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Monotonic attention mechanism with Bahdanau-style energy function.
Inherits From: AttentionMechanism
tfa.seq2seq.BahdanauMonotonicAttention(
units: tfa.types.TensorLike
,
memory: Optional[TensorLike] = None,
memory_sequence_length: Optional[TensorLike] = None,
normalize: bool = False,
sigmoid_noise: tfa.types.FloatTensorLike
= 0.0,
sigmoid_noise_seed: Optional[FloatTensorLike] = None,
score_bias_init: tfa.types.FloatTensorLike
= 0.0,
mode: str = 'parallel',
kernel_initializer: tfa.types.Initializer
= 'glorot_uniform',
dtype: tfa.types.AcceptableDTypes
= None,
name: str = 'BahdanauMonotonicAttention',
**kwargs
)
This type of attention enforces a monotonic constraint on the attention
distributions; that is once the model attends to a given point in the
memory it can't attend to any prior points at subsequence output timesteps.
It achieves this by using the _monotonic_probability_fn
instead of softmax
to construct its attention distributions. Since the attention scores are
passed through a sigmoid, a learnable scalar bias parameter is applied
after the score function and before the sigmoid. Otherwise, it is
equivalent to tfa.seq2seq.BahdanauAttention
. This approach is proposed in
Colin Raffel, Minh-Thang Luong, Peter J. Liu, Ron J. Weiss, Douglas Eck, "Online and Linear-Time Attention by Enforcing Monotonic Alignments." ICML 2017. https://arxiv.org/abs/1704.00784
Args | |
---|---|
units
|
The depth of the query mechanism. |
memory
|
The memory to query; usually the output of an RNN encoder.
This tensor should be shaped [batch_size, max_time, ...] .
|
memory_sequence_length
|
(optional): Sequence lengths for the batch entries in memory. If provided, the memory tensor rows are masked with zeros for values past the respective sequence lengths. |
normalize
|
Python boolean. Whether to normalize the energy term. |
sigmoid_noise
|
Standard deviation of pre-sigmoid noise. See the
docstring for _monotonic_probability_fn for more information.
|
sigmoid_noise_seed
|
(optional) Random seed for pre-sigmoid noise. |
score_bias_init
|
Initial value for score bias scalar. It's recommended to initialize this to a negative value when the length of the memory is large. |
mode
|
How to compute the attention distribution. Must be one of
'recursive', 'parallel', or 'hard'. See the docstring for
tfa.seq2seq.monotonic_attention for more information.
|
kernel_initializer
|
(optional), the name of the initializer for the attention kernel. |
dtype
|
The data type for the query and memory layers of the attention mechanism. |
name
|
Name to use when creating ops. |
**kwargs
|
Dictionary that contains other common arguments for layer creation. |
Attributes | |
---|---|
activity_regularizer
|
Optional regularizer function for the output of this layer. |
alignments_size
|
|
compute_dtype
|
The dtype of the layer's computations.
This is equivalent to Layers automatically cast their inputs to the compute dtype, which
causes computations and the output to be in the compute dtype as well.
This is done by the base Layer class in Layers often perform certain internal computations in higher precision
when |
dtype
|
The dtype of the layer weights.
This is equivalent to |
dtype_policy
|
The dtype policy associated with this layer.
This is an instance of a |
dynamic
|
Whether the layer is dynamic (eager-only); set in the constructor. |
input
|
Retrieves the input tensor(s) of a layer.
Only applicable if the layer has exactly one input, i.e. if it is connected to one incoming layer. |
input_spec
|
InputSpec instance(s) describing the input format for this layer.
When you create a layer subclass, you can set
Now, if you try to call the layer on an input that isn't rank 4
(for instance, an input of shape
Input checks that can be specified via
For more information, see |
losses
|
List of losses added using the add_loss() API.
Variable regularization tensors are created when this property is
accessed, so it is eager safe: accessing
|
memory_initialized
|
Returns True if this attention mechanism has been initialized with a memory.
|
metrics
|
List of metrics added using the add_metric() API.
|
name
|
Name of the layer (string), set in the constructor. |
name_scope
|
Returns a tf.name_scope instance for this class.
|
non_trainable_weights
|
List of all non-trainable weights tracked by this layer.
Non-trainable weights are not updated during training. They are
expected to be updated manually in |
output
|
Retrieves the output tensor(s) of a layer.
Only applicable if the layer has exactly one output, i.e. if it is connected to one incoming layer. |
state_size
|
|
submodules
|
Sequence of all sub-modules.
