netgen/libsrc/occ/python_occ_shapes.cpp
2021-10-11 12:48:14 +02:00

2048 lines
73 KiB
C++

#ifdef NG_PYTHON
#ifdef OCCGEOMETRY
#include <../general/ngpython.hpp>
#include <core/python_ngcore.hpp>
#include "../meshing/python_mesh.hpp"
#include <meshing.hpp>
#include <occgeom.hpp>
#include <gp_Ax1.hxx>
#include <gp_Ax2.hxx>
#include <gp_Ax2d.hxx>
#include <gp_Trsf.hxx>
#include <BRepPrimAPI_MakeSphere.hxx>
#include <BRepPrimAPI_MakeCylinder.hxx>
#include <BRepPrimAPI_MakeRevol.hxx>
#include <BRepPrimAPI_MakeBox.hxx>
#include <BRepPrimAPI_MakePrism.hxx>
#include <BRepPrimAPI_MakeHalfSpace.hxx>
#include <BRepOffsetAPI_MakePipe.hxx>
#include <BRepOffsetAPI_MakePipeShell.hxx>
#include <BRepAlgoAPI_Cut.hxx>
#include <BRepAlgoAPI_Common.hxx>
#include <BRepAlgoAPI_Fuse.hxx>
// #include <XCAFDoc_VisMaterialTool.hxx>
#include <TDF_Attribute.hxx>
#include <Standard_GUID.hxx>
#include <Geom_TrimmedCurve.hxx>
#include <Geom_Plane.hxx>
#include <Geom_BSplineCurve.hxx>
#include <Geom_BezierCurve.hxx>
#include <GeomAPI_PointsToBSpline.hxx>
#include <GC_MakeSegment.hxx>
#include <GC_MakeCircle.hxx>
#include <GC_MakeArcOfCircle.hxx>
#include <BRepBuilderAPI_MakeEdge.hxx>
#include <BRepBuilderAPI_MakeWire.hxx>
#include <BRepBuilderAPI_Transform.hxx>
#include <BRepBuilderAPI_MakeFace.hxx>
#include <BRepFilletAPI_MakeFillet.hxx>
#include <BRepFilletAPI_MakeChamfer.hxx>
#include <BRepOffsetAPI_ThruSections.hxx>
#include <BRepOffsetAPI_MakeOffset.hxx>
#include <BRepExtrema_DistShapeShape.hxx>
#include <BRepGProp.hxx>
#include <BRepOffsetAPI_MakeThickSolid.hxx>
#include <BRepLib.hxx>
#include <Geom2d_Curve.hxx>
#include <Geom2d_Ellipse.hxx>
#include <Geom2d_TrimmedCurve.hxx>
#include <GCE2d_MakeSegment.hxx>
#include <GCE2d_MakeCircle.hxx>
#include <GCE2d_MakeArcOfCircle.hxx>
#include <ShapeUpgrade_UnifySameDomain.hxx>
#include <GeomLProp_SLProps.hxx>
#include <BOPTools_AlgoTools.hxx>
#include <IntTools_Context.hxx>
#include <STEPControl_Writer.hxx>
#include <python_occ.hpp>
#if OCC_VERSION_MAJOR>=7 && OCC_VERSION_MINOR>=4
#define OCC_HAVE_DUMP_JSON
#endif
using namespace netgen;
struct ShapeLess
{
bool operator() (const TopoDS_Shape& s1, const TopoDS_Shape& s2) const
{
return s1.TShape() < s2.TShape();
}
};
class ListOfShapes : public std::vector<TopoDS_Shape>
{
public:
TopoDS_Shape Max(gp_Vec dir)
{
double maxval = -1e99;
TopoDS_Shape maxshape;
for (auto shape : *this)
{
GProp_GProps props;
gp_Pnt center;
switch (shape.ShapeType())
{
case TopAbs_VERTEX:
center = BRep_Tool::Pnt (TopoDS::Vertex(shape)); break;
case TopAbs_FACE:
BRepGProp::SurfaceProperties (shape, props);
center = props.CentreOfMass();
break;
default:
BRepGProp::LinearProperties(shape, props);
center = props.CentreOfMass();
}
double val = center.X()*dir.X() + center.Y()*dir.Y() + center.Z() * dir.Z();
if (val > maxval)
{
maxval = val;
maxshape = shape;
}
}
return maxshape;
}
TopoDS_Shape Nearest(gp_Pnt pnt)
{
double mindist = 1e99;
TopoDS_Shape nearestshape;
auto vertex = BRepBuilderAPI_MakeVertex (pnt).Vertex();
for (auto shape : *this)
{
double dist = BRepExtrema_DistShapeShape(shape, vertex).Value();
// cout << "dist = " << dist << endl;
if (dist < mindist)
nearestshape = shape;
}
return nearestshape;
}
ListOfShapes SubShapes(TopAbs_ShapeEnum type) const
{
std::set<TopoDS_Shape, ShapeLess> unique_shapes;
for(const auto& shape : *this)
for(TopExp_Explorer e(shape, type); e.More(); e.Next())
unique_shapes.insert(e.Current());
ListOfShapes sub;
for(const auto& shape : unique_shapes)
sub.push_back(shape);
return sub;
}
ListOfShapes Solids() const
{
return SubShapes(TopAbs_SOLID);
}
ListOfShapes Faces() const
{
return SubShapes(TopAbs_FACE);
}
ListOfShapes Edges() const
{
return SubShapes(TopAbs_EDGE);
}
ListOfShapes Vertices() const
{
return SubShapes(TopAbs_VERTEX);
}
ListOfShapes operator*(const ListOfShapes& other) const
{
ListOfShapes common;
for(const auto& shape : (*this))
for(const auto& shape_o : other)
if(shape.IsSame(shape_o))
common.push_back(shape);
return common;
}
};
void ExtractEdgeData( const TopoDS_Edge & edge, int index, std::vector<double> * p, Box<3> & box )
{
if (BRep_Tool::Degenerated(edge)) return;
Handle(Poly_PolygonOnTriangulation) poly;
Handle(Poly_Triangulation) T;
TopLoc_Location loc;
BRep_Tool::PolygonOnTriangulation(edge, poly, T, loc);
if (poly.IsNull())
{
cout << "no edge mesh, do my own sampling" << endl;
double s0, s1;
Handle(Geom_Curve) c = BRep_Tool::Curve(edge, s0, s1);
constexpr int num = 100;
for (int i = 0; i < num; i++)
{
auto p0 = occ2ng(c->Value (s0 + i*(s1-s0)/num));
auto p1 = occ2ng(c->Value (s0 + (i+1)*(s1-s0)/num));
for(auto k : Range(3))
{
p[0].push_back(p0[k]);
p[1].push_back(p1[k]);
}
p[0].push_back(index);
p[1].push_back(index);
box.Add(p0);
box.Add(p1);
}
return;
}
int nbnodes = poly -> NbNodes();
for (int j = 1; j < nbnodes; j++)
{
auto p0 = occ2ng((T -> Node(poly->Nodes()(j))).Transformed(loc));
auto p1 = occ2ng((T -> Node(poly->Nodes()(j+1))).Transformed(loc));
for(auto k : Range(3))
{
p[0].push_back(p0[k]);
p[1].push_back(p1[k]);
}
p[0].push_back(index);
p[1].push_back(index);
box.Add(p0);
box.Add(p1);
}
}
void ExtractFaceData( const TopoDS_Face & face, int index, std::vector<double> * p, std::vector<double> * n, Box<3> & box )
{
TopLoc_Location loc;
Handle(Poly_Triangulation) triangulation = BRep_Tool::Triangulation (face, loc);
Handle(Geom_Surface) surf = BRep_Tool::Surface (face);
BRepAdaptor_Surface sf(face, Standard_False);
BRepLProp_SLProps prop(sf, 1, 1e-5);
bool flip = TopAbs_REVERSED == face.Orientation();
if (triangulation.IsNull())
{
cout << "pls build face triangulation before" << endl;
return;
}
int ntriangles = triangulation -> NbTriangles();
for (int j = 1; j <= ntriangles; j++)
{
Poly_Triangle triangle = triangulation -> Triangle(j);
std::array<Point<3>,3> pts;
std::array<Vec<3>,3> normals;
for (int k = 0; k < 3; k++)
pts[k] = occ2ng( (triangulation -> Node(triangle(k+1))).Transformed(loc) );
for (int k = 0; k < 3; k++)
{
auto uv = triangulation -> UVNode(triangle(k+1));
prop.SetParameters (uv.X(), uv.Y());
if (prop.IsNormalDefined())
normals[k] = occ2ng (prop.Normal());
else
normals[k] = Cross(pts[1]-pts[0], pts[2]-pts[0]);
}
if(flip)
{
Swap(pts[1], pts[2]);
Swap(normals[1], normals[2]);
for (int k = 0; k < 3; k++)
normals[k] = -normals[k];
}
for (int k = 0; k < 3; k++)
{
box.Add(pts[k]);
for (int d = 0; d < 3; d++)
{
p[k].push_back( pts[k][d] );
n[k].push_back( normals[k][d] );
}
p[k].push_back( index );
}
}
}
py::object CastShape(const TopoDS_Shape & s)
{
switch (s.ShapeType())
{
