Exemple #1
0
    def kinks(self, threshold=1e-3):
        """Return the XYZ coordinates of kinks, i.e. tangency discontinuities, along the surface's boundaries.

        Returns
        -------
        list
            The list of XYZ coordinates of surface boundary kinks.

        """
        kinks = []
        borders = self.borders(type=0)

        for border in borders:
            border = RhinoCurve(border)
            extremities = map(
                lambda x: rs.EvaluateCurve(border.guid,
                                           rs.CurveParameter(border.guid, x)),
                [0., 1.])

            if border.is_closed():
                start_tgt, end_tgt = border.tangents(extremities)
                if angle_vectors(start_tgt, end_tgt) > threshold:
                    kinks += extremities

            else:
                kinks += extremities

        return list(set(kinks))
Exemple #2
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 def identify_vertices_on_curve(diagram, guid):
     gkey_key = diagram.gkey_key()
     keys = []
     curve = RhinoCurve(guid)
     for key in diagram.vertices():
         xyz = diagram.vertex_coordinates(key)
         closest = curve.closest_point(xyz)
         gkey = geometric_key(closest)
         if gkey in gkey_key:
             if key == gkey_key[gkey]:
                 keys.append(key)
     return keys
Exemple #3
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    def from_guid(guid):
        """Create a ``RhinoGeometry`` instance of the correct type based on a given guid.

        Parameters
        ----------
        guid : str or System.Guid
            The *guid* of the Rhino object.

        Returns
        -------
        RhinoPoint
            If the type of the Rhino object is ``rs.filter.point``.
        RhinoCurve
            If the type of the Rhino object is ``rs.filter.curve``.
        RhinoMesh
            If the type of the Rhino object is ``rs.filter.mesh``.
        RhinoSurface
            If the type of the Rhino object is ``rs.filter.surface``.

        Examples
        --------
        >>>

        """
        from compas_rhino.geometry import RhinoPoint
        from compas_rhino.geometry import RhinoCurve
        from compas_rhino.geometry import RhinoMesh
        from compas_rhino.geometry import RhinoSurface

        otype = rs.ObjectType(guid)

        if otype == rs.filter.point:
            return RhinoPoint(guid)

        if otype == rs.filter.curve:
            return RhinoCurve(guid)

        if otype == rs.filter.mesh:
            return RhinoMesh(guid)

        if otype == rs.filter.surface:
            return RhinoSurface(guid)
Exemple #4
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    def closest_point_on_boundaries(self, xyz):
        """Return the XYZ coordinates of the closest point on the boundaries of the surface from input XYZ-coordinates.
    
        Parameters
        ----------
        xyz : list
            XYZ coordinates.

        Returns
        -------
        list
            The XYZ coordinates of the closest point on the boundaries of the surface.

        """
        borders = self.borders(type=0)
        proj_dist = {
            tuple(proj_xyz): distance_point_point(xyz, proj_xyz)
            for proj_xyz in
            [RhinoCurve(border).closest_point(xyz) for border in borders]
        }
        delete_objects(borders)
        return min(proj_dist, key=proj_dist.get)
Exemple #5
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kmax = 300

# select the original mesh
# select the border
# select the fixed points

guid_target = compas_rhino.select_mesh()
guid_border = compas_rhino.select_polyline()
guid_points = compas_rhino.select_points()

# wrap the Rhino mesh object for convenience
# wrap the Rhino curve object for convenience
# get the point coordinates

target = RhinoMesh(guid_target)
border = RhinoCurve(guid_border)
points = compas_rhino.get_point_coordinates(guid_points)

# make a mesh datastructure from the Rhino mesh
# triangulate the mesh

mesh = mesh_from_guid(Mesh, guid_target)
mesh_quads_to_triangles(mesh)

# identify the fixed vertices
# by matching the coordinates of the selected points
# up to a precision

keys = mesh_identify_vertices(mesh, points, '1f')
fixed = set(keys)
from compas_rhino.geometry import RhinoCurve
from compas_rhino.artists import MeshArtist

# ==============================================================================
# RPC
# ==============================================================================

igl = Proxy("compas_libigl")

