/*************************************************************************** * Copyright (c) 2016 Werner Mayer * * * * This file is part of the FreeCAD CAx development system. * * * * This library is free software; you can redistribute it and/or * * modify it under the terms of the GNU Library General Public * * License as published by the Free Software Foundation; either * * version 2 of the License, or (at your option) any later version. * * * * This library is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU Library General Public License for more details. * * * * You should have received a copy of the GNU Library General Public * * License along with this library; see the file COPYING.LIB. If not, * * write to the Free Software Foundation, Inc., 59 Temple Place, * * Suite 330, Boston, MA 02111-1307, USA * * * ***************************************************************************/ #include "PreCompiled.h" #ifndef _PreComp_ # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include # include #endif #include #include #include "Geom2d/Curve2dPy.h" #include "Geom2d/Curve2dPy.cpp" #include "Geom2d/BSplineCurve2dPy.h" #include "GeometrySurfacePy.h" #include "OCCError.h" #include "TopoShapeFacePy.h" namespace Part { extern const Py::Object makeGeometryCurvePy(const Handle(Geom_Curve)& c); } using namespace Part; // returns a string which represents the object e.g. when printed in python std::string Curve2dPy::representation() const { return ""; } PyObject *Curve2dPy::PyMake(struct _typeobject *, PyObject *, PyObject *) // Python wrapper { // never create such objects with the constructor PyErr_SetString(PyExc_RuntimeError, "You cannot create an instance of the abstract class 'Curve2d'."); return nullptr; } // constructor method int Curve2dPy::PyInit(PyObject* /*args*/, PyObject* /*kwd*/) { return 0; } PyObject* Curve2dPy::reverse(PyObject * args) { if (PyArg_ParseTuple(args, "")) { try { Handle(Geom2d_Curve) curve = Handle(Geom2d_Curve)::DownCast(getGeom2dCurvePtr()->handle()); curve->Reverse(); Py_Return; } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } } return nullptr; } namespace Part { extern Py::Object shape2pyshape(const TopoDS_Shape &shape); void create3dCurve(const TopoDS_Edge& edge) { TopoDS_Edge edge3d; BRepAdaptor_Curve adapt_curve(edge); switch(adapt_curve.GetType()) { case GeomAbs_Line: { BRepBuilderAPI_MakeEdge mkBuilder3d(adapt_curve.Line(), adapt_curve.FirstParameter(), adapt_curve.LastParameter()); edge3d = mkBuilder3d.Edge(); } break; case GeomAbs_Circle: { BRepBuilderAPI_MakeEdge mkBuilder3d(adapt_curve.Circle(), adapt_curve.FirstParameter(), adapt_curve.LastParameter()); edge3d = mkBuilder3d.Edge(); } break; case GeomAbs_Ellipse: { BRepBuilderAPI_MakeEdge mkBuilder3d(adapt_curve.Ellipse(), adapt_curve.FirstParameter(), adapt_curve.LastParameter()); edge3d = mkBuilder3d.Edge(); } break; case GeomAbs_Hyperbola: { BRepBuilderAPI_MakeEdge mkBuilder3d(adapt_curve.Hyperbola(), adapt_curve.FirstParameter(), adapt_curve.LastParameter()); edge3d = mkBuilder3d.Edge(); } break; case GeomAbs_Parabola: { BRepBuilderAPI_MakeEdge mkBuilder3d(adapt_curve.Parabola(), adapt_curve.FirstParameter(), adapt_curve.LastParameter()); edge3d = mkBuilder3d.Edge(); } break; case GeomAbs_BezierCurve: { BRepBuilderAPI_MakeEdge