def layer_test(layer_cls, kwargs={}, input_shape=None, input_dtype=None,
input_data=None, expected_output=None,
expected_output_dtype=None, fixed_batch_size=False):
# generate input data
if input_data is None:
if not input_shape:
raise AssertionError()
if not input_dtype:
input_dtype = K.floatx()
input_data_shape = list(input_shape)
for i, e in enumerate(input_data_shape):
if e is None:
input_data_shape[i] = np.random.randint(1, 4)
if all(isinstance(e, tuple) for e in input_data_shape):
input_data = []
for e in input_data_shape:
input_data.append(
(10 * np.random.random(e)).astype(input_dtype))
else:
input_data = (10 * np.random.random(input_data_shape))
input_data = input_data.astype(input_dtype)
else:
if input_shape is None:
input_shape = input_data.shape
if input_dtype is None:
input_dtype = input_data.dtype
if expected_output_dtype is None:
expected_output_dtype = input_dtype
# instantiation
layer = layer_cls(**kwargs)
# test get_weights , set_weights at layer level
weights = layer.get_weights()
layer.set_weights(weights)
try:
expected_output_shape = layer.compute_output_shape(input_shape)
except Exception:
expected_output_shape = layer._compute_output_shape(input_shape)
# test in functional API
if isinstance(input_shape, list):
if fixed_batch_size:
x = [Input(batch_shape=e, dtype=input_dtype) for e in input_shape]
else:
x = [Input(shape=e[1:], dtype=input_dtype) for e in input_shape]
else:
if fixed_batch_size:
x = Input(batch_shape=input_shape, dtype=input_dtype)
else:
x = Input(shape=input_shape[1:], dtype=input_dtype)
y = layer(x)
if not (K.dtype(y) == expected_output_dtype):
raise AssertionError()
# check with the functional API
model = Model(x, y)
actual_output = model.predict(input_data)
actual_output_shape = actual_output.shape
for expected_dim, actual_dim in zip(expected_output_shape,
actual_output_shape):
if expected_dim is not None:
if not (expected_dim == actual_dim):
raise AssertionError()
if expected_output is not None:
assert_allclose(actual_output, expected_output, rtol=1e-3)
# test serialization, weight setting at model level
model_config = model.get_config()
recovered_model = model.__class__.from_config(model_config)
if model.weights:
weights = model.get_weights()
recovered_model.set_weights(weights)
_output = recovered_model.predict(input_data)
assert_allclose(_output, actual_output, rtol=1e-3)
# test training mode (e.g. useful when the layer has a
# different behavior at training and testing time).
if has_arg(layer.call, 'training'):
model.compile('rmsprop', 'mse')
model.train_on_batch(input_data, actual_output)
# test instantiation from layer config
layer_config = layer.get_config()
layer_config['batch_input_shape'] = input_shape
layer = layer.__class__.from_config(layer_config)
# for further checks in the caller function
return actual_output
def layer_test(layer_cls,
kwargs={},
input_shape=None,
input_dtype=None,
input_data=None,
expected_output=None,
expected_output_dtype=None,
fixed_batch_size=False,
supports_masking=False):
# generate input data
if input_data is None:
if not input_shape:
raise AssertionError()
if not input_dtype:
input_dtype = K.floatx()
input_data_shape = list(input_shape)
for i, e in enumerate(input_data_shape):
if e is None:
input_data_shape[i] = np.random.randint(1, 4)
input_mask = []
if all(isinstance(e, tuple) for e in input_data_shape):
input_data = []
for e in input_data_shape:
input_data.append(
(10 * np.random.random(e)).astype(input_dtype))
if supports_masking:
a = np.full(e[:2], False)
a[:, :e[1] // 2] = True
input_mask.append(a)
else:
input_data = (10 * np.random.random(input_data_shape))
input_data = input_data.astype(input_dtype)
if supports_masking:
a = np.full(input_data_shape[:2], False)
a[:, :input_data_shape[1] // 2] = True
print(a)
print(a.shape)
input_mask.append(a)
else:
if input_shape is None:
input_shape = input_data.shape
if input_dtype is None:
input_dtype = input_data.dtype
if expected_output_dtype is None:
expected_output_dtype = input_dtype
# instantiation
layer = layer_cls(**kwargs)
# test get_weights , set_weights at layer level
weights = layer.get_weights()
layer.set_weights(weights)
try:
expected_output_shape = layer.compute_output_shape(input_shape)
except Exception:
expected_output_shape = layer._compute_output_shape(input_shape)
# test in functional API
if isinstance(input_shape, list):
if fixed_batch_size:
x = [Input(batch_shape=e, dtype=input_dtype) for e in input_shape]
if supports_masking:
mask = [
