#ifdef NG_PYTHON #ifdef OCCGEOMETRY #include #include #include #include #include "occgeom.hpp" #include #include #include #include #include #include #include #include using namespace netgen; DLL_HEADER void ExportNgOCCBasic(py::module &m) { py::class_(m, "gp_Pnt", "3d OCC point") .def(py::init([] (py::tuple pnt) { if (py::len(pnt) != 3) throw std::length_error("need 3-tuple to create gp_Pnt"); return gp_Pnt(py::cast(pnt[0]), py::cast(pnt[1]), py::cast(pnt[2])); })) .def(py::init([] (double x, double y, double z) { return gp_Pnt(x, y, z); }), py::arg("x"), py::arg("y"), py::arg("z")) .def_property("x", [](gp_Pnt&p) { return p.X(); }, [](gp_Pnt&p,double x) { p.SetX(x); }) .def_property("y", [](gp_Pnt&p) { return p.Y(); }, [](gp_Pnt&p,double y) { p.SetY(y); }) .def_property("z", [](gp_Pnt&p) { return p.Z(); }, [](gp_Pnt&p,double z) { p.SetZ(z); }) .def("__str__", [] (const gp_Pnt & p) { stringstream str; str << "(" << p.X() << ", " << p.Y() << ", " << p.Z() << ")"; return str.str(); }) .def("__repr__", [] (const gp_Pnt & p) { stringstream str; str << "(" << p.X() << ", " << p.Y() << ", " << p.Z() << ")"; return str.str(); }) .def("__sub__", [](gp_Pnt p1, gp_Pnt p2) { return gp_Vec(p2, p1); }) .def("__add__", [](gp_Pnt p, gp_Vec v) { return p.Translated(v); }) // gp_Pnt(p.X()+v.X(), p.Y()+v.Y(), p.Z()+v.Z()); }) .def("__sub__", [](gp_Pnt p, gp_Vec v) { return p.Translated(-v); }) // gp_Pnt(p.X()-v.X(), p.Y()-v.Y(), p.Z()-v.Z()); }) .def("__getitem__", [](const gp_Pnt& p, int index) { if(index == 0) return p.X(); if(index == 1) return p.Y(); if(index == 2) return p.Z(); throw std::out_of_range("Point index must be in range [0,3)!"); }) ; py::class_(m, "gp_Vec", "3d OCC vector") .def(py::init([] (py::tuple vec) { return gp_Vec(py::cast(vec[0]), py::cast(vec[1]), py::cast(vec[2])); })) .def(py::init([] (double x, double y, double z) { return gp_Vec(x, y, z); }), py::arg("x"), py::arg("y"), py::arg("z")) .def(py::init([](gp_Dir d) { return gp_Vec(d); })) .def_property("x", [](gp_Vec&p) { return p.X(); }, [](gp_Vec&p,double x) { p.SetX(x); }) .def_property("y", [](gp_Vec&p) { return p.Y(); }, [](gp_Vec&p,double y) { p.SetY(y); }) .def_property("z", [](gp_Vec&p) { return p.Z(); }, [](gp_Vec&p,double z) { p.SetZ(z); }) .def("Norm", [](const gp_Vec& v) { return v.Magnitude(); }) .def("__str__", [] (const gp_Vec & p) { stringstream str; str << "(" << p.X() << ", " << p.Y() << ", " << p.Z() << ")"; return str.str(); }) .def("__repr__", [] (const gp_Vec & p) { stringstream str; str << "(" << p.X() << ", " << p.Y() << ", " << p.Z() << ")"; return str.str(); }) .def("__add__", [](gp_Vec v1, gp_Vec v2) { return v1+v2; }) .def("__sub__", [](gp_Vec v1, gp_Vec v2) { return v1-v2; }) .def("__rmul__", [](gp_Vec v, double s) { return s*v; }) .def("__mul__", [](gp_Vec v1, gp_Vec v2) { return v1*v2; }) .def("__neg__", [](gp_Vec v) { return -v; }) .def("__xor__", [](gp_Vec v1, gp_Vec v2) { return v1^v2; }) .def("__lt__", [](gp_Vec v, double val) { cout << IM(6) << "vec, lt v - " << netgen::occ2ng(v) << ", val = " << val << endl; return DirectionalInterval(v) < val; }) .def("__gt__", [](gp_Vec v, double val) { cout << IM(6) << "vec, gt v - " << netgen::occ2ng(v) << ", val = " << val << endl; return DirectionalInterval(v) > val; }) .def("__le__", [](gp_Vec v, double val) { return DirectionalInterval(v) <= val; }) .def("__ge__", [](gp_Vec v, double val) { return DirectionalInterval(v) >= val; }) ; py::class_(m, "gp_Dir", "3d OCC direction") .def(py::init([] (py::tuple dir) { return gp_Dir(py::cast(dir[0]), py::cast(dir[1]), py::cast(dir[2])); })) .def(py::init([] (double x, double y, double z) { return gp_Dir(x, y, z); }), py::arg("x"), py::arg("y"), py::arg("z")) .def(py::init()) .def("__str__", [] (const gp_Dir & p) { stringstream str; str << "(" << p.X() << ", " << p.Y() << ", " << p.Z() << ")"; return str.str(); }) ; py::class_(m, "gp_Mat", "3d OCC matrix") .def("__getitem__", [](const gp_Mat& mat, tuple index) { return mat.Row(get<0>(index)+1).Coord(get<1>(index)+1); }) ; py::class_(m, "Axis", "an OCC axis in 3d") .def(py::init([](gp_Pnt p, gp_Dir d) { return gp_Ax1(p,d); }), py::arg("p"), py::arg("d")) ; py::class_(m, "gp_Ax2") .def(py::init([](gp_Pnt p, gp_Dir d) { return gp_Ax2(p,d); })) .def(py::init([](const gp_Ax3 & ax3) { return gp_Ax2(ax3.Ax2()); })) ; py::class_(m, "Axes", "an OCC coordinate system in 3d") .def(py::init([](gp_Pnt p, gp_Dir N, gp_Dir Vx) { return gp_Ax3(p,N, Vx); }), py::arg("p")=gp_Pnt(0,0,0), py::arg("n")=gp_Vec(0,0,1), py::arg("h")=gp_Vec(1,0,0)) .def(py::init([](gp_Ax1 ax1) { return gp_Ax3(ax1.Location(), ax1.Direction()); }), py::arg("axis")) .def(py::init()) .def_property("p", [](gp_Ax3 & ax) { return ax.Location(); }, [](gp_Ax3&ax, gp_Pnt p) { ax.SetLocation(p); }) ; py::class_(m, "gp_Pnt2d", "2d OCC point") .def(py::init([] (std::tuple pnt) { return gp_Pnt2d(get<0>(pnt), get<1>(pnt)); })) .def(py::init([] (double x, double y) { return gp_Pnt2d(x, y); }), py::arg("x"), py::arg("y")) .def_property("x", [](gp_Pnt2d&p) { return p.X(); }, [](gp_Pnt2d&p,double x) { p.SetX(x); }) .def_property("y", [](gp_Pnt2d&p) { return p.Y(); }, [](gp_Pnt2d&p,double y) { p.SetY(y); }) .def("__str__", [] (const gp_Pnt2d & p) { stringstream str; str << "(" << p.X() << ", " << p.Y() << ")"; return str.str(); }) .def("__repr__", [] (const gp_Pnt2d & p) { stringstream str; str << "(" << p.X() << ", " << p.Y() << ")"; return str.str(); }) .def("__sub__", [](gp_Pnt2d p1, gp_Pnt2d p2) { return gp_Vec2d(p1.X()-p2.X(), p1.Y()-p2.Y()); }) .def("__add__", [](gp_Pnt2d p, gp_Vec2d v) { return p.Translated(v); }) .def("__sub__", [](gp_Pnt2d p, gp_Vec2d v) { return p.Translated(-v); }) ; py::class_(m, "gp_Vec2d", "2d OCC vector") .def(py::init([] (py::tuple vec) { if (py::len(vec) != 2) throw Exception("need 2-tuple to create gp_Vec2d"); return gp_Vec2d(py::cast(vec[0]), py::cast(vec[1])); })) .def(py::init([] (double x, double y) { return gp_Vec2d(x, y); }), py::arg("x"), py::arg("y")) .def_property("x", [](gp_Vec2d&p) { return p.X(); }, [](gp_Vec2d&p,double x) { p.SetX(x); }) .def_property("y", [](gp_Vec2d&p) { return