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transformer.py
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# Copyright 2018 The TensorFlow Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ==============================================================================
"""Defines the Transformer model in TF 2.0.
Model paper: https://arxiv.org/pdf/1706.03762.pdf
Transformer model code source: https://github.com/tensorflow/tensor2tensor
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import tensorflow as tf
from official.nlp.modeling.layers import position_embedding
from official.nlp.transformer import attention_layer
from official.nlp.transformer import beam_search
from official.nlp.transformer import embedding_layer
from official.nlp.transformer import ffn_layer
from official.nlp.transformer import metrics
from official.nlp.transformer import model_utils
from official.nlp.transformer.utils.tokenizer import EOS_ID
# Disable the not-callable lint error, since it claims many objects are not
# callable when they actually are.
# pylint: disable=not-callable
def create_model(params, is_train):
"""Creates transformer model."""
with tf.name_scope("model"):
if is_train:
inputs = tf.keras.layers.Input((None,), dtype="int64", name="inputs")
targets = tf.keras.layers.Input((None,), dtype="int64", name="targets")
internal_model = Transformer(params, name="transformer_v2")
logits = internal_model([inputs, targets], training=is_train)
vocab_size = params["vocab_size"]
label_smoothing = params["label_smoothing"]
if params["enable_metrics_in_training"]:
logits = metrics.MetricLayer(vocab_size)([logits, targets])
logits = tf.keras.layers.Lambda(lambda x: x, name="logits",
dtype=tf.float32)(logits)
model = tf.keras.Model([inputs, targets], logits)
# TODO(reedwm): Can we do this loss in float16 instead of float32?
loss = metrics.transformer_loss(
logits, targets, label_smoothing, vocab_size)
model.add_loss(loss)
return model
else:
inputs = tf.keras.layers.Input((None,), dtype="int64", name="inputs")
internal_model = Transformer(params, name="transformer_v2")
ret = internal_model([inputs], training=is_train)
outputs, scores = ret["outputs"], ret["scores"]
return tf.keras.Model(inputs, [outputs, scores])
class Transformer(tf.keras.Model):
"""Transformer model with Keras.
Implemented as described in: https://arxiv.org/pdf/1706.03762.pdf
The Transformer model consists of an encoder and decoder. The input is an int
sequence (or a batch of sequences). The encoder produces a continuous
representation, and the decoder uses the encoder output to generate
probabilities for the output sequence.
"""
def __init__(self, params, name=None):
"""Initialize layers to build Transformer model.
Args:
params: hyperparameter object defining layer sizes, dropout values, etc.
name: name of the model.
"""
super(Transformer, self).__init__(name=name)
self.params = params
self.embedding_softmax_layer = embedding_layer.EmbeddingSharedWeights(
params["vocab_size"], params["hidden_size"])
self.encoder_stack = EncoderStack(params)
self.decoder_stack = DecoderStack(params)
self.position_embedding = position_embedding.RelativePositionEmbedding(
hidden_size=self.params["hidden_size"])
def get_config(self):
return {
"params": self.params,
}
def call(self, inputs, training):
"""Calculate target logits or inferred target sequences.
Args:
inputs: input tensor list of size 1 or 2.
First item, inputs: int tensor with shape [batch_size, input_length].
Second item (optional), targets: None or int tensor with shape
[batch_size, target_length].
training: boolean, whether in training mode or not.
Returns:
If targets is defined, then return logits for each word in the target
sequence. float tensor with shape [batch_size, target_length, vocab_size]
If target is none, then generate output sequence one token at a time.
returns a dictionary {
outputs: [batch_size, decoded length]
scores: [batch_size, float]}
Even when float16 is used, the output tensor(s) are always float32.
Raises:
NotImplementedError: If try to use padded decode method on CPU/GPUs.
"""
if len(inputs) == 2:
inputs, targets = inputs[0], inputs[1]
else:
# Decoding path.
inputs, targets = inputs[0], None
if self.params["padded_decode"]:
if not self.params["num_replicas"]:
raise NotImplementedError(
"Padded decoding on CPU/GPUs is not supported.")
decode_batch_size = int(self.params["decode_batch_size"] /
self.params["num_replicas"])
inputs.set_shape([
decode_batch_size, self.params["decode_max_length"]
])
# Variance scaling is used here because it seems to work in many problems.
# Other reasonable initializers may also work just as well.
with tf.name_scope("Transformer"):
# Calculate attention bias for encoder self-attention and decoder
# multi-headed attention layers.
attention_bias = model_utils.get_padding_bias(inputs)
# Run the inputs through the encoder layer to map the symbol
# representations to continuous representations.
encoder_outputs = self.encode(inputs, attention_bias, training)
# Generate output sequence if targets is None, or return logits if target
# sequence is known.
if targets is None:
return self.predict(encoder_outputs, attention_bias, training)
else:
logits = self.decode(targets, encoder_outputs, attention_bias, training)
return logits
def encode(self, inputs, attention_bias, training):
"""Generate continuous representation for inputs.
