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///////////////////////////////////////////////////////////////////////////////
// File: DDHGCalMixRotatedCassette.cc
// Description: Geometry factory class for HGCal (Mix) adopted for DD4hep
///////////////////////////////////////////////////////////////////////////////
#include <cmath>
#include <memory>
#include <string>
#include <unordered_set>
#include <vector>
#include "Geometry/HGCalCommonData/interface/HGCalCell.h"
#include "Geometry/HGCalCommonData/interface/HGCalCassette.h"
#include "Geometry/HGCalCommonData/interface/HGCalGeomTools.h"
#include "Geometry/HGCalCommonData/interface/HGCalParameters.h"
#include "Geometry/HGCalCommonData/interface/HGCalProperty.h"
#include "Geometry/HGCalCommonData/interface/HGCalTileIndex.h"
#include "Geometry/HGCalCommonData/interface/HGCalTypes.h"
#include "Geometry/HGCalCommonData/interface/HGCalWaferIndex.h"
#include "Geometry/HGCalCommonData/interface/HGCalWaferType.h"
#include "DD4hep/DetFactoryHelper.h"
#include "DataFormats/Math/interface/angle_units.h"
#include "DetectorDescription/DDCMS/interface/DDPlugins.h"
#include "DetectorDescription/DDCMS/interface/DDutils.h"
#include "FWCore/MessageLogger/interface/MessageLogger.h"
//#define EDM_ML_DEBUG
using namespace angle_units::operators;
struct HGCalMixRotatedCassette {
HGCalMixRotatedCassette() { throw cms::Exception("HGCalGeom") << "Wrong initialization to HGCalMixRotatedCassette"; }
HGCalMixRotatedCassette(cms::DDParsingContext& ctxt, xml_h e) {
cms::DDNamespace ns(ctxt, e, true);
cms::DDAlgoArguments args(ctxt, e);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Creating an instance";
#endif
static constexpr double tol1 = 0.01 * dd4hep::mm;
dd4hep::Volume mother = ns.volume(args.parentName());
waferTypes_ = args.value<int>("WaferTypes");
passiveTypes_ = args.value<int>("PassiveTypes");
facingTypes_ = args.value<int>("FacingTypes");
orientationTypes_ = args.value<int>("OrientationTypes");
partialTypes_ = args.value<int>("PartialTypes");
placeOffset_ = args.value<int>("PlaceOffset");
phiBinsScint_ = args.value<int>("NPhiBinScint");
forFireworks_ = args.value<int>("ForFireWorks");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette::Number of types of wafers: " << waferTypes_
<< " passives: " << passiveTypes_ << " facings: " << facingTypes_
<< " Orientations: " << orientationTypes_ << " PartialTypes: " << partialTypes_
<< " PlaceOffset: " << placeOffset_ << "; number of cells along phi " << phiBinsScint_
<< " forFireworks_: " << forFireworks_;
#endif
firstLayer_ = args.value<int>("FirstLayer");
absorbMode_ = args.value<int>("AbsorberMode");
sensitiveMode_ = args.value<int>("SensitiveMode");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette::First Layer " << firstLayer_ << " and "
<< "Absober:Sensitive mode " << absorbMode_ << ":" << sensitiveMode_;
#endif
zMinBlock_ = args.value<double>("zMinBlock");
waferSize_ = args.value<double>("waferSize");
waferSepar_ = args.value<double>("SensorSeparation");
sectors_ = args.value<int>("Sectors");
cassettes_ = args.value<int>("Cassettes");
alpha_ = (1._pi) / sectors_;
cosAlpha_ = cos(alpha_);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: zStart " << cms::convert2mm(zMinBlock_)
<< " wafer width " << cms::convert2mm(waferSize_) << " separations "
<< cms::convert2mm(waferSepar_) << " sectors " << sectors_ << ":"
<< convertRadToDeg(alpha_) << ":" << cosAlpha_ << " with " << cassettes_
<< " cassettes";
#endif
slopeB_ = args.value<std::vector<double>>("SlopeBottom");
zFrontB_ = args.value<std::vector<double>>("ZFrontBottom");
rMinFront_ = args.value<std::vector<double>>("RMinFront");
slopeT_ = args.value<std::vector<double>>("SlopeTop");
zFrontT_ = args.value<std::vector<double>>("ZFrontTop");
rMaxFront_ = args.value<std::vector<double>>("RMaxFront");
#ifdef EDM_ML_DEBUG
for (unsigned int i = 0; i < slopeB_.size(); ++i)
edm::LogVerbatim("HGCalGeom") << "Bottom Block [" << i << "] Zmin " << cms::convert2mm(zFrontB_[i]) << " Rmin "
<< cms::convert2mm(rMinFront_[i]) << " Slope " << slopeB_[i];
for (unsigned int i = 0; i < slopeT_.size(); ++i)