p.Y(); }, [](gp_Vec2d&p,double y) { p.SetY(y); }) .def("__str__", [] (const gp_Vec & p) { stringstream str; str << "(" << p.X() << ", " << p.Y() << ")"; return str.str(); }) .def("__repr__", [] (const gp_Vec & p) { stringstream str; str << "(" << p.X() << ", " << p.Y() << ")"; return str.str(); }) .def("__add__", [](gp_Vec2d v1, gp_Vec2d v2) { return v1+v2; }) .def("__sub__", [](gp_Vec2d v1, gp_Vec2d v2) { return v1-v2; }) .def("__rmul__", [](gp_Vec2d v, double s) { return s*v; }) .def("__neg__", [](gp_Vec2d v) { return -v; }) .def("__xor__", [](gp_Vec2d v1, gp_Vec2d v2) { return v1^v2; }) ; py::class_(m, "gp_Dir2d", "2d OCC direction") .def(py::init([] (py::tuple dir) { if (py::len(dir) != 2) throw Exception("need 2-tuple to create gp_Dir2d"); return gp_Dir2d(py::cast(dir[0]), py::cast(dir[1])); })) .def(py::init([] (double x, double y) { return gp_Dir2d(x, y); }), py::arg("x"), py::arg("y")) ; m.def("Pnt", [](double x, double y) { return gp_Pnt2d(x,y); }, py::arg("x"), py::arg("y"), "create 2d OCC point"); m.def("Pnt", [](double x, double y, double z) { return gp_Pnt(x,y,z); }, py::arg("x"), py::arg("y"), py::arg("z"), "create 3d OCC point"); m.def("Pnt", [](std::vector p) { if (p.size() == 2) return py::cast(gp_Pnt2d(p[0], p[1])); if (p.size() == 3) return py::cast(gp_Pnt(p[0], p[1], p[2])); throw Exception("OCC-Points only in 2D or 3D"); }, py::arg("p"), "create 2d or 3d OCC point"); m.def("Vec", [](double x, double y) { return gp_Vec2d(x,y); }, py::arg("x"), py::arg("y"), "create 2d OCC point"); m.def("Vec", [](double x, double y, double z) { return gp_Vec(x,y,z); }, py::arg("x"), py::arg("y"), py::arg("z"), "create 3d OCC point"); m.def("Vec", [](std::vector p) { if (p.size() == 2) return py::cast(gp_Vec2d(p[0], p[1])); if (p.size() == 3) return py::cast(gp_Vec(p[0], p[1], p[2])); throw Exception("OCC-Vecs only in 2D or 3D"); }, py::arg("v"), "create 2d or 3d OCC vector"); m.def("Dir", [](double x, double y) { return gp_Dir2d(x,y); }, py::arg("x"), py::arg("y"), "create 2d OCC direction"); m.def("Dir", [](double x, double y, double z) { return gp_Dir(x,y,z); }, py::arg("x"), py::arg("y"), py::arg("z"), "create 3d OCC direction"); m.def("Dir", [](std::vector p) { if (p.size() == 2) return py::cast(gp_Dir2d(p[0], p[1])); if (p.size() == 3) return py::cast(gp_Dir(p[0], p[1], p[2])); throw Exception("OCC-Dirs only in 2D or 3D"); }, py::arg("d"), "create 2d or 3d OCC direction"); py::class_(m, "gp_Ax2d", "2d OCC coordinate system") .def(py::init([](gp_Pnt2d p, gp_Dir2d d) { return gp_Ax2d(p,d); }), py::arg("p")=gp_Pnt2d(0,0), py::arg("d")=gp_Dir2d(1,0)) ; py::class_(m, "gp_GTrsf") .def(py::init([](const std::vector& mat, const std::vector& vec) { if(mat.size() != 9) throw Exception("Need 9 matrix values for construction of gp_GTrsf"); if(vec.size() != 3) throw Exception("Need 3 vector values for construction of gp_GTrsf"); gp_GTrsf trafo; trafo.SetVectorialPart({ mat[0], mat[1], mat[2], mat[3], mat[4], mat[5], mat[6], mat[7], mat[8] }); trafo.SetTranslationPart( { vec[0], vec[1], vec[2] }); return