Esempio n. 1
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def make_drawer_box(dx, dy, dz, separator_offsets):
    """Makes a box to contain simple drawers.

    Args:
        dx (float): The total outer width of the drawer box
        dy (float): The total outer depth of the drawer box
        dz (float): The total outer height of the drawer box
        separator_offsets (List[float]): The distance from 
            the outer bottom of the drawer box to the top of
            each drawer separator.

    Returns:
        A TopoDS_Compound representing the drawer box.
    """
    pieces = [
        _make_side(dx, dy, dz, separator_offsets, True),
        _make_side(dx, dy, dz, separator_offsets, False),
        _make_topbottom(dx, dy, dz, True),
        _make_topbottom(dx, dy, dz, False),
        _make_back(dx, dy, dz)
    ]
    for separator_offset in separator_offsets:
        pieces.append(_make_separator(dx, dy, separator_offset))

    builder = TopoDS_Builder()
    compound = TopoDS_Compound()
    builder.MakeCompound(compound)
    for piece in pieces:
        builder.Add(compound, piece)
    return compound
Esempio n. 2
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def _combine(*components):
    builder = TopoDS_Builder()
    compound = TopoDS_Compound()
    builder.MakeCompound(compound)
    for c in components:
        builder.Add(compound, c)
    return compound
Esempio n. 3
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def make_drawers(dx, dy, dz, arrangement):
    air_space = 0.05
    available_z_space = dz - THICKNESS_0 * (len(arrangement) + 1)
    drawer_space_height = available_z_space / len(arrangement)
    drawer_depth = dy - BACK_INSET - THICKNESS_1
    offsets = []
    for i in range(len(arrangement) - 1):
        offsets.append(THICKNESS_0 + (i + 1) *
                       (drawer_space_height + THICKNESS_0))
    drawer_box = make_drawer_box(dx, dy, dz, offsets)
    drawers = []
    for level, num_drawers in enumerate(arrangement):
        drawer_width = (dx - THICKNESS_0 * 2 -
                        (num_drawers + 1) * air_space) / float(num_drawers)
        z_pos = dz - (level + 1) * (THICKNESS_0 +
                                    drawer_space_height) + air_space
        for drawer_index in range(num_drawers):
            drawer = make_drawer(drawer_width, drawer_depth,
                                 drawer_space_height - 2 * air_space)
            _move(
                drawer, THICKNESS_0 + air_space +
                (air_space + drawer_width) * drawer_index, 0, z_pos)
            drawers.append(drawer)

    builder = TopoDS_Builder()
    compound = TopoDS_Compound()
    builder.MakeCompound(compound)
    builder.Add(compound, drawer_box)
    for drawer in drawers:
        builder.Add(compound, drawer)
    return compound
Esempio n. 4
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    def extrudeLinearWithRotation(cls, outerWire, innerWires, vecCenter,
                                  vecNormal, angleDegrees):
        """
            Creates a 'twisted prism' by extruding, while simultaneously rotating around the extrusion vector.

            Though the signature may appear to be similar enough to extrudeLinear to merit combining them, the
            construction methods used here are different enough that they should be separate.

            At a high level, the steps followed are:
            (1) accept a set of wires
            (2) create another set of wires like this one, but which are transformed and rotated
            (3) create a ruledSurface between the sets of wires
            (4) create a shell and compute the resulting object

            :param outerWire: the outermost wire, a cad.Wire
            :param innerWires: a list of inner wires, a list of cad.Wire
            :param vecCenter: the center point about which to rotate.  the axis of rotation is defined by
                   vecNormal, located at vecCenter. ( a cad.Vector )
            :param vecNormal: a vector along which to extrude the wires ( a cad.Vector )
            :param angleDegrees: the angle to rotate through while extruding
            :return: a cad.Solid object
        """
        # make straight spine
        straight_spine_e = Edge.makeLine(vecCenter, vecCenter.add(vecNormal))
        straight_spine_w = Wire.combine([
            straight_spine_e,
        ]).wrapped

        # make an auxliliary spine
        pitch = 360. / angleDegrees * vecNormal.Length
        radius = 1
        aux_spine_w = Wire.makeHelix(pitch,
                                     vecNormal.Length,
                                     radius,
                                     center=vecCenter,
                                     dir=vecNormal).wrapped

        # extrude the outer wire
        outer_solid = cls._extrudeAuxSpine(outerWire.wrapped, straight_spine_w,
                                           aux_spine_w)

