Exemplo n.º 1
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 def __init__(self, points, point_size=0.001, color='green'):
     geometry = BufferGeometry(
         attributes={
             'position': BufferAttribute(array=points.astype(np.float32))
         })
     material = PointsMaterial(size=point_size, color=color)
     Points.__init__(self, geometry=geometry, material=material)
Exemplo n.º 2
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    def AddVerticesToScene(self, pnt_list, vertex_color, vertex_width=5):
        """ shp is a list of gp_Pnt
        """
        vertices_list = []  # will be passed to pythreejs
        BB = BRep_Builder()
        compound = TopoDS_Compound()
        BB.MakeCompound(compound)

        for vertex in pnt_list:
            vertex_to_add = BRepBuilderAPI_MakeVertex(vertex).Shape()
            BB.Add(compound, vertex_to_add)
            vertices_list.append([vertex.X(), vertex.Y(), vertex.Z()])

        # map the Points and the AIS_PointCloud
        # and to the dict of shapes, to have a mapping between meshes and shapes
        point_cloud_id = "%s" % uuid.uuid4().hex
        self._shapes[point_cloud_id] = compound

        vertices_list = np.array(vertices_list, dtype=np.float32)
        attributes = {
            "position": BufferAttribute(vertices_list, normalized=False)
        }
        mat = PointsMaterial(color=vertex_color,
                             sizeAttenuation=True,
                             size=vertex_width)
        geom = BufferGeometry(attributes=attributes)
        points = Points(geometry=geom, material=mat, name=point_cloud_id)
        return points
Exemplo n.º 3
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def vertices_to_mesh(name, vertices, vertex_color, vertex_width=5):
    """

    :param name:
    :param vertices:
    :param vertex_color: RGB tuple (r, g, b)
    :param vertex_width:
    :return:
    :rtype: pythreejs.objects.Points_autogen.Points
    """
    vertices = np.array(vertices, dtype=np.float32)
    attributes = {"position": BufferAttribute(vertices, normalized=False)}
    mat = PointsMaterial(color=format_color(*vertex_color),
                         sizeAttenuation=False,
                         size=vertex_width)
    geom = BufferGeometry(attributes=attributes)
    points = Points(geometry=geom, material=mat, name=name)
    return points
Exemplo n.º 4
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    def DisplayMesh(self,
                    part: "Part",
                    edge_color=None,
                    vertex_color=None,
                    vertex_width=2):
        from OCC.Core.BRep import BRep_Builder
        from OCC.Core.BRepBuilderAPI import BRepBuilderAPI_MakeVertex
        from OCC.Core.gp import gp_Pnt
        from OCC.Core.TopoDS import TopoDS_Compound

        # edge_color = format_color(*part.colour) if edge_color is None else edge_color
        rgb = randint(0, 255), randint(0, 255), randint(0, 255)
        edge_color = format_color(*rgb) if edge_color is None else edge_color
        vertex_color = self._default_vertex_color if vertex_color is None else vertex_color

        pmesh_id = "%s" % uuid.uuid4().hex

        BB = BRep_Builder()
        compound = TopoDS_Compound()
        BB.MakeCompound(compound)
        vertices_list = []

        def togp(n_):
            return gp_Pnt(float(n_[0]), float(n_[1]), float(n_[2]))

        for vertex in map(togp, part.fem.nodes):
            vertex_to_add = BRepBuilderAPI_MakeVertex(vertex).Shape()
            BB.Add(compound, vertex_to_add)
            vertices_list.append([vertex.X(), vertex.Y(), vertex.Z()])

        attributes = {
            "position": BufferAttribute(vertices_list, normalized=False)
        }
        mat = PointsMaterial(color=vertex_color,
                             sizeAttenuation=False,
                             size=vertex_width)
        geom = BufferGeometry(attributes=attributes)
        points_geom = Points(geometry=geom, material=mat, name=pmesh_id)
        lmesh_id = "%s" % uuid.uuid4().hex
        edges_nodes = list(
            chain.from_iterable(
                filter(
                    None,
                    [get_vertices_from_elem(el) for el in part.fem.elements])))
        np_edge_vertices = np.array(edges_nodes, dtype=np.float32)
        np_edge_indices = np.arange(np_edge_vertices.shape[0], dtype=np.uint32)
        vertex_col = tuple([x / 255 for x in rgb])
        edge_geometry = BufferGeometry(
            attributes={
                "position": BufferAttribute(np_edge_vertices),
                "index": BufferAttribute(np_edge_indices),
                "color": BufferAttribute(
                    [vertex_col for n in np_edge_vertices]),
            })
        edge_material = LineBasicMaterial(vertexColors="VertexColors",
                                          linewidth=5)