trafo; }), py::arg("mat"), py::arg("vec") = std::vector{ 0., 0., 0. }) .def("__call__", [] (gp_GTrsf & trafo, const TopoDS_Shape & shape) { BRepBuilderAPI_GTransform builder(shape, trafo, true); PropagateProperties(builder, shape, occ2ng(trafo)); return builder.Shape(); }) ; py::class_(m, "gp_Trsf") .def(py::init<>()) .def("SetMirror", [] (gp_Trsf & trafo, const gp_Ax1 & ax) { trafo.SetMirror(ax); return trafo; }) .def("Inverted", &gp_Trsf::Inverted) .def_static("Translation", [] (const gp_Vec & v) { gp_Trsf trafo; trafo.SetTranslation(v); return trafo; }) .def_static("Scale", [] (const gp_Pnt & p, double s) { gp_Trsf trafo; trafo.SetScale(p,s); return trafo; }) .def_static("Mirror", [] (const gp_Ax1 & ax) { gp_Trsf trafo; trafo.SetMirror(ax); return trafo; }) .def_static("Rotation", [] (const gp_Ax1 & ax, double ang) { gp_Trsf trafo; trafo.SetRotation(ax, ang*M_PI/180); return trafo; }) .def_static("Rotation", [] (const gp_Pnt & p, const gp_Dir & d, double ang) { gp_Trsf trafo; trafo.SetRotation(gp_Ax1(p,d), ang*M_PI/180); return trafo; }) .def_static("Transformation", [] (const gp_Ax3 & ax) { gp_Trsf trafo; trafo.SetTransformation(ax); return trafo; }) .def_static("Transformation", [] (const gp_Ax3 & from, const gp_Ax3 to) { gp_Trsf trafo; trafo.SetTransformation(from, to); return trafo; }) .def(py::self * py::self) .def("__call__", [] (gp_Trsf & trafo, const TopoDS_Shape & shape) { BRepBuilderAPI_Transform builder(shape, trafo, true); PropagateProperties(builder, shape, occ2ng(trafo)); return builder.Shape(); }) .def("__str__", [](gp_Trsf & trafo) { stringstream str; gp_XYZ xyz = trafo.TranslationPart(); str << xyz.X() << ", " << xyz.Y() << ", " << xyz.Z(); return str.str(); }) ; py::class_(m, "TopLoc_Location") .def(py::init()) .def("Transformation", [](const TopLoc_Location & loc) { return loc.Transformation(); }) ; py::class_ (m, "DirectionalInterval") .def("__str__", [](DirectionalInterval self) { stringstream str; str << "(" << self.minval << ", " << self.maxval << ")"; return str.str(); }) .def("__lt__", [](DirectionalInterval i, double val) { cout << "directionalinterval, lt, imin/max = " << i.minval << " / " << i.maxval << endl; return i < val; }) .def("__gt__", [](DirectionalInterval i, double val) { cout << "directionalinterval, gt, imin/max = " << i.minval << " / " << i.maxval << endl; return i > val; }) .def("__and__", [](DirectionalInterval self, DirectionalInterval other) { cout << "and of intervals" << endl; return self.Intersect(other); }) ; py::implicitly_convertible(); py::implicitly_convertible(); py::implicitly_convertible(); py::implicitly_convertible(); py::implicitly_convertible(); py::implicitly_convertible(); py::implicitly_convertible(); py::implicitly_convertible(); py::implicitly_convertible(); py::implicitly_convertible(); py::implicitly_convertible(); m.attr("X") = py::cast(gp_Vec(1,0,0)); m.attr("Y") = py::cast(gp_Vec(0,1,0)); m.attr("Z") = py::cast(gp_Vec(0,0,1)); } #endif // OCCGEOMETRY #endif // NG_PYTHON