def _pointer_feedback(pointers, encoder_output, shift=True):
"""Feedback loop for pointer networks.
Args:
pointers: [batch_size, target_length] int tensor with pointers into the
source sentence.
encoder_output: [batch_size, input_length, hidden_size] tensor with encoder
outputs.
shift: Whether to shift the pointers to the right.
Returns:
A [batch_size, target_length, hidden_size] tensor with encoder outputs.
"""
if shift:
pointers = common_layers.shift_right_2d(pointers)
return gather_2d(encoder_output, pointers)
def transformer_prepare_decoder(targets_emb_var,
targets,
hparams,
features=None):
"""Prepare one shard of the model for the decoder.
Args:
targets_emb_var: a Tensor
targets: a Tensor.
hparams: run hyperparameters
features: optionally pass the entire features dictionary as well.
This is needed now for "packed" datasets.
Returns:
decoder_input: a Tensor, bottom of decoder stack
decoder_self_attention_bias: a bias tensor for use in decoder self-attention
"""
decoder_self_attention_bias = (
common_attention.attention_bias_lower_triangle(
common_layers.shape_list(targets)[1]))
if features and "targets_segmentation" in features:
# "Packed" dataset - keep the examples from seeing each other.
targets_segmentation = features["targets_segmentation"]
targets_position = features["targets_position"]
decoder_self_attention_bias += common_attention.attention_bias_same_segment(
targets_segmentation, targets_segmentation)
else:
targets_position = None
decoder_input = tf.gather(targets_emb_var,
common_layers.shift_right_2d(targets))
with tf.variable_scope(tf.get_variable_scope(), reuse=tf.AUTO_REUSE):
decoder_input = common_attention.add_positional_embedding(
decoder_input, hparams.max_length, "positional_embedding",
targets_position)
if hparams.activation_dtype == "bfloat16":
decoder_self_attention_bias = tf.cast(decoder_self_attention_bias,
tf.bfloat16)
return (decoder_input, decoder_self_attention_bias)
def body(self, features):
# Remove dropout if not training
hparams = self._hparams
ps_devices = self._ps_devices
assert hparams.num_model_shards % len(ps_devices) == 0
shards_per_device = hparams.num_model_shards // len(ps_devices)
model_devices = [
ps_devices[i // shards_per_device]
for i in range(hparams.num_model_shards)
]
print("model_devices = %s" % model_devices)
mp = expert_utils.Parallelism(model_devices, reuse=False)
vocab_size = self._problem_hparams.vocabulary["targets"].vocab_size
# squeeze out channels, heights
targets = features["targets_raw"]
targets = tf.squeeze(targets, 3)
targets = tf.squeeze(targets, 2)
shifted_targets = common_layers.shift_right_2d(targets)
# Bypass the symbol modality and use a different embedding on each shard.
decoder_input = mp(common_layers.embedding,
shifted_targets,
vocab_size,
hparams.hidden_size,
multiplier=hparams.hidden_size**0.5,
symbol_dropout_rate=hparams.symbol_dropout)
decoder_self_attention_bias = mp(
common_attention.attention_bias_lower_triangle,
tf.shape(targets)[1])
if "targets_segmentation" in features:
# "Packed" dataset - keep the examples from seeing each other.
targets_segmentation = features["targets_segmentation"]
targets_position = features["targets_position"]
decoder_self_attention_bias = mp(
tf.add, decoder_self_attention_bias,
mp(common_attention.attention_bias_same_segment,
targets_segmentation, targets_segmentation))
else:
targets_position = None
if hparams.pos == "timing":
if targets_position is None:
decoder_input = mp(common_attention.add_timing_signal_1d,
decoder_input)
else:
decoder_input = mp(
common_attention.add_timing_signal_1d_given_position,
decoder_input, targets_position)
decoder_input = mp(tf.nn.dropout, decoder_input,
1.0 - hparams.layer_prepostprocess_dropout)
decoder_output, extra_loss = _super_stack(decoder_input,
decoder_self_attention_bias,
hparams, mp)
# Bypass the symbol modality and compute logits directly.
# We compute a different set of logits on each shard, and sum them.
logits = mp(tf.layers.dense, decoder_output, vocab_size, name="logits")
logits = expert_utils.all_reduce_ring(logits, mp)
logits = mp(tf.multiply, logits, mp.n**-0.5)
# We now have identical logits on all shards.
# Shard 0 gets returned to the estimator.
logits_shard_0 = logits[0]
logits_shard_0 = tf.expand_dims(logits_shard_0, 2)
logits_shard_0 = tf.expand_dims(logits_shard_0, 3)