mkBuilder3d(adapt_curve.Bezier(), adapt_curve.FirstParameter(), adapt_curve.LastParameter()); edge3d = mkBuilder3d.Edge(); } break; default: edge3d = edge; BRepLib::BuildCurves3d(edge3d, Precision::Confusion(), GeomAbs_Shape::GeomAbs_C1, 14, 10000); break; } Standard_Real aFirst, aLast; Handle(Geom_Curve) curve = BRep_Tool::Curve(edge3d, aFirst, aLast); BRep_Builder builder; builder.UpdateEdge(edge, curve, Precision::Confusion()); builder.Range(edge, aFirst, aLast, true); return; } } PyObject* Curve2dPy::toShape(PyObject *args) { if (PyArg_ParseTuple(args, "")) { try { Handle(Geom2d_Curve) curv = Handle(Geom2d_Curve)::DownCast(getGeometry2dPtr()->handle()); BRepBuilderAPI_MakeEdge2d mkBuilder(curv); TopoDS_Shape edge = mkBuilder.Shape(); return Py::new_reference_to(shape2pyshape(edge)); } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } } PyErr_Clear(); double u1, u2; if (PyArg_ParseTuple(args, "dd", &u1, &u2)) { try { Handle(Geom2d_Curve) curv = Handle(Geom2d_Curve)::DownCast(getGeometry2dPtr()->handle()); BRepBuilderAPI_MakeEdge2d mkBuilder(curv, u1, u2); TopoDS_Shape edge = mkBuilder.Shape(); return Py::new_reference_to(shape2pyshape(edge)); } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } } PyErr_Clear(); PyObject* p; if (PyArg_ParseTuple(args, "O!", &(Part::GeometrySurfacePy::Type), &p)) { try { Handle(Geom_Surface) surf = Handle(Geom_Surface)::DownCast( static_cast(p)->getGeomSurfacePtr()->handle()); Handle(Geom2d_Curve) curv = Handle(Geom2d_Curve)::DownCast(getGeometry2dPtr()->handle()); BRepBuilderAPI_MakeEdge mkBuilder(curv, surf); TopoDS_Edge edge = mkBuilder.Edge(); create3dCurve(edge); return Py::new_reference_to(shape2pyshape(edge)); } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } } PyErr_Clear(); if (PyArg_ParseTuple(args, "O!dd", &(Part::GeometrySurfacePy::Type), &p, &u1, &u2)) { try { Handle(Geom_Surface) surf = Handle(Geom_Surface)::DownCast( static_cast(p)->getGeomSurfacePtr()->handle()); Handle(Geom2d_Curve) curv = Handle(Geom2d_Curve)::DownCast(getGeometry2dPtr()->handle()); BRepBuilderAPI_MakeEdge mkBuilder(curv, surf, u1, u2); TopoDS_Edge edge = mkBuilder.Edge(); create3dCurve(edge); return Py::new_reference_to(shape2pyshape(edge)); } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } } PyErr_Clear(); if (PyArg_ParseTuple(args, "O!", &(Part::TopoShapeFacePy::Type), &p)) { try { const TopoDS_Face& face = TopoDS::Face(static_cast(p)->getTopoShapePtr()->getShape()); Handle(Geom2d_Curve) curv = Handle(Geom2d_Curve)::DownCast(getGeometry2dPtr()->handle()); BRepAdaptor_Surface adapt(face); BRepBuilderAPI_MakeEdge mkBuilder(curv, adapt.Surface().Surface()); TopoDS_Edge edge = mkBuilder.Edge(); create3dCurve(edge); return Py::new_reference_to(shape2pyshape(edge)); } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } } PyErr_Clear(); if (PyArg_ParseTuple(args, "O!dd", &(Part::TopoShapeFacePy::Type), &p, &u1, &u2)) { try { const TopoDS_Face& face = TopoDS::Face(static_cast(p)->getTopoShapePtr()->getShape()); Handle(Geom2d_Curve) curv = Handle(Geom2d_Curve)::DownCast(getGeometry2dPtr()->handle()); BRepAdaptor_Surface adapt(face); BRepBuilderAPI_MakeEdge mkBuilder(curv, adapt.Surface().Surface(), u1, u2); TopoDS_Edge edge = mkBuilder.Edge(); create3dCurve(edge); return