        edge_geom = LineSegments(
            geometry=edge_geometry,
            material=edge_material,
            type="LinePieces",
            name=lmesh_id,
        )
        output = [points_geom, edge_geom]

        for elem in output:
            self._shapes[elem.name] = compound
            self._refs[elem.name] = part
            self._displayed_pickable_objects.add(elem)

        self._fem_sets_opts.options = ["None"] + [
            f"{part.fem.name}.{s.name}" for s in filter(
                lambda x: "internal" not in x.metadata.keys(), part.fem.sets)
        ]
        self._fem_refs[part.fem.name] = (part.fem, edge_geometry)
Exemplo n.º 5
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    def _render_shape(self,
                      shape_index,
                      shape=None,
                      edges=None,
                      vertices=None,
                      mesh_color=None,
                      edge_color=None,
                      vertex_color=None,
                      render_edges=False,
                      edge_width=1,
                      vertex_width=5,
                      deflection=0.05,
                      transparent=False,
                      opacity=1.0):

        edge_list = None
        edge_lines = None
        points = None
        shape_mesh = None

        if shape is not None:
            if mesh_color is None:
                mesh_color = self.default_mesh_color
            if edge_color is None:
                edge_color = self.default_edge_color
            if vertex_color is None:
                vertex_color = self.default_edge_color  # same as edge_color

            # BEGIN copy
            # The next lines are copied with light modifications from
            # https://github.com/tpaviot/pythonocc-core/blob/master/src/Display/WebGl/jupyter_renderer.py

            # first, compute the tesselation
            tess = Tesselator(shape)
            tess.Compute(uv_coords=False,
                         compute_edges=render_edges,
                         mesh_quality=self.quality,
                         parallel=True)

            # get vertices and normals
            vertices_position = tess.GetVerticesPositionAsTuple()

            number_of_triangles = tess.ObjGetTriangleCount()
            number_of_vertices = len(vertices_position)

            # number of vertices should be a multiple of 3
            if number_of_vertices % 3 != 0:
                raise AssertionError("Wrong number of vertices")
            if number_of_triangles * 9 != number_of_vertices:
                raise AssertionError("Wrong number of triangles")

            # then we build the vertex and faces collections as numpy ndarrays
            np_vertices = np.array(vertices_position, dtype='float32')\
                            .reshape(int(number_of_vertices / 3), 3)
            # Note: np_faces is just [0, 1, 2, 3, 4, 5, ...], thus arange is used
            np_faces = np.arange(np_vertices.shape[0], dtype='uint32')

            # compute normals
            np_normals = np.array(tess.GetNormalsAsTuple(),
                                  dtype='float32').reshape(-1, 3)
            if np_normals.shape != np_vertices.shape:
                raise AssertionError("Wrong number of normals/shapes")

            # build a BufferGeometry instance
            shape_geometry = BufferGeometry(
                attributes={
                    'position': BufferAttribute(np_vertices),
                    'index': BufferAttribute(np_faces),
                    'normal': BufferAttribute(np_normals)
                })

            shp_material = self._material(mesh_color,
                                          transparent=True,
                                          opacity=opacity)

            shape_mesh = Mesh(geometry=shape_geometry,
                              material=shp_material,
                              name="mesh_%d" % shape_index)

            if render_edges:
                edge_list = list(
                    map(
                        lambda i_edge: [
                            tess.GetEdgeVertex(i_edge, i_vert)
                            for i_vert in range(
                                tess.ObjEdgeGetVertexCount(i_edge))
                        ], range(tess.ObjGetEdgeCount())))

            # END copy

        if vertices is not None:
            vertices_list = []
            for vertex in vertices:
                p = BRep_Tool.Pnt(vertex)
                vertices_list.append((p.X(), p.Y(), p.Z()))
            vertices_list = np.array(vertices_list, dtype=np.float32)

            attributes = {
                "position": BufferAttribute(vertices_list, normalized=False)
            }

            mat = PointsMaterial(color=vertex_color,
                                 sizeAttenuation=False,
                                 size=vertex_width)
            geom = BufferGeometry(attributes=attributes)
            points = Points(geometry=geom, material=mat)

        if edges is not None:
            edge_list = [discretize_edge(edge, deflection) for edge in edges]

        if edge_list is not None:
            edge_list = _flatten(list(map(_explode, edge_list)))
            lines = LineSegmentsGeometry(positions=edge_list)
            mat = LineMaterial(linewidth=edge_width, color=edge_color)
            edge_lines = LineSegments2(lines,
                                       mat,
                                       name="edges_%d" % shape_index)

