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#include "Fireworks/Calo/plugins/FWL1THGCalProxyTemplate.cc"
#include "Fireworks/Core/interface/FWEventItem.h"
#include "Fireworks/Core/interface/FWGeometry.h"
#include "Fireworks/Core/interface/BuilderUtils.h"
#include "DataFormats/HcalDetId/interface/HcalDetId.h"
#include "DataFormats/ForwardDetId/interface/HGCalTriggerDetId.h"
#include "DataFormats/ForwardDetId/interface/HGCScintillatorDetId.h"
#include "DataFormats/L1THGCal/interface/HGCalTriggerCell.h"
// #include "L1Trigger/L1THGCal/plugins/geometries/HGCalTriggerGeometryV9Imp2.cc"
#include "TEveBoxSet.h"
class FWHGCalTriggerCellProxyBuilder : public FWL1THGCalProxyTemplate<l1t::HGCalTriggerCell> {
public:
FWHGCalTriggerCellProxyBuilder(void) {}
~FWHGCalTriggerCellProxyBuilder(void) override {}
REGISTER_PROXYBUILDER_METHODS();
FWHGCalTriggerCellProxyBuilder(const FWHGCalTriggerCellProxyBuilder &) = delete; // stop default
const FWHGCalTriggerCellProxyBuilder &operator=(const FWHGCalTriggerCellProxyBuilder &) = delete; // stop default
private:
void build(const l1t::HGCalTriggerCell &iData,
unsigned int iIndex,
TEveElement &oItemHolder,
const FWViewContext *) override;
};
void FWHGCalTriggerCellProxyBuilder::build(const l1t::HGCalTriggerCell &iData,
unsigned int iIndex,
TEveElement &oItemHolder,
const FWViewContext *) {
const long layer = item()->getConfig()->value<long>("Layer");
const double saturation_energy = item()->getConfig()->value<double>("EnergyCutOff");
const bool heatmap = item()->getConfig()->value<bool>("Heatmap");
const bool z_plus = item()->getConfig()->value<bool>("Z+");
const bool z_minus = item()->getConfig()->value<bool>("Z-");
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);
const float energy = fmin(10 * iData.energy() / saturation_energy, 1.0);
std::unordered_set<unsigned> cells = getCellsFromTriggerCell(iData.detId());
for (std::unordered_set<unsigned>::const_iterator it = cells.begin(), itEnd = cells.end(); it != itEnd; ++it) {
const bool z = (*it >> 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 *corners = item()->getGeom()->getCorners(*it);
const float *parameters = item()->getGeom()->getParameters(*it);
const float *shapes = item()->getGeom()->getShapePars(*it);
if (corners == nullptr || parameters == nullptr || shapes == nullptr) {
continue;
}
const int total_points = parameters[0];
const bool isScintillator = (total_points == 4);
const uint8_t type = ((*it >> 28) & 0xF);
uint8_t ll = layer;
if (layer > 0) {
if (layer > 28) {
if (type == 8) {
continue;
}
ll -= 28;
} else {
if (type != 8) {
continue;
}
}
if (ll != ((*it >> (isScintillator ? 17 : 20)) & 0x1F))
continue;
}
// 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]);
boxset->DigitColor(energy * 255, 0, 255 - energy * 255);
h_box = true;
}
// Silicon
else {
const 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, shapes[2], shapes[3]);
hex_boxset->DigitColor(energy * 255, 0, 255 - energy * 255);
h_hex = true;
}
}
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(FWHGCalTriggerCellProxyBuilder,
l1t::HGCalTriggerCell,
"HGCal Trigger Cell",
FWViewType::kAll3DBits);
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