case TopAbs_VERTEX:
return py::cast(TopoDS::Vertex(s));
case TopAbs_FACE:
return py::cast(TopoDS::Face(s));
case TopAbs_EDGE:
return py::cast(TopoDS::Edge(s));
case TopAbs_WIRE:
return py::cast(TopoDS::Wire(s));
case TopAbs_COMPOUND:
case TopAbs_COMPSOLID:
case TopAbs_SOLID:
case TopAbs_SHELL:
case TopAbs_SHAPE:
return py::cast(s);
}
};
template <class TBuilder>
void PropagateProperties (TBuilder & builder, TopoDS_Shape shape)
{
// #ifdef OCC_HAVE_HISTORY
// Handle(BRepTools_History) history = builder.History();
for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE })
for (TopExp_Explorer e(shape, typ); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
// for (auto mods : history->Modified(e.Current()))
for (auto mods : builder.Modified(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
// #endif
}
class WorkPlane : public enable_shared_from_this<WorkPlane>
{
gp_Ax3 axes;
gp_Ax2d localpos;
gp_Pnt2d startpnt;
TopoDS_Vertex lastvertex, startvertex;
Handle(Geom_Surface) surf;
// Geom_Plane surf;
BRepBuilderAPI_MakeWire wire_builder;
std::vector<TopoDS_Wire> wires;
public:
WorkPlane (const gp_Ax3 & _axes, const gp_Ax2d _localpos = gp_Ax2d())
: axes(_axes), localpos(_localpos) // , surf(_axis)
{
// surf = GC_MakePlane (gp_Ax1(axis.Location(), axis.Direction()));
surf = new Geom_Plane(axes);
}
auto Finish()
{
if (!startvertex.IsNull())
{
wires.push_back (wire_builder.Wire());
wire_builder = BRepBuilderAPI_MakeWire();
startvertex.Nullify();
}
return shared_from_this();
}
auto MoveTo (double h, double v)
{
startpnt = gp_Pnt2d(h,v);
localpos.SetLocation(startpnt);
startvertex.Nullify();
return shared_from_this();
}
auto Move(double len)
{
gp_Dir2d dir = localpos.Direction();
gp_Pnt2d oldp = localpos.Location();
auto newp = oldp.Translated(len*dir);
return MoveTo(newp.X(), newp.Y());
}
auto Direction (double h, double v)
{
localpos.SetDirection(gp_Dir2d(h,v));
return shared_from_this();
}
auto LineTo (double h, double v, optional<string> name = nullopt)
{
gp_Pnt2d old2d = localpos.Location();
gp_Pnt oldp = axes.Location() . Translated(old2d.X() * axes.XDirection() + old2d.Y() * axes.YDirection());
// localpos.Translate (gp_Vec2d(h,v));
localpos.SetLocation (gp_Pnt2d(h,v));
gp_Pnt2d new2d = localpos.Location();
gp_Pnt newp = axes.Location() . Translated(new2d.X() * axes.XDirection() + new2d.Y() * axes.YDirection());
if (new2d.Distance(old2d) < 1e-10) return shared_from_this();
bool closing = new2d.Distance(startpnt) < 1e-10;
cout << IM(6) << "lineto, oldp = " << occ2ng(oldp) << endl;
cout << IM(6) << "lineto, newp = " << occ2ng(newp) << endl;
gp_Pnt pfromsurf = surf->Value(new2d.X(), new2d.Y());
cout << IM(6) << "p from plane = " << occ2ng(pfromsurf) << endl;
Handle(Geom_TrimmedCurve) curve = GC_MakeSegment(oldp, newp);
if (startvertex.IsNull())
startvertex = lastvertex = BRepBuilderAPI_MakeVertex(oldp);
auto endv = closing ? startvertex : BRepBuilderAPI_MakeVertex(newp);
// liefert noch Fehler bei close
auto edge = BRepBuilderAPI_MakeEdge(curve, lastvertex, endv).Edge();
lastvertex = endv;
// auto edge = BRepBuilderAPI_MakeEdge(curve).Edge();
if (name)
OCCGeometry::global_shape_properties[edge.TShape()].name = name;
wire_builder.Add(edge);
if (closing) Finish();
return shared_from_this();
}
auto Line(double h, double v, optional<string> name = nullopt)
{
gp_Pnt2d oldp = localpos.Location();
oldp.Translate(gp_Vec2d(h,v));
return LineTo (oldp.X(), oldp.Y(), name);
}
auto Line(double len, optional<string> name = nullopt)
{
gp_Dir2d dir = localpos.Direction();
cout << IM(6) << "dir = " << dir.X() << ", " << dir.Y() << endl;
gp_Pnt2d oldp = localpos.Location();
oldp.Translate(len*dir);
return LineTo (oldp.X(), oldp.Y(), name);
}
auto Rotate (double angle)
{
localpos.Rotate(localpos.Location(), angle*M_PI/180);
return shared_from_this();
}
auto ArcTo (double h, double v, const gp_Vec2d t)
{
gp_Pnt2d P1 = localpos.Location();
//check input
if(P1.X() == h && P1.Y() == v)
throw Exception("points P1 and P2 must not be congruent");
localpos.SetLocation (gp_Pnt2d(h,v));
gp_Pnt2d P2 = localpos.Location();
cout << IM(6) << "ArcTo:" << endl;
cout << IM(6) << "P1 = (" << P1.X() <<", " << P1.Y() << ")"<<endl;
cout << IM(6) << "P2 = (" << P2.X() <<", " << P2.Y() << ")"<<endl;
cout << IM(6) << "t = (" << t.X() << ", " << t.Y() << ")" << endl;
//compute circle center point M
//point midway between p1 and p2
gp_Pnt2d P12 = gp_Pnt2d((P1.X() + h) / 2, (P1.Y() + v) / 2);
//vector normal to vector from P1 to P12
gp_Vec2d p12n = gp_Vec2d( - (P12.Y() - P1.Y()), (P12.X() - P1.X()));
//M is intersection of p12n and tn (tn ... normalvector to t)
double k = ((P12.Y()- P1.Y())*p12n.X() + (P1.X() - P12.X())*p12n.Y() )/ (t.X()*p12n.X() + t.Y()*p12n.Y());
gp_Pnt2d M = gp_Pnt2d(P1.X()-k*t.Y(), P1.Y() + k*t.X());
cout << IM(6) << "P12 = (" << P12.X() <<", " << P12.Y() << ")"<<endl;
cout << IM(6) << "p12n = (" << p12n.X() <<", " << p12n.Y() << ")"<<endl;
cout << IM(6) << "k = " << k <<endl;
cout << IM(6) << "M = (" << M.X() <<", " << M.Y() << ")"<<endl;
//radius
double r = P1.Distance(M);
//compute point P3 on circle between P1 and P2
p12n.Normalize(); //docu: reverses direction of p12n ??
cout << IM(6) << "p12n = (" << p12n.X() <<", " << p12n.Y() << ")"<<endl;
gp_Pnt2d P3;
double angletp12n = t.Angle(p12n);
if(angletp12n > -M_PI/2 && angletp12n < M_PI/2)
P3 = gp_Pnt2d(M.X() + r * p12n.X() , M.Y() + r * p12n.Y());
else
P3 = gp_Pnt2d(M.X() - r * p12n.X() , M.Y() - r * p12n.Y());
cout << IM(6) << "r = " << r <<endl;
cout << IM(6) << "angle t,p12n = " << t.Angle(p12n)<<endl;
cout << IM(6) << "P3 = (" << P3.X() <<", " << P3.Y() << ")"<<endl;
cout << IM(6) << "dist(M,P3) = " << P3.Distance(M) <<endl;
//Draw 2d arc of circle from P1 to P2 through P3
Handle(Geom2d_TrimmedCurve) curve2d = GCE2d_MakeArcOfCircle(P1, P3, P2).Value();
gp_Pnt P13d = surf->Value(P1.X(), P1.Y());
gp_Pnt P23d = surf->Value(P2.X(), P2.Y());
cout << IM(6) << "p13d = " << occ2ng(P13d) << ", p23d = " << occ2ng(P23d) << endl;
bool closing = P2.Distance(startpnt) < 1e-10;
if (startvertex.IsNull())
startvertex = lastvertex = BRepBuilderAPI_MakeVertex(P13d);
auto endv = closing ? startvertex : BRepBuilderAPI_MakeVertex(P23d);
//create 3d edge from 2d curve using surf
auto edge = BRepBuilderAPI_MakeEdge(curve2d, surf, lastvertex, endv).Edge();
lastvertex = endv;
BRepLib::BuildCurves3d(edge);
wire_builder.Add(edge);
//compute angle of rotation
//compute tangent t2 in P2
gp_Vec2d p2 = gp_Vec2d(P1.X()-P2.X(),P1.Y()-P2.Y());
gp_Vec2d t2;
if(t.Angle(p2) >=0)
