FWCaloClusterProxyBuilder.cc

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#include "Fireworks/Calo/interface/FWHeatmapProxyBuilderTemplate.h"
#include "Fireworks/Core/interface/FWEventItem.h"
#include "Fireworks/Core/interface/FWGeometry.h"
#include "Fireworks/Core/interface/BuilderUtils.h"
#include "DataFormats/CaloRecHit/interface/CaloClusterFwd.h"
#include "DataFormats/Common/interface/ValueMap.h"

#include "TEveBoxSet.h"
#include "TEveStraightLineSet.h"

class FWCaloClusterProxyBuilder : public FWHeatmapProxyBuilderTemplate<reco::CaloCluster> {
public:
  FWCaloClusterProxyBuilder(void) {}
  ~FWCaloClusterProxyBuilder(void) override {}

  REGISTER_PROXYBUILDER_METHODS();

  FWCaloClusterProxyBuilder(const FWCaloClusterProxyBuilder &) = delete;                   // stop default
  const FWCaloClusterProxyBuilder &operator=(const FWCaloClusterProxyBuilder &) = delete;  // stop default

private:
  edm::Handle<edm::ValueMap<std::pair<float, float>>> TimeValueMapHandle;
  double timeLowerBound, timeUpperBound;
  long layer;
  double saturation_energy;
  bool heatmap;
  bool z_plus;
  bool z_minus;
  bool enableTimeFilter;

  void setItem(const FWEventItem *iItem) override;

  void build(const FWEventItem *iItem, TEveElementList *product, const FWViewContext *vc) override;
  void build(const reco::CaloCluster &iData,
             unsigned int iIndex,
             TEveElement &oItemHolder,
             const FWViewContext *) override;
};

void FWCaloClusterProxyBuilder::setItem(const FWEventItem *iItem) {
  FWHeatmapProxyBuilderTemplate::setItem(iItem);
  if (iItem) {
    iItem->getConfig()->assertParam("Cluster(0)/RecHit(1)", false);
    iItem->getConfig()->assertParam("EnableTimeFilter", false);
    iItem->getConfig()->assertParam("TimeLowerBound(ns)", 0.01, 0.0, 75.0);
    iItem->getConfig()->assertParam("TimeUpperBound(ns)", 0.01, 0.0, 75.0);
  }
}

void FWCaloClusterProxyBuilder::build(const FWEventItem *iItem, TEveElementList *product, const FWViewContext *vc) {
  iItem->getEvent()->getByLabel(edm::InputTag("hgcalLayerClusters", "timeLayerCluster"), TimeValueMapHandle);
  if (TimeValueMapHandle.isValid()) {
    timeLowerBound = std::min(item()->getConfig()->value<double>("TimeLowerBound(ns)"),
                              item()->getConfig()->value<double>("TimeUpperBound(ns)"));
    timeUpperBound = std::max(item()->getConfig()->value<double>("TimeLowerBound(ns)"),
                              item()->getConfig()->value<double>("TimeUpperBound(ns)"));
  } else {
    std::cerr << "Warning: couldn't locate 'timeLayerCluster' ValueMap in root file." << std::endl;
  }

  layer = item()->getConfig()->value<long>("Layer");
  saturation_energy = item()->getConfig()->value<double>("EnergyCutOff");
  heatmap = item()->getConfig()->value<bool>("Heatmap");
  z_plus = item()->getConfig()->value<bool>("Z+");
  z_minus = item()->getConfig()->value<bool>("Z-");
  enableTimeFilter = item()->getConfig()->value<bool>("EnableTimeFilter");

  FWHeatmapProxyBuilderTemplate::build(iItem, product, vc);
}

void FWCaloClusterProxyBuilder::build(const reco::CaloCluster &iData,
                                      unsigned int iIndex,
                                      TEveElement &oItemHolder,
                                      const FWViewContext *) {
  if (enableTimeFilter && TimeValueMapHandle.isValid()) {
    const float time = TimeValueMapHandle->get(iIndex).first;
    if (time < timeLowerBound || time > timeUpperBound)
      return;
  }

  std::vector<std::pair<DetId, float>> clusterDetIds = iData.hitsAndFractions();

  bool h_hex(false);
  TEveBoxSet *hex_boxset = new TEveBoxSet();
  if (!heatmap)
    hex_boxset->UseSingleColor();
  hex_boxset->SetPickable(true);
  hex_boxset->Reset(TEveBoxSet::kBT_Hex, true, 64);
  hex_boxset->SetAntiFlick(true);

  bool h_box(false);
  TEveBoxSet *boxset = new TEveBoxSet();
  if (!heatmap)
    boxset->UseSingleColor();
  boxset->SetPickable(true);
  boxset->Reset(TEveBoxSet::kBT_FreeBox, true, 64);
  boxset->SetAntiFlick(true);

  for (std::vector<std::pair<DetId, float>>::iterator it = clusterDetIds.begin(), itEnd = clusterDetIds.end();
       it != itEnd;
       ++it) {
    const uint8_t type = ((it->first >> 28) & 0xF);

    const float *corners = item()->getGeom()->getCorners(it->first);
    if (corners == nullptr)
      continue;

    // HGCal
    if (iData.algo() == 8 || (type >= 8 && type <= 10)) {
      if (heatmap && hitmap->find(it->first) == hitmap->end())
        continue;

      const bool z = (it->first >> 25) & 0x1;