Py::new_reference_to(shape2pyshape(edge)); } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } } PyErr_SetString(PyExc_TypeError, "empty parameter list, parameter range or surface expected"); return nullptr; } PyObject* Curve2dPy::discretize(PyObject *args, PyObject *kwds) { try { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); if (c.IsNull()) { PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } Geom2dAdaptor_Curve adapt(c); double first = adapt.FirstParameter(); double last = adapt.LastParameter(); // use Number kwds static const std::array kwds_numPoints {"Number", "First", "Last", nullptr}; PyErr_Clear(); int numPoints = -1; if (Base::Wrapped_ParseTupleAndKeywords(args, kwds, "i|dd", kwds_numPoints, &numPoints, &first, &last)) { GCPnts_UniformAbscissa discretizer; discretizer.Initialize (adapt, numPoints, first, last); if (discretizer.IsDone () && discretizer.NbPoints () > 0) { Py::List points; int nbPoints = discretizer.NbPoints (); for (int i=1; i<=nbPoints; i++) { gp_Pnt2d p = adapt.Value (discretizer.Parameter (i)); points.append(Base::Vector2dPy::create(p.X(), p.Y())); } return Py::new_reference_to(points); } else { PyErr_SetString(PartExceptionOCCError, "Discretization of curve failed"); return nullptr; } } // use Distance kwds static const std::array kwds_Distance{"Distance", "First", "Last", nullptr}; PyErr_Clear(); double distance = -1; if (Base::Wrapped_ParseTupleAndKeywords(args, kwds, "d|dd", kwds_Distance, &distance, &first, &last)) { GCPnts_UniformAbscissa discretizer; discretizer.Initialize (adapt, distance, first, last); if (discretizer.IsDone () && discretizer.NbPoints () > 0) { Py::List points; int nbPoints = discretizer.NbPoints (); for (int i=1; i<=nbPoints; i++) { gp_Pnt2d p = adapt.Value (discretizer.Parameter (i)); points.append(Base::Vector2dPy::create(p.X(), p.Y())); } return Py::new_reference_to(points); } else { PyErr_SetString(PartExceptionOCCError, "Discretization of curve failed"); return nullptr; } } // use Deflection kwds static const std::array kwds_Deflection{"Deflection", "First", "Last", nullptr}; PyErr_Clear(); double deflection; if (Base::Wrapped_ParseTupleAndKeywords(args, kwds, "d|dd", kwds_Deflection, &deflection, &first, &last)) { GCPnts_UniformDeflection discretizer(adapt, deflection, first, last); if (discretizer.IsDone () && discretizer.NbPoints () > 0) { Py::List points; int nbPoints = discretizer.NbPoints (); for (int i=1; i<=nbPoints; i++) { gp_Pnt p = discretizer.Value (i); points.append(Base::Vector2dPy::create(p.X(), p.Y())); } return Py::new_reference_to(points); } else { PyErr_SetString(PartExceptionOCCError, "Discretization of curve failed"); return nullptr; } } // use TangentialDeflection kwds static const std::array kwds_TangentialDeflection{"Angular", "Curvature", "First", "Last", "Minimum", nullptr}; PyErr_Clear(); double angular; double curvature; int minimumPoints = 2; if (Base::Wrapped_ParseTupleAndKeywords(args, kwds, "dd|ddi", kwds_TangentialDeflection, &angular, &curvature, &first, &last, &minimumPoints)) { GCPnts_TangentialDeflection discretizer(adapt, first, last, angular, curvature, minimumPoints); if (discretizer.NbPoints () > 0) { Py::List points; int nbPoints = discretizer.NbPoints (); for (int i=1; i<=nbPoints; i++) { gp_Pnt p = discretizer.Value (i); points.append(Base::Vector2dPy::create(p.X(), p.Y())); } return