t2 = gp_Vec2d((P2.Y()-M.Y()),-(P2.X()-M.X()));
else
t2 = gp_Vec2d(-(P2.Y()-M.Y()),(P2.X()-M.X()));
double angle = -t2.Angle(t); //angle \in [-pi,pi]
//update localpos.Direction()
Rotate(angle*180/M_PI);
if (closing)
Finish();
return shared_from_this();
}
auto Arc(double radius, double angle)
{
double newAngle = fmod(angle,360)*M_PI/180;
//check input
if(newAngle<1e-16 && newAngle>-1e-16)
throw Exception("angle must not be an integer multiple of 360");
gp_Dir2d dir = localpos.Direction();
gp_Dir2d dirn;
//compute center point of arc
if(newAngle>=0)
dirn = gp_Dir2d(-dir.Y(),dir.X());
else
dirn = gp_Dir2d(dir.Y(),-dir.X());
gp_Pnt2d oldp = localpos.Location();
oldp.Translate(radius*dirn);
cout << IM(6) << "M = (" << oldp.X() << ", " << oldp.Y() << ")" << endl;
dirn.Rotate(newAngle-M_PI);
oldp.Translate(radius*dirn);
//compute tangent vector in P1
gp_Vec2d t = gp_Vec2d(dir.X(),dir.Y());
cout << IM(6) << "t = (" << t.X() << ", " << t.Y() << ")" << endl;
//add arc
return ArcTo (oldp.X(), oldp.Y(), t);
}
auto Rectangle (double l, double w)
{
Line (l);
Rotate (90);
Line(w);
Rotate (90);
Line (l);
Rotate (90);
Line(w);
Rotate (90);
return shared_from_this();
}
auto RectangleCentered (double l, double w)
{
Move(-l/2);
Rotate(-90);
Move(w/2);
Rotate(90);
Rectangle(l,w);
Rotate(-90);
Move(-w/2);
Rotate(90);
Move(l/2);
return shared_from_this();
}
auto Circle(double x, double y, double r)
{
/*
MoveTo(x+r, y);
Direction (0, 1);
Arc(r, 180);
Arc(r, 180);
// wires.push_back (wire_builder.Wire());
// wire_builder = BRepBuilderAPI_MakeWire();
return shared_from_this();
*/
gp_Pnt2d p(x,y);
Handle(Geom2d_Circle) circ_curve = GCE2d_MakeCircle(p, r).Value();
auto edge = BRepBuilderAPI_MakeEdge(circ_curve, surf).Edge();
BRepLib::BuildCurves3d(edge);
wire_builder.Add(edge);
wires.push_back (wire_builder.Wire());
wire_builder = BRepBuilderAPI_MakeWire();
return shared_from_this();
}
auto NameVertex (string name)
{
if (!lastvertex.IsNull())
OCCGeometry::global_shape_properties[lastvertex.TShape()].name = name;
return shared_from_this();
}
auto Circle (double r)
{
gp_Pnt2d pos = localpos.Location();
return Circle (pos.X(), pos.Y(), r);
}
shared_ptr<WorkPlane> Close ()
{
if (startpnt.Distance(localpos.Location()) > 1e-10)
{
LineTo (startpnt.X(), startpnt.Y());
return shared_from_this();
}
if (!startvertex.IsNull())
Finish();
return shared_from_this();
}
auto Reverse()
{
wires.back().Reverse();
return shared_from_this();
}
auto Offset(double d)
{
TopoDS_Wire wire = wires.back();
wires.pop_back();
BRepOffsetAPI_MakeOffset builder;
builder.AddWire(wire);
builder.Perform(d);
auto shape = builder.Shape();
wires.push_back (TopoDS::Wire(shape.Reversed()));
return shared_from_this();
}
TopoDS_Wire Last()
{
return wires.back();
}
TopoDS_Face Face()
{
BRepBuilderAPI_MakeFace builder(surf, 1e-8);
for (auto w : wires)
builder.Add(w);
wires.clear();
return builder.Face();
}
auto Wires()
{
ListOfShapes ws;
for (auto w : wires)
ws.push_back(w);
return ws;
}
};
DLL_HEADER void ExportNgOCCShapes(py::module &m)
{
py::enum_<TopAbs_ShapeEnum>(m, "TopAbs_ShapeEnum", "Enumeration of all supported TopoDS_Shapes")
.value("COMPOUND", TopAbs_COMPOUND) .value("COMPSOLID", TopAbs_COMPSOLID)
.value("SOLID", TopAbs_SOLID) .value("SHELL", TopAbs_SHELL)
.value("FACE", TopAbs_FACE) .value("WIRE", TopAbs_WIRE)
.value("EDGE", TopAbs_EDGE) .value("VERTEX", TopAbs_VERTEX)
.value("SHAPE", TopAbs_SHAPE)
.export_values()
;
py::class_<TopoDS_Shape> (m, "TopoDS_Shape")
.def("__str__", [] (const TopoDS_Shape & shape)
{
stringstream str;
#ifdef OCC_HAVE_DUMP_JSON
shape.DumpJson(str);
#endif // OCC_HAVE_DUMP_JSON
return str.str();
})
.def("ShapeType", [] (const TopoDS_Shape & shape)
{
throw Exception ("use 'shape.type' instead of 'shape.ShapeType()'");
}, "deprecated, use 'shape.type' instead")
.def_property_readonly("type", [](const TopoDS_Shape & shape)
{ return shape.ShapeType(); }, "returns type of shape, i.e. 'EDGE', 'FACE', ...")
.def("SubShapes", [] (const TopoDS_Shape & shape, TopAbs_ShapeEnum & type)
{
ListOfShapes sub;
for (TopExp_Explorer e(shape, type); e.More(); e.Next())
sub.push_back(e.Current());
return sub;
}, py::arg("type"), "returns list of sub-shapes of type 'type'")
.def_property_readonly("solids", [] (const TopoDS_Shape & shape)
{
ListOfShapes solids;
for(TopExp_Explorer e(shape, TopAbs_SOLID); e.More(); e.Next())
solids.push_back(e.Current());
return solids;
}, "returns all sub-shapes of type 'SOLID'")
.def_property_readonly("faces", [] (const TopoDS_Shape & shape)
{
ListOfShapes sub;
for (TopExp_Explorer e(shape, TopAbs_FACE); e.More(); e.Next())
sub.push_back(e.Current());
return sub;
}, "returns all sub-shapes of type 'FACE'")
.def_property_readonly("edges", [] (const TopoDS_Shape & shape)
{
ListOfShapes sub;
for (TopExp_Explorer e(shape, TopAbs_EDGE); e.More(); e.Next())
sub.push_back(e.Current());
return sub;
}, "returns all sub-shapes of type 'EDGE'")
.def_property_readonly("vertices", [] (const TopoDS_Shape & shape)
{
ListOfShapes sub;
for (TopExp_Explorer e(shape, TopAbs_VERTEX); e.More(); e.Next())
sub.push_back(e.Current());
return sub;
}, "returns all sub-shapes of type 'VERTEX'")
.def("Properties", [] (const TopoDS_Shape & shape)
{
GProp_GProps props;
switch (shape.ShapeType())
{
case TopAbs_FACE:
BRepGProp::SurfaceProperties (shape, props); break;
default:
BRepGProp::LinearProperties(shape, props);
// throw Exception("Properties implemented only for FACE");
}
double mass = props.Mass();
gp_Pnt center = props.CentreOfMass();
return tuple( py::cast(mass), py::cast(center) );
}, "returns tuple of shape properties, currently ('mass', 'center'")
.def_property_readonly("center", [](const TopoDS_Shape & shape) {
GProp_GProps props;
switch (shape.ShapeType())
{
case TopAbs_FACE:
BRepGProp::SurfaceProperties (shape, props); break;
default:
BRepGProp::LinearProperties(shape, props);
}
return props.CentreOfMass();
}, "returns center of gravity of shape")
.def_property_readonly("mass", [](const TopoDS_Shape & shape) {
GProp_GProps props;
switch (shape.ShapeType())
{
case TopAbs_FACE:
BRepGProp::SurfaceProperties (shape, props); break;
default:
BRepGProp::LinearProperties(shape, props);
}
return props.Mass();
}, "returns mass of shape, what is length, face, or volume")
.def("Move", [](const TopoDS_Shape & shape, const gp_Vec v)
{
// which one to choose ?
// version 1: Transoformation
gp_Trsf trafo;
trafo.SetTranslation(v);
BRepBuilderAPI_Transform builder(shape, trafo);
PropagateProperties(builder, shape);
return builder.Shape();
// version 2: change location
// ...
