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/*
* DDHGCalWaferF.cc
*
* Created on: 09-Jan-2021
*/
#include "DD4hep/DetFactoryHelper.h"
#include "DetectorDescription/DDCMS/interface/DDPlugins.h"
#include "DetectorDescription/DDCMS/interface/DDutils.h"
#include "FWCore/MessageLogger/interface/MessageLogger.h"
#include "FWCore/Utilities/interface/Exception.h"
#include "Geometry/HGCalCommonData/interface/HGCalTypes.h"
#include <string>
#include <vector>
#include <sstream>
//#define EDM_ML_DEBUG
static long algorithm(dd4hep::Detector& /* description */, cms::DDParsingContext& ctxt, xml_h e) {
cms::DDNamespace ns(ctxt, e, true);
cms::DDAlgoArguments args(ctxt, e);
std::string motherName = args.parentName();
const auto& material = args.value<std::string>("ModuleMaterial");
const auto& thick = args.value<double>("ModuleThickness");
const auto& waferSize = args.value<double>("WaferSize");
const auto& waferThick = args.value<double>("WaferThickness");
#ifdef EDM_ML_DEBUG
const auto& waferSepar = args.value<double>("SensorSeparation");
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferF: Module " << motherName << " made of " << material << " T "
<< cms::convert2mm(thick) << " Wafer 2r " << cms::convert2mm(waferSize)
<< " Half Separation " << cms::convert2mm(waferSepar) << " T "
<< cms::convert2mm(waferThick);
#endif
const auto& layerNames = args.value<std::vector<std::string>>("LayerNames");
const auto& materials = args.value<std::vector<std::string>>("LayerMaterials");
const auto& layerThick = args.value<std::vector<double>>("LayerThickness");
const auto& layerType = args.value<std::vector<int>>("LayerTypes");
std::vector<int> copyNumber(materials.size(), 1);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferF: " << layerNames.size() << " types of volumes";
for (unsigned int i = 0; i < layerNames.size(); ++i)
edm::LogVerbatim("HGCalGeom") << "Volume [" << i << "] " << layerNames[i] << " of thickness "
<< cms::convert2mm(layerThick[i]) << " filled with " << materials[i] << " type "
<< layerType[i];
#endif
const auto& layers = args.value<std::vector<int>>("Layers");
#ifdef EDM_ML_DEBUG
std::ostringstream st1;
for (unsigned int i = 0; i < layers.size(); ++i)
st1 << " [" << i << "] " << layers[i];
edm::LogVerbatim("HGCalGeom") << "There are " << layers.size() << " blocks" << st1.str();
#endif
const auto& nCells = args.value<int>("NCells");
const auto& cellTypeX = args.value<int>("CellType");
const auto& cellNames = args.value<std::vector<std::string>>("CellNames");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferF: Cells/Wafer " << nCells << " Cell Type " << cellTypeX
<< " NameSpace " << ns.name() << " # of cells " << cellNames.size();
for (unsigned int k = 0; k < cellNames.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferF: Cell[" << k << "] " << cellNames[k];
int counter(0);
#endif
static constexpr double tol = 0.00001 * dd4hep::mm;
static const double sqrt3 = std::sqrt(3.0);
double rM = 0.5 * waferSize;
double RM2 = rM / sqrt3;
double R = waferSize / (3.0 * nCells);
double r = 0.5 * R * sqrt3;
double r2 = 0.5 * waferSize;
double R2 = r2 / sqrt3;
// Mother Module
std::vector<double> xM = {rM, 0, -rM, -rM, 0, rM};
std::vector<double> yM = {RM2, 2 * RM2, RM2, -RM2, -2 * RM2, -RM2};
std::vector<double> zw = {-0.5 * thick, 0.5 * thick};
std::vector<double> zx(2, 0), zy(2, 0), scale(2, 1.0);
dd4hep::Material matter = ns.material(material);
dd4hep::Solid solid = dd4hep::ExtrudedPolygon(xM, yM, zw, zx, zy, scale);
ns.addSolidNS(ns.prepend(motherName), solid);
dd4hep::Volume glogM = dd4hep::Volume(solid.name(), solid, matter);
ns.addVolumeNS(glogM);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferF: " << solid.name() << " extruded polygon made of " << material
<< " z|x|y|s (0) " << cms::convert2mm(zw[0]) << ":" << cms::convert2mm(zx[0]) << ":"
<< cms::convert2mm(zy[0]) << ":" << scale[0] << " z|x|y|s (1) "
<< cms::convert2mm(zw[1]) << ":" << cms::convert2mm(zx[1]) << ":"
<< cms::convert2mm(zy[1]) << ":" << scale[1] << " and " << xM.size() << " edges";
