// File: TDataXtd.cxx // Created: Thu May 29 12:53:57 2008 // Author: Sergey ZARITCHNY // //Copyright: Open CasCade SA 2009 #include #include #include #include #include #include #include #include #include #include #include #include //======================================================================= //function : IDList //purpose : //======================================================================= void TDataXtd::IDList(TDF_IDList& anIDList) { anIDList.Append(TDataXtd_Axis::GetID()); anIDList.Append(TDataXtd_Constraint::GetID()); anIDList.Append(TDataXtd_Geometry::GetID()); anIDList.Append(TDataXtd_PatternStd::GetID()); anIDList.Append(TDataXtd_Placement::GetID()); anIDList.Append(TDataXtd_Point::GetID()); anIDList.Append(TDataXtd_Plane::GetID()); anIDList.Append(TDataXtd_Position::GetID()); anIDList.Append(TDataXtd_Shape::GetID()); } //======================================================================= //function : //purpose : print the name of the constraint //======================================================================= Standard_OStream& TDataXtd::Print(const TDataXtd_ConstraintEnum C, Standard_OStream& s) { switch (C) { //2d planar constraints case TDataXtd_RADIUS : { s << "RADIUS"; break;} case TDataXtd_DIAMETER : { s << "DIAMETER"; break;} case TDataXtd_MINOR_RADIUS : { s << "MINOR_RADIUS"; break;} case TDataXtd_MAJOR_RADIUS : { s << "MAJOR_RADIUS"; break;} case TDataXtd_TANGENT : { s << "TANGENT"; break;} case TDataXtd_PARALLEL : { s << "PARALLEL"; break;} case TDataXtd_PERPENDICULAR : { s << "PERPENDICULAR"; break;} case TDataXtd_CONCENTRIC : { s << "CONCENTRIC"; break;} case TDataXtd_COINCIDENT : { s << "COINCIDENT"; break;} case TDataXtd_DISTANCE : { s << "DISTANCE"; break;} case TDataXtd_ANGLE : { s << "ANGLE"; break;} case TDataXtd_EQUAL_RADIUS : { s << "EQUAL_RADIUS"; break;} case TDataXtd_SYMMETRY : { s << "SYMMETRY"; break;} case TDataXtd_MIDPOINT : { s << "MIDPOINT"; break;} case TDataXtd_EQUAL_DISTANCE : { s << "EQUAL_DISTANCE"; break;} case TDataXtd_FIX : { s << "FIX"; break;} case TDataXtd_RIGID : { s << "RIGID"; break;} // placement constraint case TDataXtd_FROM : { s << "FROM"; break;} case TDataXtd_AXIS : { s << "AXIS"; break;} case TDataXtd_MATE : { s << "MATE"; break;} case TDataXtd_ALIGN_FACES : { s << "ALIGN_FACES"; break;} case TDataXtd_ALIGN_AXES : { s << "ALIGN_AXES"; break;} case TDataXtd_AXES_ANGLE : { s << "AXES_ANGLE"; break;} case TDataXtd_FACES_ANGLE : { s << "FACES_ANGLE"; break;} case TDataXtd_ROUND : { s << "ROUND"; break;} case TDataXtd_OFFSET : { s << "OFFSET"; break;} default : { s << "UNKNOWN"; break; } } return s; } //======================================================================= //function : //purpose : print the name of the real dimension //======================================================================= Standard_OStream& TDataXtd::Print(const TDataXtd_GeometryEnum G, Standard_OStream& s) { switch (G) { case TDataXtd_ANY_GEOM : { s << "ANY_GEOM"; break; } case TDataXtd_POINT : { s << "POINT"; break; } case TDataXtd_LINE : { s << "LINE"; break; } case TDataXtd_CIRCLE : { s << "CIRCLE"; break; } case TDataXtd_ELLIPSE : { s << "ELLIPSE"; break; } case TDataXtd_SPLINE : { s << "SPLINE"; break; } case TDataXtd_PLANE : { s << "PLANE"; break; } case TDataXtd_CYLINDER : { s << "CYLINDER"; break; } default : { s << "UNKNOWN"; break; } } return s; }