# ==============================================================================
# Input
# ==============================================================================

# boundary
guids = compas_rhino.select_curves()
curve = RhinoCurve.from_guid(guids[0])
points = [list(point) for point in curve.points]
boundary = points

# segments
guids = compas_rhino.select_curves()
curve = RhinoCurve.from_guid(guids[0])
points = curve.divide(10, over_space=True)
segments = points

# hole
guids = compas_rhino.select_curves()
curve = RhinoCurve.from_guid(guids[0])
points = curve.divide(10, over_space=True)
hole = points
Exemple #7
0
def RunCommand(is_interactive):

    scene = get_scene()
    if not scene:
        return

    proxy = get_proxy()
    if not proxy:
        return

    conforming_delaunay_triangulation = proxy.function(
        'compas.geometry.conforming_delaunay_triangulation')

    boundary_guids = compas_rhino.select_curves('Select outer boundary.')
    if not boundary_guids:
        return

    hole_guids = compas_rhino.select_curves('Select inner boundaries.')
    segments_guids = compas_rhino.select_curves('Select constraint curves.')

    target_length = rs.GetReal('Specifiy target edge length.', 1.0)
    if not target_length:
        return

    gkey_constraints = {}

    # outer boundary
    boundary = []
    for guid in boundary_guids:
        compas_rhino.rs.EnableRedraw(False)
        segments = compas_rhino.rs.ExplodeCurves(guid)
        for segment in segments:
            curve = RhinoCurve.from_guid(segment)
            N = max(int(curve.length() / target_length), 1)
            points = map(list, curve.divide(N, over_space=True))
            for point in points:
                gkey = geometric_key(point)
                if gkey not in gkey_constraints:
                    gkey_constraints[gkey] = []
                gkey_constraints[gkey].append(segment)
            boundary.extend(points)
        compas_rhino.delete_objects(segments, purge=True)
        compas_rhino.rs.EnableRedraw(True)

    # constraint polylines
    polylines = []
    if segments_guids:
        for guid in segments_guids:
            curve = RhinoCurve.from_guid(guid)
            N = int(curve.length() / target_length) or 1
            points = map(list, curve.divide(N, over_space=True))
            for point in points:
                gkey = geometric_key(point)
                if gkey not in gkey_constraints:
                    gkey_constraints[gkey] = []
                gkey_constraints[gkey].append(guid)
            polylines.append(points)

    # hole polygons
    polygons = []
    if hole_guids:
        for guid in hole_guids:
            curve = RhinoCurve.from_guid(guid)
            N = int(curve.length() / target_length) or 1
            points = map(list, curve.divide(N, over_space=True))
            for point in points[:-1]:
                gkey = geometric_key(point)
                if gkey not in gkey_constraints:
                    gkey_constraints[gkey] = []
                gkey_constraints[gkey].append(guid)
            polygons.append(points)

    area = target_length**2 * 0.5 * 0.5 * 1.732

    vertices, faces = conforming_delaunay_triangulation(boundary,
                                                        polylines=polylines,
                                                        polygons=polygons,
                                                        angle=30,
                                                        area=area)
    # vertices, faces = constrained_delaunay_triangulation(boundary, polylines=polylines, polygons=polygons)
    vertices[:] = [[float(x), float(y), float(z)] for x, y, z in vertices]

    pattern = Pattern.from_vertices_and_faces(vertices, faces)

    gkey_key = {
        geometric_key(pattern.vertex_coordinates(key)): key
        for key in pattern.vertices()
    }

    for gkey in gkey_constraints:
        guids = gkey_constraints[gkey]
        if gkey in gkey_key:
            key = gkey_key[gkey]
            if len(guids) > 1:
                pattern.vertex_attribute(key, 'is_fixed', True)
            pattern.vertex_attribute(key, 'constraints',
                                     [str(guid) for guid in guids])

    compas_rhino.rs.HideObject(boundary_guids + hole_guids + segments_guids)

    scene.clear()
    scene.add(pattern, name='pattern')
    scene.update()

    print(
        "Pattern object successfully created. Input geometry have been hidden."
    )