def setup_network(self):
# Setup character embedding
embedded_encoder_input, embedded_decoder_input, embed_func = self.setup_character_embedding(
)
# Output projection
with tf.variable_scope('alphabet_projection') as scope:
self.projection_W, self.projection_b = intialize_projections(
input_size=4 *
self.config.num_units, # Because we use bidirectional encoder
output_size=self.config.alphabet_size,
scope=scope)
# Encoder
with tf.variable_scope('encoder') as scope:
# Normalize batch
embedded_encoder_input = tf.layers.batch_normalization(
inputs=embedded_encoder_input,
center=True,
scale=True,
training=not self.prediction_mode,
trainable=True,
)
enc_outputs, enc_final_state = self.encoder.encode(
inputs=embedded_encoder_input,
seq_lengths=self.encoder_sequence_length,
scope=scope)
# Predict question categories
with tf.variable_scope('question') as scope:
# Convert StateTuple to vector
state_vector = tf.concat(flatten(enc_final_state),
axis=1,
name='combined-state-vec')
# Add dense layer
layer = projection(x=state_vector,
input_size=4 * self.config.num_units *
self.config.num_cells,
output_size=128,
nonlinearity=tf.nn.relu)
if self.add_dropout:
layer = tf.nn.dropout(x=layer, keep_prob=self.keep_prob_ph)
class_logits = projection(x=layer,
input_size=128,
output_size=self.config.num_classes)
W_penalty = 0.0
# Define loss
self.setup_losses(class_logits=class_logits,
class_idx=self.class_idx,
W_penalty=W_penalty)
def setup_network(self):
# Setup character embedding
embedded_encoder_input, embedded_decoder_input, embed_func = self.setup_character_embedding(
)
# Output projection
with tf.variable_scope('alphabet_projection') as scope:
self.projection_W, self.projection_b = intialize_projections(
input_size=4 * self.config.
num_units, # We use bidirectional encoder + attention
output_size=self.config.alphabet_size,
scope=scope)
# Define alphabet projection function
def project_func(output):
return projection(output,
W=self.projection_W,
b=self.projection_b)
# Encoder
with tf.variable_scope('encoder') as scope:
enc_outputs, enc_final_state = self.encoder.encode(
inputs=embedded_encoder_input,
seq_lengths=self.encoder_sequence_length,
# enc_word_indices=self.enc_word_indices,
# word_seq_lengths=self.word_seq_lengths,
# max_words=self.config.max_words,
scope=scope)
# Set decoder initial state and encoder outputs based on the binary
# mode input value
# - If `self.is_lm_mode=0` Use the passed initial state from encoder
# - If `self.is_lm_mode=1` Use the zero vector
self.enc_outputs, self.enc_final_state = select_decoder_inputs(
is_lm_mode=self.is_lm_mode,
enc_outputs=enc_outputs,
initial_state=enc_final_state,
)
# Pack state to tensor
self.enc_final_state_tensor = pack_state_tuple(self.enc_final_state)
# Initialize decoder attention function using encoder outputs
self.decoder.initialize_attention_func(
input_size=embedded_decoder_input.get_shape().as_list()[-1],
attention_states=self.enc_outputs)
# Define initial attention tensor
self.initial_attention = self.decoder.attention_func(
self.enc_final_state)
# Define decoder
with tf.variable_scope('decoder'):
dec_outputs, dec_final_state = self.decoder.decode(
inputs=embedded_decoder_input,
initial_state=self.enc_final_state,
seq_length=self.decoder_sequence_length,
embed_func=embed_func,
project_func=project_func,
)
# Project output to alphabet size and reshape
dec_outputs = tf.reshape(dec_outputs,
[-1, 4 * self.config.num_units])
dec_outputs = projection(dec_outputs,
W=self.projection_W,
b=self.projection_b)
dec_outputs = tf.reshape(dec_outputs, [
-1, self.config.max_dec_seq_length + 1,
self.config.alphabet_size
])
if self.prediction_mode:
dec_outputs = self.decoder_logits
# Define loss
self.setup_losses(dec_outputs=dec_outputs,
target_chars=self.target_chars,
decoder_sequence_length=self.decoder_sequence_length)
if self.prediction_mode:
# Look up inputs
decoder_inputs_embedded = tf.nn.embedding_lookup(
self.embedding_matrix,
self.decoder_inputs,
name='decoder_input')
is_lm_mode_tensor = tf.to_float(
