df/dcb/TrackingMaterialPlotter_8cc_source.html

 #include <iostream>

 #include <TROOT.h>
 #include <TObjArray.h>
 #include <TColor.h>
 #include <TStyle.h>
 #include <TCanvas.h>
 #include <TFrame.h>
 #include "XHistogram.h"
 #include "TrackingMaterialPlotter.h"

 #include "SimDataFormats/ValidationFormats/interface/MaterialAccountingStep.h"

 void TrackingMaterialPlotter::fill_color(void) {
   m_color.push_back(kBlack);        // unassigned
   m_color.push_back(kAzure);        // PixelBarrel
   m_color.push_back(kAzure + 1);    //
   m_color.push_back(kAzure + 1);    //
   m_color.push_back(kAzure + 3);    //
   m_color.push_back(kAzure + 3);    //
   m_color.push_back(kGreen);        // TIB
   m_color.push_back(kGreen);        //
   m_color.push_back(kGreen + 2);    //
   m_color.push_back(kGreen + 2);    //
   m_color.push_back(kGreen - 3);    //
   m_color.push_back(kGreen - 3);    //
   m_color.push_back(kGreen - 1);    //
   m_color.push_back(kGreen - 1);    //
   m_color.push_back(kRed);          // TOB
   m_color.push_back(kRed);          //
   m_color.push_back(kRed);          //
   m_color.push_back(kRed + 3);      //
   m_color.push_back(kRed + 3);      //
   m_color.push_back(kRed + 3);      //
   m_color.push_back(kRed - 3);      //
   m_color.push_back(kRed - 3);      //
   m_color.push_back(kRed - 3);      //
   m_color.push_back(kOrange + 9);   //
   m_color.push_back(kOrange + 9);   //
   m_color.push_back(kOrange + 9);   //
   m_color.push_back(kOrange + 7);   //
   m_color.push_back(kOrange + 7);   //
   m_color.push_back(kOrange + 7);   //
   m_color.push_back(kOrange + 5);   //
   m_color.push_back(kOrange + 5);   //
   m_color.push_back(kOrange + 5);   //
   m_color.push_back(kOrange + 8);   // PixelEndcap Z-
   m_color.push_back(kOrange + 10);  //
   m_color.push_back(kOrange - 3);   //
   m_color.push_back(kOrange - 1);   // PixelEndcap Z+
   m_color.push_back(kOrange - 8);   //
   m_color.push_back(kYellow);       // TID Z-
   m_color.push_back(kYellow);       //
   m_color.push_back(kYellow + 2);   //
   m_color.push_back(kYellow + 2);   //
   m_color.push_back(kYellow + 2);   //
   m_color.push_back(kYellow + 3);   //
   m_color.push_back(kMagenta);      //
   m_color.push_back(kMagenta);      //
   m_color.push_back(kMagenta);      //
   m_color.push_back(kMagenta);      //
   m_color.push_back(kMagenta);      //
   m_color.push_back(kMagenta + 1);  //
   m_color.push_back(kMagenta + 2);  //
   m_color.push_back(kMagenta + 3);  //
   m_color.push_back(kMagenta + 4);  //
   m_color.push_back(kMagenta + 5);  //
   m_color.push_back(kMagenta + 6);  //
   m_color.push_back(kMagenta + 7);  //
   m_color.push_back(kMagenta + 8);  //
 }

 unsigned int TrackingMaterialPlotter::fill_gradient(const TColor& first,
                                                     const TColor& last,
                                                     unsigned int steps /*= 100*/,
                                                     unsigned int index /* = 0*/) {
   if (index == 0) {
     // if no index was given, find the highest used one and start from that plus one
     index = ((TObjArray*)gROOT->GetListOfColors())->GetLast() + 1;
   }

   float r1, g1, b1, r2, g2, b2;
   first.GetRGB(r1, g1, b1);
   last.GetRGB(r2, g2, b2);
   float delta_r = (r2 - r1) / (steps - 1);
   float delta_g = (g2 - g1) / (steps - 1);
   float delta_b = (b2 - b1) / (steps - 1);

   m_gradient.resize(steps);
   for (unsigned int i = 0; i < steps; ++i) {
     new TColor(static_cast<Int_t>(index + i), r1 + delta_r * i, g1 + delta_g * i, b1 + delta_b * i);
     m_gradient[i] = index + i;
   }

   return index;
 }

 unsigned int TrackingMaterialPlotter::fill_gradient(unsigned int first,
                                                     unsigned int last,
                                                     unsigned int steps /*= 100*/,
                                                     unsigned int index /* = 0*/) {
   return fill_gradient(
       *(TColor*)gROOT->GetListOfColors()->At(first), *(TColor*)gROOT->GetListOfColors()->At(last), steps, index);
 }