Submodules are modules which are properties of this module, or found as properties of modules which are properties of this module (and so on).
|
supports_masking
|
Whether this layer supports computing a mask using compute_mask .
|
trainable
|
|
trainable_weights
|
List of all trainable weights tracked by this layer.
Trainable weights are updated via gradient descent during training. |
variable_dtype
|
Alias of Layer.dtype , the dtype of the weights.
|
weights
|
Returns the list of all layer variables/weights. |
Methods
add_loss
add_loss(
losses, **kwargs
)
Add loss tensor(s), potentially dependent on layer inputs.
Some losses (for instance, activity regularization losses) may be
dependent on the inputs passed when calling a layer. Hence, when reusing
the same layer on different inputs a
and b
, some entries in
layer.losses
may be dependent on a
and some on b
. This method
automatically keeps track of dependencies.
This method can be used inside a subclassed layer or model's call
function, in which case losses
should be a Tensor or list of Tensors.
Example:
class MyLayer(tf.keras.layers.Layer):
def call(self, inputs):
self.add_loss(tf.abs(tf.reduce_mean(inputs)))
return inputs
The same code works in distributed training: the input to add_loss()
is treated like a regularization loss and averaged across replicas
by the training loop (both built-in Model.fit()
and compliant custom
training loops).
The add_loss
method can also be called directly on a Functional Model
during construction. In this case, any loss Tensors passed to this Model
must be symbolic and be able to be traced back to the model's Input
s.
These losses become part of the model's topology and are tracked in
get_config
.
Example:
inputs = tf.keras.Input(shape=(10,))
x = tf.keras.layers.Dense(10)(inputs)
outputs = tf.keras.layers.Dense(1)(x)
model = tf.keras.Model(inputs, outputs)
# Activity regularization.
model.add_loss(tf.abs(tf.reduce_mean(x)))
If this is not the case for your loss (if, for example, your loss
references a Variable
of one of the model's layers), you can wrap your
loss in a zero-argument lambda. These losses are not tracked as part of
the model's topology since they can't be serialized.
Example:
inputs = tf.keras.Input(shape=(10,))
d = tf.keras.layers.Dense(10)
x = d(inputs)
outputs = tf.keras.layers.Dense(1)(x)
model = tf.keras.Model(inputs, outputs)
# Weight regularization.
model.add_loss(lambda: tf.reduce_mean(d.kernel))
Args | |
---|---|
losses
|
Loss tensor, or list/tuple of tensors. Rather than tensors, losses may also be zero-argument callables which create a loss tensor. |
**kwargs
|
Used for backwards compatibility only. |
add_metric
add_metric(
value, name=None, **kwargs
)
Adds metric tensor to the layer.
This method can be used inside the call()
method of a subclassed layer
or model.
class MyMetricLayer(tf.keras.layers.Layer):
def __init__(self):
super(MyMetricLayer, self).__init__(name='my_metric_layer')
self.mean = tf.keras.metrics.Mean(name='metric_1')
def call(self, inputs):
self.add_metric(self.mean(inputs))
self.add_metric(tf.reduce_sum(inputs), name='metric_2')
return inputs
This method can also be called directly on a Functional Model during
construction. In this case, any tensor passed to this Model must
be symbolic and be able to be traced back to the model's Input
s. These
metrics become part of the model's topology and are tracked when you
save the model via save()
.
inputs = tf.keras.Input(shape=(10,))
x = tf.keras.layers.Dense(10)(inputs)
outputs = tf.keras.layers.Dense(1)(x)
model = tf.keras.Model(inputs, outputs)
model.add_metric(math_ops.reduce_sum(x), name='metric_1')
inputs = tf.keras.Input(shape=(10,))
x = tf.keras.layers.Dense(10)(inputs)
outputs = tf.keras.layers.Dense(1)(x)
model = tf.keras.Model(inputs, outputs)
model.add_metric(tf.keras.metrics.Mean()(x), name='metric_1')
Args | |
---|---|
value
|
Metric tensor. |
name
|
String metric name. |
**kwargs
|
Additional keyword arguments for backward compatibility.
Accepted values:
aggregation - When the value tensor provided is not the result
of calling a keras.Metric instance, it will be aggregated by
default using a keras.Metric.Mean .
|
build
build(
input_shape
)
Creates the variables of the layer (for subclass implementers).
This is a method that implementers of subclasses of Layer
or Model
can override if they need a state-creation step in-between
layer instantiation and layer call. It is invoked automatically before
the first execution of call()
.