tf.expand_dims(self.is_lm_mode, axis=1))
decoder_inputs = tf.concat(
[decoder_inputs_embedded, is_lm_mode_tensor], axis=1)
# Unpack state
initial_state = unpack_state_tensor(self.decoder_state)
with tf.variable_scope('decoder', reuse=True):
decoder_output, decoder_final_state, self.decoder_new_attention = self.decoder.predict(
inputs=decoder_inputs,
initial_state=initial_state,
attention_states=self.decoder_attention)
# Project output to alphabet size
self.decoder_output = projection(decoder_output,
W=self.projection_W,
b=self.projection_b,
name='decoder_output')
# Compute decayed logits
self.decoder_probs_decayed = compute_decayed_probs(
logits=self.decoder_output,
decay_parameter_ph=self.probs_decay_parameter)
# Pack state to tensor
self.decoder_final_state = pack_state_tuple(
decoder_final_state, name='decoder_final_state')
def setup_network(self):
# Setup character embedding
embedded_encoder_input, embedded_decoder_input, embed_func = self.setup_character_embedding(
)
# Output projection
with tf.variable_scope('alphabet_projection') as scope:
self.projection_W, self.projection_b = intialize_projections(
input_size=4 *
self.config.num_units, # Because we use bidirectional encoder
output_size=self.config.alphabet_size,
scope=scope)
# Encoder
with tf.variable_scope('encoder') as scope:
# Normalize batch
# TODO: What axis should it be?
embedded_encoder_input = tf.layers.batch_normalization(
inputs=embedded_encoder_input,
center=True,
scale=True,
training=not self.prediction_mode,
trainable=True,
)
enc_outputs, enc_final_state = self.encoder.encode(
inputs=embedded_encoder_input,
seq_lengths=self.encoder_sequence_length,
enc_word_indices=self.enc_word_indices,
word_seq_lengths=self.word_seq_lengths,
max_words=self.config.max_words,
scope=scope)
# Predict question categories
with tf.variable_scope('question') as scope:
# Convert StateTuple to vector
state_vector = tf.concat(flatten(enc_final_state),
axis=1,
name='combined-state-vec')
# Add dense layer
W, b = intialize_projections(input_size=4 * self.config.num_units *
self.config.num_cells,
output_size=128)
layer = tf.nn.relu(tf.matmul(state_vector, W) + b)
if self.add_dropout:
layer = tf.nn.dropout(x=layer, keep_prob=self.keep_prob_ph)
# Compute L2-weight decay
W_penalty = tf.contrib.layers.apply_regularization(
regularizer=tf.contrib.layers.l2_regularizer(
scale=self.config.W_lambda),
weights_list=[W])
class_logits = projection(x=layer,
input_size=128,
output_size=self.config.num_classes)
# Define loss
self.setup_losses(class_logits=class_logits,
class_idx=self.class_idx,
W_penalty=W_penalty)
def setup_network(self):
# Setup character embedding (defines `self.embedding_matrix`)
with tf.device('/cpu:0'), tf.variable_scope(name_or_scope='embedding'):
self.embedding_matrix = tf.get_variable(
shape=[self.config.alphabet_size, self.config.embedding_size],
initializer=tf.contrib.layers.xavier_initializer(),
name='W')
# Gather slices from `params` according to `indices`
embedded_decoder_input = tf.nn.embedding_lookup(
self.embedding_matrix,
self.decoder_input_chars,
name='dec_input')
def embed_func(input_chars):
return tf.gather(self.embedding_matrix, input_chars)
# Output projection
with tf.variable_scope('alphabet_projection') as scope:
self.projection_W, self.projection_b = intialize_projections(
input_size=self.config.num_units,
output_size=self.config.alphabet_size,
scope=scope)
# Define alphabet projection function
def project_func(output):
return projection(output,
W=self.projection_W,
b=self.projection_b)
# Define initial state as zero states
self.enc_final_state = self.decoder.cell.zero_state(
batch_size=tf.shape(embedded_decoder_input)[0], dtype=tf.float32)
# Define decoder
with tf.variable_scope('decoder'):
dec_outputs, dec_final_state = self.decoder.decode(
inputs=embedded_decoder_input,
initial_state=self.enc_final_state,
seq_length=self.decoder_sequence_length,
embed_func=embed_func,
project_func=project_func)
