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/*
* DDHGCalWaferP.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 "Geometry/HGCalCommonData/interface/HGCalWaferMask.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 parentName = 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") << "DDHGCalWaferP: Module " << parentName << " made of " << material << " T "
<< cms::convert2mm(thick) << " Wafer 2r " << cms::convert2mm(waferSize)
<< " Half Separation " << cms::convert2mm(waferSepar) << " T "
<< cms::convert2mm(waferThick);
#endif
const auto& tags = args.value<std::vector<std::string>>("Tags");
const auto& partialTypes = args.value<std::vector<int>>("PartialTypes");
const auto& orientations = args.value<std::vector<int>>("Orientations");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferP: " << tags.size() << " variations of wafer types";
for (unsigned int k = 0; k < tags.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "Type[" << k << "] " << tags[k] << " Partial " << partialTypes[k]
<< " Orientation " << orientations[k];
#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");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferP: " << 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& senseName = args.value<std::string>("SenseName");
const auto& senseT = args.value<double>("SenseThick");
const auto& senseType = args.value<int>("SenseType");
const auto& posSense = args.value<int>("PosSensitive");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferP: NameSpace " << ns.name() << " Sensitive Layer Name " << senseName
<< " Thickness " << senseT << " Type " << senseType << " Position " << posSense;
#endif
static constexpr double tol = 0.00001 * dd4hep::mm;
// Loop over all types
for (unsigned int k = 0; k < tags.size(); ++k) {
// First the mother
std::string mother = parentName + tags[k];
std::vector<std::pair<double, double>> wxy =
HGCalWaferMask::waferXY(partialTypes[k], orientations[k], 1, waferSize, 0.0, 0.0, 0.0, true);
std::vector<double> xM, yM;
for (unsigned int i = 0; i < (wxy.size() - 1); ++i) {
xM.emplace_back(wxy[i].first);
yM.emplace_back(wxy[i].second);
}
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(mother), solid);
dd4hep::Volume glogM = dd4hep::Volume(solid.name(), solid, matter);
ns.addVolumeNS(glogM);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferP: " << 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] << " partial " << partialTypes[k]
<< " orientation " << orientations[k] << " and " << xM.size() << " edges";
for (unsigned int j = 0; j < xM.size(); ++j)
edm::LogVerbatim("HGCalGeom") << "[" << j << "] " << cms::convert2mm(xM[j]) << ":" << cms::convert2mm(yM[j]);
#endif
// Then the layers
dd4hep::Rotation3D rotation;
wxy = HGCalWaferMask::waferXY(partialTypes[k], orientations[k], 1, waferSize, 0.0, 0.0, 0.0, true);
std::vector<double> xL, yL;
for (unsigned int i = 0; i < (wxy.size() - 1); ++i) {
xL.emplace_back(wxy[i].first);
yL.emplace_back(wxy[i].second);
}
std::vector<dd4hep::Volume> glogs(materials.size());
std::vector<int> copyNumber(materials.size(), 1);
double zi(-0.5 * thick), thickTot(0.0);
for (unsigned int l = 0; l < layers.size(); l++) {
unsigned int i = layers[l];
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferP:Layer " << l << ":" << i << " T " << layerThick[i] << " Copy "
<< copyNumber[i];
#endif
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);
std::string lname = layerNames[i] + tags[k];
ns.addSolidNS(ns.prepend(lname), 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") << "DDHGCalWaferP: " << 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] << " partial "
<< partialTypes[k] << " orientation " << orientations[k] << " and " << xM.size()
<< " edges";
for (unsigned int j = 0; j < xL.size(); ++j)
edm::LogVerbatim("HGCalGeom") << "[" << j << "] " << cms::convert2mm(xL[j]) << ":" << cms::convert2mm(yL[j]);
#endif
}
if (layerType[i] > 0) {
std::string sname = senseName + tags[k];
zw[0] = -0.5 * senseT;
zw[1] = 0.5 * senseT;
solid = dd4hep::ExtrudedPolygon(xL, yL, zw, zx, zy, scale);
ns.addSolidNS(ns.prepend(sname), solid);
dd4hep::Volume glog = dd4hep::Volume(solid.name(), solid, matter);
ns.addVolumeNS(glog);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferP: " << 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] << " partial "
<< partialTypes[k] << " orientation " << orientations[k] << " and " << xL.size()
<< " edges";
for (unsigned int j = 0; j < xL.size(); ++j)
edm::LogVerbatim("HGCalGeom") << "[" << j << "] " << cms::convert2mm(xL[j]) << ":" << cms::convert2mm(yL[j]);
#endif
double zpos = (posSense == 0) ? -0.5 * (waferThick - senseT) : 0.5 * (waferThick - senseT);
dd4hep::Position tran(0, 0, zpos);
int copy = 10 + senseType;
glogs[i].placeVolume(glog, copy, tran);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalWaferP: " << glog.name() << " number " << copy << " positioned in "
<< glogs[i].name() << " at (0,0," << cms::convert2mm(zpos)
<< ") with no rotation";
#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") << "DDHGCalWaferP: " << 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 (std::abs(thickTot - thick) >= tol) {
if (thickTot > thick) {
edm::LogError("HGCalGeom") << "Thickness of the partition " << cms::convert2mm(thick) << " is smaller than "
<< cms::convert2mm(thickTot) << ": thickness of all its components **** ERROR ****";
} else {
edm::LogWarning("HGCalGeom") << "Thickness of the partition " << cms::convert2mm(thick)
<< " does not match with " << cms::convert2mm(thickTot) << " of the components";
}
}
}
return cms::s_executed;
}
// first argument is the type from the xml file
DECLARE_DDCMS_DETELEMENT(DDCMS_hgcal_DDHGCalWaferP, algorithm)
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