 TrackingMaterialPlotter::TrackingMaterialPlotter(float maxZ, float maxR, float resolution) {
   const float rzMinZ = -maxZ;
   const float rzMaxZ = maxZ;
   const float rzMinR = 0.;
   const float rzMaxR = maxR;
   const int rzBinsZ = (int)(2. * maxZ * resolution);
   const int rzBinsR = (int)(maxR * resolution);

   std::vector<double> max;
   max.push_back(0.08);
   max.push_back(0.00016);
   m_tracker = XHistogram(
       2, rzBinsZ, rzBinsR, std::make_pair(rzMinZ, rzMaxZ), std::make_pair(rzMinR, rzMaxR), m_color.size(), max);

   TColor::InitializeColors();
   fill_color();
   fill_gradient(kWhite, kBlack, 100);  // 100-steps gradient from white to black
 }

 void TrackingMaterialPlotter::plotSegmentUnassigned(const MaterialAccountingStep& step) {
   std::vector<double> w(2);
   w[0] = step.radiationLengths();
   w[1] = step.energyLoss();
   m_tracker.fill(std::make_pair(step.in().z(), step.out().z()),
                  std::make_pair(step.in().perp(), step.out().perp()),
                  w,
                  step.length(),
                  1);  // 0 is empty, 1 is unassigned
 }

 void TrackingMaterialPlotter::plotSegmentInLayer(const MaterialAccountingStep& step, int layer) {
   std::vector<double> w(2);
   w[0] = step.radiationLengths();
   w[1] = step.energyLoss();
   m_tracker.fill(std::make_pair(step.in().z(), step.out().z()),
                  std::make_pair(step.in().perp(), step.out().perp()),
                  w,
                  step.length(),
                  layer + 1);  // layer is 1-based, but plot uses: 0 is empty, 1 is unassigned
 }

 void TrackingMaterialPlotter::draw(void) {
   const double scale = 10.;
   TCanvas* canvas;

   XHistogram::Histogram* radlen = m_tracker.get(0);
   canvas = new TCanvas("radlen_rz", "RadiationLengths - RZ view", (int)(600 * scale * 1.25), (int)(120 * scale * 1.50));
   gStyle->SetOptStat(0);
   gStyle->SetPalette(m_gradient.size(), &m_gradient.front());
   gStyle->SetNumberContours(m_gradient.size());
   canvas->GetFrame()->SetFillColor(kWhite);
   radlen->Draw("colz");
   radlen->Draw("same axis y+");
   radlen->SaveAs("radlen.root");
   canvas->SaveAs("radlen.png");
   // Replicate RainBow palette, with White in the first white_slots
   // positions
   int white_slots = 1;
   int MyPalette[100];
   double stops[9] = {0.0000, 0.1250, 0.2500, 0.3750, 0.5000, 0.6250, 0.7500, 0.8750, 1.0000};
   double red[9] = {
       0. / 255., 5. / 255., 15. / 255., 35. / 255., 102. / 255., 196. / 255., 208. / 255., 199. / 255., 110. / 255.};
   double green[9] = {
       0. / 255., 48. / 255., 124. / 255., 192. / 255., 206. / 255., 226. / 255., 97. / 255., 16. / 255., 0. / 255.};
   double blue[9] = {
       99. / 255., 142. / 255., 198. / 255., 201. / 255., 90. / 255., 22. / 255., 13. / 255., 8. / 255., 2. / 255.};
   int palette_index = TColor::CreateGradientColorTable(9, stops, red, green, blue, 100 - white_slots);
   for (int i = 0; i < white_slots; i++)
     MyPalette[i] = kWhite;
   for (int i = 0; i < 100 - white_slots; i++)
     MyPalette[i + white_slots] = palette_index + i;
   canvas->Clear();
   gStyle->SetNumberContours(100);
   gStyle->SetPalette(100, MyPalette);  // ROOT Rainbow color palette
   radlen->Draw("colz");
   radlen->Draw("same axis y+");
   canvas->SaveAs("radlenColor.png");

   delete canvas;