for (unsigned int k = 0; k < xM.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << cms::convert2mm(xM[k]) << ":" << cms::convert2mm(yM[k]);
#endif
// Then the layers
dd4hep::Rotation3D rotation;
std::vector<double> xL = {r2, 0, -r2, -r2, 0, r2};
std::vector<double> yL = {R2, 2 * R2, R2, -R2, -2 * R2, -R2};
std::vector<dd4hep::Volume> glogs(materials.size());
double zi(-0.5 * thick), thickTot(0.0);
for (unsigned int l = 0; l < layers.size(); l++) {
unsigned int i = layers[l];
if (copyNumber[i] == 1) {
if (layerType[i] > 0) {
zw[0] = -0.5 * waferThick;
zw[1] = 0.5 * waferThick;
} else {
zw[0] = -0.5 * layerThick[i];
zw[1] = 0.5 * layerThick[i];
}
solid = dd4hep::ExtrudedPolygon(xL, yL, zw, zx, zy, scale);
ns.addSolidNS(ns.prepend(layerNames[i]), solid);
matter = ns.material(materials[i]);
glogs[i] = dd4hep::Volume(solid.name(), solid, matter);
ns.addVolumeNS(glogs[i]);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferF: " << solid.name() << " extruded polygon made of " << materials[i]
<< " z|x|y|s (0) " << cms::convert2mm(zw[0]) << ":" << cms::convert2mm(zx[0]) << ":"
<< cms::convert2mm(zy[0]) << ":" << scale[0] << " z|x|y|s (1) "
<< cms::convert2mm(zw[1]) << ":" << cms::convert2mm(zx[1]) << ":"
<< cms::convert2mm(zy[1]) << ":" << scale[1] << " and " << xM.size() << " edges";
for (unsigned int k = 0; k < xL.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << cms::convert2mm(xL[k]) << ":" << cms::convert2mm(yL[k]);
#endif
}
dd4hep::Position tran0(0, 0, (zi + 0.5 * layerThick[i]));
glogM.placeVolume(glogs[i], copyNumber[i], tran0);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferF: " << glogs[i].name() << " number " << copyNumber[i]
<< " positioned in " << glogM.name() << " at (0,0,"
<< cms::convert2mm(zi + 0.5 * layerThick[i]) << ") with no rotation";
#endif
++copyNumber[i];
zi += layerThick[i];
thickTot += layerThick[i];
if (layerType[i] > 0) {
int n2 = nCells / 2;
double y0 = (cellTypeX >= 3) ? 0.5 : 0.0;
double x0 = (cellTypeX >= 3) ? 0.5 : 1.0;
int voff = (cellTypeX >= 3) ? 0 : 1;
int uoff = 1 - voff;
int cellType = (cellTypeX >= 3) ? (cellTypeX - 3) : cellTypeX;
for (int u = 0; u < 2 * nCells; ++u) {
for (int v = 0; v < 2 * nCells; ++v) {
if (((v - u) < (nCells + uoff)) && (u - v) < (nCells + voff)) {
#ifdef EDM_ML_DEBUG
counter++;
#endif
double yp = (u - 0.5 * v - n2 + y0) * 2 * r;
double xp = (1.5 * (v - nCells) + x0) * R;
int cell(0);
if ((u == 0) && (v == 0))
cell = 7;
else if ((u == 0) && (v == nCells - 1))
cell = 8;
else if ((u == nCells) && (v == 2 * nCells - 1))
cell = 9;
else if ((u == 2 * nCells - 1) && (v == 2 * nCells - 1))
cell = 10;
else if ((u == 2 * nCells - 1) && (v == nCells - 1))
cell = 11;
else if ((u == nCells) && (v == 0))
cell = 12;
else if (u == 0)
cell = 1;
else if ((v - u) == (nCells - 1))
cell = 4;
else if (v == (2 * nCells - 1))
cell = 2;
else if (u == (2 * nCells - 1))
cell = 5;
else if ((u - v) == nCells)
cell = 3;
else if (v == 0)
cell = 6;
dd4hep::Position tran(xp, yp, 0);
int copy = HGCalTypes::packCellTypeUV(cellType, u, v);
glogs[i].placeVolume(ns.volume(cellNames[cell]), copy, dd4hep::Transform3D(rotation, tran));
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom")
<< "DDHGCalWaferF: " << cellNames[cell] << " number " << copy << " positioned in " << glogs[i].name()
<< " at (" << cms::convert2mm(xp) << "," << cms::convert2mm(yp) << ",0) with no rotation";
#endif
}
}
}
}
}
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "\nDDHGCalWaferF::Counter : " << counter << "\n===============================\n";
#endif
if (std::abs(thickTot - thick) >= tol) {
if (thickTot > thick) {
edm::LogError("HGCalGeom") << "Thickness of the partition " << thick << " is smaller than " << thickTot
<< ": thickness of all its components **** ERROR ****";
} else {
edm::LogWarning("HGCalGeom") << "Thickness of the partition " << thick << " does not match with " << thickTot
<< " of the components";
}
}
return cms::s_executed;
}
// first argument is the type from the xml file
DECLARE_DDCMS_DETELEMENT(DDCMS_hgcal_DDHGCalWaferF, algorithm)
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