create/src/Mod/Part/App/TopoShapePy.xml

<?xml version="1.0" encoding="UTF-8"?>
<GenerateModel xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:noNamespaceSchemaLocation="generateMetaModel_Module.xsd">
  <PythonExport 
      Father="ComplexGeoDataPy" 
      Name="TopoShapePy" 
      Twin="TopoShape" 
      TwinPointer="TopoShape" 
      Include="Mod/Part/App/TopoShape.h" 
      Namespace="Part" 
      FatherInclude="App/ComplexGeoDataPy.h" 
      FatherNamespace="Data"
      Constructor="true">
    <Documentation>
      <Author Licence="LGPL" Name="Juergen Riegel" EMail="Juergen.Riegel@web.de" />
      <UserDocu>TopoShape is the OpenCasCade topological shape wrapper.
Sub-elements such as vertices, edges or faces are accessible as:
* Vertex#, where # is in range(1, number of vertices)
* Edge#, where # is in range(1, number of edges)
* Face#, where # is in range(1, number of faces)</UserDocu>
    </Documentation>
    <Methode Name="read">
      <Documentation>
        <UserDocu>Read in an IGES, STEP or BREP file.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="writeInventor" Const="true">
      <Documentation>
        <UserDocu>Write the mesh in OpenInventor format to a string.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="exportIges" Const="true">
      <Documentation>
        <UserDocu>Export the content of this shape to an IGES file.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="exportStep" Const="true">
      <Documentation>
        <UserDocu>Export the content of this shape to an STEP file.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="exportBrep" Const="true">
      <Documentation>
        <UserDocu>Export the content of this shape to an BREP file. BREP is a CasCade native format.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="exportBrepToString" Const="true">
      <Documentation>
        <UserDocu>Export the content of this shape to a string in BREP format. BREP is a CasCade native format.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="exportStl" Const="true">
      <Documentation>
        <UserDocu>Export the content of this shape to an STL mesh file.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="importBrep">
      <Documentation>
        <UserDocu>Import the content to this shape of a string in BREP format.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="importBrepFromString">
      <Documentation>
        <UserDocu>Import the content to this shape from a string in BREP format.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="extrude" Const="true">
      <Documentation>
        <UserDocu>Extrude the shape along a direction.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="revolve" Const="true">
      <Documentation>
        <UserDocu>Revolve the shape around a Axis to a given degree.
Part.revolve(Vector(0,0,0),Vector(0,0,1),360) - revolves the shape around the Z Axis 360 degree. 
        </UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="check" Const="true">
      <Documentation>
        <UserDocu>Checks the shape and report errors in the shape structure.
This is a more detailed check as done in isValid().</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="fuse" Const="true">
      <Documentation>
        <UserDocu>Union of this and a given topo shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="oldFuse" Const="true">
      <Documentation>
        <UserDocu>Union of this and a given topo shape (old algorithm).</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="common" Const="true">
      <Documentation>
        <UserDocu>Intersection of this and a given topo shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="section" Const="true">
      <Documentation>
        <UserDocu>Section of this with a given topo shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="slices" Const="true">
      <Documentation>
        <UserDocu>Make slices of this shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="slice" Const="true">
      <Documentation>
        <UserDocu>Make single slice of this shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="cut" Const="true">
      <Documentation>
        <UserDocu>Difference of this and a given topo shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="sewShape">
      <Documentation>
        <UserDocu>Sew the shape if there is a gap.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="removeInternalWires">
      <Documentation>
        <UserDocu>Removes internal wires (also holes) from the shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="mirror" Const="true">
      <Documentation>
        <UserDocu>Mirror this shape on a given plane.
The plane is given with its base point and its normal direction.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="transformGeometry" Const="true">
      <Documentation>
        <UserDocu>Apply geometric transformation on a copy of the shape.
The transformation to be applied is defined as a 4x4 matrix.
The underlying geometry of the following shapes may change:
- a curve which supports an edge of the shape, or
- a surface which supports a face of the shape;

For example, a circle may be transformed into an ellipse when
applying an affinity transformation. It may also happen that
the circle then is represented as a b-spline curve.