This is typically used to create the weights of Layer
subclasses
(at the discretion of the subclass implementer).
Args | |
---|---|
input_shape
|
Instance of TensorShape , or list of instances of
TensorShape if the layer expects a list of inputs
(one instance per input).
|
build_from_config
build_from_config(
config
)
compute_mask
compute_mask(
inputs, mask=None
)
Computes an output mask tensor.
Args | |
---|---|
inputs
|
Tensor or list of tensors. |
mask
|
Tensor or list of tensors. |
Returns | |
---|---|
None or a tensor (or list of tensors, one per output tensor of the layer). |
compute_output_shape
compute_output_shape(
input_shape
)
Computes the output shape of the layer.
This method will cause the layer's state to be built, if that has not happened before. This requires that the layer will later be used with inputs that match the input shape provided here.
Args | |
---|---|
input_shape
|
Shape tuple (tuple of integers) or tf.TensorShape ,
or structure of shape tuples / tf.TensorShape instances
(one per output tensor of the layer).
Shape tuples can include None for free dimensions,
instead of an integer.
|
Returns | |
---|---|
A tf.TensorShape instance
or structure of tf.TensorShape instances.
|
count_params
count_params()
Count the total number of scalars composing the weights.
Returns | |
---|---|
An integer count. |
Raises | |
---|---|
ValueError
|
if the layer isn't yet built (in which case its weights aren't yet defined). |
deserialize_inner_layer_from_config
@classmethod
deserialize_inner_layer_from_config( config, custom_objects )
Helper method that reconstruct the query and memory from the config.
In the get_config() method, the query and memory layer configs are serialized into dict for persistence, this method perform the reverse action to reconstruct the layer from the config.
Args | |
---|---|
config
|
dict, the configs that will be used to reconstruct the object. |
custom_objects
|
dict mapping class names (or function names) of custom (non-Keras) objects to class/functions. |
Returns | |
---|---|
config
|
dict, the config with layer instance created, which is ready to be used as init parameters. |
from_config
@classmethod
from_config( config, custom_objects=None )
Creates a layer from its config.
This method is the reverse of get_config
,
capable of instantiating the same layer from the config
dictionary. It does not handle layer connectivity
(handled by Network), nor weights (handled by set_weights
).
Args | |
---|---|
config
|
A Python dictionary, typically the output of get_config. |
Returns | |
---|---|
A layer instance. |
get_build_config
get_build_config()
get_config
get_config()
Returns the config of the layer.
A layer config is a Python dictionary (serializable) containing the configuration of a layer. The same layer can be reinstantiated later (without its trained weights) from this configuration.
The config of a layer does not include connectivity
information, nor the layer class name. These are handled
by Network
(one layer of abstraction above).
Note that get_config()
does not guarantee to return a fresh copy of
dict every time it is called. The callers should make a copy of the
returned dict if they want to modify it.
Returns | |
---|---|
Python dictionary. |
get_weights
get_weights()
Returns the current weights of the layer, as NumPy arrays.
The weights of a layer represent the state of the layer. This function returns both trainable and non-trainable weight values associated with this layer as a list of NumPy arrays, which can in turn be used to load state into similarly parameterized layers.
For example, a Dense
layer returns a list of two values: the kernel
matrix and the bias vector. These can be used to set the weights of
another Dense
layer:
layer_a = tf.keras.layers.Dense(1,
kernel_initializer=tf.constant_initializer(1.))
a_out = layer_a(tf.convert_to_tensor([[1., 2., 3.]]))
layer_a.get_weights()
[array([[1.],
[1.],
[1.]], dtype=float32), array([0.], dtype=float32)]
layer_b = tf.keras.layers.Dense(1,
kernel_initializer=tf.constant_initializer(2.))
b_out = layer_b(tf.convert_to_tensor([[10., 20., 30.]]))
layer_b.get_weights()
[array([[2.],
[2.],
[2.]], dtype=float32), array([0.], dtype=float32)]
layer_b.set_weights(layer_a.get_weights())
layer_b.get_weights()
[array([[1.],
[1.],
[1.]], dtype=float32), array([0.], dtype=float32)]
Returns | |
---|---|
Weights values as a list of NumPy arrays. |
initial_alignments
initial_alignments(
batch_size, dtype
)
Creates the initial alignment values for the monotonic attentions.
Initializes to dirac distributions, i.e. [1, 0, 0, ...memory length..., 0] for all entries in the batch.