   XHistogram::Histogram* dedx = m_tracker.get(1);
   canvas = new TCanvas("dedx_rz", "-dE/dx term - RZ view", (int)(600 * scale * 1.25), (int)(120 * scale * 1.50));
   canvas->GetFrame()->SetFillColor(kWhite);
   gStyle->SetOptStat(0);
   gStyle->SetPalette(m_gradient.size(), &m_gradient.front());
   gStyle->SetNumberContours(m_gradient.size());
   dedx->Draw("colz");
   dedx->Draw("same axis y+");
   dedx->SaveAs("dedx.root");
   canvas->SaveAs("dedx.png");
   canvas->Clear();
   gStyle->SetNumberContours(100);
   gStyle->SetPalette(100, MyPalette);  // ROOT Rainbow color palette
   dedx->Draw("colz");
   dedx->Draw("same axis y+");
   canvas->SaveAs("dedxColor.png");
   delete canvas;

   XHistogram::ColorMap* colormap = m_tracker.colormap();
   canvas = new TCanvas("layer_rz", "Layers - RZ view", (int)(600 * scale * 1.25), (int)(120 * scale * 1.50));
   canvas->GetFrame()->SetFillColor(kWhite);
   gStyle->SetOptStat(0);
   gStyle->SetPalette(m_color.size(), &m_color.front());
   gStyle->SetNumberContours(m_color.size());
   colormap->SetMinimum(1);
   colormap->SetMaximum(m_color.size());
   colormap->Draw("col");
   colormap->Draw("same axis y+");
   colormap->SaveAs("layers.root");
   canvas->SaveAs("layers.png");
   delete canvas;
 }
customisers.steps
steps
Definition: customisers.py:48

TrackingMaterialPlotter::plotSegmentUnassigned
void plotSegmentUnassigned(const MaterialAccountingStep &step)
Definition: TrackingMaterialPlotter.cc:125

CosmicsPD_Skims.maxZ
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Definition: CosmicsPD_Skims.py:136

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Definition: L1TObjectsTimingClient_cff.py:52

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Definition: mps_fire.py:429

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Definition: l1tEGammaCrystalsEmulatorProducer_cfi.py:10

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Definition: diffTwoXMLs.py:52

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T w() const
Definition: extBasic3DVector.h:229

TrackingMaterialPlotter::fill_color
void fill_color()
Definition: TrackingMaterialPlotter.cc:14

XHistogram::Histogram
TH2F Histogram
Definition: XHistogram.h:16

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Definition: diffTwoXMLs.py:73

TrackingMaterialPlotter::m_color
std::vector< int > m_color
Definition: TrackingMaterialPlotter.h:31

TrackingMaterialPlotter.h

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list blue
Definition: DivergingColor.py:173

XHistogram.h

XHistogram::colormap
ColorMap * colormap(void) const
access the colormap
Definition: XHistogram.h:97

TrackingMaterialPlotter::m_tracker
XHistogram m_tracker
Definition: TrackingMaterialPlotter.h:29

TrackingMaterialPlotter::draw
void draw(void)
Definition: TrackingMaterialPlotter.cc:147

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Definition: createfilelist.py:10

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Definition: AlignmentPayloadInspectorHelper.h:93

TrackingMaterialPlotter::TrackingMaterialPlotter
TrackingMaterialPlotter(float maxZ, float maxR, float resolution)
Definition: TrackingMaterialPlotter.cc:106

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Definition: XHistogram.h:13

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double delta_r(const Fourvec &a, const Fourvec &b)
Find the distance between two four-vectors in the two-dimensional space .
Definition: fourvec.cc:238

TrackingMaterialPlotter::m_gradient
std::vector< int > m_gradient
Definition: TrackingMaterialPlotter.h:32

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Definition: SiStripPayloadInspectorHelper.h:178

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Definition: diffTwoXMLs.py:71

TrackingMaterialPlotter::fill_gradient
unsigned int fill_gradient(const TColor &first, const TColor &last, unsigned int steps=100, unsigned int index=0)
Definition: TrackingMaterialPlotter.cc:73

b2
bias2_t b2[25]
Definition: b2.h:9

MaterialAccountingStep.h

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Definition: nano_mu_digi_cff.py:28

MaterialAccountingStep
Definition: MaterialAccountingStep.h:9

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Definition: dqmdumpme.py:56

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Definition: XHistogram.h:15

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Definition: DivergingColor.py:172

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Definition: dqmdumpme.py:55

TrackingMaterialPlotter::plotSegmentInLayer
void plotSegmentInLayer(const MaterialAccountingStep &step, int layer)
Definition: TrackingMaterialPlotter.cc:136

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void fill(double x, double y, const std::vector< double > &weight, double norm)
fill one point
Definition: XHistogram.cc:70

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def canvas(sub, attr)
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access one of the histograms
Definition: XHistogram.h:86

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Definition: diffTwoXMLs.py:53