}, py::arg("v"), "copy shape, and translate copy by vector 'v'")
.def("Rotate", [](const TopoDS_Shape & shape, const gp_Ax1 ax, double ang)
{
gp_Trsf trafo;
trafo.SetRotation(ax, ang*M_PI/180);
BRepBuilderAPI_Transform builder(shape, trafo);
PropagateProperties(builder, shape);
return builder.Shape();
}, py::arg("axis"), py::arg("ang"),
"copy shape, and rotet copy by 'ang' degrees around 'axis'")
.def("Mirror", [] (const TopoDS_Shape & shape, const gp_Ax3 & ax)
{
gp_Trsf trafo;
trafo.SetMirror(ax.Ax2());
BRepBuilderAPI_Transform builder(shape, trafo);
PropagateProperties(builder, shape);
return builder.Shape();
}, py::arg("axes"),
"copy shape, and mirror over plane defined by 'axes'")
.def("Mirror", [] (const TopoDS_Shape & shape, const gp_Ax1 & ax)
{
gp_Trsf trafo;
trafo.SetMirror(ax);
BRepBuilderAPI_Transform builder(shape, trafo);
PropagateProperties(builder, shape);
return builder.Shape();
}, py::arg("axes"),
"copy shape, and mirror around axis 'axis'")
.def("Scale", [](const TopoDS_Shape & shape, const gp_Pnt p, double s)
{
gp_Trsf trafo;
trafo.SetScale(p, s);
BRepBuilderAPI_Transform builder(shape, trafo);
PropagateProperties(builder, shape);
return builder.Shape();
}, py::arg("p"), py::arg("s"),
"copy shape, and scale copy by factor 's'")
.def("WriteStep", [](TopoDS_Shape shape, string filename)
{
STEPControl_Writer writer;
writer.Transfer(shape, STEPControl_ManifoldSolidBrep);
// Translates TopoDS_Shape into manifold_solid_brep entity
writer.Write(filename.c_str());
}, py::arg("filename"), "export shape in STEP - format")
.def("bc", [](const TopoDS_Shape & shape, const string & name)
{
for (TopExp_Explorer e(shape, TopAbs_FACE); e.More(); e.Next())
OCCGeometry::global_shape_properties[e.Current().TShape()].name = name;
return shape;
}, py::arg("name"), "sets 'name' property for all faces of shape")
.def("mat", [](const TopoDS_Shape & shape, const string & name)
{
for (TopExp_Explorer e(shape, TopAbs_SOLID); e.More(); e.Next())
OCCGeometry::global_shape_properties[e.Current().TShape()].name = name;
return shape;
}, py::arg("name"), "sets 'name' property to all solids of shape")
.def_property("name", [](const TopoDS_Shape & self) {
if (auto name = OCCGeometry::global_shape_properties[self.TShape()].name)
return *name;
else
return string();
}, [](const TopoDS_Shape & self, string name) {
OCCGeometry::global_shape_properties[self.TShape()].name = name;
}, "'name' of shape")
.def_property("maxh",
[](const TopoDS_Shape& self)
{
return OCCGeometry::global_shape_properties[self.TShape()].maxh;
},
[](TopoDS_Shape& self, double val)
{
for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE, TopAbs_VERTEX })
for (TopExp_Explorer e(self, typ); e.More(); e.Next())
{
auto & maxh = OCCGeometry::global_shape_properties[e.Current().TShape()].maxh;
maxh = min2(val, maxh);
}
}, "maximal mesh-size for shape")
.def_property("col", [](const TopoDS_Shape & self) {
auto it = OCCGeometry::global_shape_properties.find(self.TShape());
Vec<4> col(0.2, 0.2, 0.2);
if (it != OCCGeometry::global_shape_properties.end() && it->second.col)
col = *it->second.col;
return std::vector<double> ( { col(0), col(1), col(2) } );
}, [](const TopoDS_Shape & self, std::vector<double> c) {
Vec<4> col(c[0], c[1], c[2], 1.0);
if(c.size() == 4)
col[3] = c[3];
OCCGeometry::global_shape_properties[self.TShape()].col = col;
}, "color of shape as RGB - tuple")
.def("UnifySameDomain", [](const TopoDS_Shape& shape,
bool edges, bool faces,
bool concatBSplines)
{
ShapeUpgrade_UnifySameDomain unify(shape, edges, faces,
concatBSplines);
unify.Build();
Handle(BRepTools_History) history = unify.History ();
for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE })
for (TopExp_Explorer e(shape, typ); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
for (auto mods : history->Modified(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
return unify.Shape();
}, py::arg("unifyEdges")=true, py::arg("unifyFaces")=true,
py::arg("concatBSplines")=true)
.def_property("location",
[](const TopoDS_Shape & shape) { return shape.Location(); },
[](TopoDS_Shape & shape, const TopLoc_Location & loc)
{ shape.Location(loc); }, "Location of shape")
.def("Located", [](const TopoDS_Shape & shape, const TopLoc_Location & loc)
{ return shape.Located(loc); }, py::arg("loc"), "copy shape and sets location of copy")
.def("__add__", [] (const TopoDS_Shape & shape1, const TopoDS_Shape & shape2) {
BRepAlgoAPI_Fuse builder(shape1, shape2);
PropagateProperties (builder, shape1);
PropagateProperties (builder, shape2);
/*
#ifdef OCC_HAVE_HISTORY
Handle(BRepTools_History) history = builder.History ();
for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE })
for (auto & s : { shape1, shape2 })
for (TopExp_Explorer e(s, typ); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
for (auto mods : history->Modified(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
#endif
*/
auto fused = builder.Shape();
// make one face when fusing in 2D
// from https://gitlab.onelab.info/gmsh/gmsh/-/issues/627
// int cntsolid = 0;
// for (TopExp_Explorer e(shape1, TopAbs_SOLID); e.More(); e.Next())
// cntsolid++;
// for (TopExp_Explorer e(shape2, TopAbs_SOLID); e.More(); e.Next())
// cntsolid++;
// if (cntsolid == 0)
// {
ShapeUpgrade_UnifySameDomain unify(fused, true, true, true);
unify.Build();
// #ifdef OCC_HAVE_HISTORY
Handle(BRepTools_History) history = unify.History ();
for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE })
for (TopExp_Explorer e(fused, typ); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
for (auto mods : history->Modified(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
// #endif
// PropagateProperties (unify, fused);
return unify.Shape();
// }
// else
// return fused;
}, "fuses shapes")
.def("__radd__", [] (const TopoDS_Shape & shape, int i) // for sum([shapes])
{ return shape; }, "needed for Sum([shapes])")
.def("__mul__", [] (const TopoDS_Shape & shape1, const TopoDS_Shape & shape2) {
BRepAlgoAPI_Common builder(shape1, shape2);
/*
#ifdef OCC_HAVE_HISTORY
Handle(BRepTools_History) history = builder.History ();
for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE })
for (auto & s : { shape1, shape2 })
for (TopExp_Explorer e(s, typ); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
for (auto mods : history->Modified(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
#endif // OCC_HAVE_HISTORY
*/
PropagateProperties (builder, shape1);
PropagateProperties (builder, shape2);
return builder.Shape();
}, "common of shapes")
.def("__sub__", [] (const TopoDS_Shape & shape1, const TopoDS_Shape & shape2) {
BRepAlgoAPI_Cut builder(shape1, shape2);
/*
#ifdef OCC_HAVE_HISTORY
Handle(BRepTools_History) history = builder.History ();
for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE })
for (auto & s : { shape1, shape2 })
for (TopExp_Explorer e(s, typ); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
for (auto mods : history->Modified(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
#endif // OCC_HAVE_HISTORY
*/
PropagateProperties (builder, shape1);
PropagateProperties (builder, shape2);
return builder.Shape();
}, "cut of shapes")
.def("Reversed", [](const TopoDS_Shape & shape) {
return CastShape(shape.Reversed()); })
.def("Extrude", [](const TopoDS_Shape & shape, double h) {
for (TopExp_Explorer e(shape, TopAbs_FACE); e.More(); e.Next())
{
Handle(Geom_Surface) surf = BRep_Tool::Surface (TopoDS::Face(e.Current()));
gp_Vec du, dv;
gp_Pnt p;
surf->D1 (0,0,p,du,dv);
BRepPrimAPI_MakePrism builder(shape, h*du^dv);
for (auto typ : { TopAbs_EDGE, TopAbs_VERTEX })
for (TopExp_Explorer e(shape, typ); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
for (auto mods : builder.Generated(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
return builder.Shape();
}
throw Exception("no face found for extrusion");
}, py::arg("h"), "extrude shape to thickness 'h', shape must contain a plane surface")
.def("Extrude", [] (const TopoDS_Shape & face, gp_Vec vec) {
return BRepPrimAPI_MakePrism (face, vec).Shape();
}, py::arg("v"), "extrude shape by vector 'v'")
.def("Revolve", [](const TopoDS_Shape & shape, const gp_Ax1 &A, const double D) {
// for (TopExp_Explorer e(shape, TopAbs_FACE); e.More(); e.Next())
{
// return BRepPrimAPI_MakeRevol (shape, A, D*M_PI/180).Shape();
BRepPrimAPI_MakeRevol builder(shape, A, D*M_PI/180);
for (auto typ : { TopAbs_EDGE, TopAbs_VERTEX })
for (TopExp_Explorer e(shape, typ); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
for (auto mods : builder.Generated(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
return builder.Shape();
}
// throw Exception("no face found for revolve");
}, py::arg("axis"), py::arg("ang"), "revolve shape around 'axis' by 'ang' degrees")
.def("MakeFillet", [](const TopoDS_Shape & shape, std::vector<TopoDS_Shape> edges, double r) {
BRepFilletAPI_MakeFillet mkFillet(shape);
for (auto e : edges)
mkFillet.Add (r, TopoDS::Edge(e));
mkFillet.Build();
PropagateProperties (mkFillet, shape);
for (auto e : edges)
for (auto gen : mkFillet.Generated(e))
OCCGeometry::global_shape_properties[gen.TShape()].name = "fillet";
return mkFillet.Shape();