edm::LogVerbatim("HGCalGeom") << "Top Block [" << i << "] Zmin " << cms::convert2mm(zFrontT_[i]) << " Rmax "
<< cms::convert2mm(rMaxFront_[i]) << " Slope " << slopeT_[i];
#endif
waferFull_ = args.value<std::vector<std::string>>("WaferNamesFull");
waferPart_ = args.value<std::vector<std::string>>("WaferNamesPartial");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << waferFull_.size() << " full and "
<< waferPart_.size() << " partial modules\nDDHGCalMixRotatedCassette:Full Modules:";
unsigned int i1max = static_cast<unsigned int>(waferFull_.size());
for (unsigned int i1 = 0; i1 < i1max; i1 += 2) {
std::ostringstream st1;
unsigned int i2 = std::min((i1 + 2), i1max);
for (unsigned int i = i1; i < i2; ++i)
st1 << " [" << i << "] " << waferFull_[i];
edm::LogVerbatim("HGCalGeom") << st1.str();
}
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Partial Modules:";
i1max = static_cast<unsigned int>(waferPart_.size());
for (unsigned int i1 = 0; i1 < i1max; i1 += 2) {
std::ostringstream st1;
unsigned int i2 = std::min((i1 + 2), i1max);
for (unsigned int i = i1; i < i2; ++i)
st1 << " [" << i << "] " << waferPart_[i];
edm::LogVerbatim("HGCalGeom") << st1.str();
}
#endif
passiveFull_ = args.value<std::vector<std::string>>("PassiveNamesFull");
passivePart_ = args.value<std::vector<std::string>>("PassiveNamesPartial");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalSiliconRotatedCassette: " << passiveFull_.size() << " full and "
<< passivePart_.size() << " partial passive modules";
i1max = static_cast<unsigned int>(passiveFull_.size());
for (unsigned int i1 = 0; i1 < i1max; i1 += 2) {
std::ostringstream st1;
unsigned int i2 = std::min((i1 + 2), i1max);
for (unsigned int i = i1; i < i2; ++i)
st1 << " [" << i << "] " << passiveFull_[i];
edm::LogVerbatim("HGCalGeom") << st1.str();
}
edm::LogVerbatim("HGCalGeom") << "DDHGCalSiliconRotatedCassette: Partial Modules:";
i1max = static_cast<unsigned int>(passivePart_.size());
for (unsigned int i1 = 0; i1 < i1max; i1 += 2) {
std::ostringstream st1;
unsigned int i2 = std::min((i1 + 2), i1max);
for (unsigned int i = i1; i < i2; ++i)
st1 << " [" << i << "] " << passivePart_[i];
edm::LogVerbatim("HGCalGeom") << st1.str();
}
#endif
materials_ = args.value<std::vector<std::string>>("MaterialNames");
names_ = args.value<std::vector<std::string>>("VolumeNames");
thick_ = args.value<std::vector<double>>("Thickness");
copyNumber_.resize(materials_.size(), 1);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << materials_.size() << " types of volumes";
for (unsigned int i = 0; i < names_.size(); ++i)
edm::LogVerbatim("HGCalGeom") << "Volume [" << i << "] " << names_[i] << " of thickness "
<< cms::convert2mm(thick_[i]) << " filled with " << materials_[i]
<< " first copy number " << copyNumber_[i];
#endif
layers_ = args.value<std::vector<int>>("Layers");
layerThick_ = args.value<std::vector<double>>("LayerThick");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "There are " << layers_.size() << " blocks";
for (unsigned int i = 0; i < layers_.size(); ++i)
edm::LogVerbatim("HGCalGeom") << "Block [" << i << "] of thickness " << cms::convert2mm(layerThick_[i])
<< " with " << layers_[i] << " layers";
#endif
layerType_ = args.value<std::vector<int>>("LayerType");
layerSense_ = args.value<std::vector<int>>("LayerSense");
layerOrient_ = args.value<std::vector<int>>("LayerTypes");
for (unsigned int k = 0; k < layerOrient_.size(); ++k)
layerOrient_[k] = HGCalTypes::layerType(layerOrient_[k]);
#ifdef EDM_ML_DEBUG
for (unsigned int i = 0; i < layerOrient_.size(); ++i)
edm::LogVerbatim("HGCalGeom") << "LayerOrient [" << i << "] " << layerOrient_[i];
#endif
if (firstLayer_ > 0) {
for (unsigned int i = 0; i < layerType_.size(); ++i) {
if (layerSense_[i] != 0) {
int ii = layerType_[i];
copyNumber_[ii] = firstLayer_;
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "First copy number for layer type " << i << ":" << ii << " with "
<< materials_[ii] << " changed to " << copyNumber_[ii];
#endif
}
}
} else {
firstLayer_ = 1;
}
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "There are " << layerType_.size() << " layers";
