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description: Additive attention layer, a.k.a. Bahdanau-style attention.
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View source on GitHub
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Additive attention layer, a.k.a. Bahdanau-style attention.
tf.keras.layers.AdditiveAttention(
use_scale=True, **kwargs
)
Inputs are query tensor of shape [batch_size, Tq, dim], value tensor of
shape [batch_size, Tv, dim] and key tensor of shape
[batch_size, Tv, dim]. The calculation follows the steps:
query and value into shapes [batch_size, Tq, 1, dim]
and [batch_size, 1, Tv, dim] respectively.[batch_size, Tq, Tv] as a non-linear
sum: scores = tf.reduce_sum(tf.tanh(query + value), axis=-1)[batch_size, Tq, Tv]: distribution = tf.nn.softmax(scores).distribution to create a linear combination of value with
shape batch_size, Tq, dim]:
return tf.matmul(distribution, value).Args | |
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use_scale
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If True, will create a variable to scale the attention scores.
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causal
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Boolean. Set to True for decoder self-attention. Adds a mask such
that position i cannot attend to positions j > i. This prevents the
flow of information from the future towards the past.
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dropout
|
Float between 0 and 1. Fraction of the units to drop for the attention scores. |
inputs: List of the following tensors:
Tensor of shape [batch_size, Tq, dim].Tensor of shape [batch_size, Tv, dim].Tensor of shape [batch_size, Tv, dim]. If not
given, will use value for both key and value, which is the
most common case.mask: List of the following tensors:
Tensor of shape [batch_size, Tq].
If given, the output will be zero at the positions where
mask==False.Tensor of shape [batch_size, Tv].
If given, will apply the mask such that values at positions where
mask==False do not contribute to the result.training: Python boolean indicating whether the layer should behave in
training mode (adding dropout) or in inference mode (no dropout).return_attention_scores: bool, it True, returns the attention scores
(after masking and softmax) as an additional output argument.Attention outputs of shape [batch_size, Tq, dim].
[Optional] Attention scores after masking and softmax with shape
[batch_size, Tq, Tv].
The meaning of query, value and key depend on the application. In the
case of text similarity, for example, query is the sequence embeddings of
the first piece of text and value is the sequence embeddings of the second
piece of text. key is usually the same tensor as value.
Here is a code example for using AdditiveAttention in a CNN+Attention
network:
# Variable-length int sequences.
query_input = tf.keras.Input(shape=(None,), dtype='int32')
value_input = tf.keras.Input(shape=(None,), dtype='int32')
# Embedding lookup.
token_embedding = tf.keras.layers.Embedding(max_tokens, dimension)
# Query embeddings of shape [batch_size, Tq, dimension].
query_embeddings = token_embedding(query_input)
# Value embeddings of shape [batch_size, Tv, dimension].
value_embeddings = token_embedding(value_input)
# CNN layer.
cnn_layer = tf.keras.layers.Conv1D(
filters=100,
kernel_size=4,
# Use 'same' padding so outputs have the same shape as inputs.
padding='same')
# Query encoding of shape [batch_size, Tq, filters].
query_seq_encoding = cnn_layer(query_embeddings)
# Value encoding of shape [batch_size, Tv, filters].
value_seq_encoding = cnn_layer(value_embeddings)
# Query-value attention of shape [batch_size, Tq, filters].
query_value_attention_seq = tf.keras.layers.AdditiveAttention()(
[query_seq_encoding, value_seq_encoding])
# Reduce over the sequence axis to produce encodings of shape
# [batch_size, filters].
query_encoding = tf.keras.layers.GlobalAveragePooling1D()(
query_seq_encoding)
query_value_attention = tf.keras.layers.GlobalAveragePooling1D()(
query_value_attention_seq)
# Concatenate query and document encodings to produce a DNN input layer.
input_layer = tf.keras.layers.Concatenate()(
[query_encoding, query_value_attention])
# Add DNN layers, and create Model.
# ...