}, py::arg("edges"), py::arg("r"), "make fillets for edges 'edges' of radius 'r'")
.def("MakeChamfer", [](const TopoDS_Shape & shape, std::vector<TopoDS_Shape> edges, double d) {
#if OCC_VERSION_MAJOR>=7 && OCC_VERSION_MINOR>=4
BRepFilletAPI_MakeChamfer mkChamfer(shape);
for (auto e : edges)
mkChamfer.Add (d, TopoDS::Edge(e));
mkChamfer.Build();
PropagateProperties (mkChamfer, shape);
for (auto e : edges)
for (auto gen : mkChamfer.Generated(e))
OCCGeometry::global_shape_properties[gen.TShape()].name = "chamfer";
return mkChamfer.Shape();
#else
throw Exception("MakeChamfer not available for occ-version < 7.4");
#endif
}, py::arg("edges"), py::arg("d"), "make symmetric chamfer for edges 'edges' of distrance 'd'")
.def("MakeThickSolid", [](const TopoDS_Shape & body, std::vector<TopoDS_Shape> facestoremove,
double offset, double tol) {
TopTools_ListOfShape faces;
for (auto f : facestoremove)
faces.Append(f);
BRepOffsetAPI_MakeThickSolid maker;
maker.MakeThickSolidByJoin(body, faces, offset, tol);
return maker.Shape();
}, py::arg("facestoremove"), py::arg("offset"), py::arg("tol"), "makes shell-like solid from faces")
.def("MakeTriangulation", [](const TopoDS_Shape & shape)
{
BRepTools::Clean (shape);
double deflection = 0.01;
BRepMesh_IncrementalMesh (shape, deflection, true);
})
.def("Identify", [](const TopoDS_Shape & me, const TopoDS_Shape & you, string name) {
// only edges supported, by now
auto me_edge = TopoDS::Edge(me);
auto you_edge = TopoDS::Edge(you);
GProp_GProps props;
BRepGProp::LinearProperties(me, props);
gp_Pnt cme = props.CentreOfMass();
BRepGProp::LinearProperties(you, props);
gp_Pnt cyou = props.CentreOfMass();
double s0, s1;
auto curve_me = BRep_Tool::Curve(me_edge, s0, s1);
auto vme = occ2ng(curve_me->Value(s1))-occ2ng(curve_me->Value(s0));
auto curve_you = BRep_Tool::Curve(you_edge, s0, s1);
auto vyou = occ2ng(curve_you->Value(s1))-occ2ng(curve_you->Value(s0));
bool inv = vme*vyou < 0;
OCCGeometry::identifications[me.TShape()].push_back
(OCCIdentification { you, Transformation<3>(occ2ng(cyou) - occ2ng(cme)), inv, name });
OCCGeometry::identifications[you.TShape()].push_back
(OCCIdentification { me, Transformation<3>(occ2ng(cme) - occ2ng(cyou)), inv, name });
}, py::arg("other"), py::arg("name"), "Identify shapes for periodic meshing")
.def("Triangulation", [](const TopoDS_Shape & shape)
{
// extracted from vsocc.cpp
TopoDS_Face face;
try
{
face = TopoDS::Face(shape);
}
catch (Standard_Failure & e)
{
e.Print (cout);
throw NgException ("Triangulation: shape is not a face");
}
/*
BRepTools::Clean (shape);
double deflection = 0.01;
BRepMesh_IncrementalMesh (shape, deflection, true);
*/
Handle(Geom_Surface) surf = BRep_Tool::Surface (face);
TopLoc_Location loc;
Handle(Poly_Triangulation) triangulation = BRep_Tool::Triangulation (face, loc);
if (triangulation.IsNull())
{
BRepTools::Clean (shape);
double deflection = 0.01;
BRepMesh_IncrementalMesh (shape, deflection, true);
triangulation = BRep_Tool::Triangulation (face, loc);
}
// throw Exception("Don't have a triangulation, call 'MakeTriangulation' first");
int ntriangles = triangulation -> NbTriangles();
Array< std::array<Point<3>,3> > triangles;
for (int j = 1; j <= ntriangles; j++)
{
Poly_Triangle triangle = triangulation -> Triangle(j);
std::array<Point<3>,3> pts;
for (int k = 0; k < 3; k++)
pts[k] = occ2ng( (triangulation -> Node(triangle(k+1))).Transformed(loc) );
triangles.Append ( pts );
}
// return MoveToNumpyArray(triangles);
return triangles;
})
.def("_webgui_data", [](const TopoDS_Shape & shape)
{
BRepTools::Clean (shape);
double deflection = 0.01;
BRepMesh_IncrementalMesh (shape, deflection, true);
// triangulation = BRep_Tool::Triangulation (face, loc);
std::vector<double> p[3];
std::vector<double> n[3];
py::list names, colors;
int index = 0;
Box<3> box(Box<3>::EMPTY_BOX);
for (TopExp_Explorer e(shape, TopAbs_FACE); e.More(); e.Next())
{
TopoDS_Face face = TopoDS::Face(e.Current());
// Handle(TopoDS_Face) face = e.Current();
ExtractFaceData(face, index, p, n, box);
auto & props = OCCGeometry::global_shape_properties[face.TShape()];
if(props.col)
{
auto & c = *props.col;
colors.append(py::make_tuple(c[0], c[1], c[2]));
}
else
colors.append(py::make_tuple(0.0, 1.0, 0.0));
if(props.name)
{
names.append(*props.name);
}
else
names.append("");
index++;
}
std::vector<double> edge_p[2];
py::list edge_names, edge_colors;
index = 0;
for (TopExp_Explorer e(shape, TopAbs_EDGE); e.More(); e.Next())
{
TopoDS_Edge edge = TopoDS::Edge(e.Current());
ExtractEdgeData(edge, index, edge_p, box);
auto & props = OCCGeometry::global_shape_properties[edge.TShape()];
if(props.col)
{
auto & c = *props.col;
edge_colors.append(py::make_tuple(c[0], c[1], c[2]));
}
else
edge_colors.append(py::make_tuple(0.0, 0.0, 0.0));
if(props.name)
{
edge_names.append(*props.name);
}
else
edge_names.append("");
index++;
}
auto center = box.Center();
py::list mesh_center;
mesh_center.append(center[0]);
mesh_center.append(center[1]);
mesh_center.append(center[2]);
py::dict data;
data["ngsolve_version"] = "Netgen x.x"; // TODO
data["mesh_dim"] = 3; // TODO
data["mesh_center"] = mesh_center;
data["mesh_radius"] = box.Diam()/2;
data["order2d"] = 1;
data["order3d"] = 0;
data["draw_vol"] = false;
data["draw_surf"] = true;
data["funcdim"] = 0;
data["have_normals"] = true;
data["show_wireframe"] = true;
data["show_mesh"] = true;
data["Bezier_points"] = py::list{};
py::list points;
points.append(p[0]);
points.append(p[1]);
points.append(p[2]);
points.append(n[0]);
points.append(n[1]);
points.append(n[2]);
data["Bezier_trig_points"] = points;
data["funcmin"] = 0;
data["funcmax"] = 1;
data["mesh_regions_2d"] = index;
data["autoscale"] = false;
data["colors"] = colors;
data["names"] = names;
py::list edges;
edges.append(edge_p[0]);
edges.append(edge_p[1]);
data["edges"] = edges;
data["edge_names"] = edge_names;
data["edge_colors"] = edge_colors;
return data;
})
;
py::class_<TopoDS_Vertex, TopoDS_Shape> (m, "Vertex")
.def(py::init([] (const TopoDS_Shape & shape) {
return TopoDS::Vertex(shape);
}))
.def(py::init([] (const gp_Pnt & p) {
return BRepBuilderAPI_MakeVertex (p).Vertex();
}))
.def_property_readonly("p", [] (const TopoDS_Vertex & v) -> gp_Pnt {
return BRep_Tool::Pnt (v); }, "coordinates of vertex")
;
py::class_<TopoDS_Edge, TopoDS_Shape> (m, "Edge")
.def(py::init([] (const TopoDS_Shape & shape) {
return TopoDS::Edge(shape);
}))
.def(py::init([] (Handle(Geom2d_Curve) curve2d, TopoDS_Face face) {
auto edge = BRepBuilderAPI_MakeEdge(curve2d, BRep_Tool::Surface (face)).Edge();
BRepLib::BuildCurves3d(edge);
return edge;
}))
.def("Value", [](const TopoDS_Edge & e, double s) {
double s0, s1;
auto curve = BRep_Tool::Curve(e, s0, s1);
return curve->Value(s);
}, py::arg("s"), "evaluate curve for paramters 's'")
.def("Tangent", [](const TopoDS_Edge & e, double s) {
gp_Pnt p; gp_Vec v;
double s0, s1;
auto curve = BRep_Tool::Curve(e, s0, s1);
curve->D1(s, p, v);
return v;
}, py::arg("s"), "tangent vector to curve at parameter 's'")
.def_property_readonly("start",
[](const TopoDS_Edge & e) {
double s0, s1;
auto curve = BRep_Tool::Curve(e, s0, s1);
return curve->Value(s0);
},
"start-point of curve")
.def_property_readonly("end",
[](const TopoDS_Edge & e) {
double s0, s1;
auto curve = BRep_Tool::Curve(e, s0, s1);
return curve->Value(s1);
},
"end-point of curve")
.def_property_readonly("start_tangent",
[](const TopoDS_Edge & e) {
double s0, s1;
auto curve = BRep_Tool::Curve(e, s0, s1);
gp_Pnt p; gp_Vec v;
curve->D1(s0, p, v);
return v;
},
"tangent at start-point")
.def_property_readonly("end_tangent",
[](const TopoDS_Edge & e) {
double s0, s1;
auto curve = BRep_Tool::Curve(e, s0, s1);
gp_Pnt p; gp_Vec v;
curve->D1(s1, p, v);
return v;
},
"tangent at end-point")
.def_property_readonly("parameter_interval",
[](const TopoDS_Edge & e) {
double s0, s1;
auto curve = BRep_Tool::Curve(e, s0, s1);
return tuple(s0, s1);
},
"parameter interval of curve")
.def("Split", [](const TopoDS_Edge& self, py::args args)
{
ListOfShapes new_edges;
double s0, s1;
auto curve = BRep_Tool::Curve(self, s0, s1);
double tstart, t, dist;
TopoDS_Vertex vstart, vend;
vstart = TopExp::FirstVertex(self);
IntTools_Context context;
tstart = s0;
for(auto arg : args)
{
if(py::isinstance<py::float_>(arg))
t = s0 + py::cast<double>(arg) * (s1-s0);
else
{
auto p = py::cast<gp_Pnt>(arg);
auto result = context.ComputePE(p, 0., self, t, dist);
if(result != 0)
throw Exception("Error in finding splitting points on edge!");
}
auto p = curve->Value(t);
vend = BRepBuilderAPI_MakeVertex(p);
auto newE = TopoDS::Edge(self.EmptyCopied());
BOPTools_AlgoTools::MakeSplitEdge(self, vstart, tstart, vend, t, newE);
new_edges.push_back(newE);
vstart = vend;
tstart = t;
}
auto newE = TopoDS::Edge(self.EmptyCopied());
t = s1;
vend = TopExp::LastVertex(self);
BOPTools_AlgoTools::MakeSplitEdge(self, vstart, tstart, vend, t, newE);
new_edges.push_back(newE);
return new_edges;
}, "Splits edge at given parameters. Parameters can either be floating values in (0,1), then edge parametrization is used. Or it can be points, then the projection of these points are used for splitting the edge.")