# On each device, we compute the loss for a part of the batch.
# This is faster than computing the whole loss on one shard.
mp, logits = expert_utils.reduce_by_device(mp, logits, lambda l: l[0])
def _loss_for_shard(logits, targets, shard):
if mp.n > 1:
logits = common_layers.approximate_split(logits, mp.n,
0)[shard]
targets = common_layers.approximate_split(targets, mp.n,
0)[shard]
return common_layers.padded_cross_entropy(logits, targets,
hparams.label_smoothing)
num, denom = mp(_loss_for_shard, logits, targets, range(mp.n))
# override training loss so that it is not computed externally.
losses = {"training": tf.add_n(num) / tf.add_n(denom)}
if extra_loss is not None:
losses["extra"] = extra_loss
return logits_shard_0, losses
def body(self, features):
hparams = self._hparams
ps_devices = self._ps_devices
single_device = (len(ps_devices) == 1)
assert hparams.num_model_shards % len(ps_devices) == 0
shards_per_device = hparams.num_model_shards // len(ps_devices)
model_devices = [ps_devices[i // shards_per_device]
for i in range(hparams.num_model_shards)]
print("model_devices = %s" % model_devices)
mp = expert_utils.Parallelism(model_devices, reuse=False)
targets_vocab_size = self._problem_hparams.vocabulary["targets"].vocab_size
# squeeze out channels, heights
targets = tf.squeeze(features["targets_raw"], [2, 3])
targets_embedding_var = mp(
tf.get_variable, "embedding",
[[targets_vocab_size, hparams.hidden_size]] * mp.n,
initializer=tf.random_normal_initializer(
0.0, hparams.hidden_size**-0.5))
shifted_targets = common_layers.shift_right_2d(targets)
# Bypass the symbol modality and use a different embedding on each shard.
if single_device:
targets_embedding_var_combined = tf.concat(targets_embedding_var, 1)
decoder_input_combined = common_layers.embedding(
shifted_targets, targets_vocab_size,
hparams.hidden_size * mp.n,
multiplier=hparams.hidden_size**0.5,
embedding_var=targets_embedding_var_combined,
)
decoder_input = tf.split(decoder_input_combined, mp.n, axis=2)
else:
targets_embedding_var_combined = None
decoder_input = mp(
common_layers.embedding, shifted_targets, targets_vocab_size,
hparams.hidden_size,
multiplier=hparams.hidden_size**0.5,
embedding_var=targets_embedding_var,
)
decoder_self_attention_bias = mp(
common_attention.attention_bias_lower_triangle,
tf.shape(targets)[1])
if "targets_segmentation" in features:
# "Packed" dataset - keep the examples from seeing each other.
targets_segmentation = features["targets_segmentation"]
targets_position = features["targets_position"]
decoder_self_attention_bias = mp(
tf.add, decoder_self_attention_bias,
mp(common_attention.attention_bias_same_segment,
targets_segmentation, targets_segmentation))
decoder_input = mp(
common_attention.add_timing_signal_1d_given_position,
decoder_input, targets_position)
else:
targets_position = None
decoder_self_attention_bias = mp(
common_attention.attention_bias_lower_triangle,
tf.shape(targets)[1])
decoder_input = mp(common_attention.add_timing_signal_1d, decoder_input)
if self.has_input:
inputs = tf.squeeze(features["inputs_raw"], [2, 3])
inputs_vocab_size = self._problem_hparams.vocabulary["inputs"].vocab_size
# share everything for now
share_inputs_and_targets_embedding = True
if share_inputs_and_targets_embedding:
assert inputs_vocab_size == targets_vocab_size
inputs_embedding_var = targets_embedding_var
inputs_embedding_var_combined = targets_embedding_var_combined
if single_device:
encoder_input_combined = common_layers.embedding(
inputs, inputs_vocab_size,
hparams.hidden_size * mp.n,
multiplier=hparams.hidden_size**0.5,
embedding_var=inputs_embedding_var_combined,
)
encoder_input = tf.split(encoder_input_combined, mp.n, axis=2)
else:
encoder_input = mp(
common_layers.embedding, inputs, inputs_vocab_size,
hparams.hidden_size,
multiplier=hparams.hidden_size**0.5,
embedding_var=inputs_embedding_var,
)
if "inputs_segmentation" in features:
# "Packed" dataset - keep the examples from seeing each other.
inputs_segmentation = features["inputs_segmentation"]
inputs_position = features["inputs_position"]
encoder_self_attention_bias = mp(
common_attention.attention_bias_same_segment,
inputs_segmentation, inputs_segmentation)
encoder_decoder_attention_bias = mp(
common_attention.attention_bias_same_segment,
targets_segmentation, inputs_segmentation)
encoder_input = mp(
common_attention.add_timing_signal_1d_given_position,
encoder_input, inputs_position)
else:
encoder_padding = tf.to_float(tf.equal(inputs, 0))
ignore_padding = common_attention.attention_bias_ignore_padding(
encoder_padding)
encoder_self_attention_bias = ignore_padding
encoder_decoder_attention_bias = ignore_padding
inputs_position = None
encoder_input = mp(common_attention.add_timing_signal_1d, encoder_input)
# encoder stack here
with tf.variable_scope("encoder"):
encoder_input = mp(
tf.nn.dropout, encoder_input,
1.0 - hparams.layer_prepostprocess_dropout)
encoder_output = _layer_stack(
mp,
encoder_input,
encoder_self_attention_bias,
hparams.encoder_layers,
hparams)
else:
encoder_decoder_attention_bias = None
encoder_output = None
with tf.variable_scope("decoder"):
decoder_input = mp(
tf.nn.dropout, decoder_input,
1.0 - hparams.layer_prepostprocess_dropout)
decoder_output = _layer_stack(
mp,
decoder_input,
decoder_self_attention_bias,
layers=hparams.decoder_layers,
hparams=hparams,
encoder_output=encoder_output,
encoder_decoder_attention_bias=encoder_decoder_attention_bias)
# Bypass the symbol modality and compute logits directly.
# We compute a different set of logits on each shard, and sum them.
# Share the weights with the target embedding.
output_var = targets_embedding_var
output_var_combined = targets_embedding_var_combined
if single_device:
decoder_output = tf.concat(decoder_output, 2)
logits = tf.tensordot(decoder_output, output_var_combined, [[2], [1]])
num, denom = common_layers.padded_cross_entropy(
logits, targets, hparams.label_smoothing)
training_loss = num / denom
else:
logits = mp(
tf.tensordot, decoder_output, output_var, [[[2], [1]]] * mp.n)
logits = expert_utils.all_reduce_ring(logits, mp)
# On each device, we compute the loss for a part of the batch.
# This is faster than computing the whole loss on one shard.
mp, logits = expert_utils.reduce_by_device(mp, logits, lambda l: l[0])
def _loss_for_shard(logits, targets, shard):
logits = common_layers.approximate_split(logits, mp.n, 0)[shard]
targets = common_layers.approximate_split(targets, mp.n, 0)[shard]
return common_layers.padded_cross_entropy(
logits, targets, hparams.label_smoothing)
num, denom = mp(_loss_for_shard, logits, targets, range(mp.n))
training_loss = tf.add_n(num) / tf.add_n(denom)
logits = logits[0]
logits = tf.expand_dims(tf.expand_dims(logits, 2), 3)
# override training loss so that it is not computed externally.
losses = {"training": training_loss}
return logits, losses
def _mtf_model_fn(self, features, mesh):
features = copy.copy(features)
hparams = self._hparams
targets = tf.to_int32(features["targets"])
if len(targets.get_shape()) > 2:
tf.logging.info("targets = %s" % targets)
targets = tf.squeeze(targets, [2, 3])
# pad targets to max_length
def pad_to_max_length(x):
extra_length = hparams.max_length - tf.shape(x)[1]
x = tf.pad(x, [[0, 0], [0, extra_length]])
x = tf.reshape(x, [hparams.batch_size, hparams.max_length])
return x
targets = pad_to_max_length(targets)
for key in [
"targets_segmentation", "targets_position",
"inputs_segmentation", "inputs_position"
]:
if key in features:
features[key] = pad_to_max_length(features[key])
shifted_targets = common_layers.shift_right_2d(targets)
targets = self._import_to_batch_by_length(targets, "targets", mesh,
hparams)
shifted_targets = self._import_to_batch_by_length(
shifted_targets, "shifted_targets", mesh, hparams)
if "targets_segmentation" in features:
# "Packed" dataset - keep the examples from seeing each other.
targets_segmentation = self._import_to_batch_by_length(
features["targets_segmentation"], "targets_segmentation", mesh,
hparams)
targets_position = self._import_to_batch_by_length(
features["targets_position"], "targets_position", mesh,
hparams)
decoder_self_attention_mask = (
mtf.layers.attention_mask_autoregressive(
targets_position, dtype=self.activation_dtype) +
mtf.layers.attention_mask_same_segment(
targets_segmentation, dtype=self.activation_dtype))
else:
targets_position = mtf.range(mesh, self.length_dim, dtype=tf.int32)
decoder_self_attention_mask = mtf.layers.attention_mask_autoregressive(
targets_position, dtype=self.activation_dtype)
def layer_prepostprocess_dropout(x):
return mtf.dropout(
x,
keep_prob=1.0 - hparams.layer_prepostprocess_dropout,
noise_shape=mtf.Shape(self.batch_dims + [self.model_dim]))
extra_losses = []
(inputs_embedding_var, targets_embedding_var, softmax_var,
positional_embedding_var) = self._embedding_and_softmax_vars(mesh)
if hparams.transformer_type == "decoder":
encoder_output = None
encoder_decoder_attention_mask = None
else:
inputs = tf.squeeze(tf.to_int32(features["inputs"]), [2, 3])
inputs = pad_to_max_length(inputs)
inputs = self._import_to_batch_by_length(inputs, "inputs", mesh,
hparams)
if "inputs_segmentation" in features:
# "Packed" dataset - keep the examples from seeing each other.
inputs_segmentation = self._import_to_batch_by_length(
features["inputs_segmentation"], "inputs_segmentation",
mesh, hparams)
inputs_position = self._import_to_batch_by_length(
features["inputs_position"], "inputs_position", mesh,
hparams)
encoder_self_attention_mask = (
mtf.layers.attention_mask_same_segment(
inputs_segmentation, dtype=self.activation_dtype))
else:
inputs_position = mtf.range(mesh,
self.length_dim,
dtype=tf.int32)
encoder_self_attention_mask = (
mtf.layers.attention_mask_ignore_padding(
inputs, dtype=self.activation_dtype))
x = (mtf.gather(inputs_embedding_var, inputs,
self.inputs_vocab_dim) +
mtf.gather(positional_embedding_var, inputs_position,
self.max_length_dim))
x = layer_prepostprocess_dropout(x)
with tf.variable_scope("encoder"):
x = self._layer_stack(
x,
hparams.encoder_layers,
self_attention_mask=encoder_self_attention_mask,
losses=extra_losses)
if hparams.transformer_type == "encdec":
if "inputs_segmentation" in features:
encoder_decoder_attention_mask = (
mtf.layers.attention_mask_same_segment(
targets_segmentation,
inputs_segmentation,
dtype=self.activation_dtype))
else:
encoder_decoder_attention_mask = encoder_self_attention_mask
encoder_output = mtf.rename_dimension(x, self.length_dim.name,
self.memory_length_dim.name)
if hparams.transformer_type != "encoder":
# DECODER
x = (mtf.gather(targets_embedding_var, shifted_targets,
self.targets_vocab_dim) +
mtf.gather(positional_embedding_var, targets_position,
self.max_length_dim))
x = layer_prepostprocess_dropout(x)
with tf.variable_scope("decoder"):
x = self._layer_stack(
x,
hparams.decoder_layers,
encoder_output=encoder_output,
self_attention_mask=decoder_self_attention_mask,
encdec_attention_mask=encoder_decoder_attention_mask,
losses=extra_losses)
logits = mtf.matmul(x, softmax_var)
if hparams.mode == tf.estimator.ModeKeys.TRAIN:
logits = mtf.layers.multiplicative_jitter(logits, epsilon=1e-2)
off_value = hparams.label_smoothing / self._targets_vocab_size
on_value = 1.0 - hparams.label_smoothing + off_value
soft_targets = mtf.one_hot(targets,
self.targets_vocab_dim,
on_value=on_value,
off_value=off_value,
dtype=self.activation_dtype)
loss = mtf.layers.softmax_cross_entropy_with_logits(
logits, soft_targets, self.targets_vocab_dim)
weights = mtf.layers.weights_nonzero(targets,
dtype=self.activation_dtype)
loss = mtf.reduce_mean(loss * weights)
for l in extra_losses:
loss += l
logits = mtf.to_float(logits)
# combine batch dims
if len(self.batch_dims) > 1:
combined_batch_dim = mtf.Dimension(self.batch_dims[0].name,
mtf.Shape(self.batch_dims).size)
logits = mtf.reshape(logits,
[combined_batch_dim] + logits.shape.dims[-2:])
return logits, loss
def body(self, features):
hparams = self._hparams
ps_devices = self._ps_devices
single_device = (len(ps_devices) == 1)
assert hparams.num_model_shards % len(ps_devices) == 0
shards_per_device = hparams.num_model_shards // len(ps_devices)
model_devices = [ps_devices[i // shards_per_device]
for i in range(hparams.num_model_shards)]
print("model_devices = %s" % model_devices)
mp = expert_utils.Parallelism(model_devices, reuse=False)
targets_vocab_size = self._problem_hparams.vocabulary["targets"].vocab_size
# squeeze out channels, heights
targets = tf.squeeze(features["targets_raw"], [2, 3])
targets_embedding_var = mp(
tf.get_variable, "embedding",
[[targets_vocab_size, hparams.hidden_size]] * mp.n,
initializer=tf.random_normal_initializer(
0.0, hparams.hidden_size**-0.5))
shifted_targets = common_layers.shift_right_2d(targets)