Args | |
---|---|
batch_size
|
int32 scalar, the batch_size.
|
dtype
|
The dtype .
|
Returns | |
---|---|
A dtype tensor shaped [batch_size, alignments_size]
(alignments_size is the values' max_time ).
|
initial_state
initial_state(
batch_size, dtype
)
Creates the initial state values for the tfa.seq2seq.AttentionWrapper
class.
This is important for attention mechanisms that use the previous alignment to calculate the alignment at the next time step (e.g. monotonic attention).
The default behavior is to return the same output as
initial_alignments
.
Args | |
---|---|
batch_size
|
int32 scalar, the batch_size.
|
dtype
|
The dtype .
|
Returns | |
---|---|
A structure of all-zero tensors with shapes as described by
state_size .
|
set_weights
set_weights(
weights
)
Sets the weights of the layer, from NumPy arrays.
The weights of a layer represent the state of the layer. This function sets the weight values from numpy arrays. The weight values should be passed in the order they are created by the layer. Note that the layer's weights must be instantiated before calling this function, by calling the layer.
For example, a Dense
layer returns a list of two values: the kernel
matrix and the bias vector. These can be used to set the weights of
another Dense
layer:
layer_a = tf.keras.layers.Dense(1,
kernel_initializer=tf.constant_initializer(1.))
a_out = layer_a(tf.convert_to_tensor([[1., 2., 3.]]))
layer_a.get_weights()
[array([[1.],
[1.],
[1.]], dtype=float32), array([0.], dtype=float32)]
layer_b = tf.keras.layers.Dense(1,
kernel_initializer=tf.constant_initializer(2.))
b_out = layer_b(tf.convert_to_tensor([[10., 20., 30.]]))
layer_b.get_weights()
[array([[2.],
[2.],
[2.]], dtype=float32), array([0.], dtype=float32)]
layer_b.set_weights(layer_a.get_weights())
layer_b.get_weights()
[array([[1.],
[1.],
[1.]], dtype=float32), array([0.], dtype=float32)]
Args | |
---|---|
weights
|
a list of NumPy arrays. The number
of arrays and their shape must match
number of the dimensions of the weights
of the layer (i.e. it should match the
output of get_weights ).
|
Raises | |
---|---|
ValueError
|
If the provided weights list does not match the layer's specifications. |
setup_memory
setup_memory(
memory, memory_sequence_length=None, memory_mask=None
)
Pre-process the memory before actually query the memory.
This should only be called once at the first invocation of call()
.
Args | |
---|---|
memory
|
The memory to query; usually the output of an RNN encoder.
This tensor should be shaped [batch_size, max_time, ...] .
|
memory_sequence_length
|
optional
Sequence lengths for the batch entries in memory. If provided, the memory tensor rows are masked with zeros for values past the respective sequence lengths. |
memory_mask
|
(Optional) The boolean tensor with shape [batch_size,
max_time] . For any value equal to False, the corresponding value
in memory should be ignored.
|
with_name_scope
@classmethod
with_name_scope( method )
Decorator to automatically enter the module name scope.
class MyModule(tf.Module):
@tf.Module.with_name_scope
def __call__(self, x):
if not hasattr(self, 'w'):
self.w = tf.Variable(tf.random.normal([x.shape[1], 3]))
return tf.matmul(x, self.w)
Using the above module would produce tf.Variable
s and tf.Tensor
s whose
names included the module name:
mod = MyModule()
mod(tf.ones([1, 2]))
<tf.Tensor: shape=(1, 3), dtype=float32, numpy=..., dtype=float32)>
mod.w
<tf.Variable 'my_module/Variable:0' shape=(2, 3) dtype=float32,
numpy=..., dtype=float32)>
Args | |
---|---|
method
|
The method to wrap. |
Returns | |
---|---|
The original method wrapped such that it enters the module's name scope. |
__call__
__call__(
inputs, **kwargs
)
Preprocess the inputs before calling base_layer.__call__()
.
Note that there are situation here, one for setup memory, and one with actual query and state.
- When the memory has not been configured, we just pass all the param
to
base_layer.__call__()
, which will then invokeself.call()
with proper inputs, which allows this class to setup memory. - When the memory has already been setup, the input should contain
query and state, and optionally processed memory. If the processed
memory is not included in the input, we will have to append it to
the inputs and give it to the
base_layer.__call__()
. The processed memory is the output of first invocation ofself.__call__()
. If we don't add it here, then from keras perspective, the graph is disconnected since the output from previous call is never used.
Args | |
---|---|
inputs
|
the inputs tensors. |
**kwargs
|
dict, other keyeword arguments for the __call__()
|