;
py::class_<TopoDS_Wire, TopoDS_Shape> (m, "Wire")
.def(py::init([](const TopoDS_Edge & edge) {
BRepBuilderAPI_MakeWire builder;
builder.Add(edge);
return builder.Wire();
}))
.def(py::init([](std::vector<TopoDS_Shape> edges) {
BRepBuilderAPI_MakeWire builder;
try
{
for (auto s : edges)
switch (s.ShapeType())
{
case TopAbs_EDGE:
builder.Add(TopoDS::Edge(s)); break;
case TopAbs_WIRE:
builder.Add(TopoDS::Wire(s)); break;
default:
throw Exception("can make wire only from edges and wires");
}
return builder.Wire();
}
catch (Standard_Failure & e)
{
stringstream errstr;
e.Print(errstr);
throw NgException("error in wire builder: "+errstr.str());
}
}))
;
py::class_<TopoDS_Face, TopoDS_Shape> (m, "Face")
.def(py::init([](TopoDS_Wire wire) {
return BRepBuilderAPI_MakeFace(wire).Face();
}), py::arg("w"))
.def(py::init([](const TopoDS_Face & face, const TopoDS_Wire & wire) {
return BRepBuilderAPI_MakeFace(BRep_Tool::Surface (face), wire).Face();
}), py::arg("f"), py::arg("w"))
.def(py::init([](const TopoDS_Face & face, std::vector<TopoDS_Wire> wires) {
auto surf = BRep_Tool::Surface (face);
BRepBuilderAPI_MakeFace builder(surf, 1e-8);
for (auto w : wires)
builder.Add(w);
return builder.Face();
}), py::arg("f"), py::arg("w"))
.def(py::init([] (const TopoDS_Shape & shape) {
return TopoDS::Face(shape);
}))
.def_property_readonly("surf", [] (TopoDS_Face face) -> Handle(Geom_Surface)
{
Handle(Geom_Surface) surf = BRep_Tool::Surface (face);
return surf;
})
.def("WorkPlane",[] (const TopoDS_Face & face) {
Handle(Geom_Surface) surf = BRep_Tool::Surface (face);
gp_Vec du, dv;
gp_Pnt p;
surf->D1 (0,0,p,du,dv);
auto ax = gp_Ax3(p, du^dv, du);
return make_shared<WorkPlane> (ax);
})
;
py::class_<TopoDS_Solid, TopoDS_Shape> (m, "Solid");
py::class_<TopoDS_Compound, TopoDS_Shape> (m, "Compound")
.def(py::init([](std::vector<TopoDS_Shape> shapes) {
BRep_Builder builder;
TopoDS_Compound comp;
builder.MakeCompound(comp);
for(auto& s : shapes)
builder.Add(comp, s);
return comp;
}))
;
py::class_<Handle(Geom_Surface)> (m, "Geom_Surface")
.def("Value", [] (const Handle(Geom_Surface) & surf, double u, double v) {
return surf->Value(u, v); })
.def("D1", [] (const Handle(Geom_Surface) & surf, double u, double v) {
gp_Vec du, dv;
gp_Pnt p;
surf->D1 (u,v,p,du,dv);
return tuple(p,du,dv);
})
.def("Normal", [] (const Handle(Geom_Surface) & surf, double u, double v) {
GeomLProp_SLProps lprop(surf,u,v,1,1e-8);
if (lprop.IsNormalDefined())
return lprop.Normal();
throw Exception("normal not defined");
})
;
py::implicitly_convertible<TopoDS_Shape, TopoDS_Face>();
py::implicitly_convertible<TopoDS_Edge, TopoDS_Wire>();
class ListOfShapesIterator
{
TopoDS_Shape * ptr;
public:
ListOfShapesIterator (TopoDS_Shape * aptr) : ptr(aptr) { }
ListOfShapesIterator operator++ () { return ListOfShapesIterator(++ptr); }
auto operator*() const { return CastShape(*ptr); }
bool operator!=(ListOfShapesIterator it2) const { return ptr != it2.ptr; }
bool operator==(ListOfShapesIterator it2) const { return ptr == it2.ptr; }
};
py::class_<ListOfShapes> (m, "ListOfShapes")
.def("__iter__", [](ListOfShapes &s) {
return py::make_iterator(ListOfShapesIterator(&*s.begin()),
ListOfShapesIterator(&*s.end()));
},
py::keep_alive<0, 1>() /* Essential: keep object alive while iterator exists */)
.def("__getitem__", [](const ListOfShapes & list, size_t i) {
return CastShape(list[i]); })
.def("__getitem__", [](const ListOfShapes & self, py::slice inds) {
size_t start, step, n, stop;
if (!inds.compute(self.size(), &start, &stop, &step, &n))
throw py::error_already_set();
ListOfShapes sub;
sub.reserve(n);
for (size_t i = 0; i < n; i++)
sub.push_back (self[start+i*step]);
return sub;
})
.def("__add__", [](const ListOfShapes & l1, const ListOfShapes & l2) {
ListOfShapes l = l1;
for (auto s : l2) l.push_back(s);
return l;
} )
.def("__add__", [](const ListOfShapes & l1, py::list l2) {
ListOfShapes l = l1;
for (auto s : l2) l.push_back(py::cast<TopoDS_Shape>(s));
return l;
} )
.def("__len__", [](const ListOfShapes & self) { return self.size(); })
.def("__getitem__",[](const ListOfShapes & self, string name)
{
ListOfShapes selected;
for (auto s : self)
if (auto sname = OCCGeometry::global_shape_properties[s.TShape()].name)
if (sname == name)
selected.push_back(s);
return selected;
}, "returns list of all shapes named 'name'")
.def("__getitem__",[](const ListOfShapes & self, DirectionalInterval interval)
{
ListOfShapes selected;
for (auto s : self)
if (interval.Contains(Center(s)))
selected.push_back(s);
return selected;
})
.def_property_readonly("solids", &ListOfShapes::Solids)
.def_property_readonly("faces", &ListOfShapes::Faces)
.def_property_readonly("edges", &ListOfShapes::Edges)
.def_property_readonly("vertices", &ListOfShapes::Vertices)
.def(py::self * py::self)
.def("Sorted",[](ListOfShapes self, gp_Vec dir)
{
std::map<Handle(TopoDS_TShape), double> sortval;
for (auto shape : self)
{
GProp_GProps props;
gp_Pnt center;
switch (shape.ShapeType())
{
case TopAbs_VERTEX:
center = BRep_Tool::Pnt (TopoDS::Vertex(shape)); break;
case TopAbs_FACE:
BRepGProp::SurfaceProperties (shape, props);
center = props.CentreOfMass();
break;
default:
BRepGProp::LinearProperties(shape, props);
center = props.CentreOfMass();
}
double val = center.X()*dir.X() + center.Y()*dir.Y() + center.Z() * dir.Z();
sortval[shape.TShape()] = val;
}
std::sort (std::begin(self), std::end(self),
[&](TopoDS_Shape a, TopoDS_Shape b)
{ return sortval[a.TShape()] < sortval[b.TShape()]; });
return self;
}, py::arg("dir"), "returns list of shapes, where center of gravity is sorted in direction of 'dir'")
.def("Max", [] (ListOfShapes & shapes, gp_Vec dir)
{ return CastShape(shapes.Max(dir)); },
py::arg("dir"), "returns shape where center of gravity is maximal in the direction 'dir'")
.def("Min", [] (ListOfShapes & shapes, gp_Vec dir)
{ return CastShape(shapes.Max(-dir)); },
py::arg("dir"), "returns shape where center of gravity is minimal in the direction 'dir'")
.def("Nearest", [] (ListOfShapes & shapes, gp_Pnt pnt)
{ return CastShape(shapes.Nearest(pnt)); },
py::arg("p"), "returns shape nearest to point 'p'")
.def_property("name", [](ListOfShapes& shapes)
{
throw Exception("Cannot get property of ListOfShapes, get the property from individual shapes!");
},
[](ListOfShapes& shapes, std::string name)
{
for(auto& shape : shapes)
{
OCCGeometry::global_shape_properties[shape.TShape()].name = name;
}
}, "set name for all elements of list")
.def_property("col", [](ListOfShapes& shapes) {
throw Exception("Cannot get property of ListOfShapes, get the property from individual shapes!");
}, [](ListOfShapes& shapes, std::vector<double> c) {
Vec<4> col(c[0], c[1], c[2], 1.0);
if(c.size() == 4)
col[3] = c[3];
for(auto& shape : shapes)
OCCGeometry::global_shape_properties[shape.TShape()].col = col;
}, "set col for all elements of list")
.def_property("maxh", [](ListOfShapes& shapes)
{
throw Exception("Cannot get property of ListOfShapes, get the property from individual shapes!");
},
[](ListOfShapes& shapes, double maxh)
{
for(auto& shape : shapes)
{
OCCGeometry::global_shape_properties[shape.TShape()].maxh = maxh;
}
}, "set maxh for all elements of list")
;
py::class_<Handle(Geom2d_Curve)> (m, "Geom2d_Curve")
.def("Trim", [](Handle(Geom2d_Curve) curve, double u1, double u2) -> Handle(Geom2d_Curve)
{
return new Geom2d_TrimmedCurve (curve, u1, u2);
})
.def("Value", [](Handle(Geom2d_Curve) curve, double s) {
return curve->Value(s);
})
.def_property_readonly("start", [](Handle(Geom2d_Curve) curve) {
return curve->Value(curve->FirstParameter());
})
.def_property_readonly("end", [](Handle(Geom2d_Curve) curve) {
return curve->Value(curve->LastParameter());
})
.def("Edge", [](Handle(Geom2d_Curve) curve) {
// static Geom_Plane surf{gp_Ax3()}; // crashes in nbconvert ???