# Bypass the symbol modality and use a different embedding on each shard.
if single_device:
targets_embedding_var_combined = tf.concat(targets_embedding_var, 1)
decoder_input_combined = common_layers.embedding(
shifted_targets, targets_vocab_size,
hparams.hidden_size * mp.n,
multiplier=hparams.hidden_size**0.5,
embedding_var=targets_embedding_var_combined,
)
decoder_input = tf.split(decoder_input_combined, mp.n, axis=2)
else:
targets_embedding_var_combined = None
decoder_input = mp(
common_layers.embedding, shifted_targets, targets_vocab_size,
hparams.hidden_size,
multiplier=hparams.hidden_size**0.5,
embedding_var=targets_embedding_var,
)
decoder_self_attention_bias = mp(
common_attention.attention_bias_lower_triangle,
tf.shape(targets)[1])
if "targets_segmentation" in features:
# "Packed" dataset - keep the examples from seeing each other.
targets_segmentation = features["targets_segmentation"]
targets_position = features["targets_position"]
decoder_self_attention_bias = mp(
tf.add, decoder_self_attention_bias,
mp(common_attention.attention_bias_same_segment,
targets_segmentation, targets_segmentation))
decoder_input = mp(
common_attention.add_timing_signal_1d_given_position,
decoder_input, targets_position)
else:
targets_position = None
decoder_self_attention_bias = mp(
common_attention.attention_bias_lower_triangle,
tf.shape(targets)[1])
decoder_input = mp(common_attention.add_timing_signal_1d, decoder_input)
if self.has_input:
inputs = tf.squeeze(features["inputs_raw"], [2, 3])
inputs_vocab_size = self._problem_hparams.vocabulary["inputs"].vocab_size
# share everything for now
share_inputs_and_targets_embedding = True
if share_inputs_and_targets_embedding:
assert inputs_vocab_size == targets_vocab_size
inputs_embedding_var = targets_embedding_var
inputs_embedding_var_combined = targets_embedding_var_combined
if single_device:
encoder_input_combined = common_layers.embedding(
inputs, inputs_vocab_size,
hparams.hidden_size * mp.n,
multiplier=hparams.hidden_size**0.5,
embedding_var=inputs_embedding_var_combined,
)
encoder_input = tf.split(encoder_input_combined, mp.n, axis=2)
else:
encoder_input = mp(
common_layers.embedding, inputs, inputs_vocab_size,
hparams.hidden_size,
multiplier=hparams.hidden_size**0.5,
embedding_var=inputs_embedding_var,
)
if "inputs_segmentation" in features:
# "Packed" dataset - keep the examples from seeing each other.
inputs_segmentation = features["inputs_segmentation"]
inputs_position = features["inputs_position"]
encoder_self_attention_bias = mp(
common_attention.attention_bias_same_segment,
inputs_segmentation, inputs_segmentation)
encoder_decoder_attention_bias = mp(
common_attention.attention_bias_same_segment,
targets_segmentation, inputs_segmentation)
encoder_input = mp(
common_attention.add_timing_signal_1d_given_position,
encoder_input, inputs_position)
else:
encoder_padding = tf.to_float(tf.equal(inputs, 0))
ignore_padding = common_attention.attention_bias_ignore_padding(
encoder_padding)
encoder_self_attention_bias = ignore_padding
encoder_decoder_attention_bias = ignore_padding
inputs_position = None
encoder_input = mp(common_attention.add_timing_signal_1d, encoder_input)
# encoder stack here
with tf.variable_scope("encoder"):
encoder_input = mp(
tf.nn.dropout, encoder_input,
1.0 - hparams.layer_prepostprocess_dropout)
encoder_output = _layer_stack(
mp,
encoder_input,
encoder_self_attention_bias,
hparams.encoder_layers,
hparams)
else:
encoder_decoder_attention_bias = None
encoder_output = None
with tf.variable_scope("decoder"):
decoder_input = mp(
tf.nn.dropout, decoder_input,
1.0 - hparams.layer_prepostprocess_dropout)
decoder_output = _layer_stack(
mp,
decoder_input,
decoder_self_attention_bias,
layers=hparams.decoder_layers,
hparams=hparams,
encoder_output=encoder_output,
encoder_decoder_attention_bias=encoder_decoder_attention_bias)