Args:
inputs: int tensor with shape [batch_size, input_length].
attention_bias: float tensor with shape [batch_size, 1, 1, input_length].
training: boolean, whether in training mode or not.
Returns:
float tensor with shape [batch_size, input_length, hidden_size]
"""
with tf.name_scope("encode"):
# Prepare inputs to the layer stack by adding positional encodings and
# applying dropout.
embedded_inputs = self.embedding_softmax_layer(inputs)
embedded_inputs = tf.cast(embedded_inputs, self.params["dtype"])
inputs_padding = model_utils.get_padding(inputs)
attention_bias = tf.cast(attention_bias, self.params["dtype"])
with tf.name_scope("add_pos_encoding"):
pos_encoding = self.position_embedding(inputs=embedded_inputs)
pos_encoding = tf.cast(pos_encoding, self.params["dtype"])
encoder_inputs = embedded_inputs + pos_encoding
if training:
encoder_inputs = tf.nn.dropout(
encoder_inputs, rate=self.params["layer_postprocess_dropout"])
return self.encoder_stack(
encoder_inputs, attention_bias, inputs_padding, training=training)
def decode(self, targets, encoder_outputs, attention_bias, training):
"""Generate logits for each value in the target sequence.
Args:
targets: target values for the output sequence. int tensor with shape
[batch_size, target_length]
encoder_outputs: continuous representation of input sequence. float tensor
with shape [batch_size, input_length, hidden_size]
attention_bias: float tensor with shape [batch_size, 1, 1, input_length]
training: boolean, whether in training mode or not.
Returns:
float32 tensor with shape [batch_size, target_length, vocab_size]
"""
with tf.name_scope("decode"):
# Prepare inputs to decoder layers by shifting targets, adding positional
# encoding and applying dropout.
decoder_inputs = self.embedding_softmax_layer(targets)
decoder_inputs = tf.cast(decoder_inputs, self.params["dtype"])
attention_bias = tf.cast(attention_bias, self.params["dtype"])
with tf.name_scope("shift_targets"):
# Shift targets to the right, and remove the last element
decoder_inputs = tf.pad(decoder_inputs,
[[0, 0], [1, 0], [0, 0]])[:, :-1, :]
with tf.name_scope("add_pos_encoding"):
length = tf.shape(decoder_inputs)[1]
pos_encoding = self.position_embedding(decoder_inputs)
pos_encoding = tf.cast(pos_encoding, self.params["dtype"])
decoder_inputs += pos_encoding
if training:
decoder_inputs = tf.nn.dropout(
decoder_inputs, rate=self.params["layer_postprocess_dropout"])
# Run values
decoder_self_attention_bias = model_utils.get_decoder_self_attention_bias(
length, dtype=self.params["dtype"])
outputs = self.decoder_stack(
decoder_inputs,
encoder_outputs,
decoder_self_attention_bias,
attention_bias,
training=training)
logits = self.embedding_softmax_layer(outputs, mode="linear")
logits = tf.cast(logits, tf.float32)
return logits
def _get_symbols_to_logits_fn(self, max_decode_length, training):
"""Returns a decoding function that calculates logits of the next tokens."""
timing_signal = self.position_embedding(
inputs=None, length=max_decode_length + 1)
timing_signal = tf.cast(timing_signal, self.params["dtype"])
decoder_self_attention_bias = model_utils.get_decoder_self_attention_bias(
max_decode_length, dtype=self.params["dtype"])
# TODO(b/139770046): Refactor code with better naming of i.
def symbols_to_logits_fn(ids, i, cache):
"""Generate logits for next potential IDs.
Args:
ids: Current decoded sequences. int tensor with shape [batch_size *
beam_size, i + 1].
i: Loop index.
cache: dictionary of values storing the encoder output, encoder-decoder
attention bias, and previous decoder attention values.
Returns:
Tuple of
(logits with shape [batch_size * beam_size, vocab_size],
updated cache values)
"""
# Set decoder input to the last generated IDs
decoder_input = ids[:, -1:]
# Preprocess decoder input by getting embeddings and adding timing signal.
decoder_input = self.embedding_softmax_layer(decoder_input)
if self.params["padded_decode"]:
timing_signal_shape = timing_signal.shape.as_list()
decoder_input += tf.slice(timing_signal, [i, 0],
[1, timing_signal_shape[1]])
bias_shape = decoder_self_attention_bias.shape.as_list()
self_attention_bias = tf.slice(
decoder_self_attention_bias, [0, 0, i, 0],
[bias_shape[0], bias_shape[1], 1, bias_shape[3]])
else:
decoder_input += timing_signal[i:i + 1]
self_attention_bias = decoder_self_attention_bias[:, :, i:i + 1, :i + 1]
decoder_outputs = self.decoder_stack(
decoder_input,
cache.get("encoder_outputs"),
self_attention_bias,
cache.get("encoder_decoder_attention_bias"),
training=training,
cache=cache,
decode_loop_step=i if self.params["padded_decode"] else None)
logits = self.embedding_softmax_layer(decoder_outputs, mode="linear")
logits = tf.squeeze(logits, axis=[1])
return logits, cache
return symbols_to_logits_fn
def predict(self, encoder_outputs, encoder_decoder_attention_bias, training):
"""Return predicted sequence."""
