17 #include <DD4hep/DD4hepUnits.h> 37 const auto *
const transArray = fv.
trans();
40 center_ =
GlobalPoint(transArray[0] / dd4hep::cm, transArray[1] / dd4hep::cm, transArray[2] / dd4hep::cm);
43 string volName =
name;
44 volName.erase(0, volName.rfind(
'_') + 1);
45 volumeno =
static_cast<unsigned short>(std::atoi(volName.c_str()));
47 for (
int i = 0;
i < 6; ++
i) {
55 double halfX = box.x() / dd4hep::cm;
56 double halfY = box.y() / dd4hep::cm;
57 double halfZ = box.z() / dd4hep::cm;
62 double x1 = trap.bottomLow1() / dd4hep::cm;
63 double x2 = trap.topLow1() / dd4hep::cm;
64 double x3 = trap.bottomLow2() / dd4hep::cm;
65 double x4 = trap.topLow2() / dd4hep::cm;
66 double y1 = trap.high1() / dd4hep::cm;
67 double y2 = trap.high2() / dd4hep::cm;
68 double theta = trap.theta();
69 double phi = trap.phi();
70 double halfZ = trap.dZ() / dd4hep::cm;
71 double alpha1 = trap.alpha1();
72 double alpha2 = trap.alpha2();
73 buildTrap(x1, x2, x3, x4,
y1,
y2,
theta, phi, halfZ, alpha1, alpha2);
78 double zhalf = cons.dZ() / dd4hep::cm;
79 double rInMinusZ = cons.rMin1() / dd4hep::cm;
80 double rOutMinusZ = cons.rMax1() / dd4hep::cm;
81 double rInPlusZ = cons.rMin2() / dd4hep::cm;
82 double rOutPlusZ = cons.rMax2() / dd4hep::cm;
83 double startPhi = cons.startPhi();
89 double zhalf = tubs.dZ() / dd4hep::cm;
90 double rIn = tubs.rMin() / dd4hep::cm;
91 double rOut = tubs.rMax() / dd4hep::cm;
93 double deltaPhi = tubs.endPhi() - startPhi;
111 LogTrace(
"MagGeoBuilder") <<
" Pseudo trap params raw = " <<
d[0] <<
", " <<
d[1] <<
", " <<
d[2] <<
", " 112 <<
d[3] <<
", " <<
d[4] <<
", " <<
d[5] <<
", " <<
d[6];
115 transform(
d.begin(), --(
d.end()),
d.begin(), [](
double val) {
return val / dd4hep::cm; });
118 LogTrace(
"MagGeoBuilder") <<
" Pseudo trap params converted = " <<
d[0] <<
", " <<
d[1] <<
", " <<
d[2] <<
", " 119 <<
d[3] <<
", " <<
d[4] <<
", " <<
d[5] <<
", " <<
d[6];
125 double zhalf = tubs.dZ() / dd4hep::cm;
126 double rIn = tubs.rMin() / dd4hep::cm;
127 double rOut = tubs.rMax() / dd4hep::cm;
130 double cutAtStart = tubs.cutAtStart() / dd4hep::cm;
131 double cutAtDelta = tubs.cutAtDelta() / dd4hep::cm;
132 bool cutInside = tubs.cutInside();
136 LogError(
"magneticfield::volumeHandle")
137 <<
"ctor: Unexpected shape # " <<
static_cast<int>(
theShape) <<
" for vol " <<
name;
141 if (fv.
volume().material().density() > 3.)
148 LogTrace(
"MagGeoBuilder") <<
"*** WARNING: wrong RMin/RN/RMax";
155 LogTrace(
"MagGeoBuilder") <<
" Orientation of surfaces:";
156 std::string sideName[3] = {
"positiveSide",
"negativeSide",
"onSurface"};
157 for (
int i = 0;
i < 6; ++
i) {
198 dd4hep::Rotation3D refRot;
200 refRot.GetComponents(
x, y, z);
202 if (
x.Cross(y).Dot(z) < 0.5) {
203 LogTrace(
"MagGeoBuilder") <<
"*** WARNING: Rotation is not RH ";
232 globalZdir = -globalZdir;
236 LogTrace(
"MagGeoBuilder") <<
"*** WARNING RefPlane check failed!***" << chk;
241 std::vector<VolumeSide>
result;
242 for (
int i = 0;
i < 6; ++
i) {
258 #include "buildBox.icc" 259 #include "buildTrap.icc" 260 #include "buildTubs.icc" 261 #include "buildCons.icc" 262 #include "buildPseudoTrap.icc" 263 #include "buildTruncTubs.icc" GlobalPoint toGlobal(const LocalPoint &lp) const
constexpr double deltaPhi(double phi1, double phi2)
void buildBox(double halfX, double halfY, double halfZ)
MagGeoBuilderFromDDD::volumeHandle volumeHandle
A truncated tube section.
double startPhi(void) const
angular start of the tube-section
Surface::LocalVector LocalVector
Geom::Phi< T > phi() const
const Double_t * rot() const
The absolute rotation of the current node.
ALPAKA_FN_ACC int side(int ieta, int iphi)
Log< level::Error, false > LogError
const GlobalPoint & center() const
Return the center of the volume.
unsigned short volumeno
volume number
unsigned short copyno
copy number
std::string_view name() const
const Double_t * trans() const
The absolute translation of the current node.
GloballyPositioned< float > * refPlane
void referencePlane(const cms::DDFilteredView &fv)
const DDSolidShape theShape
Surface::GlobalPoint GlobalPoint
void buildTrap(double x1, double x2, double x3, double x4, double y1, double y2, double theta, double phi, double halfZ, double alpha1, double alpha2)
void buildTruncTubs(double zhalf, double rIn, double rOut, double startPhi, double deltaPhi, double cutAtStart, double cutAtDelta, bool cutInside)
Interface to a Trapezoid.
int masterSector
The sector for which an interpolator for this class of volumes should be built.
std::string_view materialName() const
unsigned short copyNum() const
void buildPseudoTrap(double x1, double x2, double y1, double y2, double halfZ, double radius, bool atMinusZ)
const PositionType & position() const
XYZVectorD XYZVector
spatial vector with cartesian internal representation
std::string name
Name of the volume.
void buildCons(double zhalf, double rInMinusZ, double rOutMinusZ, double rInPlusZ, double rOutPlusZ, double startPhi, double deltaPhi)
dd4hep::Solid solid() const
double startPhi(void) const
const PlacedVolume volume() const
The physical volume of the current node.
std::vector< VolumeSide > sides() const override
The surfaces and they orientation, as required to build a MagVolume.
const std::vector< double > parameters() const
extract shape parameters
Geom::Theta< T > theta() const
std::string magFile
Name of magnetic field table file.
const cms::DDFilteredView & solid
Global3DVector GlobalVector
void buildTubs(double zhalf, double rIn, double rOut, double startPhi, double deltaPhi)