#ifdef NG_PYTHON #include <../general/ngpython.hpp> #include #include using namespace netgen; namespace netgen { extern std::shared_ptr ng_geometry; } DLL_HEADER void ExportGeom2d(py::module &m) { py::class_> (m, "SplineGeometry", "a 2d boundary representation geometry model by lines and splines") .def(py::init<>()) .def("__init__", [](SplineGeometry2d *instance, const string & filename) { cout << "load geometry"; ifstream ist(filename); new (instance) SplineGeometry2d(); instance->Load (filename.c_str()); ng_geometry = shared_ptr(instance, NOOP_Deleter); }) .def("Load",&SplineGeometry2d::Load) .def("AppendPoint", FunctionPointer ([](SplineGeometry2d &self, double px, double py, double maxh, double hpref) { Point<2> p; p(0) = px; p(1) = py; GeomPoint<2> gp(p); gp.hmax = maxh; gp.hpref = hpref; self.geompoints.Append(gp); return self.geompoints.Size()-1; }), py::arg("x"), py::arg("y"), py::arg("maxh") = 1e99, py::arg("hpref")=0) .def("Append", FunctionPointer([](SplineGeometry2d &self, py::list segment, int leftdomain, int rightdomain, py::object bc, py::object copy, double maxh, double hpref) { py::extract segtype(segment[0]); SplineSegExt * seg; if (segtype().compare("line") == 0) { py::extract point_index1(segment[1]); py::extract point_index2(segment[2]); //point_index1.check() LineSeg<2> * l = new LineSeg<2>(self.GetPoint(point_index1()), self.GetPoint(point_index2())); seg = new SplineSegExt(*l); } else if (segtype().compare("spline3") == 0) { py::extract point_index1(segment[1]); py::extract point_index2(segment[2]); py::extract point_index3(segment[3]); SplineSeg3<2> * seg3 = new SplineSeg3<2>(self.GetPoint(point_index1()), self.GetPoint(point_index2()), self.GetPoint(point_index3())); seg = new SplineSegExt(*seg3); } else { cout << "Appended segment is not a line or a spline3" << endl; } seg->leftdom = leftdomain; seg->rightdom = rightdomain; seg->hmax = maxh; seg->hpref_left = hpref; seg->hpref_right = hpref; seg->reffak = 1; seg->copyfrom = -1; if (py::extract(copy).check()) seg->copyfrom = py::extract(copy)()+1; if (py::extract(bc).check()) seg->bc = py::extract(bc)(); else if (py::extract(bc).check()) { string bcname = py::extract(bc)(); seg->bc = self.GetNSplines()+1; self.SetBCName(seg->bc, bcname); } else seg->bc = self.GetNSplines()+1; self.AppendSegment(seg); return self.GetNSplines()-1; }), py::arg("point_indices"), py::arg("leftdomain") = 1, py::arg("rightdomain") = py::int_(0), py::arg("bc")=NGDummyArgument(), py::arg("copy")=NGDummyArgument(), py::arg("maxh")=1e99, py::arg("hpref")=0) .def("AppendSegment", FunctionPointer([](SplineGeometry2d &self, py::list point_indices, int leftdomain, int rightdomain) { int npts = py::len(point_indices); SplineSegExt * seg; //int a = py::extract(point_indices[0]); if (npts == 2) { LineSeg<2> * l = new LineSeg<2>(self.GetPoint(py::extract(point_indices[0])()), self.GetPoint(py::extract(point_indices[1])())); seg = new SplineSegExt(*l); } else if (npts == 3) { SplineSeg3<2> * seg3 = new SplineSeg3<2>(self.GetPoint(py::extract(point_indices[0])()), self.GetPoint(py::extract(point_indices[1])()), self.GetPoint(py::extract(point_indices[2])())); seg = new SplineSegExt(*seg3); } seg->leftdom = leftdomain; seg->rightdom = rightdomain; seg->hmax = 1e99; seg->reffak = 1; seg->copyfrom = -1; self.AppendSegment(seg); }), py::arg("point_indices"), py::arg("leftdomain") = 1, py::arg("rightdomain") = py::int_(0)) //.def("AppendSegment", FunctionPointer([](SplineGeometry2d &self, int point_index1, int point_index2)//, int leftdomain, int rightdomain) // { // LineSeg<2> * l = new LineSeg<2>(self.GetPoint(point_index1), self.GetPoint(point_index2)); // SplineSegExt * seg = new SplineSegExt(*l); // seg->leftdom = 1;// leftdomain; // seg->rightdom = 0;// rightdomain; // seg->hmax = 1e99; // seg->reffak = 1; // seg->copyfrom = -1; // self.AppendSegment(seg); // }))//, (py::arg("self"), py::arg("point_index1"), py::arg("point_index2"), py::arg("leftdomain") = 1, py::arg("rightdomain") = 0) ) //.def("AppendSegment", FunctionPointer([](SplineGeometry2d &self, int point_index1, int point_index2, int point_index3)//, int leftdomain, int rightdomain) // { // SplineSeg3<2> * seg3 = new SplineSeg3<2>(self.GetPoint(point_index1), self.GetPoint(point_index2), self.GetPoint(point_index3)); // SplineSegExt * seg = new SplineSegExt(*seg3); // seg->leftdom = 1;// leftdomain; // seg->rightdom = 0;// rightdomain; // seg->hmax = 1e99; // seg->reffak = 1; // seg->copyfrom = -1; // self.AppendSegment(seg); // }))//, (py::arg("self"), py::arg("point_index1"), py::arg("point_index2"), py::arg("point_index3"), py::arg("leftdomain") = 