20 #include "CLHEP/Units/GlobalSystemOfUnits.h"
37 DDValue val(attribute, value, 0.0);
72 DDValue numbOfStrips(
"nStrips");
74 std::vector<const DDsvalues_type* > specs(fview.
specifics());
75 std::vector<const DDsvalues_type* >::iterator is=specs.begin();
77 for (;is!=specs.end(); is++){
78 if (
DDfetch( *is, numbOfStrips)){
79 nStrips=int(numbOfStrips.
doubles()[0]);
83 std::cout <<
"No strip found!!"<<std::endl;
87 std::vector<std::string> strpars;
89 strpars.push_back(name);
94 rota.GetComponents(x,y,z);
95 std::vector<double> pars;
97 double width = dpar[0];
98 double length = dpar[1];
99 double thickness = dpar[2];
100 pars.push_back(width);
101 pars.push_back(length);
102 pars.push_back(thickness);
103 pars.push_back(numbOfStrips.
doubles()[0]);
105 pars.push_back(dpar[4]);
106 pars.push_back(dpar[8]);
107 pars.push_back(dpar[0]);
109 pars.push_back(numbOfStrips.
doubles()[0]);
113 std::vector<double> vtra(3);
114 std::vector<double> vrot(9);
115 vtra[0]=(float) 1.0 * (tran.x());
116 vtra[1]=(float) 1.0 * (tran.y());
117 vtra[2]=(float) 1.0 * (tran.z());
118 vrot[0]=(float) 1.0 * x.X();
119 vrot[1]=(float) 1.0 * x.Y();
120 vrot[2]=(float) 1.0 * x.Z();
121 vrot[3]=(float) 1.0 * y.X();
122 vrot[4]=(float) 1.0 * y.Y();
123 vrot[5]=(float) 1.0 * y.Z();
124 vrot[6]=(float) 1.0 * z.X();
125 vrot[7]=(float) 1.0 * z.Y();
126 vrot[8]=(float) 1.0 * z.Z();
127 rgeo.
insert(rpcid.
rawId(),vtra,vrot, pars,strpars);
const std::vector< double > & parameters(void) const
Give the parameters of the solid.
void build(const DDCompactView *cview, const MuonDDDConstants &muonConstants, RecoIdealGeometry &rgeo)
const DDLogicalPart & logicalPart() const
The logical-part of the current node in the filtered-view.
const std::vector< double > & doubles() const
a reference to the double-valued values stored in the given instance of DDValue
void addFilter(const DDFilter &, log_op op=AND)
void buildGeometry(DDFilteredView &fview, const MuonDDDConstants &muonConstants, RecoIdealGeometry &rgeo)
bool nextSibling()
set the current node to the next sibling ...
const DDRotationMatrix & rotation() const
The absolute rotation of the current node.
bool insert(DetId id, const std::vector< double > &trans, const std::vector< double > &rot, const std::vector< double > &pars)
const DDSolid & solid(void) const
Returns a reference object of the solid being the shape of this LogicalPart.
type of data representation of DDCompactView
const DDGeoHistory & geoHistory() const
The list of ancestors up to the root-node of the current node.
bool DDfetch(const DDsvalues_type *, DDValue &)
helper for retrieving DDValues from DDsvalues_type *.
ROOT::Math::DisplacementVector3D< ROOT::Math::Cartesian3D< double > > DDTranslation
uint32_t rawId() const
get the raw id
ROOT::Math::DisplacementVector3D< ROOT::Math::Cartesian3D< double > > DD3Vector
A DD Translation is currently implemented with Root Vector3D.
virtual int baseNumberToUnitNumber(const MuonBaseNumber)
bool firstChild()
set the current node to the first child ...
void setCriteria(const DDValue &nameVal, comp_op, log_op l=AND, bool asString=true, bool merged=true)
const DDTranslation & translation() const
The absolute translation of the current node.
std::vector< const DDsvalues_type * > specifics() const
MuonBaseNumber geoHistoryToBaseNumber(const DDGeoHistory &history)
ROOT::Math::Rotation3D DDRotationMatrix
A DDRotationMatrix is currently implemented with a ROOT Rotation3D.
const std::string & name() const
Returns the name.
The DDGenericFilter is a runtime-parametrized Filter looking on DDSpecifcs.