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seq2seq_lib.py
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seq2seq_lib.py
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# Copyright 2016 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.
# ==============================================================================
"""seq2seq library codes copied from elsewhere for customization."""
import tensorflow as tf
# Adapted to support sampled_softmax loss function, which accepts activations
# instead of logits.
def sequence_loss_by_example(inputs, targets, weights, loss_function,
average_across_timesteps=True, name=None):
"""Sampled softmax loss for a sequence of inputs (per example).
Args:
inputs: List of 2D Tensors of shape [batch_size x hid_dim].
targets: List of 1D batch-sized int32 Tensors of the same length as logits.
weights: List of 1D batch-sized float-Tensors of the same length as logits.
loss_function: Sampled softmax function (inputs, labels) -> loss
average_across_timesteps: If set, divide the returned cost by the total
label weight.
name: Optional name for this operation, default: 'sequence_loss_by_example'.
Returns:
1D batch-sized float Tensor: The log-perplexity for each sequence.
Raises:
ValueError: If len(inputs) is different from len(targets) or len(weights).
"""
if len(targets) != len(inputs) or len(weights) != len(inputs):
raise ValueError('Lengths of logits, weights, and targets must be the same '
'%d, %d, %d.' % (len(inputs), len(weights), len(targets)))
with tf.name_scope(values=inputs + targets + weights, name=name,
default_name='sequence_loss_by_example'):
log_perp_list = []
for inp, target, weight in zip(inputs, targets, weights):
crossent = loss_function(inp, target)
log_perp_list.append(crossent * weight)
log_perps = tf.add_n(log_perp_list)
if average_across_timesteps:
total_size = tf.add_n(weights)
total_size += 1e-12 # Just to avoid division by 0 for all-0 weights.
log_perps /= total_size
return log_perps
def sampled_sequence_loss(inputs, targets, weights, loss_function,
average_across_timesteps=True,
average_across_batch=True, name=None):
"""Weighted cross-entropy loss for a sequence of logits, batch-collapsed.
Args:
inputs: List of 2D Tensors of shape [batch_size x hid_dim].
targets: List of 1D batch-sized int32 Tensors of the same length as inputs.
weights: List of 1D batch-sized float-Tensors of the same length as inputs.
loss_function: Sampled softmax function (inputs, labels) -> loss
average_across_timesteps: If set, divide the returned cost by the total
label weight.
average_across_batch: If set, divide the returned cost by the batch size.
name: Optional name for this operation, defaults to 'sequence_loss'.
Returns:
A scalar float Tensor: The average log-perplexity per symbol (weighted).
Raises:
ValueError: If len(inputs) is different from len(targets) or len(weights).
"""
with tf.name_scope(values=inputs + targets + weights, name=name,
default_name='sampled_sequence_loss'):
cost = tf.reduce_sum(sequence_loss_by_example(
inputs, targets, weights, loss_function,
average_across_timesteps=average_across_timesteps))
if average_across_batch:
batch_size = tf.shape(targets[0])[0]
return cost / tf.cast(batch_size, tf.float32)
else:
return cost
def linear(args, output_size, bias, bias_start=0.0, scope=None):
"""Linear map: sum_i(args[i] * W[i]), where W[i] is a variable.
Args:
args: a 2D Tensor or a list of 2D, batch x n, Tensors.
output_size: int, second dimension of W[i].
bias: boolean, whether to add a bias term or not.
bias_start: starting value to initialize the bias; 0 by default.
scope: VariableScope for the created subgraph; defaults to "Linear".
Returns:
A 2D Tensor with shape [batch x output_size] equal to
sum_i(args[i] * W[i]), where W[i]s are newly created matrices.
Raises:
ValueError: if some of the arguments has unspecified or wrong shape.
"""
if args is None or (isinstance(args, (list, tuple)) and not args):
raise ValueError('`args` must be specified')
if not isinstance(args, (list, tuple)):
args = [args]
# Calculate the total size of arguments on dimension 1.
total_arg_size = 0
shapes = [a.get_shape().as_list() for a in args]
for shape in shapes:
if len(shape) != 2:
raise ValueError('Linear is expecting 2D arguments: %s' % str(shapes))
if not shape[1]:
raise ValueError('Linear expects shape[1] of arguments: %s' % str(shapes))
else:
total_arg_size += shape[1]
# Now the computation.
with tf.variable_scope(scope or 'Linear'):
matrix = tf.get_variable('Matrix', [total_arg_size, output_size])
if len(args) == 1:
res = tf.matmul(args[0], matrix)
else:
res = tf.matmul(tf.concat(axis=1, values=args), matrix)
if not bias:
return res
bias_term = tf.get_variable(
'Bias', [output_size],
initializer=tf.constant_initializer(bias_start))
return res + bias_term