static auto surf = new Geom_Plane{gp_Ax3()};
auto edge = BRepBuilderAPI_MakeEdge(curve, surf).Edge();
BRepLib::BuildCurves3d(edge);
return edge;
})
.def("Wire", [](Handle(Geom2d_Curve) curve) {
// static Geom_Plane surf{gp_Ax3()}; // crashes in nbconvert ???
static auto surf = new Geom_Plane{gp_Ax3()};
auto edge = BRepBuilderAPI_MakeEdge(curve, surf).Edge();
BRepLib::BuildCurves3d(edge);
return BRepBuilderAPI_MakeWire(edge).Wire();
})
.def("Face", [](Handle(Geom2d_Curve) curve) {
// static Geom_Plane surf{gp_Ax3()}; // crashes in nbconvert ???
static auto surf = new Geom_Plane{gp_Ax3()};
auto edge = BRepBuilderAPI_MakeEdge(curve, surf).Edge();
BRepLib::BuildCurves3d(edge);
auto wire = BRepBuilderAPI_MakeWire(edge).Wire();
return BRepBuilderAPI_MakeFace(wire).Face();
})
;
m.def("HalfSpace", [] (gp_Pnt p, gp_Vec n)
{
gp_Pln plane(p, n);
BRepBuilderAPI_MakeFace bface(plane);
auto face = bface.Face();
auto refpnt = p.Translated(-n);
BRepPrimAPI_MakeHalfSpace builder(face, refpnt);
return builder.Shape();
}, py::arg("p"), py::arg("n"), "Create a half space threw point p normal to n");
m.def("Sphere", [] (gp_Pnt cc, double r) {
return BRepPrimAPI_MakeSphere (cc, r).Solid();
}, py::arg("c"), py::arg("r"), "create sphere with center 'c' and radius 'r'");
m.def("Cylinder", [] (gp_Pnt cpnt, gp_Dir cdir, double r, double h,
optional<string> bot, optional<string> top, optional<string> mantle) {
auto builder = BRepPrimAPI_MakeCylinder (gp_Ax2(cpnt, cdir), r, h);
if(mantle)
OCCGeometry::global_shape_properties[builder.Face().TShape()].name = *mantle;
auto pyshape = py::cast(builder.Solid());
gp_Vec v = cdir;
if(bot)
pyshape.attr("faces").attr("Min")(v).attr("name") = *bot;
if(top)
pyshape.attr("faces").attr("Max")(v).attr("name") = *top;
return pyshape;
}, py::arg("p"), py::arg("d"), py::arg("r"), py::arg("h"),
py::arg("bottom") = nullopt, py::arg("top") = nullopt,
py::arg("mantle") = nullopt,
"create cylinder with base point 'p', axis direction 'd', radius 'r', and height 'h'");
m.def("Cylinder", [] (gp_Ax2 ax, double r, double h) {
return BRepPrimAPI_MakeCylinder (ax, r, h).Solid();
}, py::arg("axis"), py::arg("r"), py::arg("h"),
"create cylinder given by axis, radius and height");
m.def("Box", [] (gp_Pnt cp1, gp_Pnt cp2) {
return BRepPrimAPI_MakeBox (cp1, cp2).Solid();
}, py::arg("p1"), py::arg("p2"),
"create box with opposite points 'p1' and 'p2'");
m.def("Prism", [] (const TopoDS_Shape & face, gp_Vec vec) {
return BRepPrimAPI_MakePrism (face, vec).Shape();
}, py::arg("face"), py::arg("v"),
"extrude face along the vector 'v'");
m.def("Revolve", [] (const TopoDS_Shape & face,const gp_Ax1 &A, const double D) {
//comvert angle from deg to rad
return BRepPrimAPI_MakeRevol (face, A, D*M_PI/180).Shape();
});
m.def("Pipe", [] (const TopoDS_Wire & spine, const TopoDS_Shape & profile,
optional<tuple<gp_Pnt, double>> twist,
optional<TopoDS_Wire> auxspine) {
if (twist)
{
auto [pnt, angle] = *twist;
/*
cyl = Cylinder((0,0,0), Z, r=1, h=1).faces[0]
heli = Edge(Segment((0,0), (2*math.pi, 1)), cyl)
auxspine = Wire( [heli] )
Handle(Geom_Surface) cyl = new Geom_CylindricalSurface (gp_Ax3(pnt, gp_Vec(0,0,1)), 1);
auto edge = BRepBuilderAPI_MakeEdge(curve2d, cyl).Edge();
BRepLib::BuildCurves3d(edge);
*/
throw Exception("twist not implemented");
}
if (auxspine)
{
BRepOffsetAPI_MakePipeShell builder(spine);
builder.SetMode (*auxspine, Standard_True);
for (TopExp_Explorer e(profile, TopAbs_WIRE); e.More(); e.Next())
builder.Add (TopoDS::Wire(e.Current()));
builder.Build();
builder.MakeSolid();
return builder.Shape();
}
return BRepOffsetAPI_MakePipe (spine, profile).Shape();
}, py::arg("spine"), py::arg("profile"), py::arg("twist")=nullopt, py::arg("auxspine")=nullopt);
m.def("PipeShell", [] (const TopoDS_Wire & spine, const TopoDS_Shape & profile, const TopoDS_Wire & auxspine) {
try
{
BRepOffsetAPI_MakePipeShell builder(spine);
builder.SetMode (auxspine, Standard_True);
builder.Add (profile);
// builder.Build();
// builder.MakeSolid();
return builder.Shape();
}
catch (Standard_Failure & e)
{
stringstream errstr;
e.Print(errstr);
throw NgException("cannot create PipeShell: "+errstr.str());
}
}, py::arg("spine"), py::arg("profile"), py::arg("auxspine"));
// Handle(Geom2d_Ellipse) anEllipse1 = new Geom2d_Ellipse(anAx2d, aMajor, aMinor);
m.def("Ellipse", [] (const gp_Ax2d & ax, double major, double minor) -> Handle(Geom2d_Curve)
{
return new Geom2d_Ellipse(ax, major, minor);
}, py::arg("axes"), py::arg("major"), py::arg("minor"), "create 2d ellipse curve");
m.def("Segment", [](gp_Pnt2d p1, gp_Pnt2d p2) -> Handle(Geom2d_Curve) {
return Handle(Geom2d_TrimmedCurve)(GCE2d_MakeSegment(p1, p2));
/*
Handle(Geom2d_TrimmedCurve) curve = GCE2d_MakeSegment(p1, p2);
return curve;
*/
}, py::arg("p1"), py::arg("p2"), "create 2d line curve");
m.def("Circle", [](gp_Pnt2d p1, double r) -> Handle(Geom2d_Curve) {
return Handle(Geom2d_Circle)(GCE2d_MakeCircle(p1, r));
/*
Handle(Geom2d_Circle) curve = GCE2d_MakeCircle(p1, r);
return curve;
*/
}, py::arg("c"), py::arg("r"), "create 2d circle curve");
m.def("Glue", [] (const std::vector<TopoDS_Shape> shapes) -> TopoDS_Shape
{
BOPAlgo_Builder builder;
for (auto & s : shapes)
{
bool has_solid = false;
for (TopExp_Explorer e(s, TopAbs_SOLID); e.More(); e.Next())
{
builder.AddArgument(e.Current());
has_solid = true;
}
if (has_solid) continue;
bool has_face = false;
for (TopExp_Explorer e(s, TopAbs_FACE); e.More(); e.Next())
{
builder.AddArgument(e.Current());
has_face = true;
}
if (has_face) continue;
bool has_edge = false;
for (TopExp_Explorer e(s, TopAbs_EDGE); e.More(); e.Next())
{
builder.AddArgument(e.Current());
has_edge = true;
}
if (has_edge) continue;
for (TopExp_Explorer e(s, TopAbs_VERTEX); e.More(); e.Next())
{
builder.AddArgument(e.Current());
}
}
builder.Perform();
/*
#ifdef OCC_HAVE_HISTORY
Handle(BRepTools_History) history = builder.History ();
for (auto typ : { TopAbs_SOLID, TopAbs_FACE, TopAbs_EDGE })
for (auto & s : shapes)
for (TopExp_Explorer e(s, typ); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
for (auto mods : history->Modified(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
#endif // OCC_HAVE_HISTORY
*/
for (auto & s : shapes)
PropagateProperties (builder, s);
return builder.Shape();
}, py::arg("shapes"), "glue together shapes of list");
m.def("Glue", [] (TopoDS_Shape shape) -> TopoDS_Shape
{
BOPAlgo_Builder builder;
for (TopExp_Explorer e(shape, TopAbs_SOLID); e.More(); e.Next())
builder.AddArgument(e.Current());
builder.Perform();
if (builder.HasErrors())
builder.DumpErrors(cout);
if (builder.HasWarnings())
builder.DumpWarnings(cout);
/*
#ifdef OCC_HAVE_HISTORY
