Example #1
0
def make_loft(elements, ruled=False, tolerance=TOLERANCE, continuity=GeomAbs_C2, check_compatibility=True):
    from OCC.Core.BRepOffsetAPI import BRepOffsetAPI_ThruSections
    sections = BRepOffsetAPI_ThruSections(False, ruled, tolerance)
    for i in elements:
        if isinstance(i, TopoDS_Wire):
            sections.AddWire(i)
        elif isinstance(i, TopoDS_Vertex):
            sections.AddVertex(i)
        else:
            raise TypeError('elements is a list of TopoDS_Wire or TopoDS_Vertex, found a %s fool' % i.__class__)

    sections.CheckCompatibility(check_compatibility)
    sections.SetContinuity(continuity)
    sections.Build()
    with assert_isdone(sections, 'failed lofting'):
        te = ShapeToTopology()
        loft = te(sections.Shape())
        return loft
Example #2
0
def startBottle(startOnly=True):  # minus the neck fillet, shelling & threads
    partName = "Bottle-start"
    # The points we'll use to create the profile of the bottle's body
    aPnt1 = gp_Pnt(-width / 2.0, 0, 0)
    aPnt2 = gp_Pnt(-width / 2.0, -thickness / 4.0, 0)
    aPnt3 = gp_Pnt(0, -thickness / 2.0, 0)
    aPnt4 = gp_Pnt(width / 2.0, -thickness / 4.0, 0)
    aPnt5 = gp_Pnt(width / 2.0, 0, 0)

    aArcOfCircle = GC_MakeArcOfCircle(aPnt2, aPnt3, aPnt4)
    aSegment1 = GC_MakeSegment(aPnt1, aPnt2)
    aSegment2 = GC_MakeSegment(aPnt4, aPnt5)

    # Could also construct the line edges directly using the points
    # instead of the resulting line.
    aEdge1 = BRepBuilderAPI_MakeEdge(aSegment1.Value())
    aEdge2 = BRepBuilderAPI_MakeEdge(aArcOfCircle.Value())
    aEdge3 = BRepBuilderAPI_MakeEdge(aSegment2.Value())

    # Create a wire out of the edges
    aWire = BRepBuilderAPI_MakeWire(aEdge1.Edge(), aEdge2.Edge(),
                                    aEdge3.Edge())

    # Quick way to specify the X axis
    xAxis = gp_OX()

    # Set up the mirror
    aTrsf = gp_Trsf()
    aTrsf.SetMirror(xAxis)

    # Apply the mirror transformation
    aBRespTrsf = BRepBuilderAPI_Transform(aWire.Wire(), aTrsf)

    # Get the mirrored shape back out of the transformation
    # and convert back to a wire
    aMirroredShape = aBRespTrsf.Shape()

    # A wire instead of a generic shape now
    aMirroredWire = topods.Wire(aMirroredShape)

    # Combine the two constituent wires
    mkWire = BRepBuilderAPI_MakeWire()
    mkWire.Add(aWire.Wire())
    mkWire.Add(aMirroredWire)
    myWireProfile = mkWire.Wire()

    # The face that we'll sweep to make the prism
    myFaceProfile = BRepBuilderAPI_MakeFace(myWireProfile)

    # We want to sweep the face along the Z axis to the height
    aPrismVec = gp_Vec(0, 0, height)
    myBody = BRepPrimAPI_MakePrism(myFaceProfile.Face(), aPrismVec)

    # Add fillets to all edges through the explorer
    mkFillet = BRepFilletAPI_MakeFillet(myBody.Shape())
    anEdgeExplorer = TopExp_Explorer(myBody.Shape(), TopAbs_EDGE)

    while anEdgeExplorer.More():
        anEdge = topods.Edge(anEdgeExplorer.Current())
        mkFillet.Add(thickness / 12.0, anEdge)

        anEdgeExplorer.Next()

    myBody = mkFillet.Shape()

    # Create the neck of the bottle
    neckLocation = gp_Pnt(0, 0, height)
    neckAxis = gp_DZ()
    neckAx2 = gp_Ax2(neckLocation, neckAxis)

    myNeckRadius = thickness / 4.0
    myNeckHeight = height / 10.0

    mkCylinder = BRepPrimAPI_MakeCylinder(neckAx2, myNeckRadius, myNeckHeight)
    myBody = BRepAlgoAPI_Fuse(myBody, mkCylinder.Shape())
    if startOnly:  # quit here
        uid = win.getNewPartUID(myBody.Shape(), name=partName)
        win.redraw()
        return

    partName = "Bottle-complete"
    # Our goal is to find the highest Z face and remove it
    faceToRemove = None
    zMax = -1

