def test(self):
direction = Direction(1, -1, -1, 1)
position = (3, 5, 2, 1)
actual = direction.get_previous_step_positions(position)
expected = [(2, 5, 2, 1), (3, 6, 2, 1), (3, 5, 3, 1), (3, 5, 2, 0)]
self.assertEqual(expected, actual)
def test_right_to_left(self):
direction = Direction(-1)
it = direction.iterate_over_positions(dim_lengths=[3])
positions = list(it)
expected = [(2,), (1,), (0,)]
self.assertEqual(expected, positions)
def get_expected_last_state(self):
if self._direction == Direction.south_east():
return self.south_east_state
elif self._direction == Direction.south_west():
return self.south_west_state
elif self._direction == Direction.north_east():
return self.north_east_state
elif self._direction == Direction.north_west():
return self.north_west_state
def get_expected_result(self):
if self._direction == Direction.south_east():
return self.south_east_output
elif self._direction == Direction.south_west():
return self.south_west_output
elif self._direction == Direction.north_east():
return self.north_east_output
elif self._direction == Direction.north_west():
return self.north_west_output
def test_getting_8_directions_for_3_dimensional_space(self):
directions = Direction.get_all_directions(ndims=3)
expected = [Direction(1, 1, 1), Direction(1, 1, -1),
Direction(1, -1, 1), Direction(1, -1, -1),
Direction(-1, 1, 1), Direction(-1, 1, -1),
Direction(-1, -1, 1), Direction(-1, -1, -1)]
self.assertEqual(expected, directions)
def make_rnns(return_sequences, return_state, go_backwards=False):
seed = 1
kernel_initializer = initializers.glorot_uniform(seed)
recurrent_initializer = initializers.he_normal(seed)
bias_initializer = initializers.he_normal(seed)
kwargs = dict(units=3,
input_shape=(None, 5),
activation='tanh',
recurrent_activation='sigmoid',
kernel_initializer=kernel_initializer,
recurrent_initializer=recurrent_initializer,
bias_initializer=bias_initializer,
return_sequences=return_sequences,
return_state=return_state)
if go_backwards:
kwargs.update(dict(direction=Direction(-1)))
rnn = MDGRU(**kwargs)
keras_rnn = tf.keras.layers.GRU(
units=3,
activation='tanh',
recurrent_activation='sigmoid',
implementation=1,
kernel_initializer=kernel_initializer,
recurrent_initializer=recurrent_initializer,
bias_initializer=bias_initializer,
return_sequences=return_sequences,
reset_after=False,
return_state=return_state,
go_backwards=go_backwards)
return rnn, keras_rnn
def test_bidirectional_rnn_returns_result_with_correct_shape(self):
rnn = self.create_mdrnn(direction=Direction(1))
rnn = MultiDirectional(rnn)
a = rnn.call(self.x, initial_state=self.initial_state, dtype=np.float)
self.assertEqual((1, 3, 2), a.shape)
def test_backward_direction(self):
mdrnn = self.create_mdrnn(direction=Direction(-1))
a = mdrnn.call(self.x, initial_state=self.initial_state, dtype=np.float)
expected_result = np.array(self.backward_result).reshape((1, 3, 1))
np.testing.assert_almost_equal(expected_result, a.numpy(), 8)
def test_returns_list_of_correct_length(self):
rnn_setup = Rnn2dTestSetup(direction=Direction.south_east())
rnn = rnn_setup.make_rnn()
rnn = MultiDirectional(rnn)
x = rnn_setup.make_input()
actual = rnn.call(x)
# 1 element for output of RNN and 4 elements for states, 1 state per each direction
self.assertEqual(5, len(actual))
def test_bidirectional_rnn_returns_correct_result(self):
rnn = self.create_mdrnn(direction=Direction(1))
rnn = MultiDirectional(rnn)
a = rnn.call(self.x, initial_state=self.initial_state, dtype=np.float)
expected_result = np.array([
[2, 8],
[4, 4],
[8, 2]
]).reshape((1, 3, 2))
np.testing.assert_almost_equal(expected_result, a.numpy(), 8)
def test_with_functor(self):
rnn = self.create_mdrnn(direction=Direction(1))
rnn = MultiDirectional(rnn)
a = rnn(self.x, initial_state=self.initial_state)
expected_result = np.array([
[2, 8],
[4, 4],
[8, 2]
]).reshape((1, 3, 2))
np.testing.assert_almost_equal(expected_result, a.numpy(), 8)
def test_results(self):
rnn_setup = Rnn2dTestSetup(direction=Direction.south_east())
rnn = rnn_setup.make_rnn()
rnn = MultiDirectional(rnn)
x = rnn_setup.make_input()
expected = rnn_setup.get_expected_result_for_multi_directional_rnn()
actual = rnn.call(x)
num_elements = 5
for i in range(num_elements):
actual_output = actual[i]
expected_output = expected[i]
np.testing.assert_almost_equal(expected_output,
actual_output.numpy(), 6)
def make_rnns(self, return_sequences, return_state, go_backwards=False):
seed = 1
kwargs = dict(units=3, input_shape=(None, 5),
kernel_initializer=initializers.glorot_uniform(seed),
recurrent_initializer=initializers.he_normal(seed),
bias_initializer=initializers.Constant(2),
return_sequences=return_sequences,
return_state=return_state,
activation='relu'
)
mdrnn_kwargs = dict(kwargs)
if go_backwards:
mdrnn_kwargs.update(dict(direction=Direction(-1)))
rnn = MDRNN(**mdrnn_kwargs)
keras_rnn_kwargs = dict(kwargs)
keras_rnn_kwargs.update(dict(go_backwards=go_backwards))
keras_rnn = tf.keras.layers.SimpleRNN(**keras_rnn_kwargs)
return rnn, keras_rnn
def test_with_valid_direction(self):
self.assert_valid_direction(Direction(-1, 1))
def test_pass_invalid_direction_to_2drnn(self):
self.assert_invalid_direction(Direction(1))
def test_cannot_instantiate_direction_with_arbitrary_number(self):
self.assertRaises(TypeError, lambda: Direction(8))
self.assertRaises(TypeError, lambda: Direction(0))
self.assertRaises(TypeError, lambda: Direction(-2, 1, -1))
def test_length_of_direction_vector_must_match_dimensionality_of_input(self):
self.assert_invalid_direction(Direction())
self.assert_invalid_direction(Direction(1, 1))
def test_no_duplicate_directions(self):
n = 7
directions = Direction.get_all_directions(ndims=n)
unique = set(directions)
self.assertEqual(len(directions), len(unique))
def test_getting_2_to_the_n_directions_for_n_dimensional_space(self):
n = 5
directions = Direction.get_all_directions(ndims=n)
self.assertEqual(2**n, len(directions))
def test_getting_2_directions_for_1_dimensional_space(self):
directions = Direction.get_all_directions(ndims=1)
self.assertEqual([Direction(1), Direction(-1)], directions)
def get_direction(self):
return Direction(1, 1)
def test_going_right_to_left(self):
direction = Direction(-1)
position = (3,)
self.assertEqual([(4,)], direction.get_previous_step_positions(position))
def create_direction(self):
return Direction(-1, -1)
def create_direction(self):
return Direction(1, 1)
def get_direction(self):
return Direction(-1, -1)