Py::new_reference_to(points); } else { PyErr_SetString(PartExceptionOCCError, "Discretization of curve failed"); return nullptr; } } // use QuasiNumber kwds static const std::array kwds_QuasiNumPoints{"QuasiNumber", "First", "Last", nullptr}; PyErr_Clear(); int quasiNumPoints; if (Base::Wrapped_ParseTupleAndKeywords(args, kwds, "i|dd", kwds_QuasiNumPoints, &quasiNumPoints, &first, &last)) { GCPnts_QuasiUniformAbscissa discretizer(adapt, quasiNumPoints, first, last); if (discretizer.NbPoints () > 0) { Py::List points; int nbPoints = discretizer.NbPoints (); for (int i=1; i<=nbPoints; i++) { gp_Pnt2d p = adapt.Value (discretizer.Parameter (i)); points.append(Base::Vector2dPy::create(p.X(), p.Y())); } return Py::new_reference_to(points); } else { PyErr_SetString(PartExceptionOCCError, "Discretization of curve failed"); return nullptr; } } // use QuasiDeflection kwds static const std::array kwds_QuasiDeflection {"QuasiDeflection","First","Last",nullptr}; PyErr_Clear(); double quasiDeflection; if (Base::Wrapped_ParseTupleAndKeywords(args, kwds, "d|dd", kwds_QuasiDeflection, &quasiDeflection, &first, &last)) { GCPnts_QuasiUniformDeflection discretizer(adapt, quasiDeflection, first, last); if (discretizer.NbPoints () > 0) { Py::List points; int nbPoints = discretizer.NbPoints (); for (int i=1; i<=nbPoints; i++) { gp_Pnt p = discretizer.Value (i); points.append(Base::Vector2dPy::create(p.X(), p.Y())); } return Py::new_reference_to(points); } else { PyErr_SetString(PartExceptionOCCError, "Discretization of curve failed"); return nullptr; } } } catch (const Base::Exception& e) { PyErr_SetString(PartExceptionOCCError, e.what()); return nullptr; } PyErr_SetString(PartExceptionOCCError,"Wrong arguments"); return nullptr; } PyObject* Curve2dPy::length(PyObject *args) { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); try { if (!c.IsNull()) { double u=c->FirstParameter(); double v=c->LastParameter(); double t=Precision::Confusion(); if (!PyArg_ParseTuple(args, "|ddd", &u,&v,&t)) return nullptr; Geom2dAdaptor_Curve adapt(c); double len = GCPnts_AbscissaPoint::Length(adapt,u,v,t); return PyFloat_FromDouble(len); } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } PyObject* Curve2dPy::parameterAtDistance(PyObject *args) { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); try { if (!c.IsNull()) { double abscissa; double u = 0; if (!PyArg_ParseTuple(args, "d|d", &abscissa,&u)) return nullptr; Geom2dAdaptor_Curve adapt(c); GCPnts_AbscissaPoint abscissaPoint(adapt,abscissa,u); double parm = abscissaPoint.Parameter(); return PyFloat_FromDouble(parm); } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } PyObject* Curve2dPy::value(PyObject *args) { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); try { if (!c.IsNull()) { double u; if (!PyArg_ParseTuple(args, "d", &u)) return nullptr; gp_Pnt2d p = c->Value(u); return Py::new_reference_to(Base::Vector2dPy::create(p.X(), p.Y())); } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } PyObject* Curve2dPy::tangent(PyObject *args) { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); try { if (!c.IsNull()) { double u; if (!PyArg_ParseTuple(args, "d", &u)) return nullptr; gp_Dir2d dir; Geom2dLProp_CLProps2d prop(c,u,2,Precision::Confusion()); if (prop.IsTangentDefined()) { prop.Tangent(dir); } return