        # extrude inner wires
        inner_solids = [
            cls._extrudeAuxSpine(w.wrapped, straight_spine_w.aux_spine_w)
            for w in innerWires
        ]

        # combine dthe inner solids into compund
        inner_comp = TopoDS_Compound()
        comp_builder = TopoDS_Builder()
        comp_builder.MakeCompound(inner_comp)  # TODO this could be not needed

        for i in inner_solids:
            comp_builder.Add(inner_comp, i)

        # subtract from the outer solid
        return cls(BRepAlgoAPI_Cut(outer_solid, inner_comp).Shape())
Esempio n. 5
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    def makeShell(cls, listOfFaces):

        shell_wrapped = TopoDS_Shell()
        shell_builder = TopoDS_Builder()
        shell_builder.MakeShell(shell_wrapped)

        for face in listOfFaces:
            shell_builder.Add(face.wrapped)

        return cls(shell_wrapped)
Esempio n. 6
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 def testTopoDS_byref_arguments(self):
     '''
     Test byref pass arguments to TopoDS
     '''
     cyl1 = BRepPrimAPI_MakeCylinder(10., 10.).Shape()
     cyl2 = BRepPrimAPI_MakeCylinder(100., 50.).Shape()
     c = TopoDS_Compound()
     bb = TopoDS_Builder()
     bb.MakeCompound(c)
     for child in [cyl1, cyl2]:
         bb.Add(c, child)
Esempio n. 7
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def compound(topo):
    """
    accumulate a bunch of TopoDS_* in list `topo` to a TopoDS_Compound
    @param topo: list of TopoDS_* instances
    """
    bd = TopoDS_Builder()
    comp = TopoDS_Compound()
    bd.MakeCompound(comp)
    for i in topo:
        bd.Add(comp, i)
    return comp
Esempio n. 8
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    def makeCompound(cls, listOfShapes):
        """
        Create a compound out of a list of shapes
        """
        comp = TopoDS_Compound()
        comp_builder = TopoDS_Builder()
        comp_builder.MakeCompound(comp)  # TODO this could be not needed

        for s in listOfShapes:
            comp_builder.Add(comp, s.wrapped)

        return cls(comp)
Esempio n. 9
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def make_drawer(dx, dy, dz):
    pieces = [
        _make_side(dx, dy, dz, True),
        _make_side(dx, dy, dz, False),
        _make_end(dx, dy, dz, True),
        _make_end(dx, dy, dz, False),
        _make_bottom(dx, dy)
    ]

    builder = TopoDS_Builder()
    compound = TopoDS_Compound()
    builder.MakeCompound(compound)
    for piece in pieces:
        builder.Add(compound, piece)
    return compound
Esempio n. 10
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    def GenerateStruct(self, ChordFactor, ScaleFactor):
        from OCC.TopoDS import TopoDS_Builder, TopoDS_Compound, TopoDS_Shape, TopoDS_HShape

        x0 = [ChordFactor, ScaleFactor]

        SectionRibs, RibFace = self._BuildRibs(*x0)
        LSparLEFullWing, LSparTEFullWing, LSparMIDFullWing, StringerUpFullWing, StringerDownFullWing, PointsFullwingUp, PointsFullWingDown = self._BuildSpars(
            *x0)
        PanelUp, PanelDown = self._BuildPanels(*x0)

        builder = TopoDS_Builder()

        # Add Ribs
        Ribs = TopoDS_Compound()
        builder.MakeCompound(Ribs)
        for g in RibFace:
            builder.Add(Ribs, g)
        self.AddComponent(Ribs, 'Ribs')

        ##Add Spars
        Spars = TopoDS_Compound()
        builder.MakeCompound(Spars)
        SparsLEMIDTE = LSparLEFullWing + LSparMIDFullWing + LSparTEFullWing
        for h in SparsLEMIDTE:
            builder.Add(Spars, h)
        self.AddComponent(Spars, 'Spars')
        #Add Stringers
        Stringers = TopoDS_Compound()
        builder.MakeCompound(Stringers)
        for p in xrange(self.NoStiffners * self.SegmentNoLoft):
            p1 = StringerUpFullWing[p]
            p2 = StringerDownFullWing[p]
            builder.Add(Stringers, p1)
            builder.Add(Stringers, p2)
        self.AddComponent(Stringers, 'Stringers')