for (unsigned int i = 0; i < layerType_.size(); ++i)
edm::LogVerbatim("HGCalGeom") << "Layer [" << i << "] with material type " << layerType_[i] << " sensitive class "
<< layerSense_[i];
#endif
materialTop_ = args.value<std::vector<std::string>>("TopMaterialNames");
namesTop_ = args.value<std::vector<std::string>>("TopVolumeNames");
layerThickTop_ = args.value<std::vector<double>>("TopLayerThickness");
layerTypeTop_ = args.value<std::vector<int>>("TopLayerType");
copyNumberTop_.resize(materialTop_.size(), firstLayer_);
coverTypeTop_ = args.value<int>("TopCoverLayerType");
copyNumberCoverTop_ = firstLayer_;
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << materialTop_.size()
<< " types of volumes in the top part; cover Type " << coverTypeTop_
<< " with initial copy number " << copyNumberCoverTop_;
for (unsigned int i = 0; i < materialTop_.size(); ++i)
edm::LogVerbatim("HGCalGeom") << "Volume [" << i << "] " << namesTop_[i] << " of thickness "
<< cms::convert2mm(layerThickTop_[i]) << " filled with " << materialTop_[i]
<< " first copy number " << copyNumberTop_[i];
edm::LogVerbatim("HGCalGeom") << "There are " << layerTypeTop_.size() << " layers in the top part";
for (unsigned int i = 0; i < layerTypeTop_.size(); ++i)
edm::LogVerbatim("HGCalGeom") << "Layer [" << i << "] with material type " << layerTypeTop_[i];
#endif
waferIndex_ = args.value<std::vector<int>>("WaferIndex");
waferProperty_ = args.value<std::vector<int>>("WaferProperties");
waferLayerStart_ = args.value<std::vector<int>>("WaferLayerStart");
cassetteShift_ = args.value<std::vector<double>>("CassetteShift");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "waferProperties with " << waferIndex_.size() << " entries in "
<< waferLayerStart_.size() << " layers";
for (unsigned int k = 0; k < waferLayerStart_.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "LayerStart[" << k << "] " << waferLayerStart_[k];
for (unsigned int k = 0; k < waferIndex_.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << waferIndex_[k] << " ("
<< HGCalWaferIndex::waferLayer(waferIndex_[k]) << ", "
<< HGCalWaferIndex::waferU(waferIndex_[k]) << ", "
<< HGCalWaferIndex::waferV(waferIndex_[k]) << ") : ("
<< HGCalProperty::waferThick(waferProperty_[k]) << ":"
<< HGCalProperty::waferPartial(waferProperty_[k]) << ":"
<< HGCalProperty::waferOrient(waferProperty_[k]) << ")";
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << cassetteShift_.size()
<< " elements for cassette shifts";
unsigned int j1max = cassetteShift_.size();
for (unsigned int j1 = 0; j1 < j1max; j1 += 6) {
std::ostringstream st1;
unsigned int j2 = std::min((j1 + 6), j1max);
for (unsigned int j = j1; j < j2; ++j)
st1 << " [" << j << "] " << std::setw(9) << cassetteShift_[j];
edm::LogVerbatim("HGCalGeom") << st1.str();
}
#endif
tileRMin_ = args.value<std::vector<double>>("TileRMin");
tileRMax_ = args.value<std::vector<double>>("TileRMax");
tileIndex_ = args.value<std::vector<int>>("TileLayerRings");
tilePhis_ = args.value<std::vector<int>>("TilePhiRange");
tileLayerStart_ = args.value<std::vector<int>>("TileLayerStart");
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette:: with " << tileRMin_.size() << " rings";
for (unsigned int k = 0; k < tileRMin_.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "Ring[" << k << "] " << cms::convert2mm(tileRMin_[k]) << " : "
<< cms::convert2mm(tileRMax_[k]);
edm::LogVerbatim("HGCalGeom") << "TileProperties with " << tileIndex_.size() << " entries in "
<< tileLayerStart_.size() << " layers";
for (unsigned int k = 0; k < tileLayerStart_.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "LayerStart[" << k << "] " << tileLayerStart_[k];
for (unsigned int k = 0; k < tileIndex_.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "[" << k << "] " << tileIndex_[k] << " ("
<< "Layer " << std::get<0>(HGCalTileIndex::tileUnpack(tileIndex_[k])) << " Ring "
<< std::get<1>(HGCalTileIndex::tileUnpack(tileIndex_[k])) << ":"
<< std::get<2>(HGCalTileIndex::tileUnpack(tileIndex_[k])) << ") Phi "
<< std::get<1>(HGCalTileIndex::tileUnpack(tilePhis_[k])) << ":"
<< std::get<2>(HGCalTileIndex::tileUnpack(tilePhis_[k]));
