def test_get_shifted_base(): data = np.random.random((6, 7)) tile_origin = np.array((0, 0)) tile_shape = np.array((6, 7)) target_tup, offsets = get_shifted( arr_shape=np.array(data.shape), tile_origin=tile_origin, tile_shape=tile_shape, shift=np.array((0, 0)) ) print(target_tup) print(offsets) (target_slice, source_slice) = to_slices(target_tup, offsets) print(target_slice, source_slice) res = np.full(tile_shape, 17, dtype=data.dtype) res[target_slice] = data[source_slice] print("result:", res) print("data:", data) assert np.all(res == data) assert res.dtype == data.dtype assert res.shape == data.shape
def test_get_shifted_minus_partial(): data_shape = np.array((6, 7)) data = np.random.random(data_shape) tile_origin = np.array((1, 2)) tile_shape = np.array((3, 4)) target_tup, offsets = get_shifted( arr_shape=np.array(data.shape), tile_origin=tile_origin, tile_shape=tile_shape, shift=np.array((-1, -2)) ) print(target_tup) print(offsets) (target_slice, source_slice) = to_slices(target_tup, offsets) res = np.full(tile_shape, 17, dtype=data.dtype) res[target_slice] = data[source_slice] print("result:", res) print("data:", data) assert np.all(res == data[:3, :4]) assert res.dtype == data.dtype
def test_get_shifted_plus(): data_shape = np.array((4, 5)) data = np.random.random(data_shape) tile_origin = np.array((0, 0)) tile_shape = data_shape target_tup, offsets = get_shifted( arr_shape=np.array(data.shape), tile_origin=tile_origin, tile_shape=tile_shape, shift=np.array((1, 2)) ) print(target_tup) print(offsets) (target_slice, source_slice) = to_slices(target_tup, offsets) res = np.full(tile_shape, 17, dtype=data.dtype) res[target_slice] = data[source_slice] print("result:", res) print("data:", data) assert np.all(res[:-1, :-2] == data[1:, 2:]) assert np.all(res[-1:] == 17) assert np.all(res[:, -2:] == 17) assert res.dtype == data.dtype assert res.shape == data.shape
def mask_tile_pair(center_tile, tile_origin, tile_shape, filter_center, sy, sx): ''' Numerical work horse for :meth:`mask_pair_shift`, including tiling support. The tiling support could be used to calculate the mask stack on the fly, including support for UDF.process_tile(). Parameters ---------- center_tile : numpy.ndarray Tile cut out from :code:`filter_center` for re-use to increase efficiency tile_origin : tuple Origin of the tile to calculate tile_shape : tuple Shape of the tile filter_center : numpy.ndarray Center illumination, i.e. zero order disk. sy, sx : float Trotter shift value in px Returns ------- mask_positive : numpy.ndarray Positive trotter tile target_tup_p : numpy.ndarray of int Start and stop indices per axis that were used for shifting the positive trotter tile. offsets_p : numpy.ndarray Offsets per axis that were used for shifting the positive trotter tile. mask_negative : numpy.ndarray Negative trotter tile target_tup_n : numpy.ndarray Start and stop indices per axis that were used for shifting the negative trotter tile. offsets_n : numpy.ndarray Offsets per axis that were used for shifting the negative trotter tile. ''' sy, sx, = np.int(np.round(sy)), np.int(np.round(sx)) positive_tile = np.zeros_like(center_tile) negative_tile = np.zeros_like(center_tile) # We get from negative coordinates, # that means it looks like shifted to positive target_tup_p, offsets_p = get_shifted(arr_shape=np.array( filter_center.shape), tile_origin=tile_origin, tile_shape=tile_shape, shift=np.array((-sy, -sx))) # We get from positive coordinates, # that means it looks like shifted to negative target_tup_n, offsets_n = get_shifted(arr_shape=np.array( filter_center.shape), tile_origin=tile_origin, tile_shape=tile_shape, shift=np.array((sy, sx))) sta_y, sto_y, sta_x, sto_x = target_tup_p.flatten() off_y, off_x = offsets_p positive_tile[sta_y:sto_y, sta_x:sto_x] = filter_center[sta_y + off_y:sto_y + off_y, sta_x + off_x:sto_x + off_x] sta_y, sto_y, sta_x, sto_x = target_tup_n.flatten() off_y, off_x = offsets_n negative_tile[sta_y:sto_y, sta_x:sto_x] = filter_center[sta_y + off_y:sto_y + off_y, sta_x + off_x:sto_x + off_x] mask_positive = center_tile * positive_tile * (negative_tile == 0) mask_negative = center_tile * negative_tile * (positive_tile == 0) return (mask_positive, target_tup_p, offsets_p, mask_negative, target_tup_n, offsets_n)