        #Add Panels
        Panels = TopoDS_Compound()
        builder.MakeCompound(Panels)
        for h in xrange(len(PanelUp)):
            h1 = PanelUp[h]
            h2 = PanelDown[h]
            builder.Add(Panels, h1)
            builder.Add(Panels, h2)
        self.AddComponent(Panels, 'Panels')
        vec = gp_Vec(gp_Pnt(-0.5, 0., 0.), self.ApexPoint)
        self.TranslateComponents(vec)
        return None
Esempio n. 11
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 def test_default_constructor_DEFINE_STANDARD_ALLOC(self):
     ''' OCE classes the defines standard alllocator can be instanciated
     if they're not abstract nor define any protected or private
     constructor '''
     BRep_Builder()
     TopoDS_Builder()
     ShapeAnalysis_Curve()
Esempio n. 12
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 def testProtectedConstructor(self):
     ''' test if the classes with protected constructors can be created
     '''
     print 'Test: protected constructor'
     # 1st, class with no subclass
     from OCC.TopoDS import TopoDS_Builder
     tds_builder = TopoDS_Builder()
     self.assertTrue(hasattr(tds_builder, "MakeCompound"))
Esempio n. 13
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def _make_table():
    builder = TopoDS_Builder()
    compound = TopoDS_Compound()
    builder.MakeCompound(compound)
    table_top = _box(SPECS.length, SPECS.width, TABLE_THICKNESS)
    _move(table_top, 0, 0, PEDESTAL_HEIGHT)
    builder.Add(compound, table_top)
    for i in range(4):
        pedestal = _box(SPECS.pedestal_thickness, SPECS.pedestal_width, PEDESTAL_HEIGHT)
        if i < 2:
            x = SPECS.pedestal_inset
        else:
            x = SPECS.length - SPECS.pedestal_inset - SPECS.pedestal_thickness
        if i % 2 == 0:
            y = (SPECS.width + SPECS.pedestal_gap) / 2
        else:
            y = (SPECS.width - SPECS.pedestal_gap) / 2 - SPECS.pedestal_width
        _move(pedestal, x, y, 0.)
        builder.Add(compound, pedestal)
    return compound
Esempio n. 14
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 def testProtectedConstructor(self):
     """ Test: protected constructor """
     # 1st, class with no subclass
     from OCC.TopoDS import TopoDS_Builder
     tds_builder = TopoDS_Builder()
     self.assertTrue(hasattr(tds_builder, "MakeCompound"))
Esempio n. 15
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    def GenerateLiftingSurface(self, ChordFactor, ScaleFactor):
        from OCC.TopoDS import TopoDS_Builder, TopoDS_Compound, TopoDS_Shape, TopoDS_HShape
        """Builds a lifting surface (wing, tailplane, etc.) with the Chord and
        Scale factors defined in inputs
        
        If OptimizeChordScale was specified on construction of this 
        LiftingSurface class, an optimized ChordFactor and ScaleFactor is found
        instead, with the local search started from the two given values.
        
        Parameters
        ----------
        ChordFactor : scalar
            The scaling factor to apply in the chordwise direction
        
        ScaleFactor : scalar
            the scaling factor to apply uniformly in all directions
        
        Returns
        -------
        None
        
        Notes
        -----
        Called on initialisation of a lifting surface class. Adds a
        ('Surface': Shape) key value pair to self.
        
        :Example:
            >>> Wing = liftingsurface.LiftingSurface(P,
                                                mySweepAngleFunction, 
                                                myDihedralFunction, 
                                                myTwistFunction, 
                                                myChordFunction, 
                                                myAirfoilFunction)
            >>> Surface = Wing['Surface']
        
        See Also
        --------
        airconics.examples.wing_example_transonic_airliner
        """
        x0 = [ChordFactor, ScaleFactor]

        LS, ActualSemiSpan, LSP_area, AR, WingTip = \
            self._BuildLS(*x0)

        PointsSurfUp, PointsSurfDown = self._BuildSurfacePoints(*x0)
        #        Update instance components:
        self.AddComponent(LS, 'SurfaceLoft')
        builder = TopoDS_Builder()
        PointsUp = TopoDS_Compound()
        builder.MakeCompound(PointsUp)
        PointsDown = TopoDS_Compound()
        builder.MakeCompound(PointsDown)
        for g in PointsSurfUp:
            builder.Add(PointsUp, g)
        self.AddComponent(PointsUp, 'PointsSurfUp')
        for gg in PointsSurfDown:
            builder.Add(PointsDown, gg)
        self.AddComponent(PointsDown, 'PointsSurfDown')

        # Position the Components at the apex:
        vec = gp_Vec(gp_Pnt(0., 0., 0.), self.ApexPoint)
        self.TranslateComponents(vec)

        return None