The transformation is applied to:
- all the curves which support edges of the shape, and
- all the surfaces which support faces of the shape.

Note: If you want to transform a shape without changing the
underlying geometry then use the methods translate or rotate.
</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="transformShape">
      <Documentation>
        <UserDocu>Apply transformation on a shape without changing
the underlying geometry.
transformShape(Matrix,[boolean copy=False])</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="translate">
      <Documentation>
        <UserDocu>Apply the translation to the current location of this shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="rotate">
      <Documentation>
        <UserDocu>
          Apply the rotation (degree) to the current location of this shape
          Shp.rotate(Vector(0,0,0),Vector(0,0,1),180) - rotate the shape around the Z Axis 180 degrees.
        </UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="scale">
      <Documentation>
        <UserDocu>Apply scaling with point and factor to this shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="makeFillet" Const="true">
      <Documentation>
        <UserDocu>Make fillet.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="makeChamfer" Const="true">
      <Documentation>
        <UserDocu>Make chamfer.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="makeThickness" Const="true">
      <Documentation> 
        <UserDocu>makeThickness(List of shapes, Offset (Float), Tolerance (Float)) -> Shape
A hollowed solid is built from an initial solid and a set of faces on this solid,
which are to be removed. The remaining faces of the solid become the walls of
the hollowed solid, their thickness defined at the time of construction.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="makeOffsetShape" Const="true">
      <Documentation> 
        <UserDocu>Offset a given shape</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="reverse">
      <Documentation>
        <UserDocu>Reverses the orientation of this shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="complement">
      <Documentation>
        <UserDocu>Computes the complement of the orientation of this shape,
i.e. reverses the interior/exterior status of boundaries of this shape.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="nullify">
      <Documentation>
        <UserDocu>Destroys the reference to the underlying shape stored in this shape.
As a result, this shape becomes null.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="isClosed" Const="true">
      <Documentation>
        <UserDocu>Checks if the shape is closed.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="isPartner" Const="true">
      <Documentation>
        <UserDocu>Checks if both shapes share the same geometry.
        Placement and orientation may differ.
        </UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="isSame" Const="true">
      <Documentation>
        <UserDocu>Checks if both shapes share the same geometry
        and placement. Orientation may differ.
        </UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="isEqual" Const="true">
      <Documentation>
        <UserDocu>Checks if both shapes are equal.
        This means geometry, placement and orientation are equal.
        </UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="isNull" Const="true">
      <Documentation>
        <UserDocu>Checks if the shape is null.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="isValid" Const="true">
      <Documentation>
        <UserDocu>Checks if the shape is valid, i.e. neither null, nor empty nor corrupted.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="fix">
      <Documentation>
        <UserDocu>Tries t fix a broken shape. True is returned if the operation succeeded, False otherwise.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="hashCode" Const="true">
      <Documentation>
        <UserDocu>This value is computed from the value of the underlying shape reference and the location.
Orientation is not taken into account.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="tessellate" Const="true">
      <Documentation>
        <UserDocu>Tessellate the the shape and return a list of vertices and face indices</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="project" Const="true">
      <Documentation>
        <UserDocu>Project a shape on this shape</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="makeShapeFromMesh">
      <Documentation>
        <UserDocu>Make a compund shape out of mesh data.
Note: This should be used for rather small meshes only.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="toNurbs" Const="true">
      <Documentation>
        <UserDocu>Conversion of the complete geometry of a shape into NURBS geometry.
For example, all curves supporting edges of the basis shape are converted
into BSpline curves, and all surfaces supporting its faces are converted
into BSpline surfaces.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="copy" Const="true">
      <Documentation>
        <UserDocu>Create a copy of this shape</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="replaceShape" Const="true">
      <Documentation>
        <UserDocu>Replace a sub-shape with a new shape and return a new shape.
The parameter is in the form list of tuples with the two shapes.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="removeShape" Const="true">
      <Documentation>
        <UserDocu>Remove a sub-shape and return a new shape.