      // discard everything thats not at the side that we are intersted in
      if (((z_plus & z_minus) != 1) && (((z_plus | z_minus) == 0) || !(z == z_minus || z == !z_plus)))
        continue;

      const float *parameters = item()->getGeom()->getParameters(it->first);
      const float *shapes = item()->getGeom()->getShapePars(it->first);

      if (parameters == nullptr || shapes == nullptr)
        continue;

      const int total_points = parameters[0];
      const bool isScintillator = (total_points == 4);

      uint8_t ll = layer;
      if (layer > 0) {
        if (layer > 28) {
          if (type == 8) {
            continue;
          }
          ll -= 28;
        } else {
          if (type != 8) {
            continue;
          }
        }

        if (ll != ((it->first >> (isScintillator ? 17 : 20)) & 0x1F))
          continue;
      }

      // seed and cluster position
      if (iData.seed().rawId() == it->first.rawId()) {
        TEveStraightLineSet *marker = new TEveStraightLineSet;
        marker->SetLineWidth(1);

        // center of RecHit
        const float center[3] = {corners[total_points * 3 + 0],
                                 corners[total_points * 3 + 1],
                                 corners[total_points * 3 + 2] + shapes[3] * 0.5f};

        // draw 3D cross
        const float crossScale = 1.0f + fmin(iData.energy(), 5.0f);
        marker->AddLine(center[0] - crossScale, center[1], center[2], center[0] + crossScale, center[1], center[2]);
        marker->AddLine(center[0], center[1] - crossScale, center[2], center[0], center[1] + crossScale, center[2]);
        marker->AddLine(center[0], center[1], center[2] - crossScale, center[0], center[1], center[2] + crossScale);

        oItemHolder.AddElement(marker);

        TEveStraightLineSet *position_marker = new TEveStraightLineSet;
        position_marker->SetLineWidth(2);
        position_marker->SetLineColor(kOrange);
        auto const &pos = iData.position();
        const float position_crossScale = crossScale * 0.5;
        position_marker->AddLine(
            pos.x() - position_crossScale, pos.y(), pos.z(), pos.x() + position_crossScale, pos.y(), pos.z());
        position_marker->AddLine(
            pos.x(), pos.y() - position_crossScale, pos.z(), pos.x(), pos.y() + position_crossScale, pos.z());

        oItemHolder.AddElement(position_marker);
      }

      const float energy =
          fmin((item()->getConfig()->value<bool>("Cluster(0)/RecHit(1)") ? hitmap->at(it->first)->energy()
                                                                         : iData.energy()) /
                   saturation_energy,
               1.0f);
      const uint8_t colorFactor = gradient_steps * energy;

      // Scintillator
      if (isScintillator) {
        const int total_vertices = 3 * total_points;

        std::vector<float> pnts(24);
        for (int i = 0; i < total_points; ++i) {
          pnts[i * 3 + 0] = corners[i * 3];
          pnts[i * 3 + 1] = corners[i * 3 + 1];
          pnts[i * 3 + 2] = corners[i * 3 + 2];

          pnts[(i * 3 + 0) + total_vertices] = corners[i * 3];
          pnts[(i * 3 + 1) + total_vertices] = corners[i * 3 + 1];
          pnts[(i * 3 + 2) + total_vertices] = corners[i * 3 + 2] + shapes[3];
        }
        boxset->AddBox(&pnts[0]);
        if (heatmap) {
          energy ? boxset->DigitColor(gradient[0][colorFactor], gradient[1][colorFactor], gradient[2][colorFactor])
                 : boxset->DigitColor(64, 64, 64);
        }

        h_box = true;
      }
      // Silicon
      else {
        constexpr int offset = 9;

        float centerX = (corners[6] + corners[6 + offset]) / 2;
        float centerY = (corners[7] + corners[7 + offset]) / 2;
        float radius = fabs(corners[6] - corners[6 + offset]) / 2;
        hex_boxset->AddHex(TEveVector(centerX, centerY, corners[2]), radius, 90.0, shapes[3]);
        if (heatmap) {
          energy ? hex_boxset->DigitColor(gradient[0][colorFactor], gradient[1][colorFactor], gradient[2][colorFactor])
                 : hex_boxset->DigitColor(64, 64, 64);
        }

        h_hex = true;
      }
    }
    // Not HGCal
    else {
      h_box = true;

      std::vector<float> pnts(24);
      fireworks::energyTower3DCorners(corners, (*it).second, pnts);
      boxset->AddBox(&pnts[0]);
    }
  }

  if (h_hex) {
    hex_boxset->RefitPlex();

    hex_boxset->CSCTakeAnyParentAsMaster();
    if (!heatmap) {
      hex_boxset->CSCApplyMainColorToMatchingChildren();
      hex_boxset->CSCApplyMainTransparencyToMatchingChildren();
      hex_boxset->SetMainColor(item()->modelInfo(iIndex).displayProperties().color());
      hex_boxset->SetMainTransparency(item()->defaultDisplayProperties().transparency());
    }
    oItemHolder.AddElement(hex_boxset);
  }

  if (h_box) {
    boxset->RefitPlex();

    boxset->CSCTakeAnyParentAsMaster();
    if (!heatmap) {
      boxset->CSCApplyMainColorToMatchingChildren();
      boxset->CSCApplyMainTransparencyToMatchingChildren();
      boxset->SetMainColor(item()->modelInfo(iIndex).displayProperties().color());
      boxset->SetMainTransparency(item()->defaultDisplayProperties().transparency());
    }
    oItemHolder.AddElement(boxset);
  }
}

REGISTER_FWPROXYBUILDER(FWCaloClusterProxyBuilder, reco::CaloCluster, "Calo Cluster", FWViewType::kISpyBit);