def from_translation_rotation(translation, rotation, com_reference,
                                  com_moving):
        transform = gemmi.Transform()
        transform.vec.fromlist(translation.tolist())
        transform.mat.fromlist(rotation.as_matrix().tolist())

        return Transform(transform, com_reference, com_moving)
Example #2
0
def sample_map(
    gemmi_grid,
    centroid,
    rotation,
    translation,
    shape,
    scale=0.5,
):
    rotation = np.matmul(
        rotation,
        np.eye(3) * scale,
    )

    offset = -(np.array(shape) / 2) * scale

    rotated_offset = np.matmul(rotation, offset) + translation

    offset_translation = centroid + rotated_offset

    arr = np.zeros(
        shape,
        dtype=np.float32,
    )
    tr = gemmi.Transform()

    tr.mat.fromlist(rotation.tolist())
    tr.vec.fromlist(offset_translation.tolist())
    gemmi_grid.interpolate_values(
        arr,
        tr,
    )
    return arr
def test_rotation(structure, orientation):
    """Test gemmi rotation transformation does what we expect"""
    sites = structure.get_all_unit_cell_sites()
    tr = gemmi.Transform()
    tr.mat.fromlist(orientation.as_list_of_lists())

    orig_pos = [site.orth(structure.cell) for site in sites]
    plot_atom_positions(orig_pos)
    new_pos = [tr.apply(pos) for pos in orig_pos]

    for vector, rotated in zip(orig_pos, new_pos):
        rotated2 = orientation * matrix.col(vector.tolist())
        for i in range(3):
            assert rotated2[i] == pytest.approx(rotated[i])
Example #4
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def sample_dataset_global(unaligned_xmap, sample_region: SampleRegion):
    tr = gemmi.Transform()
    tr.mat.fromlist(sample_region.rotation.tolist())
    tr.vec.fromlist(sample_region.origin.tolist())

    arr = np.zeros(
        (
            int(sample_region.gridding[0]),
            int(sample_region.gridding[1]),
            int(sample_region.gridding[2]),
        ),
        dtype=np.float32,
    )

    unaligned_xmap.interpolate_values(arr, tr)

    return arr
def perturb_sample_region(transformed_sample_region, perturbation):
    # Split out the components of the perturbation
    transformation_perturbation = perturbation[0:3]
    rotation_perturbation = perturbation[3:6]

    #
    rotation_perturbation_obj = scipy.spatial.transform.Rotation.from_euler(
        "xyz",
        [rotation_perturbation[0], rotation_perturbation[1], rotation_perturbation[2]], degrees=True)
    rotation_perturbation_mat = rotation_perturbation_obj.as_matrix()

    # Package them as a transform
    transform = gemmi.Transform()
    transform.vec.fromlist(transformation_perturbation.tolist())
    transform.mat.fromlist(rotation_perturbation_mat.tolist())

    # Get the perturbed sample region
    perturbed_sample_region = get_transformed_sample_region(transformed_sample_region, Transform(transform))

    return perturbed_sample_region
def sample_map(
    gemmi_grid,
    centroid,
    rotation,
    translation,
    shape,
):
    offset = translation - (np.array(shape) / 2)

    rotated_offset = np.matmul(rotation, offset)

    offset_translation = centroid + rotated_offset

    arr = np.zeros(shape)
    tr = gemmi.Transform()
    tr.mat.fromlist(rotation.tolist())
    tr.vec.fromlist(offset_translation.tolist())
    gemmi_grid.interpolate_values(
        arr,
        tr,
    )
    return arr
Example #7
0
def sample(xmap, parameters):
    shape = 32
    scale = 0.5

    arr = np.zeros([32, 32, 32], dtype=np.float32)
    tr = gemmi.Transform()
    trans = [
        parameters[0],
        parameters[1],
        parameters[2],
    ]
    angles = [
        parameters[3],
        parameters[4],
        parameters[5],
    ]

    rotation_x = Rotation.from_euler("x", angles[0])
    rotation_y = Rotation.from_euler("y", angles[1])
    rotation_z = Rotation.from_euler("z", angles[2])

    scale = np.eye(3) * 0.5

    rotation = np.matmul(
        rotation_x.as_matrix(),
        np.matmul(
            rotation_y.as_matrix(),
            rotation_z.as_matrix(),
        ),
    )
    rotation = np.matmul(rotation, scale)

    trans = trans - np.matmul(rotation, np.array([shape, shape, shape]) / 2)

