Пример #1
0
def repeat_sources(centers,
                   colors,
                   active_scalars=1.,
                   directions=None,
                   source=None,
                   vertices=None,
                   faces=None,
                   orientation=None):
    """Transform a vtksource to glyph."""
    if source is None and faces is None:
        raise IOError("A source or faces should be defined")

    if np.array(colors).ndim == 1:
        colors = np.tile(colors, (len(centers), 1))

    pts = numpy_to_vtk_points(np.ascontiguousarray(centers))
    cols = numpy_to_vtk_colors(255 * np.ascontiguousarray(colors))
    cols.SetName('colors')
    if isinstance(active_scalars, (float, int)):
        active_scalars = np.tile(active_scalars, (len(centers), 1))
    if isinstance(active_scalars, np.ndarray):
        ascalars = numpy_support.numpy_to_vtk(np.asarray(active_scalars),
                                              deep=True,
                                              array_type=VTK_DOUBLE)
        ascalars.SetName('active_scalars')

    if directions is not None:
        directions_fa = numpy_support.numpy_to_vtk(np.asarray(directions),
                                                   deep=True,
                                                   array_type=VTK_DOUBLE)
        directions_fa.SetName('directions')

    polydata_centers = PolyData()
    polydata_geom = PolyData()

    if faces is not None:
        set_polydata_vertices(polydata_geom, vertices)
        set_polydata_triangles(polydata_geom, faces)

    polydata_centers.SetPoints(pts)
    polydata_centers.GetPointData().AddArray(cols)
    if directions is not None:
        polydata_centers.GetPointData().AddArray(directions_fa)
        polydata_centers.GetPointData().SetActiveVectors('directions')
    if isinstance(active_scalars, np.ndarray):
        polydata_centers.GetPointData().AddArray(ascalars)
        polydata_centers.GetPointData().SetActiveScalars('active_scalars')

    glyph = Glyph3D()
    if faces is None:
        if orientation is not None:
            transform = Transform()
            transform.SetMatrix(numpy_to_vtk_matrix(orientation))
            rtrans = TransformPolyDataFilter()
            rtrans.SetInputConnection(source.GetOutputPort())
            rtrans.SetTransform(transform)
            source = rtrans
        glyph.SetSourceConnection(source.GetOutputPort())
    else:
        glyph.SetSourceData(polydata_geom)
    glyph.SetInputData(polydata_centers)
    glyph.SetOrient(True)
    glyph.SetScaleModeToScaleByScalar()
    glyph.SetVectorModeToUseVector()
    glyph.Update()

    mapper = PolyDataMapper()
    mapper.SetInputData(glyph.GetOutput())
    mapper.SetScalarModeToUsePointFieldData()
    mapper.SelectColorArray('colors')

    actor = Actor()
    actor.SetMapper(mapper)
    return actor
Пример #2
0
Файл: peak.py Проект: guaje/fury
class PeakActor(Actor):
    """VTK actor for visualizing slices of ODF field.

    Parameters
    ----------
    directions : ndarray
        Peak directions. The shape of the array should be (X, Y, Z, D, 3).
    indices : tuple
        Indices given in tuple(x_indices, y_indices, z_indices)
        format for mapping 2D ODF array to 3D voxel grid.
    values : ndarray, optional
        Peak values. The shape of the array should be (X, Y, Z, D).
    affine : array, optional
        4x4 transformation array from native coordinates to world coordinates.
    colors : None or string ('rgb_standard') or tuple (3D or 4D) or
             array/ndarray (N, 3 or 4) or array/ndarray (K, 3 or 4) or
             array/ndarray(N, ) or array/ndarray (K, )
        If None a standard orientation colormap is used for every line.
        If one tuple of color is used. Then all streamlines will have the same
        color.
        If an array (N, 3 or 4) is given, where N is equal to the number of
        points. Then every point is colored with a different RGB(A) color.
        If an array (K, 3 or 4) is given, where K is equal to the number of
        lines. Then every line is colored with a different RGB(A) color.
        If an array (N, ) is given, where N is the number of points then these
        are considered as the values to be used by the colormap.
        If an array (K,) is given, where K is the number of lines then these
        are considered as the values to be used by the colormap.
    lookup_colormap : vtkLookupTable, optional
        Add a default lookup table to the colormap. Default is None which calls
        :func:`fury.actor.colormap_lookup_table`.
    linewidth : float, optional
        Line thickness. Default is 1.
    symmetric: bool, optional
        If True, peaks are drawn for both peaks_dirs and -peaks_dirs. Else,
        peaks are only drawn for directions given by peaks_dirs. Default is
        True.