# Bypass the symbol modality and compute logits directly.
# We compute a different set of logits on each shard, and sum them.
# Share the weights with the target embedding.
output_var = targets_embedding_var
output_var_combined = targets_embedding_var_combined
if single_device:
decoder_output = tf.concat(decoder_output, 2)
logits = tf.tensordot(decoder_output, output_var_combined, [[2], [1]])
num, denom = common_layers.padded_cross_entropy(
logits, targets, hparams.label_smoothing)
training_loss = num / denom
else:
logits = mp(
tf.tensordot, decoder_output, output_var, [[[2], [1]]] * mp.n)
logits = expert_utils.all_reduce_ring(logits, mp)
# On each device, we compute the loss for a part of the batch.
# This is faster than computing the whole loss on one shard.
mp, logits = expert_utils.reduce_by_device(mp, logits, lambda l: l[0])
def _loss_for_shard(logits, targets, shard):
logits = common_layers.approximate_split(logits, mp.n, 0)[shard]
targets = common_layers.approximate_split(targets, mp.n, 0)[shard]
return common_layers.padded_cross_entropy(
logits, targets, hparams.label_smoothing)
num, denom = mp(_loss_for_shard, logits, targets, range(mp.n))
training_loss = tf.add_n(num) / tf.add_n(denom)
logits = logits[0]
logits = tf.expand_dims(tf.expand_dims(logits, 2), 3)
# override training loss so that it is not computed externally.
losses = {"training": training_loss}
return logits, losses
def mtf_model_fn(self, features, mesh):
features = copy.copy(features)
tf.logging.info("features = %s" % features)
hparams = self._hparams
activation_dtype = self.activation_type
# We assume fixed vocab size for targets
targets = tf.to_int32(features["targets"])
# Image preprocessing, reshape into a 1D sequence and shift right.
length = hparams.img_len * hparams.img_len * hparams.num_channels
targets = tf.reshape(targets, [hparams.batch_size, length])
shifted_targets = common_layers.shift_right_2d(targets)
# Declare all the dimensions
batch_dim = mtf.Dimension("batch", hparams.batch_size)
def import_to_batch_by_length(x, name):
return mtf.import_tf_tensor(mesh,
x,
mtf.Shape([batch_dim,
self.length_dim]),
name=name)
targets = import_to_batch_by_length(targets, "targets")
shifted_targets = import_to_batch_by_length(shifted_targets,
"shifted_targets")
extra_losses = []
# Create targets content and position embeddings.
# Create embedding var for targets and positions and do a gather.
targets_embedding_var = mtf.get_variable(
mesh,
"targets_embedding",
mtf.Shape([self.targets_vocab_dim, self.model_dim]),
initializer=tf.random_normal_initializer(),
activation_dtype=activation_dtype)
x = mtf.gather(targets_embedding_var, shifted_targets,
self.targets_vocab_dim)
# Add positional embeddings
x += mtf.reshape(self.create_positional_emb_2d(targets),
[self.length_dim, self.model_dim])
# If conditional and input is given, add the input embedding to the target.
# TODO(nikip): Verify conditional.
if self.has_input and not hparams.unconditional:
inputs = tf.squeeze(tf.to_int32(features["inputs"]), [2, 3])
inputs = import_to_batch_by_length(inputs, "inputs")
# Input embeddings
inputs_embedding_var = mtf.layers.embedding(
mesh,
"input_embedding",
mtf.Shape([self.inputs_vocab_dim, self.model_dim]),
activation_dtype=activation_dtype)
inputs_emb = mtf.gather(inputs_embedding_var, inputs,
self.inputs_vocab_dim)
x += inputs_emb
# Image Transformer Decoder
# [ self attention - ffn - residual + dropout] x n
if hparams.attention_type == "local1d_spatial":
decoder_output = local_attention1d_spatial_decoder(
x, self.kv_dim, self.heads_dim, self.feedforward_dim, hparams)
elif hparams.attention_type == "local2d_spatial":
decoder_output = local_attention2d_spatial_decoder(
x, self.kv_dim, self.heads_dim, self.feedforward_dim, hparams)
elif hparams.attention_type == "local1d":
decoder_output = local_attention1d_masked_decoder(
x, self.kv_dim, self.heads_dim, self.feedforward_dim, hparams)
else:
raise ValueError("Invalid attention type.")