encoder_outputs = tf.cast(encoder_outputs, self.params["dtype"])
if self.params["padded_decode"]:
batch_size = encoder_outputs.shape.as_list()[0]
input_length = encoder_outputs.shape.as_list()[1]
else:
batch_size = tf.shape(encoder_outputs)[0]
input_length = tf.shape(encoder_outputs)[1]
max_decode_length = input_length + self.params["extra_decode_length"]
encoder_decoder_attention_bias = tf.cast(encoder_decoder_attention_bias,
self.params["dtype"])
symbols_to_logits_fn = self._get_symbols_to_logits_fn(
max_decode_length, training)
# Create initial set of IDs that will be passed into symbols_to_logits_fn.
initial_ids = tf.zeros([batch_size], dtype=tf.int32)
# Create cache storing decoder attention values for each layer.
# pylint: disable=g-complex-comprehension
init_decode_length = (
max_decode_length if self.params["padded_decode"] else 0)
num_heads = self.params["num_heads"]
dim_per_head = self.params["hidden_size"] // num_heads
cache = {
"layer_%d" % layer: {
"k":
tf.zeros([
batch_size, init_decode_length, num_heads, dim_per_head
],
dtype=self.params["dtype"]),
"v":
tf.zeros([
batch_size, init_decode_length, num_heads, dim_per_head
],
dtype=self.params["dtype"])
} for layer in range(self.params["num_hidden_layers"])
}
# pylint: enable=g-complex-comprehension
# Add encoder output and attention bias to the cache.
cache["encoder_outputs"] = encoder_outputs
cache["encoder_decoder_attention_bias"] = encoder_decoder_attention_bias
# Use beam search to find the top beam_size sequences and scores.
decoded_ids, scores = beam_search.sequence_beam_search(
symbols_to_logits_fn=symbols_to_logits_fn,
initial_ids=initial_ids,
initial_cache=cache,
vocab_size=self.params["vocab_size"],
beam_size=self.params["beam_size"],
alpha=self.params["alpha"],
max_decode_length=max_decode_length,
eos_id=EOS_ID,
padded_decode=self.params["padded_decode"],
dtype=self.params["dtype"])
# Get the top sequence for each batch element
top_decoded_ids = decoded_ids[:, 0, 1:]
top_scores = scores[:, 0]
return {"outputs": top_decoded_ids, "scores": top_scores}
class PrePostProcessingWrapper(tf.keras.layers.Layer):
"""Wrapper class that applies layer pre-processing and post-processing."""
def __init__(self, layer, params):
super(PrePostProcessingWrapper, self).__init__()
self.layer = layer
self.params = params
self.postprocess_dropout = params["layer_postprocess_dropout"]
def build(self, input_shape):
# Create normalization layer
self.layer_norm = tf.keras.layers.LayerNormalization(
epsilon=1e-6, dtype="float32")
super(PrePostProcessingWrapper, self).build(input_shape)
def get_config(self):
return {
"params": self.params,
}
def call(self, x, *args, **kwargs):
"""Calls wrapped layer with same parameters."""
# Preprocessing: apply layer normalization
training = kwargs["training"]
y = self.layer_norm(x)
# Get layer output
y = self.layer(y, *args, **kwargs)
# Postprocessing: apply dropout and residual connection
if training:
y = tf.nn.dropout(y, rate=self.postprocess_dropout)
return x + y
class EncoderStack(tf.keras.layers.Layer):
"""Transformer encoder stack.
The encoder stack is made up of N identical layers. Each layer is composed
of the sublayers:
1. Self-attention layer
2. Feedforward network (which is 2 fully-connected layers)
"""
def __init__(self, params):
super(EncoderStack, self).__init__()
self.params = params
self.layers = []
def build(self, input_shape):
"""Builds the encoder stack."""
params = self.params
for _ in range(params["num_hidden_layers"]):
# Create sublayers for each layer.
self_attention_layer = attention_layer.SelfAttention(
params["hidden_size"], params["num_heads"],
params["attention_dropout"])
feed_forward_network = ffn_layer.FeedForwardNetwork(
params["hidden_size"], params["filter_size"], params["relu_dropout"])
self.layers.append([
PrePostProcessingWrapper(self_attention_layer, params),
PrePostProcessingWrapper(feed_forward_network, params)
])
# Create final layer normalization layer.
self.output_normalization = tf.keras.layers.LayerNormalization(
epsilon=1e-6, dtype="float32")
super(EncoderStack, self).build(input_shape)
def get_config(self):
return {
"params": self.params,
}
def call(self, encoder_inputs, attention_bias, inputs_padding, training):
"""Return the output of the encoder layer stacks.