The parameter is a list of shapes.</UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="isInside" Const="true">
      <Documentation>
        <UserDocu>Checks whether a point is inside or outside the shape.
isInside(App.Vector, float, Boolean) => Boolean
The App.Vector is the point you want to check if it's inside or not
float gives the tolerance
Boolean indicates if the point lying directly on a face is considered to be inside or not 
        </UserDocu>
      </Documentation>
    </Methode>
    <Methode Name="removeSplitter" Const="true">
      <Documentation>
        <UserDocu>Removes redundant edges from the B-REP model</UserDocu>
      </Documentation>
    </Methode>
<!--
    <Attribute Name="Location" ReadOnly="false">
      <Documentation>
        <UserDocu>Gets or sets the local coordinate system of this shape.</UserDocu>
      </Documentation>
      <Parameter Name="Location" Type="Object"/>
    </Attribute>
-->
    <Attribute Name="ShapeType" ReadOnly="true">
      <Documentation>
        <UserDocu>Returns the type of the shape.</UserDocu>
      </Documentation>
      <Parameter Name="ShapeType" Type="String"/>
    </Attribute>
    <Attribute Name="Orientation" ReadOnly="false">
      <Documentation>
        <UserDocu>Returns the orientation of the shape.</UserDocu>
      </Documentation>
      <Parameter Name="Orientation" Type="String"/>
    </Attribute>
    <Attribute Name="Faces" ReadOnly="true">
      <Documentation>
        <UserDocu>List of faces in this shape.</UserDocu>
      </Documentation>
      <Parameter Name="Faces" Type="List"/>
    </Attribute>
    <Attribute Name="Vertexes" ReadOnly="true">
      <Documentation>
        <UserDocu>List of vertexes in this shape.</UserDocu>
      </Documentation>
      <Parameter Name="Vertexes" Type="List"/>
    </Attribute>
	  <Attribute Name="Shells" ReadOnly="true">
		  <Documentation>
			  <UserDocu>List of subsequent shapes in this shape.</UserDocu>
		  </Documentation>
		  <Parameter Name="Shells" Type="List"/>
	  </Attribute>
	  <Attribute Name="Solids" ReadOnly="true">
		  <Documentation>
			  <UserDocu>List of subsequent shapes in this shape.</UserDocu>
		  </Documentation>
		  <Parameter Name="Solids" Type="List"/>
	  </Attribute>
	  <Attribute Name="CompSolids" ReadOnly="true">
	  <Documentation>
		  <UserDocu>List of subsequent shapes in this shape.</UserDocu>
	  </Documentation>
	  <Parameter Name="CompSolids" Type="List"/>
	</Attribute>
	<Attribute Name="Edges" ReadOnly="true">
      <Documentation>
       <UserDocu>List of Edges in this shape.</UserDocu>
      </Documentation>
      <Parameter Name="Edges" Type="List"/>
   </Attribute>
    <Attribute Name="Wires" ReadOnly="true">
      <Documentation>
        <UserDocu>List of wires in this shape.</UserDocu>
      </Documentation>
      <Parameter Name="Wires" Type="List"/>
    </Attribute>
    <Attribute Name="Compounds" ReadOnly="true">
      <Documentation>
        <UserDocu>List of coumpounds in this shape.</UserDocu>
      </Documentation>
      <Parameter Name="Compounds" Type="List"/>
    </Attribute>
    <Attribute Name="Length" ReadOnly="true">
      <Documentation>
        <UserDocu>Total length of the edges of the shape.</UserDocu>
      </Documentation>
      <Parameter Name="Length" Type="Float"/>
    </Attribute>
    <Attribute Name="Area" ReadOnly="true">
      <Documentation>
        <UserDocu>Total area of the faces of the shape.</UserDocu>
      </Documentation>
      <Parameter Name="Area" Type="Float"/>
    </Attribute>
    <Attribute Name="Volume" ReadOnly="true">
      <Documentation>
        <UserDocu>Total volume of the solids of the shape.</UserDocu>
      </Documentation>
      <Parameter Name="Volume" Type="Float"/>
    </Attribute>
  </PythonExport>
</GenerateModel>