Input(batch_shape=e[0:2], dtype=bool) for e in input_shape
]
else:
x = [Input(shape=e[1:], dtype=input_dtype) for e in input_shape]
if supports_masking:
mask = [Input(shape=(e[1], ), dtype=bool) for e in input_shape]
else:
if fixed_batch_size:
x = Input(batch_shape=input_shape, dtype=input_dtype)
if supports_masking:
mask = Input(batch_shape=input_shape[0:2], dtype=bool)
else:
x = Input(shape=input_shape[1:], dtype=input_dtype)
if supports_masking:
mask = Input(shape=(input_shape[1], ), dtype=bool)
if supports_masking:
y = layer(Masking()(x), mask=mask)
else:
y = layer(x)
if not (K.dtype(y) == expected_output_dtype):
raise AssertionError()
# check with the functional API
if supports_masking:
model = Model([x, mask], y)
actual_output = model.predict([input_data, input_mask[0]])
else:
model = Model(x, y)
actual_output = model.predict(input_data)
actual_output_shape = actual_output.shape
for expected_dim, actual_dim in zip(expected_output_shape,
actual_output_shape):
if expected_dim is not None:
if not (expected_dim == actual_dim):
raise AssertionError("expected_shape", expected_output_shape,
"actual_shape", actual_output_shape)
if expected_output is not None:
assert_allclose(actual_output, expected_output, rtol=1e-3)
# test serialization, weight setting at model level
model_config = model.get_config()
recovered_model = model.__class__.from_config(model_config)
if model.weights:
weights = model.get_weights()
recovered_model.set_weights(weights)
_output = recovered_model.predict(input_data)
assert_allclose(_output, actual_output, rtol=1e-3)
# test training mode (e.g. useful when the layer has a
# different behavior at training and testing time).
if has_arg(layer.call, 'training'):
model.compile('rmsprop', 'mse')
model.train_on_batch(input_data, actual_output)
# test instantiation from layer config
layer_config = layer.get_config()
layer_config['batch_input_shape'] = input_shape
layer = layer.__class__.from_config(layer_config)
# for further checks in the caller function
return actual_output
def layer_test(layer_cls,
kwargs={},
input_shape=None,
input_dtype=None,
input_data=None,
expected_output=None,
expected_output_dtype=None,
fixed_batch_size=False):
"""Test routine for a layer with a single input tensor
and single output tensor.
"""
# generate input data
if input_data is None:
assert input_shape
if not input_dtype:
input_dtype = K.floatx()
input_data_shape = list(input_shape)
for i, e in enumerate(input_data_shape):
if e is None:
input_data_shape[i] = np.random.randint(1, 4)
input_data = (10 * np.random.random(input_data_shape))
input_data = input_data.astype(input_dtype)
else:
if input_shape is None:
input_shape = input_data.shape
if input_dtype is None:
input_dtype = input_data.dtype
if expected_output_dtype is None:
expected_output_dtype = input_dtype
# instantiation
layer = layer_cls(**kwargs)
# test get_weights , set_weights at layer level
weights = layer.get_weights()
layer.set_weights(weights)
try:
expected_output_shape = layer.compute_output_shape(input_shape)
except:
expected_output_shape = layer._compute_output_shape(input_shape)
# test in functional API
if fixed_batch_size:
x = Input(batch_shape=input_shape, dtype=input_dtype)
else:
x = Input(shape=input_shape[1:], dtype=input_dtype)
y = layer(x)
assert K.dtype(y) == expected_output_dtype
# check with the functional API
model = Model(x, y)
actual_output = model.predict(input_data)
actual_output_shape = actual_output.shape
for expected_dim, actual_dim in zip(expected_output_shape,
actual_output_shape):
if expected_dim is not None:
assert expected_dim == actual_dim
if expected_output is not None:
assert_allclose(actual_output, expected_output, rtol=1e-3)
# test serialization, weight setting at model level
model_config = model.get_config()
recovered_model = model.__class__.from_config(model_config)
if model.weights:
weights = model.get_weights()
recovered_model.set_weights(weights)
_output = recovered_model.predict(input_data)
assert_allclose(_output, actual_output, rtol=1e-3)
# test training mode (e.g. useful when the layer has a
# different behavior at training and testing time).
if has_arg(layer.call, 'training'):
model.compile('rmsprop', 'mse')
model.train_on_batch(input_data, actual_output)
# test instantiation from layer config
layer_config = layer.get_config()
layer_config['batch_input_shape'] = input_shape
layer = layer.__class__.from_config(layer_config)
# for further checks in the caller function
return actual_output