Handle(BRepTools_History) history = builder.History ();
for (TopExp_Explorer e(shape, TopAbs_SOLID); e.More(); e.Next())
{
auto prop = OCCGeometry::global_shape_properties[e.Current().TShape()];
for (auto mods : history->Modified(e.Current()))
OCCGeometry::global_shape_properties[mods.TShape()].Merge(prop);
}
#endif // OCC_HAVE_HISTORY
*/
PropagateProperties (builder, shape);
return builder.Shape();
}, py::arg("shape"), "glue together shapes from shape, typically a compound");
// py::class_<Handle(Geom_TrimmedCurve)> (m, "Geom_TrimmedCurve")
// ;
m.def("Segment", [](gp_Pnt p1, gp_Pnt p2) {
Handle(Geom_TrimmedCurve) curve = GC_MakeSegment(p1, p2);
return BRepBuilderAPI_MakeEdge(curve).Edge();
});
m.def("Circle", [](gp_Pnt c, gp_Dir n, double r) {
Handle(Geom_Circle) curve = GC_MakeCircle (c, n, r);
return BRepBuilderAPI_MakeEdge(curve).Edge();
});
m.def("ArcOfCircle", [](gp_Pnt p1, gp_Pnt p2, gp_Pnt p3) {
Handle(Geom_TrimmedCurve) curve = GC_MakeArcOfCircle(p1, p2, p3);
return BRepBuilderAPI_MakeEdge(curve).Edge();
}, py::arg("p1"), py::arg("p2"), py::arg("p3"),
"create arc from p1 through p2 to p3");
m.def("ArcOfCircle", [](gp_Pnt p1, gp_Vec v, gp_Pnt p2) {
Handle(Geom_TrimmedCurve) curve = GC_MakeArcOfCircle(p1, v, p2);
return BRepBuilderAPI_MakeEdge(curve).Edge();
}, py::arg("p1"), py::arg("v"), py::arg("p2"),
"create arc from p1, with tangent vector v, to point p2");
m.def("BSplineCurve", [](std::vector<gp_Pnt> vpoles, int degree) {
// not yet working ????
TColgp_Array1OfPnt poles(0, vpoles.size()-1);
TColStd_Array1OfReal knots(0, vpoles.size()+degree);
TColStd_Array1OfInteger mult(0, vpoles.size()+degree);
int cnt = 0;
for (int i = 0; i < vpoles.size(); i++)
{
poles.SetValue(i, vpoles[i]);
knots.SetValue(i, i);
mult.SetValue(i,1);
}
for (int i = vpoles.size(); i < vpoles.size()+degree+1; i++)
{
knots.SetValue(i, i);
mult.SetValue(i, 1);
}
Handle(Geom_Curve) curve = new Geom_BSplineCurve(poles, knots, mult, degree);
return BRepBuilderAPI_MakeEdge(curve).Edge();
});
m.def("BezierCurve", [](std::vector<gp_Pnt> vpoles) {
TColgp_Array1OfPnt poles(0, vpoles.size()-1);
for (int i = 0; i < vpoles.size(); i++)
poles.SetValue(i, vpoles[i]);
Handle(Geom_Curve) curve = new Geom_BezierCurve(poles);
return BRepBuilderAPI_MakeEdge(curve).Edge();
}, py::arg("points"), "create Bezier curve");
m.def("SplineApproximation", [](std::vector<gp_Pnt> pnts, double tol) {
TColgp_Array1OfPnt points(0, pnts.size()-1);
for (int i = 0; i < pnts.size(); i++)
points.SetValue(i, pnts[i]);
GeomAPI_PointsToBSpline builder(points);
return BRepBuilderAPI_MakeEdge(builder.Curve()).Edge();
}, py::arg("points"), py::arg("tol"),
"Generate spline-curve approximating list of points up to tolerance tol");
m.def("MakeFillet", [](TopoDS_Shape shape, std::vector<TopoDS_Shape> edges, double r) {
throw Exception("call 'shape.MakeFilled'");
BRepFilletAPI_MakeFillet mkFillet(shape);
for (auto e : edges)
mkFillet.Add (r, TopoDS::Edge(e));
return mkFillet.Shape();
}, "deprecated, use 'shape.MakeFillet'");
m.def("MakeThickSolid", [](TopoDS_Shape body, std::vector<TopoDS_Shape> facestoremove,
double offset, double tol) {
throw Exception("call 'shape.MakeThickSolid'");
TopTools_ListOfShape faces;
for (auto f : facestoremove)
faces.Append(f);
BRepOffsetAPI_MakeThickSolid maker;
maker.MakeThickSolidByJoin(body, faces, offset, tol);
return maker.Shape();
}, "deprecated, use 'shape.MakeThickSolid'");
m.def("ThruSections", [](std::vector<TopoDS_Shape> wires, bool solid)
{
BRepOffsetAPI_ThruSections aTool(solid); // Standard_True);
for (auto shape : wires)
aTool.AddWire(TopoDS::Wire(shape));
aTool.CheckCompatibility(Standard_False);
return aTool.Shape();
}, py::arg("wires"), py::arg("solid")=true,
"Building a loft. This is a shell or solid passing through a set of sections (wires). "
"First and last sections may be vertices. See https://dev.opencascade.org/doc/refman/html/class_b_rep_offset_a_p_i___thru_sections.html#details");
py::class_<WorkPlane, shared_ptr<WorkPlane>> (m, "WorkPlane")
.def(py::init<gp_Ax3, gp_Ax2d>(), py::arg("axes")=gp_Ax3(), py::arg("pos")=gp_Ax2d())
.def("MoveTo", &WorkPlane::MoveTo, py::arg("h"), py::arg("v"), "moveto (h,v), and start new wire")
.def("Move", &WorkPlane::Move, py::arg("l"), "move 'l' from current position and direction, start new wire")
.def("Direction", &WorkPlane::Direction, py::arg("dirh"), py::arg("dirv"), "reset direction to (dirh, dirv)")
// .def("LineTo", &WorkPlane::LineTo)
.def("LineTo", [](WorkPlane&wp, double x, double y, optional<string> name) { return wp.LineTo(x, y, name); },
py::arg("h"), py::arg("v"), py::arg("name")=nullopt, "draw line to position (h,v)")
.def("ArcTo", &WorkPlane::ArcTo)
.def("Arc", &WorkPlane::Arc, py::arg("r"), py::arg("ang"), "draw arc tangential to current pos/dir, of radius 'r' and angle 'ang', draw to the left/right if ang is positive/negative")
.def("Rotate", &WorkPlane::Rotate, py::arg("ang"), "rotate current direction by 'ang' degrees")
.def("Line", [](WorkPlane&wp,double l, optional<string> name) { return wp.Line(l, name); },
py::arg("l"), py::arg("name")=nullopt)
.def("Line", [](WorkPlane&wp,double h,double v, optional<string> name) { return wp.Line(h,v,name); },
py::arg("dx"), py::arg("dy"), py::arg("name")=nullopt)
.def("Rectangle", &WorkPlane::Rectangle, py::arg("l"), py::arg("w"), "draw rectangle, with current position as corner, use current direction")
.def("RectangleC", &WorkPlane::RectangleCentered, py::arg("l"), py::arg("w"), "draw rectangle, with current position as center, use current direction")
.def("Circle", [](WorkPlane&wp, double x, double y, double r) {
return wp.Circle(x,y,r); }, py::arg("h"), py::arg("v"), py::arg("r"), "draw circle with center (h,v) and radius 'r'")
.def("Circle", [](WorkPlane&wp, double r) { return wp.Circle(r); }, py::arg("r"), "draw circle with center in current position")
.def("NameVertex", &WorkPlane::NameVertex, py::arg("name"), "name vertex at current position")
.def("Offset", &WorkPlane::Offset, py::arg("d"), "replace current wire by offset curve of distance 'd'")
.def("Reverse", &WorkPlane::Reverse, "revert orientation of current wire")
.def("Close", &WorkPlane::Close, "draw line to start point of wire, and finish wire")
.def("Finish", &WorkPlane::Finish, "finish current wire without closing")
.def("Last", &WorkPlane::Last, "(deprecated) returns current wire")
.def("Wire", &WorkPlane::Last, "returns current wire")
.def("Face", &WorkPlane::Face, "generate and return face of all wires, resets list of wires")
.def("Wires", &WorkPlane::Wires, "returns all wires")
;
}
#endif // OCCGEOMETRY
#endif // NG_PYTHON