<EcalIntercalibConstantsMC> {
public:
EcalIntercalibConstantsMCPlot()
: cond::payloadInspector::PlotImage<EcalIntercalibConstantsMC>("ECAL Intercalib Constants MC - map ") {
setSingleIov(true);
}
bool fill(const std::vector<std::tuple<cond::Time_t, cond::Hash> >& iovs) override {
TH2F* barrel = new TH2F("EB", "mean EB", MAX_IPHI, 0, MAX_IPHI, 2 * MAX_IETA, -MAX_IETA, MAX_IETA);
TH2F* endc_p = new TH2F("EE+", "mean EE+", IX_MAX, IX_MIN, IX_MAX + 1, IY_MAX, IY_MIN, IY_MAX + 1);
TH2F* endc_m = new TH2F("EE-", "mean EE-", IX_MAX, IX_MIN, IX_MAX + 1, IY_MAX, IY_MIN, IY_MAX + 1);
auto iov = iovs.front();
std::shared_ptr<EcalIntercalibConstantsMC> payload = fetchPayload(std::get<1>(iov));
unsigned int run = std::get<0>(iov);
if (payload.get()) {
if (payload->barrelItems().empty())
return false;
fillEBMap_SingleIOV<EcalIntercalibConstantsMC>(payload, barrel);
if (payload->endcapItems().empty())
return false;
fillEEMap_SingleIOV<EcalIntercalibConstantsMC>(payload, endc_m, endc_p);
} // payload
gStyle->SetPalette(1);
gStyle->SetOptStat(0);
TCanvas canvas("CC map", "CC map", 1600, 450);
TLatex t1;
t1.SetNDC();
t1.SetTextAlign(26);
t1.SetTextSize(0.04);
t1.DrawLatex(0.5, 0.96, Form("Ecal IntercalibConstants MC, IOV %i", run));
float xmi[3] = {0.0, 0.24, 0.76};
float xma[3] = {0.24, 0.76, 1.00};
std::array<std::unique_ptr<TPad>, 3> pad;
for (int obj = 0; obj < 3; obj++) {
pad[obj] = std::make_unique<TPad>(Form("p_%i", obj), Form("p_%i", obj), xmi[obj], 0.0, xma[obj], 0.94);
pad[obj]->Draw();
}
// EcalDrawMaps ICMap;
pad[0]->cd();
// ICMap.DrawEE(endc_m, 0., 2.);
DrawEE(endc_m, 0., 2.5);
pad[1]->cd();
// ICMap.DrawEB(barrel, 0., 2.);
DrawEB(barrel, 0., 2.5);
pad[2]->cd();
// ICMap.DrawEE(endc_p, 0., 2.);
DrawEE(endc_p, 0., 2.5);
std::string ImageName(m_imageFileName);
canvas.SaveAs(ImageName.c_str());
return true;
} // fill method
};
/*******************************************************************
2d plot of ECAL IntercalibConstantsMC difference between 2 IOVs
*******************************************************************/
template <cond::payloadInspector::IOVMultiplicity nIOVs, int ntags, int method>
class EcalIntercalibConstantsMCBase
: public cond::payloadInspector::PlotImage<EcalIntercalibConstantsMC, nIOVs, ntags> {
public:
EcalIntercalibConstantsMCBase()
: cond::payloadInspector::PlotImage<EcalIntercalibConstantsMC, nIOVs, ntags>(
"ECAL Intercalib Constants MC comparison") {}
bool fill() override {
TH2F* barrel = new TH2F("EB", "mean EB", MAX_IPHI, 0, MAX_IPHI, 2 * MAX_IETA, -MAX_IETA, MAX_IETA);
TH2F* endc_p = new TH2F("EE+", "mean EE+", IX_MAX, IX_MIN, IX_MAX + 1, IY_MAX, IY_MIN, IY_MAX + 1);