#endif
cassette_.setParameter(cassettes_, cassetteShift_);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: NameSpace " << ns.name();
edm::LogVerbatim("HGCalGeom") << "==>> Constructing DDHGCalMixRotatedCassette...";
copies_.clear();
#endif
double zi(zMinBlock_);
int laymin(0);
for (unsigned int i = 0; i < layers_.size(); i++) {
double zo = zi + layerThick_[i];
double routF = HGCalGeomTools::radius(zi, zFrontT_, rMaxFront_, slopeT_);
int laymax = laymin + layers_[i];
double zz = zi;
double thickTot(0);
for (int ly = laymin; ly < laymax; ++ly) {
int ii = layerType_[ly];
int copy = copyNumber_[ii];
double hthick = 0.5 * thick_[ii];
double rinB = HGCalGeomTools::radius(zo, zFrontB_, rMinFront_, slopeB_);
zz += hthick;
thickTot += thick_[ii];
std::string name = names_[ii] + std::to_string(copy);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Layer " << ly << ":" << ii << " Front "
<< cms::convert2mm(zi) << ", " << cms::convert2mm(routF) << " Back "
<< cms::convert2mm(zo) << ", " << cms::convert2mm(rinB)
<< " superlayer thickness " << cms::convert2mm(layerThick_[i]);
#endif
dd4hep::Material matter = ns.material(materials_[ii]);
dd4hep::Volume glog;
if (layerSense_[ly] == 0) {
std::vector<double> pgonZ, pgonRin, pgonRout;
double rmax =
(std::min(routF, HGCalGeomTools::radius(zz + hthick, zFrontT_, rMaxFront_, slopeT_)) * cosAlpha_) - tol1;
HGCalGeomTools::radius(zz - hthick,
zz + hthick,
zFrontB_,
rMinFront_,
slopeB_,
zFrontT_,
rMaxFront_,
slopeT_,
-layerSense_[ly],
pgonZ,
pgonRin,
pgonRout);
for (unsigned int isec = 0; isec < pgonZ.size(); ++isec) {
pgonZ[isec] -= zz;
if (layerSense_[ly] == 0 || absorbMode_ == 0)
pgonRout[isec] = rmax;
else
pgonRout[isec] = pgonRout[isec] * cosAlpha_ - tol1;
}
dd4hep::Solid solid = dd4hep::Polyhedra(sectors_, -alpha_, 2._pi, pgonZ, pgonRin, pgonRout);
ns.addSolidNS(ns.prepend(name), solid);
glog = dd4hep::Volume(solid.name(), solid, matter);
ns.addVolumeNS(glog);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << solid.name() << " polyhedra of " << sectors_
<< " sectors covering " << convertRadToDeg(-alpha_) << ":"
<< convertRadToDeg(-alpha_ + 2._pi) << " with " << pgonZ.size() << " sections";
for (unsigned int k = 0; k < pgonZ.size(); ++k)
edm::LogVerbatim("HGCalGeom") << "[" << k << "] z " << cms::convert2mm(pgonZ[k]) << " R "
<< cms::convert2mm(pgonRin[k]) << ":" << cms::convert2mm(pgonRout[k]);
#endif
} else {
int mode = (layerSense_[ly] > 0) ? sensitiveMode_ : absorbMode_;
double rins = (mode < 1) ? rinB : HGCalGeomTools::radius(zz + hthick, zFrontB_, rMinFront_, slopeB_);
double routs = (mode < 1) ? routF : HGCalGeomTools::radius(zz - hthick, zFrontT_, rMaxFront_, slopeT_);
dd4hep::Solid solid = dd4hep::Tube(rins, routs, hthick, 0.0, 2._pi);
ns.addSolidNS(ns.prepend(name), solid);
glog = dd4hep::Volume(solid.name(), solid, matter);
ns.addVolumeNS(glog);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << solid.name() << " Tubs made of "
<< matter.name() << " of dimensions " << cms::convert2mm(rinB) << ":"
<< cms::convert2mm(rins) << ", " << cms::convert2mm(routF) << ":"
<< cms::convert2mm(routs) << ", " << cms::convert2mm(hthick)
<< ", 0.0, 360.0 and positioned in: " << glog.name() << " number " << copy;
#endif
positionMix(ctxt, e, glog, name, copy, thick_[ii], matter, -layerSense_[ly]);
}
dd4hep::Position r1(0, 0, zz);
mother.placeVolume(glog, copy, r1);
++copyNumber_[ii];
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << glog.name() << " number " << copy
<< " positioned in " << mother.name() << " at (0,0," << cms::convert2mm(zz)
<< ") with no rotation";
#endif
zz += hthick;
} // End of loop over layers in a block
zi = zo;
laymin = laymax;
if (std::abs(thickTot - layerThick_[i]) > tol2_) {
if (thickTot > layerThick_[i]) {
edm::LogError("HGCalGeom") << "Thickness of the partition " << cms::convert2mm(layerThick_[i])
<< " is smaller than " << cms::convert2mm(thickTot)
<< ": thickness of all its components **** ERROR ****";
} else {
edm::LogWarning("HGCalGeom") << "Thickness of the partition " << cms::convert2mm(layerThick_[i])
<< " does not match with " << cms::convert2mm(thickTot) << " of the components";