    """
    def __init__(self,
                 directions,
                 indices,
                 values=None,
                 affine=None,
                 colors=None,
                 lookup_colormap=None,
                 linewidth=1,
                 symmetric=True):
        if affine is not None:
            w_pos = apply_affine(affine, np.asarray(indices).T)

        valid_dirs = directions[indices]

        num_dirs = len(np.nonzero(np.abs(valid_dirs).max(axis=-1) > 0)[0])

        pnts_per_line = 2

        points_array = np.empty((num_dirs * pnts_per_line, 3))
        centers_array = np.empty_like(points_array, dtype=int)
        diffs_array = np.empty_like(points_array)
        line_count = 0
        for idx, center in enumerate(zip(indices[0], indices[1], indices[2])):
            if affine is None:
                xyz = np.asarray(center)
            else:
                xyz = w_pos[idx, :]
            valid_peaks = np.nonzero(
                np.abs(valid_dirs[idx, :, :]).max(axis=-1) > 0.)[0]
            for direction in valid_peaks:
                if values is not None:
                    pv = values[center][direction]
                else:
                    pv = 1.

                if symmetric:
                    point_i = directions[center][direction] * pv + xyz
                    point_e = -directions[center][direction] * pv + xyz
                else:
                    point_i = directions[center][direction] * pv + xyz
                    point_e = xyz

                diff = point_e - point_i
                points_array[line_count * pnts_per_line, :] = point_e
                points_array[line_count * pnts_per_line + 1, :] = point_i
                centers_array[line_count * pnts_per_line, :] = center
                centers_array[line_count * pnts_per_line + 1, :] = center
                diffs_array[line_count * pnts_per_line, :] = diff
                diffs_array[line_count * pnts_per_line + 1, :] = diff
                line_count += 1

        vtk_points = numpy_to_vtk_points(points_array)

        vtk_cells = _points_to_vtk_cells(points_array)

        colors_tuple = _peaks_colors_from_points(points_array, colors=colors)
        vtk_colors, colors_are_scalars, self.__global_opacity = colors_tuple

        poly_data = PolyData()
        poly_data.SetPoints(vtk_points)
        poly_data.SetLines(vtk_cells)
        poly_data.GetPointData().SetScalars(vtk_colors)

        self.__mapper = PolyDataMapper()
        self.__mapper.SetInputData(poly_data)
        self.__mapper.ScalarVisibilityOn()
        self.__mapper.SetScalarModeToUsePointFieldData()
        self.__mapper.SelectColorArray('colors')
        self.__mapper.Update()

        self.SetMapper(self.__mapper)

        attribute_to_actor(self, centers_array, 'center')
        attribute_to_actor(self, diffs_array, 'diff')

        vs_dec_code = import_fury_shader('peak_dec.vert')
        vs_impl_code = import_fury_shader('peak_impl.vert')
        fs_dec_code = import_fury_shader('peak_dec.frag')
        fs_impl_code = import_fury_shader('peak_impl.frag')

        shader_to_actor(self,
                        'vertex',
                        decl_code=vs_dec_code,
                        impl_code=vs_impl_code)
        shader_to_actor(self, 'fragment', decl_code=fs_dec_code)
        shader_to_actor(self,
                        'fragment',
                        impl_code=fs_impl_code,
                        block='light')

        # Color scale with a lookup table
        if colors_are_scalars:
            if lookup_colormap is None:
                lookup_colormap = colormap_lookup_table()

            self.__mapper.SetLookupTable(lookup_colormap)
            self.__mapper.UseLookupTableScalarRangeOn()
            self.__mapper.Update()

        self.__lw = linewidth
        self.GetProperty().SetLineWidth(self.__lw)

        if self.__global_opacity >= 0:
            self.GetProperty().SetOpacity(self.__global_opacity)

        self.__min_centers = np.min(indices, axis=1)
        self.__max_centers = np.max(indices, axis=1)

        self.__is_range = True
        self.__low_ranges = self.__min_centers
        self.__high_ranges = self.__max_centers
        self.__cross_section = self.__high_ranges // 2

        self.__mapper.AddObserver(Command.UpdateShaderEvent,
                                  self.__display_peaks_vtk_callback)

    @calldata_type(VTK_OBJECT)
    def __display_peaks_vtk_callback(self, caller, event, calldata=None):
        if calldata is not None:
            calldata.SetUniformi('isRange', self.__is_range)
            calldata.SetUniform3f('highRanges', self.__high_ranges)
            calldata.SetUniform3f('lowRanges', self.__low_ranges)
            calldata.SetUniform3f('crossSection', self.__cross_section)

    def display_cross_section(self, x, y, z):
        if self.__is_range:
            self.__is_range = False
        self.__cross_section = [x, y, z]

    def display_extent(self, x1, x2, y1, y2, z1, z2):
        if not self.__is_range:
            self.__is_range = True
        self.__low_ranges = [x1, y1, z1]
        self.__high_ranges = [x2, y2, z2]

    @property
    def cross_section(self):
        return self.__cross_section

    @property
    def global_opacity(self):
        return self.__global_opacity

    @global_opacity.setter
    def global_opacity(self, opacity):
        self.__global_opacity = opacity
        self.GetProperty().SetOpacity(self.__global_opacity)

    @property
    def high_ranges(self):
        return self.__high_ranges

    @property
    def is_range(self):
        return self.__is_range

    @property
    def low_ranges(self):
        return self.__low_ranges

    @property
    def linewidth(self):
        return self.__lw

    @linewidth.setter
    def linewidth(self, linewidth):
        self.__lw = linewidth
        self.GetProperty().SetLineWidth(self.__lw)

    @property
    def max_centers(self):
        return self.__max_centers

    @property
    def min_centers(self):
        return self.__min_centers