TH2F* endc_m = new TH2F("EE-", "mean EE-", IX_MAX, IX_MIN, IX_MAX + 1, IY_MAX, IY_MIN, IY_MAX + 1);
float pEBmin, pEEmin, pEBmax, pEEmax;
pEBmin = 10.;
pEEmin = 10.;
pEBmax = -10.;
pEEmax = -10.;
unsigned int run[2];
float pEB[kEBChannels], pEE[kEEChannels];
std::string l_tagname[2];
auto iovs = cond::payloadInspector::PlotBase::getTag<0>().iovs;
l_tagname[0] = cond::payloadInspector::PlotBase::getTag<0>().name;
auto firstiov = iovs.front();
run[0] = std::get<0>(firstiov);
std::tuple<cond::Time_t, cond::Hash> lastiov;
if (ntags == 2) {
auto tag2iovs = cond::payloadInspector::PlotBase::getTag<1>().iovs;
l_tagname[1] = cond::payloadInspector::PlotBase::getTag<1>().name;
lastiov = tag2iovs.front();
} else {
lastiov = iovs.back();
l_tagname[1] = l_tagname[0];
}
run[1] = std::get<0>(lastiov);
for (int irun = 0; irun < nIOVs; irun++) {
std::shared_ptr<EcalIntercalibConstantsMC> payload;
if (irun == 0) {
payload = this->fetchPayload(std::get<1>(firstiov));
} else {
payload = this->fetchPayload(std::get<1>(lastiov));
}
if (payload.get()) {
if (payload->barrelItems().empty())
return false;
fillEBMap_TwoIOVs<EcalIntercalibConstantsMC>(payload, barrel, irun, pEB, pEBmin, pEBmax, method);
if (payload->endcapItems().empty())
return false;
fillEEMap_TwoIOVs<EcalIntercalibConstantsMC>(payload, endc_m, endc_p, irun, pEE, pEEmin, pEEmax, method);
} // payload
} // loop over IOVs
gStyle->SetPalette(1);
gStyle->SetOptStat(0);
TCanvas canvas("CC map", "CC map", 1600, 450);
TLatex t1;
t1.SetNDC();
t1.SetTextAlign(26);
int len = l_tagname[0].length() + l_tagname[1].length();
std::string dr[2] = {"-", "/"};
if (ntags == 2) {
if (len < 170) {
t1.SetTextSize(0.05);
t1.DrawLatex(0.5,
0.96,
Form("%s IOV %i %s %s IOV %i",
l_tagname[1].c_str(),
run[1],
dr[method].c_str(),
l_tagname[0].c_str(),
run[0]));
} else {
t1.SetTextSize(0.05);
t1.DrawLatex(0.5, 0.96, Form("Ecal IntercalibConstantsMC, IOV %i %s %i", run[1], dr[method].c_str(), run[0]));
}
} else {
t1.SetTextSize(0.05);
t1.DrawLatex(0.5, 0.96, Form("%s, IOV %i %s %i", l_tagname[0].c_str(), run[1], dr[method].c_str(), run[0]));
}
float xmi[3] = {0.0, 0.24, 0.76};
float xma[3] = {0.24, 0.76, 1.00};
std::array<std::unique_ptr<TPad>, 3> pad;
for (int obj = 0; obj < 3; obj++) {
pad[obj] = std::make_unique<TPad>(Form("p_%i", obj), Form("p_%i", obj), xmi[obj], 0.0, xma[obj], 0.94);
pad[obj]->Draw();
}
pad[0]->cd();
DrawEE(endc_m, pEEmin, pEEmax);
pad[1]->cd();
DrawEB(barrel, pEBmin, pEBmax);
pad[2]->cd();
DrawEE(endc_p, pEEmin, pEEmax);
std::string ImageName(this->m_imageFileName);
canvas.SaveAs(ImageName.c_str());
return true;
} // fill method
}; // class EcalIntercalibConstantsMCDiffBase
using EcalIntercalibConstantsMCDiffOneTag = EcalIntercalibConstantsMCBase<cond::payloadInspector::SINGLE_IOV, 1, 0>;