# Calculate the logits and loss.
logits = mtf.layers.dense(decoder_output,
self.outputs_vocab_dim,
name="logits")
# Need a reshape for logits
logits = mtf.reshape(
logits,
mtf.Shape([batch_dim, self.length_dim, self.outputs_vocab_dim]))
soft_targets = mtf.one_hot(targets,
self.outputs_vocab_dim,
dtype=activation_dtype)
loss = mtf.layers.softmax_cross_entropy_with_logits(
logits, soft_targets, self.outputs_vocab_dim)
loss = mtf.reduce_mean(loss)
for l in extra_losses:
loss += l
# Reshape logits to original target shape.
logits = mtf.reshape(
logits,
mtf.Shape([
batch_dim, self.rows_dim, self.orig_cols_dim,
self.channels_dim, self.outputs_vocab_dim
]))
return logits, loss
def body(self, features):
# Remove dropout if not training
hparams = self._hparams
ps_devices = self._ps_devices
assert hparams.num_model_shards % len(ps_devices) == 0
shards_per_device = hparams.num_model_shards // len(ps_devices)
model_devices = [ps_devices[i // shards_per_device]
for i in xrange(hparams.num_model_shards)]
print("model_devices = %s" % model_devices)
mp = expert_utils.Parallelism(model_devices, reuse=False)
vocab_size = self._problem_hparams.vocabulary["targets"].vocab_size
# squeeze out channels, heights
targets = features["targets_raw"]
targets = tf.squeeze(targets, 3)
targets = tf.squeeze(targets, 2)
shifted_targets = common_layers.shift_right_2d(targets)
# Bypass the symbol modality and use a different embedding on each shard.
decoder_input = mp(
common_layers.embedding, shifted_targets, vocab_size,
hparams.hidden_size,
multiplier=hparams.hidden_size**0.5,
symbol_dropout_rate=hparams.symbol_dropout)
decoder_self_attention_bias = mp(
common_attention.attention_bias_lower_triangle,
tf.shape(targets)[1])
if "targets_segmentation" in features:
# "Packed" dataset - keep the examples from seeing each other.
targets_segmentation = features["targets_segmentation"]
targets_position = features["targets_position"]
decoder_self_attention_bias = mp(
tf.add, decoder_self_attention_bias,
mp(common_attention.attention_bias_same_segment,
targets_segmentation, targets_segmentation))
else:
targets_position = None
if hparams.pos == "timing":
if targets_position is None:
decoder_input = mp(common_attention.add_timing_signal_1d, decoder_input)
else:
decoder_input = mp(
common_attention.add_timing_signal_1d_given_position,
decoder_input, targets_position)
decoder_input = mp(
tf.nn.dropout, decoder_input,
1.0 - hparams.layer_prepostprocess_dropout)
decoder_output, extra_loss = _super_stack(
decoder_input, decoder_self_attention_bias, hparams, mp)
# Bypass the symbol modality and compute logits directly.
# We compute a different set of logits on each shard, and sum them.
logits = mp(tf.layers.dense, decoder_output, vocab_size, name="logits")
logits = common_layers.all_reduce_ring(logits, mp)
logits = mp(tf.multiply, logits, mp.n ** -0.5)
# We now have identical logits on all shards.
# Shard 0 gets returned to the estimator.
logits_shard_0 = logits[0]
logits_shard_0 = tf.expand_dims(logits_shard_0, 2)
logits_shard_0 = tf.expand_dims(logits_shard_0, 3)
# On each device, we compute the loss for a part of the batch.
# This is faster than computing the whole loss on one shard.
mp, logits = common_layers.reduce_by_device(mp, logits, lambda l: l[0])
def _loss_for_shard(logits, targets, shard):
if mp.n > 1:
logits = common_layers.approximate_split(logits, mp.n, 0)[shard]
targets = common_layers.approximate_split(targets, mp.n, 0)[shard]
return common_layers.padded_cross_entropy(
logits, targets, hparams.label_smoothing)
num, denom = mp(_loss_for_shard, logits, targets, range(mp.n))
# override training loss so that it is not computed externally.
losses = {"training": tf.add_n(num) / tf.add_n(denom)}
if extra_loss is not None:
losses["extra"] = extra_loss
return logits_shard_0, losses
def mtf_model_fn(self, features, mesh):
features = copy.copy(features)
tf.logging.info("features = %s" % features)
hparams = self._hparams
activation_dtype = self.activation_type
# We assume fixed vocab size for targets
targets = tf.to_int32(features["targets"])
# Image preprocessing, reshape into a 1D sequence and shift right.
length = hparams.img_len*hparams.img_len*hparams.num_channels
targets = tf.reshape(targets, [hparams.batch_size, length])
shifted_targets = common_layers.shift_right_2d(targets)
# Declare all the dimensions
batch_dim = mtf.Dimension("batch", hparams.batch_size)
def import_to_batch_by_length(x, name):
return mtf.import_tf_tensor(
mesh, x, mtf.Shape([batch_dim, self.length_dim]), name=name)
targets = import_to_batch_by_length(targets, "targets")
shifted_targets = import_to_batch_by_length(
shifted_targets, "shifted_targets")
extra_losses = []