}
}
} // End of loop over blocks
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << copies_.size() << " different wafer copy numbers";
int k(0);
for (std::unordered_set<int>::const_iterator itr = copies_.begin(); itr != copies_.end(); ++itr, ++k) {
edm::LogVerbatim("HGCalGeom") << "Copy [" << k << "] : " << (*itr);
}
copies_.clear();
edm::LogVerbatim("HGCalGeom") << "<<== End of DDHGCalMixRotatedCassette construction...";
#endif
}
void positionMix(cms::DDParsingContext& ctxt,
xml_h e,
const dd4hep::Volume& glog,
const std::string& nameM,
int copyM,
double thick,
const dd4hep::Material& matter,
int absType) {
cms::DDNamespace ns(ctxt, e, true);
// Make the top part first
for (unsigned int ly = 0; ly < layerTypeTop_.size(); ++ly) {
int ii = layerTypeTop_[ly];
copyNumberTop_[ii] = copyM;
}
double hthick = 0.5 * thick;
double dphi = (2._pi) / phiBinsScint_;
double thickTot(0), zpos(-hthick);
if (absType < 0) {
for (unsigned int ly = 0; ly < layerTypeTop_.size(); ++ly) {
int ii = layerTypeTop_[ly];
int copy = copyNumberTop_[ii];
int layer = copy - firstLayer_;
double hthickl = 0.5 * layerThickTop_[ii];
thickTot += layerThickTop_[ii];
zpos += hthickl;
dd4hep::Material matter1 = ns.material(materialTop_[ii]);
unsigned int k = 0;
int firstTile = tileLayerStart_[layer];
int lastTile = ((layer + 1 < static_cast<int>(tileLayerStart_.size())) ? tileLayerStart_[layer + 1]
: static_cast<int>(tileIndex_.size()));
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Layer " << ly << ":" << ii << " Copy " << copy
<< " Tiles " << firstTile << ":" << lastTile;
#endif
for (int ti = firstTile; ti < lastTile; ++ti) {
double r1 = tileRMin_[std::get<1>(HGCalTileIndex::tileUnpack(tileIndex_[ti])) - 1];
double r2 = tileRMax_[std::get<2>(HGCalTileIndex::tileUnpack(tileIndex_[ti])) - 1];
int cassette = std::get<0>(HGCalTileIndex::tileUnpack(tilePhis_[ti]));
int fimin = std::get<1>(HGCalTileIndex::tileUnpack(tilePhis_[ti]));
int fimax = std::get<2>(HGCalTileIndex::tileUnpack(tilePhis_[ti]));
double phi1 = dphi * (fimin - 1);
double phi2 = (forFireworks_ == 1) ? (dphi * (fimax - fimin + 1)) : (dphi * fimax);
auto cshift = cassette_.getShift(layer + 1, 1, cassette);
#ifdef EDM_ML_DEBUG
int cassette0 = HGCalCassette::cassetteType(2, 1, cassette); //
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Layer " << copy << ":" << (layer + 1) << " iR "
<< std::get<1>(HGCalTileIndex::tileUnpack(tileIndex_[ti])) << ":"
<< std::get<2>(HGCalTileIndex::tileUnpack(tileIndex_[ti])) << " R "
<< cms::convert2mm(r1) << ":" << cms::convert2mm(r2) << " Thick "
<< cms::convert2mm((2.0 * hthickl)) << " phi " << fimin << ":" << fimax << ":"
<< convertRadToDeg(phi1) << ":" << convertRadToDeg(phi2) << " cassette "
<< cassette << ":" << cassette0 << " Shift " << cms::convert2mm(cshift.first)
<< ":" << cms::convert2mm(cshift.second);
#endif
std::string name = namesTop_[ii] + "L" + std::to_string(copy) + "F" + std::to_string(k);
++k;
dd4hep::Solid solid = dd4hep::Tube(r1, r2, hthickl, phi1, phi2);
ns.addSolidNS(ns.prepend(name), solid);
dd4hep::Volume glog1 = dd4hep::Volume(solid.name(), solid, matter1);
ns.addVolumeNS(glog1);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << glog1.name() << " Tubs made of "
<< materialTop_[ii] << " of dimensions " << cms::convert2mm(r1) << ", "
<< cms::convert2mm(r2) << ", " << cms::convert2mm(hthickl) << ", "
<< convertRadToDeg(phi1) << ", " << convertRadToDeg(phi2);
#endif
dd4hep::Position tran(-cshift.first, cshift.second, zpos);
glog.placeVolume(glog1, copy, tran);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Position " << glog1.name() << " number " << copy
<< " in " << glog.name() << " at (" << cms::convert2mm(cshift.first) << ", "
<< cms::convert2mm(cshift.second) << ", " << cms::convert2mm(zpos)
<< ") with no rotation";
#endif
}
++copyNumberTop_[ii];
zpos += hthickl;
}
if (std::abs(thickTot - thick) > tol2_) {
if (thickTot > thick) {
edm::LogError("HGCalGeom") << "DDHGCalMixRotatedCassette: Thickness of the partition "
<< cms::convert2mm(thick) << " is smaller than " << cms::convert2mm(thickTot)