using EcalIntercalibConstantsMCDiffTwoTags = EcalIntercalibConstantsMCBase<cond::payloadInspector::SINGLE_IOV, 2, 0>;
using EcalIntercalibConstantsMCRatioOneTag = EcalIntercalibConstantsMCBase<cond::payloadInspector::SINGLE_IOV, 1, 1>;
using EcalIntercalibConstantsMCRatioTwoTags = EcalIntercalibConstantsMCBase<cond::payloadInspector::SINGLE_IOV, 2, 1>;
/***********************************************************
2d plot of Ecal Intercalib Constants MC Summary of 1 IOV
***********************************************************/
class EcalIntercalibConstantsMCSummaryPlot : public cond::payloadInspector::PlotImage<EcalIntercalibConstantsMC> {
public:
EcalIntercalibConstantsMCSummaryPlot()
: cond::payloadInspector::PlotImage<EcalIntercalibConstantsMC>("Ecal Intercalib Constants MC Summary - map ") {
setSingleIov(true);
}
bool fill(const std::vector<std::tuple<cond::Time_t, cond::Hash> >& iovs) override {
auto iov = iovs.front();
std::shared_ptr<EcalIntercalibConstantsMC> payload = fetchPayload(std::get<1>(iov));
unsigned int run = std::get<0>(iov);
TH2F* align;
int NbRows;
if (payload.get()) {
NbRows = 2;
align = new TH2F("", "", 0, 0, 0, 0, 0, 0);
float mean_x_EB = 0.0f;
float mean_x_EE = 0.0f;
float rms_EB = 0.0f;
float rms_EE = 0.0f;
int num_x_EB = 0;
int num_x_EE = 0;
payload->summary(mean_x_EB, rms_EB, num_x_EB, mean_x_EE, rms_EE, num_x_EE);
fillTableWithSummary(
align, "Ecal Intercalib Constants MC", mean_x_EB, rms_EB, num_x_EB, mean_x_EE, rms_EE, num_x_EE);
} else
return false;
gStyle->SetPalette(1);
gStyle->SetOptStat(0);
TCanvas canvas("CC map", "CC map", 1000, 1000);
TLatex t1;
t1.SetNDC();
t1.SetTextAlign(26);
t1.SetTextSize(0.04);
t1.SetTextColor(2);
t1.DrawLatex(0.5, 0.96, Form("Ecal Intercalib Constants MC Summary, IOV %i", run));
TPad pad("pad", "pad", 0.0, 0.0, 1.0, 0.94);
pad.Draw();
pad.cd();
align->Draw("TEXT");
drawTable(NbRows, 4);
std::string ImageName(m_imageFileName);
canvas.SaveAs(ImageName.c_str());
return true;
}
};
} // namespace
// Register the classes as boost python plugin
PAYLOAD_INSPECTOR_MODULE(EcalIntercalibConstantsMC) {
PAYLOAD_INSPECTOR_CLASS(EcalIntercalibConstantsMCEBMap);
PAYLOAD_INSPECTOR_CLASS(EcalIntercalibConstantsMCEEMap);
PAYLOAD_INSPECTOR_CLASS(EcalIntercalibConstantsMCPlot);
PAYLOAD_INSPECTOR_CLASS(EcalIntercalibConstantsMCDiffOneTag);
PAYLOAD_INSPECTOR_CLASS(EcalIntercalibConstantsMCDiffTwoTags);
PAYLOAD_INSPECTOR_CLASS(EcalIntercalibConstantsMCRatioOneTag);
PAYLOAD_INSPECTOR_CLASS(EcalIntercalibConstantsMCRatioTwoTags);
PAYLOAD_INSPECTOR_CLASS(EcalIntercalibConstantsMCSummaryPlot);
}
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