1, py::arg("rightdomain") = 0 ) ) .def("SetMaterial", &SplineGeometry2d::SetMaterial) .def("SetDomainMaxH", &SplineGeometry2d::SetDomainMaxh) .def("PlotData", FunctionPointer([](SplineGeometry2d &self) { Box<2> box(self.GetBoundingBox()); double xdist = box.PMax()(0) - box.PMin()(0); double ydist = box.PMax()(1) - box.PMin()(1); py::tuple xlim = py::make_tuple(box.PMin()(0) - 0.1*xdist, box.PMax()(0) + 0.1*xdist); py::tuple ylim = py::make_tuple(box.PMin()(1) - 0.1*ydist, box.PMax()(1) + 0.1*ydist); py::list xpoints, ypoints; for (int i = 0; i < self.splines.Size(); i++) { py::list xp, yp; if (self.splines[i]->GetType().compare("line")==0) { GeomPoint<2> p1 = self.splines[i]->StartPI(); GeomPoint<2> p2 = self.splines[i]->EndPI(); xp.append(py::cast(p1(0))); xp.append(py::cast(p2(0))); yp.append(py::cast(p1(1))); yp.append(py::cast(p2(1))); } else if (self.splines[i]->GetType().compare("spline3")==0) { double len = self.splines[i]->Length(); int n = floor(len/(0.05*min(xdist,ydist))); for (int j = 0; j <= n; j++) { GeomPoint<2> point = self.splines[i]->GetPoint(j*1./n); xp.append(py::cast(point(0))); yp.append(py::cast(point(1))); } } else { cout << "spline is neither line nor spline3" << endl; } xpoints.append(xp); ypoints.append(yp); } return py::tuple(py::make_tuple(xlim, ylim, xpoints, ypoints)); })) .def("_visualizationData", [](SplineGeometry2d &self) { Box<2> box(self.GetBoundingBox()); double xdist = box.PMax()(0) - box.PMin()(0); double ydist = box.PMax()(1) - box.PMin()(1); py::dict data; py::dict segment_data; auto min_val = py::make_tuple(box.PMin()(0), box.PMin()(1),0); auto max_val = py::make_tuple(box.PMax()(1),box.PMax()(1),0); py::list vertices; py::list domains; py::list segment_points; py::list segment_normals; py::list leftdom; py::list rightdom; int max_bcnr = 0; for(int i = 0; i < self.splines.Size(); i++) { std::vector> lst; if (self.splines[i]->GetType().compare("line") == 0) lst = { self.splines[i]->StartPI(), self.splines[i]->EndPI() }; else if(self.splines[i]->GetType().compare("spline3") == 0) { double len = self.splines[i]->Length(); int n = floor(len/(0.05*min(xdist,ydist))); lst.push_back(self.splines[i]->StartPI()); for (int j = 1; j < n; j++){ lst.push_back(self.splines[i]->GetPoint(j*1./n)); lst.push_back(self.splines[i]->GetPoint(j*1./n)); } lst.push_back(self.splines[i]->EndPI()); } else { throw NgException("Spline is neither line nor spline3"); } for (auto point : lst) { for(auto val : {point(0), point(1), 0.}) vertices.append(val); int bcnr = self.GetSpline(i).bc; max_bcnr = max2(max_bcnr, bcnr); domains.append(bcnr); domains.append(self.GetSpline(i).leftdom); domains.append(self.GetSpline(i).rightdom); } // segment data auto pnt = self.splines[i]->GetPoint(0.5); segment_points.append(py::make_tuple(pnt(0),pnt(1))); auto normal = self.GetSpline(i).GetTangent(0.5); std::swap(normal(0),normal(1)); normal(1) *= -1; normal *= 1./sqrt(normal(0) * normal(0) + normal(1)*normal(1)); segment_normals.append(py::make_tuple(normal(0),normal(1))); leftdom.append(self.GetSpline(i).leftdom); rightdom.append(self.GetSpline(i).rightdom); } py::list bcnames; for (int i = 1; i point = self.splines[i]->GetPoint(0.5); Vec<2> normal = self.GetSpline(i).GetTangent(0.5); double temp = normal(0); normal(0) = normal(1); normal(1) = -temp; leftdom.append(py::cast(self.GetSpline(i).leftdom)); rightdom.append(py::cast(self.GetSpline(i).rightdom)); rightpoints.append(py::make_tuple(point(0), point(1), normal(0)<0, normal(1)<0)); leftpoints.append(py::make_tuple(point(0), point(1), normal(0)<0, normal(1)<0)); } return py::tuple(py::make_tuple(leftpoints, rightpoints, leftdom, rightdom)); })) .def("Print", FunctionPointer([](SplineGeometry2d &self) { for (int i = 0; i < self.geompoints.Size(); i++) { cout << i << " : " << self.geompoints[i][0] << " , " << self.geompoints[i][1] << endl; } //Box<2> box(self.GetBoundingBox()); //cout << box.PMin() << endl; //cout << box.PMax() << endl; cout << self.splines.Size() << endl; for (int i = 0; i < self.splines.Size(); i++) { cout << self.splines[i]->GetType() << endl; //cout << i << " : " << self.splines[i]->GetPoint(0.1) << " , " << self.splines[i]->GetPoint(0.5) << endl; } })) .def("GenerateMesh", [](shared_ptr self, MeshingParameters & mparam) { shared_ptr mesh = make_shared (); mesh->SetGeometry(self); SetGlobalMesh (mesh); ng_geometry = self; self->GenerateMesh(mesh, mparam); return mesh; },py::call_guard()) ; } PYBIND11_MODULE(libgeom2d, m) { ExportGeom2d(m); } #endif