    # We have to work our way through all the faces to find the highest Z face
    aFaceExplorer = TopExp_Explorer(myBody.Shape(), TopAbs_FACE)
    while aFaceExplorer.More():
        aFace = topods.Face(aFaceExplorer.Current())

        if face_is_plane(aFace):
            aPlane = geom_plane_from_face(aFace)

            # We want the highest Z face, so compare this to the previous faces
            aPnt = aPlane.Location()
            aZ = aPnt.Z()
            if aZ > zMax:
                zMax = aZ
                faceToRemove = aFace

        aFaceExplorer.Next()

    facesToRemove = TopTools_ListOfShape()
    facesToRemove.Append(faceToRemove)

    myBody = BRepOffsetAPI_MakeThickSolid(myBody.Shape(), facesToRemove,
                                          -thickness / 50.0, 0.001)

    # Set up our surfaces for the threading on the neck
    neckAx2_Ax3 = gp_Ax3(neckLocation, gp_DZ())
    aCyl1 = Geom_CylindricalSurface(neckAx2_Ax3, myNeckRadius * 0.99)
    aCyl2 = Geom_CylindricalSurface(neckAx2_Ax3, myNeckRadius * 1.05)

    # Set up the curves for the threads on the bottle's neck
    aPnt = gp_Pnt2d(2.0 * math.pi, myNeckHeight / 2.0)
    aDir = gp_Dir2d(2.0 * math.pi, myNeckHeight / 4.0)
    anAx2d = gp_Ax2d(aPnt, aDir)

    aMajor = 2.0 * math.pi
    aMinor = myNeckHeight / 10.0

    anEllipse1 = Geom2d_Ellipse(anAx2d, aMajor, aMinor)
    anEllipse2 = Geom2d_Ellipse(anAx2d, aMajor, aMinor / 4.0)

    anArc1 = Geom2d_TrimmedCurve(anEllipse1, 0, math.pi)
    anArc2 = Geom2d_TrimmedCurve(anEllipse2, 0, math.pi)

    anEllipsePnt1 = anEllipse1.Value(0)
    anEllipsePnt2 = anEllipse1.Value(math.pi)

    aSegment = GCE2d_MakeSegment(anEllipsePnt1, anEllipsePnt2)

    # Build edges and wires for threading
    anEdge1OnSurf1 = BRepBuilderAPI_MakeEdge(anArc1, aCyl1)
    anEdge2OnSurf1 = BRepBuilderAPI_MakeEdge(aSegment.Value(), aCyl1)
    anEdge1OnSurf2 = BRepBuilderAPI_MakeEdge(anArc2, aCyl2)
    anEdge2OnSurf2 = BRepBuilderAPI_MakeEdge(aSegment.Value(), aCyl2)

    threadingWire1 = BRepBuilderAPI_MakeWire(anEdge1OnSurf1.Edge(),
                                             anEdge2OnSurf1.Edge())
    threadingWire2 = BRepBuilderAPI_MakeWire(anEdge1OnSurf2.Edge(),
                                             anEdge2OnSurf2.Edge())

    # Compute the 3D representations of the edges/wires
    breplib.BuildCurves3d(threadingWire1.Shape())
    breplib.BuildCurves3d(threadingWire2.Shape())

    # Create the surfaces of the threading
    aTool = BRepOffsetAPI_ThruSections(True)
    aTool.AddWire(threadingWire1.Wire())
    aTool.AddWire(threadingWire2.Wire())
    aTool.CheckCompatibility(False)
    myThreading = aTool.Shape()

    # Build the resulting compound
    aRes = TopoDS_Compound()
    aBuilder = BRep_Builder()
    aBuilder.MakeCompound(aRes)
    aBuilder.Add(aRes, myBody.Shape())
    aBuilder.Add(aRes, myThreading)
    uid = win.getNewPartUID(aRes, name=partName)
    win.redraw()
anEdge2OnSurf1 = BRepBuilderAPI_MakeEdge(aSegment.Value(), aCyl1)
anEdge1OnSurf2 = BRepBuilderAPI_MakeEdge(anArc2, aCyl2)
anEdge2OnSurf2 = BRepBuilderAPI_MakeEdge(aSegment.Value(), aCyl2)

threadingWire1 = BRepBuilderAPI_MakeWire(anEdge1OnSurf1.Edge(),
                                         anEdge2OnSurf1.Edge())
threadingWire2 = BRepBuilderAPI_MakeWire(anEdge1OnSurf2.Edge(),
                                         anEdge2OnSurf2.Edge())