<< ": thickness of all its components in the top part **** ERROR ****";
} else {
edm::LogWarning("HGCalGeom") << "DDHGCalMixRotatedCassette: Thickness of the partition "
<< cms::convert2mm(thick) << " does not match with " << cms::convert2mm(thickTot)
<< " of the components in top part";
}
}
} else {
int ii = coverTypeTop_;
int copy = copyNumberCoverTop_;
int layer = copy - firstLayer_;
double hthickl = 0.5 * layerThickTop_[ii];
zpos += hthickl;
dd4hep::Material matter1 = ns.material(materialTop_[ii]);
unsigned int k = 0;
int firstTile = tileLayerStart_[layer];
int lastTile = ((layer + 1 < static_cast<int>(tileLayerStart_.size())) ? tileLayerStart_[layer + 1]
: static_cast<int>(tileIndex_.size()));
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Layer " << layer << ":" << ii << " Copy " << copy
<< " Tiles " << firstTile << ":" << lastTile;
#endif
for (int ti = firstTile; ti < lastTile; ++ti) {
double r1 = tileRMin_[std::get<1>(HGCalTileIndex::tileUnpack(tileIndex_[ti])) - 1];
double r2 = tileRMax_[std::get<2>(HGCalTileIndex::tileUnpack(tileIndex_[ti])) - 1];
int cassette = std::get<0>(HGCalTileIndex::tileUnpack(tilePhis_[ti]));
int fimin = std::get<1>(HGCalTileIndex::tileUnpack(tilePhis_[ti]));
int fimax = std::get<2>(HGCalTileIndex::tileUnpack(tilePhis_[ti]));
double phi1 = dphi * (fimin - 1);
double phi2 = (forFireworks_ == 1) ? (dphi * (fimax - fimin + 1)) : (dphi * fimax);
auto cshift = cassette_.getShift(layer + 1, 1, cassette);
#ifdef EDM_ML_DEBUG
int cassette0 = HGCalCassette::cassetteType(2, 1, cassette); //
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Layer " << copy << ":" << (layer + 1) << " iR "
<< std::get<1>(HGCalTileIndex::tileUnpack(tileIndex_[ti])) << ":"
<< std::get<2>(HGCalTileIndex::tileUnpack(tileIndex_[ti])) << " R "
<< cms::convert2mm(r1) << ":" << cms::convert2mm(r2) << " Thick "
<< cms::convert2mm(2.0 * hthickl) << " phi " << fimin << ":" << fimax << ":"
<< convertRadToDeg(phi1) << ":" << convertRadToDeg(phi2) << " cassette "
<< cassette << ":" << cassette0 << " Shift " << cms::convert2mm(cshift.first)
<< ":" << cms::convert2mm(cshift.second);
#endif
std::string name = namesTop_[ii] + "L" + std::to_string(copy) + "F" + std::to_string(k);
++k;
dd4hep::Solid solid = dd4hep::Tube(r1, r2, hthickl, phi1, phi2);
ns.addSolidNS(ns.prepend(name), solid);
dd4hep::Volume glog1 = dd4hep::Volume(solid.name(), solid, matter1);
ns.addVolumeNS(glog1);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << glog1.name() << " Tubs made of "
<< matter1.name() << " of dimensions " << cms::convert2mm(r1) << ", "
<< cms::convert2mm(r2) << ", " << cms::convert2mm(hthickl) << ", "
<< convertRadToDeg(phi1) << ", " << convertRadToDeg(phi2);
#endif
dd4hep::Position tran(-cshift.first, cshift.second, zpos);
glog.placeVolume(glog1, copy, tran);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Position " << glog1.name() << " number " << copy
<< " in " << glog.name() << " at (" << cms::convert2mm(cshift.first) << ", "
<< cms::convert2mm(cshift.second) << ", " << cms::convert2mm(zpos)
<< ") with no rotation";
#endif
}
++copyNumberCoverTop_;
}
// Make the bottom part next
int layer = (copyM - firstLayer_);
static const double sqrt3 = std::sqrt(3.0);
int layercenter = layerOrient_[layer];
int layertype = HGCalTypes::layerFrontBack(layerOrient_[layer]);
int firstWafer = waferLayerStart_[layer];
int lastWafer = ((layer + 1 < static_cast<int>(waferLayerStart_.size())) ? waferLayerStart_[layer + 1]
: static_cast<int>(waferIndex_.size()));
double delx = 0.5 * (waferSize_ + waferSepar_);
double dely = 2.0 * delx / sqrt3;
double dy = 0.75 * dely;
const auto& xyoff = geomTools_.shiftXY(layercenter, (waferSize_ + waferSepar_));
#ifdef EDM_ML_DEBUG
int ium(0), ivm(0), kount(0);
std::vector<int> ntype(3, 0);
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: " << glog.name() << " r " << cms::convert2mm(delx)
<< " R " << cms::convert2mm(dely) << " dy " << cms::convert2mm(dy) << " Shift "
<< cms::convert2mm(xyoff.first) << ":" << cms::convert2mm(xyoff.second)
<< " WaferSize " << cms::convert2mm((waferSize_ + waferSepar_)) << " index "