Py::new_reference_to(Base::Vector2dPy::create(dir.X(), dir.Y())); } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } PyObject* Curve2dPy::normal(PyObject *args) { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); try { if (!c.IsNull()) { double u; if (!PyArg_ParseTuple(args, "d", &u)) return nullptr; gp_Dir2d dir; Geom2dLProp_CLProps2d prop(c,u,2,Precision::Confusion()); prop.Normal(dir); return Py::new_reference_to(Base::Vector2dPy::create(dir.X(), dir.Y())); } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } PyObject* Curve2dPy::curvature(PyObject *args) { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); try { if (!c.IsNull()) { double u; if (!PyArg_ParseTuple(args, "d", &u)) return nullptr; Geom2dLProp_CLProps2d prop(c,u,2,Precision::Confusion()); double C = prop.Curvature(); return Py::new_reference_to(Py::Float(C)); } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } PyObject* Curve2dPy::centerOfCurvature(PyObject *args) { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); try { if (!c.IsNull()) { double u; if (!PyArg_ParseTuple(args, "d", &u)) return nullptr; Geom2dLProp_CLProps2d prop(c,u,2,Precision::Confusion()); gp_Pnt2d pnt ; prop.CentreOfCurvature(pnt); return Py::new_reference_to(Base::Vector2dPy::create(pnt.X(), pnt.Y())); } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } PyObject* Curve2dPy::parameter(PyObject *args) { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); try { if (!c.IsNull()) { PyObject *p; if (!PyArg_ParseTuple(args, "O!", Base::Vector2dPy::type_object(), &p)) return nullptr; Base::Vector2d v = Py::toVector2d(p); gp_Pnt2d pnt(v.x,v.y); Geom2dAPI_ProjectPointOnCurve ppc(pnt, c); double val = ppc.LowerDistanceParameter(); return Py::new_reference_to(Py::Float(val)); } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } PyObject* Curve2dPy::toBSpline(PyObject * args) { Handle(Geom2d_Geometry) g = getGeometry2dPtr()->handle(); Handle(Geom2d_Curve) c = Handle(Geom2d_Curve)::DownCast(g); try { if (!c.IsNull()) { double u,v; u=c->FirstParameter(); v=c->LastParameter(); if (!PyArg_ParseTuple(args, "|dd", &u,&v)) return nullptr; ShapeConstruct_Curve scc; Handle(Geom2d_BSplineCurve) spline = scc.ConvertToBSpline(c, u, v, Precision::Confusion()); if (spline.IsNull()) Standard_NullValue::Raise("Conversion to B-spline failed"); return new BSplineCurve2dPy(new Geom2dBSplineCurve(spline)); } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } PyErr_SetString(PartExceptionOCCError, "Geometry is not a curve"); return nullptr; } PyObject* Curve2dPy::approximateBSpline(PyObject *args) { double tolerance; int maxSegment, maxDegree; const char* order = "C2"; if (!PyArg_ParseTuple(args, "dii|s", &tolerance, &maxSegment, &maxDegree, &order)) return nullptr; GeomAbs_Shape absShape; std::string str = order; if (str == "C0") absShape = GeomAbs_C0; else if (str == "G1") absShape = GeomAbs_G1; else if (str == "C1") absShape = GeomAbs_C1; else if (str == "G2") absShape = GeomAbs_G2; else if (str == "C2") absShape = GeomAbs_C2; else if (str == "C3") absShape = GeomAbs_C3; else if (str == "CN") absShape = GeomAbs_CN; else absShape = GeomAbs_C2; try { Handle(Geom2d_Curve) self = Handle(Geom2d_Curve)::DownCast(getGeometry2dPtr()->handle()); Geom2dConvert_ApproxCurve approx(self, tolerance, absShape, maxSegment, maxDegree); if (approx.IsDone()) { return new BSplineCurve2dPy(new Geom2dBSplineCurve(approx.Curve())); } else if (approx.HasResult()) { std::stringstream str; str << "Maximum error (" << approx.MaxError() << ") is outside tolerance"; PyErr_SetString(PyExc_RuntimeError, str.str().c_str()); return nullptr; } else { PyErr_SetString(PyExc_RuntimeError, "Approximation of curve failed"); return nullptr; } } catch (Standard_Failure& e) { PyErr_SetString(PartExceptionOCCError, e.GetMessageString()); return nullptr; } } Py::String Curve2dPy::getContinuity() const { GeomAbs_Shape c = Handle(Geom2d_Curve)::DownCast (getGeometry2dPtr()->handle())->Continuity(); std::string str; switch (c) { case GeomAbs_C0: str = "C0"; break; case GeomAbs_G1: str = "G1"; break; case GeomAbs_C1: str = "C1"; break; case GeomAbs_G2: str = "G2"; break; case GeomAbs_C2: str = "C2"; break; case GeomAbs_C3: str = "C3"; break; case GeomAbs_CN: str = "CN"; break; default: str = "Unknown"; break; } return Py::String(str); } Py::Boolean Curve2dPy::getClosed() const { return Py::Boolean(Handle(Geom2d_Curve)::DownCast (getGeometry2dPtr()->handle())->IsClosed() ? true : false); } Py::Boolean Curve2dPy::getPeriodic() const { return Py::Boolean(Handle(Geom2d_Curve)::DownCast (getGeometry2dPtr()->handle())->IsPeriodic() ? true : false); } Py::Float Curve2dPy::getFirstParameter() const { return Py::Float(Handle(Geom2d_Curve)::DownCast (getGeometry2dPtr()->handle())->FirstParameter()); } Py::Float Curve2dPy::getLastParameter() const { return Py::Float(Handle(Geom2d_Curve)::DownCast (getGeometry2dPtr()->handle())->LastParameter()); } PyObject *Curve2dPy::getCustomAttributes(const char* /*attr*/) const { return nullptr; } int Curve2dPy::setCustomAttributes(const char* /*attr*/, PyObject* /*obj*/) { return 0; } PyObject* Curve2dPy::intersectCC(PyObject *args) { Handle(Geom2d_Curve) curve1 = Handle(Geom2d_Curve)::DownCast(getGeometry2dPtr()->handle()); try { if (!curve1.IsNull()) { PyObject *p; double prec = Precision::Confusion(); if (!PyArg_ParseTuple(args, "O!|d", &(Part::Curve2dPy::Type), &p, &prec)) return nullptr; Handle(Geom2d_Curve) curve2 = Handle(Geom2d_Curve)::DownCast(static_cast(p)->getGeometry2dPtr()->handle()); Py::List points; Geom2dAPI_InterCurveCurve intersector(curve1, curve2, prec); if ((intersector.NbPoints() == 0) && (intersector.NbSegments() == 0)) { // No intersection return Py::new_reference_to(Py::List()); } if (intersector.NbPoints() > 0) { // Cross intersections for (int i = 1; i <= intersector.NbPoints(); i++) { gp_Pnt2d p1 = intersector.Point(i); points.append(Base::Vector2dPy::create(p1.X(), p1.Y())); } } if (intersector.NbSegments() > 0) { // Tangential intersections Geom2dAPI_ExtremaCurveCurve intersector2(curve1, curve2, curve1->FirstParameter(), curve1->LastParameter(), curve2->FirstParameter(), curve2->LastParameter()); for (int i = 1; i <= intersector2.NbExtrema(); i++) { if (intersector2.Distance(i) > prec) continue; gp_Pnt2d p1, p2; intersector2.Points(i, p1, p2); points.append(Base::Vector2dPy::create(p1.X(), p1.Y())); } } return Py::new_reference_to(points); } } catch (Standard_Failure& e) { PyErr_SetString(PyExc_RuntimeError, e.GetMessageString()); return nullptr; } PyErr_SetString(PyExc_TypeError, "Geometry is not a curve"); return nullptr; }