# Project output to alphabet size and reshape
dec_outputs = tf.reshape(dec_outputs, [-1, self.config.num_units])
dec_outputs = projection(dec_outputs,
W=self.projection_W,
b=self.projection_b)
dec_outputs = tf.reshape(dec_outputs, [
-1, self.config.max_dec_seq_length + 1,
self.config.alphabet_size
])
# self.packed_dec_final_state = pack_state_tuple(dec_final_state)
if self.prediction_mode:
dec_outputs = self.decoder_logits
# Define loss
self.setup_losses(dec_outputs=dec_outputs,
target_chars=self.target_chars,
decoder_sequence_length=self.decoder_sequence_length)
if self.prediction_mode:
# Pack state to tensor
self.enc_final_state_tensor = pack_state_tuple(
self.enc_final_state)
# Look up inputs
decoder_inputs_embedded = tf.nn.embedding_lookup(
self.embedding_matrix,
self.decoder_inputs,
name='decoder_input')
# Unpack state
initial_state = unpack_state_tensor(self.decoder_state)
with tf.variable_scope('decoder', reuse=True):
decoder_output, decoder_final_state = self.decoder.predict(
inputs=decoder_inputs_embedded,
initial_state=initial_state)
# Project output to alphabet size
self.decoder_output = projection(decoder_output,
W=self.projection_W,
b=self.projection_b,
name='decoder_output')
self.decoder_probs = tf.nn.softmax(self.decoder_output,
name='decoder_probs')
self.probs_decay_parameter = tf.placeholder(
tf.float64, shape=(), name='probs_decay_parameter')
self.decoder_probs_decayed = tf.pow(
tf.cast(self.decoder_probs, tf.float64),
self.probs_decay_parameter)
decoder_probs_sum = tf.expand_dims(tf.reduce_sum(
self.decoder_probs_decayed, axis=1),
axis=1)
decoder_probs_sum = tf.tile(decoder_probs_sum,
[1, self.config.alphabet_size])
self.decoder_probs_decayed = self.decoder_probs_decayed / decoder_probs_sum
# Pack state to tensor
self.decoder_final_state = pack_state_tuple(
decoder_final_state, name='decoder_final_state')
def setup_network(self):
# Setup character embedding
embedded_encoder_input, embedded_decoder_input, embed_func = self.setup_character_embedding(
)
# Output projection
with tf.variable_scope('alphabet_projection') as scope:
self.projection_W, self.projection_b = intialize_projections(
input_size=4 * self.config.num_units,
output_size=self.config.alphabet_size,
scope=scope)
# Define alphabet projection function
def project_func(output):
return projection(output,
W=self.projection_W,
b=self.projection_b)
# Encoder
with tf.variable_scope('encoder') as scope:
# Normalize batch
embedded_encoder_input = tf.layers.batch_normalization(
inputs=embedded_encoder_input,
center=True,
scale=True,
# training=not self.prediction_mode,
training=
True, # I think this should be true always, because in training
# and inference we have the entire question text.
trainable=True,
)
enc_outputs, enc_final_state = self.encoder.encode(
inputs=embedded_encoder_input,
seq_lengths=self.encoder_sequence_length,
enc_word_indices=self.enc_word_indices,
word_seq_lengths=self.word_seq_lengths,
max_words=self.config.max_words,
scope=scope)
# Predict question categories
with tf.variable_scope('question') as scope:
# Convert StateTuple to vector
state_vector = tf.concat(flatten(enc_final_state),
axis=1,
name='combined-state-vec')
# Add dense layer
W, b = intialize_projections(input_size=4 * self.config.num_units *
self.config.num_cells,
output_size=128)
layer = tf.nn.relu(tf.matmul(state_vector, W) + b)
if self.add_dropout:
layer = tf.nn.dropout(x=layer, keep_prob=self.keep_prob_ph)
# Compute L2-weight decay
W_penalty = tf.contrib.layers.apply_regularization(
regularizer=tf.contrib.layers.l2_regularizer(
scale=self.config.W_lambda),
weights_list=[W])
class_logits = projection(x=layer,
input_size=128,
output_size=self.config.num_classes)
# Set decoder initial state and encoder outputs based on the binary
# mode input value
# - If `self.is_lm_mode=0` Use the passed initial state from encoder
# - If `self.is_lm_mode=1` Use the zero vector
self.enc_outputs, enc_final_state = select_decoder_inputs(
is_lm_mode=self.is_lm_mode,
enc_outputs=enc_outputs,
initial_state=enc_final_state,
)