<< firstWafer << ":" << (lastWafer - 1) << " Copy " << copyM << ":" << layer;
#endif
for (int k = firstWafer; k < lastWafer; ++k) {
int u = HGCalWaferIndex::waferU(waferIndex_[k]);
int v = HGCalWaferIndex::waferV(waferIndex_[k]);
#ifdef EDM_ML_DEBUG
int iu = std::abs(u);
int iv = std::abs(v);
#endif
int nr = 2 * v;
int nc = -2 * u + v;
int type = HGCalProperty::waferThick(waferProperty_[k]);
int part = HGCalProperty::waferPartial(waferProperty_[k]);
int orien = HGCalProperty::waferOrient(waferProperty_[k]);
int cassette = HGCalProperty::waferCassette(waferProperty_[k]);
int place = HGCalCell::cellPlacementIndex(1, layertype, orien);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom")
<< "DDHGCalMixRotatedCassette::index:Property:layertype:type:part:orien:cassette:place:offsets:ind " << k
<< ":" << waferProperty_[k] << ":" << layertype << ":" << type << ":" << part << ":" << orien << ":"
<< cassette << ":" << place;
#endif
auto cshift = cassette_.getShift(layer + 1, -1, cassette);
double xpos = xyoff.first - cshift.first + nc * delx;
double ypos = xyoff.second + cshift.second + nr * dy;
#ifdef EDM_ML_DEBUG
double xorig = xyoff.first + nc * delx;
double yorig = xyoff.second + nr * dy;
double angle = std::atan2(yorig, xorig);
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette::Wafer: layer " << layer + 1 << " cassette "
<< cassette << " Shift " << cms::convert2mm(cshift.first) << ":"
<< cms::convert2mm(cshift.second) << " Original " << cms::convert2mm(xorig) << ":"
<< cms::convert2mm(yorig) << ":" << convertRadToDeg(angle) << " Final "
<< cms::convert2mm(xpos) << ":" << cms::convert2mm(ypos);
#endif
std::string wafer;
int i(999);
if (absType < 0) {
if (part == HGCalTypes::WaferFull) {
i = type * facingTypes_ * orientationTypes_ + place - placeOffset_;
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << " FullWafer type:place:ind " << type << ":" << place << ":" << i << ":"
<< waferFull_.size();
#endif
wafer = waferFull_[i];
} else {
int partoffset =
(part >= HGCalTypes::WaferHDTop) ? HGCalTypes::WaferPartHDOffset : HGCalTypes::WaferPartLDOffset;
i = (part - partoffset) * facingTypes_ * orientationTypes_ +
HGCalTypes::WaferTypeOffset[type] * facingTypes_ * orientationTypes_ + place - placeOffset_;
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << " layertype:type:part:orien:cassette:place:offsets:ind " << layertype << ":"
<< type << ":" << part << ":" << orien << ":" << cassette << ":" << place << ":"
<< partoffset << ":" << HGCalTypes::WaferTypeOffset[type] << ":" << i << ":"
<< waferPart_.size();
#endif
wafer = waferPart_[i];
}
} else {
type = absType;
if (part == HGCalTypes::WaferFull) {
i = absType - 1;
wafer = passiveFull_[i];
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << " layertype:abstype:part:orien:cassette:offsets:ind " << layertype << ":"
<< absType << ":" << part << ":" << orien << ":" << cassette << ":"
<< ":" << partialTypes_ << ":" << orientationTypes_ << " passive " << i << ":"
<< wafer;
#endif
} else {
int partoffset = (part >= HGCalTypes::WaferHDTop)
? HGCalTypes::WaferPartHDOffset
: (HGCalTypes::WaferPartLDOffset - HGCalTypes::WaferTypeOffset[1]);
i = (part - partoffset) * facingTypes_ * orientationTypes_ +
(absType - 1) * facingTypes_ * orientationTypes_ * partialTypes_ + place - placeOffset_;
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << " layertype:abstype:part:orien:cassette:3Types:offset:ind " << layertype
<< ":" << absType << ":" << part << ":" << orien << ":" << cassette << ":"
<< partialTypes_ << ":" << facingTypes_ << ":" << orientationTypes_ << ":"
<< partoffset << ":" << i << ":" << passivePart_.size();
#endif
wafer = passivePart_[i];
}
}
int copy = HGCalTypes::packTypeUV(type, u, v);
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << " DDHGCalMixRotatedCassette: Layer "
<< HGCalWaferIndex::waferLayer(waferIndex_[k]) << " Wafer " << wafer << " number "
<< copy << " type :part:orien:ind " << type << ":" << part << ":" << orien << ":"
<< i << " layer:u:v " << (layer + firstLayer_) << ":" << u << ":" << v;
if (iu > ium)
ium = iu;
if (iv > ivm)
ivm = iv;
kount++;
if (copies_.count(copy) == 0)