    tr.mat.fromlist(rotation.tolist())
    tr.vec.fromlist(trans)
    xmap.grid.interpolate_values(arr, tr)
    return arr
Example #8
0
 def to_gemmi(self):
     transform_gemmi = gemmi.Transform()
     transform_gemmi.mat.fromlist(self.transform)
     return transform_gemmi
def resample(
        reference_xmap: gemmi.FloatGrid,
        moving_xmap: gemmi.FloatGrid,
        reference_structure: gemmi.Structure,
        moving_structure: gemmi.Structure,
        monomerized=False,
):
    # Get transform: from ref to align
    transform = get_alignment(moving_structure, reference_structure, monomerized=monomerized)
    print(f"Transform: {transform}; {transform.transform.vec} {transform.transform.mat}")

    interpolated_grid = gemmi.FloatGrid(
        reference_xmap.nu,
        reference_xmap.nv,
        reference_xmap.nw,
    )
    interpolated_grid.set_unit_cell(reference_xmap.unit_cell)
    interpolated_grid.spacegroup = reference_xmap.spacegroup

    # points
    mask = gemmi.FloatGrid(reference_xmap.nu,
                           reference_xmap.nv,
                           reference_xmap.nw, )
    mask.set_unit_cell(reference_xmap.unit_cell)
    mask.spacegroup = gemmi.find_spacegroup_by_name("P 1")

    for model in reference_structure:
        for chain in model:
            for residue in chain.get_polymer():
                for atom in residue:
                    mask.set_points_around(atom.pos, 3.0, 1.0)

    mask_array = np.array(mask)
    mask_indicies = np.hstack([x.reshape((len(x), 1)) for x in np.nonzero(mask)])
    print(f"Mask indicies shape: {mask_indicies.shape}")

    fractional_coords = []
    for model in reference_structure:
        for chain in model:
            for residue in chain.get_polymer():
                for atom in residue:
                    fractional = reference_xmap.unit_cell.fractionalize(atom.pos)
                    fractional_coords.append([fractional.x, fractional.y, fractional.z])

    fractional_coords_array = np.array(fractional_coords)
    max_coord = np.max(fractional_coords_array, axis=0)
    min_coord = np.min(fractional_coords_array, axis=0)

    min_index = np.floor(min_coord * np.array([interpolated_grid.nu, interpolated_grid.nv, interpolated_grid.nw]))
    max_index = np.floor(max_coord * np.array([interpolated_grid.nu, interpolated_grid.nv, interpolated_grid.nw]))

    points = itertools.product(range(int(min_index[0]), int(max_index[0])),
                               range(int(min_index[1]), int(max_index[1])),
                               range(int(min_index[2]), int(max_index[2])),
                               )

    # Unpack the points, poitions and transforms
    point_list: List[Tuple[int, int, int]] = []
    position_list: List[Tuple[float, float, float]] = []
    transform_list: List[gemmi.transform] = []
    com_moving_list: List[np.array] = []
    com_reference_list: List[np.array] = []

    transform_rotate_reference_to_moving = transform.transform
    transform_rotate_reference_to_moving.vec.fromlist([0.0, 0.0, 0.0])

    transform_reference_to_centered = gemmi.Transform()
    transform_reference_to_centered.vec.fromlist((-transform.com_reference).tolist())
    transform_reference_to_centered.mat.fromlist(np.eye(3).tolist())

    tranform_centered_to_moving = gemmi.Transform()
    tranform_centered_to_moving.vec.fromlist(transform.com_moving.tolist())
    tranform_centered_to_moving.mat.fromlist(np.eye(3).tolist())

    # indicies to positions
    for point in points:
        if mask.get_value(*point) < 1.0:
            continue

        # get position
        position = interpolated_grid.get_position(*point)

        # Tranform to origin frame
        position_origin_reference = gemmi.Position(transform_reference_to_centered.apply(position))

        # Rotate
        position_origin_moving = gemmi.Position(transform_rotate_reference_to_moving.apply(position_origin_reference))

        # Transform to moving frame
        position_moving = gemmi.Position(tranform_centered_to_moving.apply(position_origin_moving))

        # Interpolate moving map
        interpolated_map_value = moving_xmap.interpolate_value(position_moving)

        # Set original point
        interpolated_grid.set_value(point[0], point[1], point[2], interpolated_map_value)

    interpolated_grid.symmetrize_max()

    return interpolated_grid
Example #10
0
 def __setstate__(self, state):
     self.transform = gemmi.Transform()
     self.transform.mat.fromlist(state["mat"])
     self.transform.vec.fromlist(state["vec"])