# If an observation has a class -> Pass the true class as 1-hot-encoded
# vector to the decoder input.
# If an observation doesn't have a class -> Pass the class logits for
# the given observation to the decoder input.
class_is_known = tf.greater_equal(self.class_idx, 0)
# Create one-hot-encoded vectors
class_one_hot = tf.one_hot(indices=self.class_idx,
depth=self.config.num_classes,
on_value=1.0,
off_value=0.0,
axis=-1,
dtype=tf.float32,
name='class-one-hot-encoded')
# Compute class probabilities
class_probs = tf.nn.softmax(class_logits)
# Select what to pass on
self.class_info_vec = tf.where(condition=class_is_known,
x=class_one_hot,
y=class_probs)
# Concatenate class info vector with decoder input
_class_info_vec = tf.expand_dims(self.class_info_vec, axis=1)
_class_info_vec = tf.tile(
_class_info_vec,
multiples=[1, self.config.max_dec_seq_length + 1, 1])
decoder_input = tf.concat([embedded_decoder_input, _class_info_vec],
axis=2)
# Pack state to tensor
self.enc_final_state_tensor = pack_state_tuple(enc_final_state)
# Initialize decoder attention function using encoder outputs
self.decoder.initialize_attention_func(
input_size=decoder_input.get_shape().as_list()[-1],
attention_states=self.enc_outputs)
# Define decoder
with tf.variable_scope('decoder'):
dec_outputs, dec_final_state = self.decoder.decode(
inputs=decoder_input,
initial_state=enc_final_state,
seq_length=self.decoder_sequence_length,
embed_func=embed_func,
project_func=project_func)
# Project output to alphabet size and reshape
dec_outputs = tf.reshape(dec_outputs,
[-1, 4 * self.config.num_units])
dec_outputs = projection(dec_outputs,
W=self.projection_W,
b=self.projection_b)
dec_outputs = tf.reshape(dec_outputs, [
-1, self.config.max_dec_seq_length + 1,
self.config.alphabet_size
])
if self.prediction_mode:
dec_outputs = self.decoder_logits
# Define loss
self.setup_losses(dec_outputs=dec_outputs,
target_chars=self.target_chars,
decoder_sequence_length=self.decoder_sequence_length,
class_probs=class_probs,
class_idx=self.class_idx,
class_is_known=class_is_known,
class_one_hot=class_one_hot,
W_penalty=W_penalty)
if self.prediction_mode:
# Define initial attention tensor
self.initial_attention = self.decoder.attention_func(
enc_final_state)
# Look up inputs
decoder_inputs_embedded = tf.nn.embedding_lookup(
self.embedding_matrix,
self.decoder_inputs,
name='decoder_input')
is_lm_mode_tensor = tf.to_float(
tf.expand_dims(self.is_lm_mode, axis=1))
decoder_inputs = tf.concat(
[decoder_inputs_embedded, is_lm_mode_tensor], axis=1)
# Concatenate class info vector
decoder_inputs = tf.concat([decoder_inputs, self.class_info_vec],
axis=1)
# Unpack state
initial_state = unpack_state_tensor(self.decoder_state)
with tf.variable_scope('decoder', reuse=True):
decoder_output, decoder_final_state, self.decoder_new_attention = self.decoder.predict(
inputs=decoder_inputs,
initial_state=initial_state,
attention_states=self.decoder_attention)
# Project output to alphabet size
self.decoder_output = projection(decoder_output,
W=self.projection_W,
b=self.projection_b,
name='decoder_output')
# Compute decayed logits
self.decoder_probs_decayed = compute_decayed_probs(
logits=self.decoder_output,
decay_parameter_ph=self.probs_decay_parameter)
# Pack state to tensor
self.decoder_final_state = pack_state_tuple(
decoder_final_state, name='decoder_final_state')