        if shape_mesh is not None or edge_lines is not None or points is not None:
            index_mapping = {"mesh": None, "edges": None, "shape": shape_index}
            if shape_mesh is not None:
                ind = len(self.pickable_objects.children)
                self.pickable_objects.add(shape_mesh)
                index_mapping["mesh"] = ind
            if edge_lines is not None:
                ind = len(self.pickable_objects.children)
                self.pickable_objects.add(edge_lines)
                index_mapping["edges"] = ind
            if points is not None:
                ind = len(self.pickable_objects.children)
                self.pickable_objects.add(points)
                index_mapping["mesh"] = ind
            self.pick_mapping.append(index_mapping)
Exemplo n.º 6
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    def DisplayMesh(self,
                    part,
                    edge_color=None,
                    vertex_color=None,
                    vertex_width=2):
        """

        :param part:
        :param edge_color:
        :param vertex_color:
        :param vertex_width:
        :type part: ada.Part
        """
        from itertools import chain
        from random import randint

        from OCC.Core.BRep import BRep_Builder
        from OCC.Core.BRepBuilderAPI import BRepBuilderAPI_MakeVertex
        from OCC.Core.gp import gp_Pnt
        from OCC.Core.TopoDS import TopoDS_Compound

        # edge_color = format_color(*part.colour) if edge_color is None else edge_color

        edge_color = (format_color(randint(0, 255), randint(
            0, 255), randint(0, 255)) if edge_color is None else edge_color)
        vertex_color = self._default_vertex_color if vertex_color is None else vertex_color

        pmesh_id = "%s" % uuid.uuid4().hex

        BB = BRep_Builder()
        compound = TopoDS_Compound()
        BB.MakeCompound(compound)
        vertices_list = []

        def togp(n_):
            return gp_Pnt(float(n_[0]), float(n_[1]), float(n_[2]))

        for vertex in map(togp, part.fem.nodes):
            vertex_to_add = BRepBuilderAPI_MakeVertex(vertex).Shape()
            BB.Add(compound, vertex_to_add)
            vertices_list.append([vertex.X(), vertex.Y(), vertex.Z()])

        attributes = {
            "position": BufferAttribute(vertices_list, normalized=False)
        }
        mat = PointsMaterial(color=vertex_color,
                             sizeAttenuation=False,
                             size=vertex_width)
        geom = BufferGeometry(attributes=attributes)
        points_geom = Points(geometry=geom, material=mat, name=pmesh_id)

        def grab_nodes(el):
            """

            :param el:
            :type el: ada.fem.Elem
            :return:
            """
            if el.edges_seq is None:
                return None
            return [
                part.fem.nodes.from_id(i).p for i in
                [el.nodes[e].id for ed_seq in el.edges_seq for e in ed_seq]
            ]

        lmesh_id = "%s" % uuid.uuid4().hex

        edges_nodes = list(
            chain.from_iterable(
                filter(None, map(grab_nodes, part.fem.elements))))
        np_edge_vertices = np.array(edges_nodes, dtype=np.float32)
        np_edge_indices = np.arange(np_edge_vertices.shape[0], dtype=np.uint32)
        edge_geometry = BufferGeometry(
            attributes={
                "position": BufferAttribute(np_edge_vertices),
                "index": BufferAttribute(np_edge_indices),
            })
        edge_material = LineBasicMaterial(color=edge_color, linewidth=1)

        edge_geom = LineSegments(
            geometry=edge_geometry,
            material=edge_material,
            type="LinePieces",
            name=lmesh_id,
        )
        output = [points_geom, edge_geom]

        for elem in output:
            self._shapes[elem.name] = compound
            self._refs[elem.name] = part
            self._displayed_pickable_objects.add(elem)

        self._fem_sets_opts.options = ["None"] + [
            s.name for s in filter(
                lambda x: "internal" not in x.metadata.keys(), part.fem.sets)
        ]
Exemplo n.º 7
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    def __init__(self,*args, **kwargs):
        """
        There are several options for arguments this this function.

        One positional array-like
            Figure#scatter(np.random.randint(0, 10, (10, 3)))

        Three positional list-likes
            Figure#scatter(xs, ys, zs)

        Three named list-likes
            Figure#scatter(xs=[1, 2], ys=[2, 3], zs=[10, 20])

        Three positional column names and a dataframe
            Figure#scatter("x", "y", "depth", my_dataframe)

        Arguments:
            attenuate_size (False): Whether items further from
                the camera should appear smaller