copies_.insert(copy);
#endif
dd4hep::Position tran(xpos, ypos, 0.0);
glog.placeVolume(ns.volume(wafer), copy, tran);
#ifdef EDM_ML_DEBUG
++ntype[type];
edm::LogVerbatim("HGCalGeom") << " DDHGCalMixRotatedCassette: " << wafer << " number " << copy << " type "
<< layertype << ":" << type << " positioned in " << glog.name() << " at ("
<< cms::convert2mm(xpos) << "," << cms::convert2mm(ypos) << ",0) with no rotation";
#endif
}
#ifdef EDM_ML_DEBUG
edm::LogVerbatim("HGCalGeom") << "DDHGCalMixRotatedCassette: Maximum # of u " << ium << " # of v " << ivm << " and "
<< kount << " wafers (" << ntype[0] << ":" << ntype[1] << ":" << ntype[2] << ") for "
<< glog.name();
#endif
}
//Required data members to cache the values from XML file
HGCalGeomTools geomTools_;
HGCalCassette cassette_;
static constexpr double tol2_ = 0.00001 * dd4hep::mm;
int waferTypes_; // Number of wafer types
int passiveTypes_; // Number of passive types
int facingTypes_; // Types of facings of modules toward IP
int orientationTypes_; // Number of partial wafer orienations
int partialTypes_; // Number of partial types
int placeOffset_; // Offset for placement
int phiBinsScint_; // Maximum number of cells along phi
int forFireworks_; // Needed for Fireworks(1)/Geant4(0)
int firstLayer_; // Copy # of the first sensitive layer
int absorbMode_; // Absorber mode
int sensitiveMode_; // Sensitive mode
double zMinBlock_; // Starting z-value of the block
double waferSize_; // Width of the wafer
double waferSepar_; // Sensor separation
int sectors_; // Sectors
int cassettes_; // Cassettes
std::vector<double> slopeB_; // Slope at the lower R
std::vector<double> zFrontB_; // Starting Z values for the slopes
std::vector<double> rMinFront_; // Corresponding rMin's
std::vector<double> slopeT_; // Slopes at the larger R
std::vector<double> zFrontT_; // Starting Z values for the slopes
std::vector<double> rMaxFront_; // Corresponding rMax's
std::vector<std::string> waferFull_; // Names of full wafer modules
std::vector<std::string> waferPart_; // Names of partial wafer modules
std::vector<std::string> passiveFull_; // Names of full passive modules
std::vector<std::string> passivePart_; // Names of partial passive modules
std::vector<std::string> materials_; // Materials
std::vector<std::string> names_; // Names
std::vector<double> thick_; // Thickness of the material
std::vector<int> copyNumber_; // Initial copy numbers
std::vector<int> layers_; // Number of layers in a section
std::vector<double> layerThick_; // Thickness of each section
std::vector<int> layerType_; // Type of the layer
std::vector<int> layerSense_; // Content of a layer (sensitive?)
std::vector<std::string> materialTop_; // Materials of top layers
std::vector<std::string> namesTop_; // Names of top layers
std::vector<double> layerThickTop_; // Thickness of the top sections
std::vector<int> layerTypeTop_; // Type of the Top layer
std::vector<int> copyNumberTop_; // Initial copy numbers (top section)
int coverTypeTop_; // Type of the Top layer cover
int copyNumberCoverTop_; // Initial copy number of top cover
std::vector<int> layerOrient_; // Layer orientation for the silicon component
std::vector<int> waferIndex_; // Wafer index for the types
std::vector<int> waferProperty_; // Wafer property
std::vector<int> waferLayerStart_; // Start index of wafers in each layer
std::vector<double> cassetteShift_; // Shifts of the cassetes
std::vector<double> tileRMin_; // Minimum radius of each ring
std::vector<double> tileRMax_; // Maximum radius of each ring
std::vector<int> tileIndex_; // Index of tile (layer/start|end ring)
std::vector<int> tilePhis_; // Tile phi range for each index
std::vector<int> tileLayerStart_; // Start index of tiles in each layer
std::unordered_set<int> copies_; // List of copy #'s
double alpha_, cosAlpha_;
};
static long algorithm(dd4hep::Detector& /* description */, cms::DDParsingContext& ctxt, xml_h e) {
HGCalMixRotatedCassette mixRotatedCassetteAlgo(ctxt, e);
return cms::s_executed;
}
DECLARE_DDCMS_DETELEMENT(DDCMS_hgcal_DDHGCalMixRotatedCassette, algorithm)
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