Args:
encoder_inputs: tensor with shape [batch_size, input_length, hidden_size]
attention_bias: bias for the encoder self-attention layer. [batch_size, 1,
1, input_length]
inputs_padding: tensor with shape [batch_size, input_length], inputs with
zero paddings.
training: boolean, whether in training mode or not.
Returns:
Output of encoder layer stack.
float32 tensor with shape [batch_size, input_length, hidden_size]
"""
for n, layer in enumerate(self.layers):
# Run inputs through the sublayers.
self_attention_layer = layer[0]
feed_forward_network = layer[1]
with tf.name_scope("layer_%d" % n):
with tf.name_scope("self_attention"):
encoder_inputs = self_attention_layer(
encoder_inputs, attention_bias, training=training)
with tf.name_scope("ffn"):
encoder_inputs = feed_forward_network(
encoder_inputs, training=training)
return self.output_normalization(encoder_inputs)
class DecoderStack(tf.keras.layers.Layer):
"""Transformer decoder stack.
Like the encoder stack, the decoder stack is made up of N identical layers.
Each layer is composed of the sublayers:
1. Self-attention layer
2. Multi-headed attention layer combining encoder outputs with results from
the previous self-attention layer.
3. Feedforward network (2 fully-connected layers)
"""
def __init__(self, params):
super(DecoderStack, self).__init__()
self.params = params
self.layers = []
def build(self, input_shape):
"""Builds the decoder stack."""
params = self.params
for _ in range(params["num_hidden_layers"]):
self_attention_layer = attention_layer.SelfAttention(
params["hidden_size"], params["num_heads"],
params["attention_dropout"])
enc_dec_attention_layer = attention_layer.Attention(
params["hidden_size"], params["num_heads"],
params["attention_dropout"])
feed_forward_network = ffn_layer.FeedForwardNetwork(
params["hidden_size"], params["filter_size"], params["relu_dropout"])
self.layers.append([
PrePostProcessingWrapper(self_attention_layer, params),
PrePostProcessingWrapper(enc_dec_attention_layer, params),
PrePostProcessingWrapper(feed_forward_network, params)
])
self.output_normalization = tf.keras.layers.LayerNormalization(
epsilon=1e-6, dtype="float32")
super(DecoderStack, self).build(input_shape)
def get_config(self):
return {
"params": self.params,
}
def call(self,
decoder_inputs,
encoder_outputs,
decoder_self_attention_bias,
attention_bias,
training,
cache=None,
decode_loop_step=None):
"""Return the output of the decoder layer stacks.
Args:
decoder_inputs: A tensor with shape
[batch_size, target_length, hidden_size].
encoder_outputs: A tensor with shape
[batch_size, input_length, hidden_size]
decoder_self_attention_bias: A tensor with shape
[1, 1, target_len, target_length], the bias for decoder self-attention
layer.
attention_bias: A tensor with shape [batch_size, 1, 1, input_length],
the bias for encoder-decoder attention layer.
training: A bool, whether in training mode or not.
cache: (Used for fast decoding) A nested dictionary storing previous
decoder self-attention values. The items are:
{layer_n: {"k": A tensor with shape [batch_size, i, key_channels],
"v": A tensor with shape [batch_size, i, value_channels]},
...}
decode_loop_step: An integer, the step number of the decoding loop. Used
only for autoregressive inference on TPU.
Returns:
Output of decoder layer stack.
float32 tensor with shape [batch_size, target_length, hidden_size]
"""
for n, layer in enumerate(self.layers):
self_attention_layer = layer[0]
enc_dec_attention_layer = layer[1]
feed_forward_network = layer[2]
# Run inputs through the sublayers.
layer_name = "layer_%d" % n
layer_cache = cache[layer_name] if cache is not None else None
with tf.name_scope(layer_name):
with tf.name_scope("self_attention"):
decoder_inputs = self_attention_layer(
decoder_inputs,
decoder_self_attention_bias,
training=training,
cache=layer_cache,
decode_loop_step=decode_loop_step)
with tf.name_scope("encdec_attention"):
decoder_inputs = enc_dec_attention_layer(
decoder_inputs,
encoder_outputs,
attention_bias,
training=training)
with tf.name_scope("ffn"):
decoder_inputs = feed_forward_network(
decoder_inputs, training=training)
return self.output_normalization(decoder_inputs)