        """
        super().__init__(**kwargs)
        pts = None
        if len(args) == 1:
            if isinstance(args[0], (np.ndarray, Iterable)):
                pts = np.asarray(args[0], dtype=np.float32)

        if len(args) == 3 and isinstance(args[0], (list, np.ndarray)):
            pts = np.asarray([i for i in zip(args[0], args[1], args[2])],dtype=np.float32)

        if pts is None:
            raise ValueError("Unsupported arguments to scatter.")
        self._coords = pts
        color = kwargs.get("c") if "c" in kwargs else None
        if color is None:
            color = kwargs.get("color", None)
        if color is None:
            color = pts / pts.max()
        if len(color) != len(pts):
            color = [color for _ in pts]

        colors = (
            BufferAttribute(array=color, dtype=np.float32)
            if color is not None
            else BufferAttribute(array=np.asarray(pts / pts.max(), dtype=np.float32))
        )
        geometry = BufferGeometry(
            attributes={
                "position": BufferAttribute(array=np.asarray(pts, dtype=np.float32)),
                "color": colors,
            }
        )

        tex = CIRCLE_MAP
        if kwargs.get("marker") in [".", "o", "circle"]:
            tex = CIRCLE_MAP
        elif kwargs.get("marker") in ["[]", "r", "q", "square"]:
            tex = None
        elif "map" in kwargs:
            tex = kwargs.get("map")

        material = PointsMaterial(
            vertexColors="VertexColors",
            size=kwargs.get("size", 5),
            sizeAttenuation=kwargs.get("attenuate_size", False),
            **({"map": tex} if tex else {}),
        )
        p = Points(geometry=geometry, material=material)
        self._objects.append(p)
Exemplo n.º 8
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    def _render_shape(
        self,
        shape_index,
        shape=None,
        edges=None,
        vertices=None,
        mesh_color=None,
        edge_color=None,
        vertex_color=None,
        render_edges=False,
        edge_width=1,
        vertex_width=5,
        transparent=False,
        opacity=1.0,
    ):

        edge_list = None
        edge_lines = None
        points = None
        shape_mesh = None

        start_render_time = self._start_timer()
        if shape is not None:
            if mesh_color is None:
                mesh_color = self.default_mesh_color
            if edge_color is None:
                edge_color = self.default_edge_color
            if vertex_color is None:
                vertex_color = self.default_edge_color  # same as edge_color

            # Compute the tesselation
            start_tesselation_time = self._start_timer()

            np_vertices, np_triangles, np_normals = tessellate(
                shape, self.quality, self.angular_tolerance
            )

            if np_normals.shape != np_vertices.shape:
                raise AssertionError("Wrong number of normals/shapes")

            self._stop_timer("tesselation time", start_tesselation_time)

            # build a BufferGeometry instance
            shape_geometry = BufferGeometry(
                attributes={
                    "position": BufferAttribute(np_vertices),
                    "index": BufferAttribute(np_triangles.ravel()),
                    "normal": BufferAttribute(np_normals),
                }
            )

            shp_material = self._material(mesh_color, transparent=True, opacity=opacity)

            shape_mesh = Mesh(
                geometry=shape_geometry, material=shp_material, name="mesh_%d" % shape_index
            )

            if render_edges:
                edges = get_edges(shape)

        if vertices is not None:
            vertices_list = []
            for vertex in vertices:
                vertices_list.append(get_point(vertex))
            vertices_list = np.array(vertices_list, dtype=np.float32)

            attributes = {"position": BufferAttribute(vertices_list, normalized=False)}

            mat = PointsMaterial(color=vertex_color, sizeAttenuation=False, size=vertex_width)
            geom = BufferGeometry(attributes=attributes)
            points = Points(geometry=geom, material=mat)

        if edges is not None:
            start_discretize_time = self._start_timer()
            edge_list = [discretize_edge(edge, self.edge_accuracy) for edge in edges]
            self._stop_timer("discretize time", start_discretize_time)

        if edge_list is not None:
            edge_list = flatten(list(map(explode, edge_list)))
            lines = LineSegmentsGeometry(positions=edge_list)
            mat = LineMaterial(linewidth=edge_width, color=edge_color)
            edge_lines = LineSegments2(lines, mat, name="edges_%d" % shape_index)

        if shape_mesh is not None or edge_lines is not None or points is not None:
            index_mapping = {"mesh": None, "edges": None, "shape": shape_index}
            if shape_mesh is not None:
                ind = len(self.pickable_objects.children)
                self.pickable_objects.add(shape_mesh)
                index_mapping["mesh"] = ind
            if edge_lines is not None:
                ind = len(self.pickable_objects.children)
                self.pickable_objects.add(edge_lines)
                index_mapping["edges"] = ind
            if points is not None:
                ind = len(self.pickable_objects.children)
                self.pickable_objects.add(points)
                index_mapping["mesh"] = ind
            self.pick_mapping.append(index_mapping)
        self._stop_timer("shape render time", start_render_time)