# Compute the 3D representations of the edges/wires
breplib.BuildCurves3d(threadingWire1.Shape())
breplib.BuildCurves3d(threadingWire2.Shape())

# Create the surfaces of the threading
aTool = BRepOffsetAPI_ThruSections(True)
aTool.AddWire(threadingWire1.Wire())
aTool.AddWire(threadingWire2.Wire())
aTool.CheckCompatibility(False)
myThreading = aTool.Shape()

# Build the resulting compound
bottle = TopoDS_Compound()
aBuilder = BRep_Builder()
aBuilder.MakeCompound(bottle)
aBuilder.Add(bottle, myBody_step3.Shape())
aBuilder.Add(bottle, myThreading)
print("bottle created")

export_shape_to_svg(bottle, "./test_mypy_classic_occ_bottle.svg")
write_step_file(bottle, "./test_mypy_classic_occ_bottle.stp")
Example #4
0
class LoftShape(object):
    """
    Loft a shape using a sequence of sections.

    :param sections: The sections of the loft. These
        are usually wires but the first and last section can be vertices.
        Edges are converted to wires before adding to the loft tool.
    :type sections: collections.Sequence(afem.topology.entities.Vertex or
        afem.topology.entities.Edge or afem.topology.entities.Wire)
    :param bool is_solid: If *True* the tool will build a solid, otherwise
        it will build a shell.
    :param bool make_ruled: If *True* the faces between sections will be ruled
        surfaces, otherwise they are smoothed out by approximation.
    :param float pres3d: Defines the precision for the approximation algorithm.
    :param bool check_compatibility: Option to check the orientation of the
        sections to avoid twisted results and update to have the same number
        of edges.
    :param bool use_smoothing: Option to use approximation algorithm.
    :param OCC.Core.Approx.Approx_ParametrizationType par_type: Parametrization
        type.

    :param OCC.Core.GeomAbs.GeomAbs_Shape continuity: The desired continuity.
    :param int max_degree: The maximum degree for the approximation
        algorithm.

    :raise TypeError: If any of the sections cannot be added to the tool
        because they are of the wrong type.
    """
    def __init__(self,
                 sections,
                 is_solid=False,
                 make_ruled=False,
                 pres3d=1.0e-6,
                 check_compatibility=None,
                 use_smoothing=None,
                 par_type=None,
                 continuity=None,
                 max_degree=None):
        self._tool = BRepOffsetAPI_ThruSections(is_solid, make_ruled, pres3d)

        if check_compatibility is not None:
            self._tool.CheckCompatibility(check_compatibility)

        if use_smoothing is not None:
            self._tool.SetSmoothing(use_smoothing)

        if par_type is not None:
            self._tool.SetParType(par_type)

        if continuity is not None:
            self._tool.SetContinuity(continuity)

        if max_degree is not None:
            self._tool.SetMaxDegree(max_degree)

        for section in sections:
            if section.is_vertex:
                self._tool.AddVertex(section.object)
            elif section.is_edge:
                wire = Wire.by_edge(section)
                self._tool.AddWire(wire.object)
            elif section.is_wire:
                self._tool.AddWire(section.object)
            else:
                raise TypeError('Invalid shape type in loft.')

        self._tool.Build()

    @property
    def is_done(self):
        """
        :return: *True* if done, *False* if not.
        :rtype: bool
        """
        return self._tool.IsDone()

    @property
    def shape(self):
        """
        :return: The lofted shape.
        :rtype: afem.topology.entities.Shape
        """
        return Shape.wrap(self._tool.Shape())

    @property
    def first_shape(self):
        """
        :return: The first/bottom shape of the loft if a solid was
            constructed.
        :rtype: afem.topology.entities.Shape
        """
        return Shape.wrap(self._tool.FirstShape())

    @property
    def last_shape(self):
        """
        :return: The last/top shape of the loft if a solid was constructed.
        :rtype: afem.topology.entities.Shape
        """
        return Shape.wrap(self._tool.LastShape())

    @property
    def max_degree(self):
        """
        :return: The max degree used in the approximation algorithm
        :rtype: int
        """
        return self._tool.MaxDegree()

    def generated_face(self, edge):
        """
        Get a face(s) generated by the edge. If the ruled option was used,
        then this returns each face generated by the edge. If the smoothing
        option was used, then this returns the face generated by the edge.

        :param afem.topology.entities.Edge edge: The edge.

        :return: The face(s) generated by the edge.
        :rtype: afem.topology.entities.Shape
        """
        return Shape.wrap(self._tool.GeneratedFace(edge.object))