# Create targets content and position embeddings.
# Create embedding var for targets and positions and do a gather.
targets_embedding_var = mtf.get_variable(
mesh, "targets_embedding",
mtf.Shape([self.targets_vocab_dim, self.model_dim]),
initializer=tf.random_normal_initializer(),
activation_dtype=activation_dtype)
x = mtf.gather(targets_embedding_var,
shifted_targets, self.targets_vocab_dim)
# Add positional embeddings
x += mtf.reshape(self.create_positional_emb_2d(targets),
[self.length_dim, self.model_dim])
# If conditional and input is given, add the input embedding to the target.
# TODO(nikip): Verify conditional.
if self.has_input and not hparams.unconditional:
inputs = tf.squeeze(tf.to_int32(features["inputs"]), [2, 3])
inputs = import_to_batch_by_length(inputs, "inputs")
# Input embeddings
inputs_embedding_var = mtf.layers.embedding(
mesh, "input_embedding",
mtf.Shape([self.inputs_vocab_dim, self.model_dim]),
activation_dtype=activation_dtype)
inputs_emb = mtf.gather(
inputs_embedding_var, inputs, self.inputs_vocab_dim)
x += inputs_emb
# Image Transformer Decoder
# [ self attention - ffn - residual + dropout] x n
if hparams.attention_type == "local1d_spatial":
decoder_output = local_attention1d_spatial_decoder(
x, self.kv_dim, self.heads_dim, self.feedforward_dim, hparams)
elif hparams.attention_type == "local2d_spatial":
decoder_output = local_attention2d_spatial_decoder(
x, self.kv_dim, self.heads_dim, self.feedforward_dim, hparams)
elif hparams.attention_type == "local1d":
decoder_output = local_attention1d_masked_decoder(
x, self.kv_dim, self.heads_dim, self.feedforward_dim, hparams)
else:
raise ValueError("Invalid attention type.")
# Calculate the logits and loss.
logits = mtf.layers.dense(
decoder_output, self.outputs_vocab_dim, name="logits")
# Need a reshape for logits
logits = mtf.reshape(
logits, mtf.Shape([batch_dim, self.length_dim, self.outputs_vocab_dim]))
soft_targets = mtf.one_hot(
targets, self.outputs_vocab_dim, dtype=activation_dtype)
loss = mtf.layers.softmax_cross_entropy_with_logits(
logits, soft_targets, self.outputs_vocab_dim)
loss = mtf.reduce_mean(loss)
for l in extra_losses:
loss += l
# Reshape logits to original target shape.
logits = mtf.reshape(
logits,
mtf.Shape([batch_dim, self.rows_dim, self.orig_cols_dim,
self.channels_dim, self.outputs_vocab_dim]))
return logits, loss
def mtf_model_fn(self, features, mesh):
features = copy.copy(features)
tf.logging.info("features = %s" % features)
hparams = self._hparams
activation_dtype = self.set_activation_type()
# We assume fixed vocab size for targets
targets_vocab_size = self._problem_hparams.target_modality._vocab_size # pylint: disable=protected-access
targets = tf.to_int32(features["targets"])
# Image preprocessing, reshape into a 1D sequence and shift right.
length = hparams.img_len * hparams.img_len * hparams.num_channels
targets = tf.reshape(targets, [hparams.batch_size, length])
shifted_targets = common_layers.shift_right_2d(targets)
# Declare all the dimensions
model_dim = mtf.Dimension("d_model", hparams.hidden_size)
batch_dim = mtf.Dimension("batch", hparams.batch_size)
length_dim = mtf.Dimension("length", length)
max_length_dim = mtf.Dimension("max_length", hparams.max_length)
filter_dim = mtf.Dimension("d_ff", hparams.d_ff)
kv_channels = mtf.Dimension("kv_channels", hparams.d_kv)
heads = mtf.Dimension("heads", hparams.num_heads)
def import_to_batch_by_length(x, name):
return mtf.import_tf_tensor(mesh,
x,
mtf.Shape([batch_dim, length_dim]),
name=name)
def layer_prepostprocess_dropout(x):
return mtf.dropout(x,
keep_prob=1.0 -
hparams.layer_prepostprocess_dropout,
noise_shape=mtf.Shape([batch_dim, model_dim]))
targets = import_to_batch_by_length(targets, "targets")
shifted_targets = import_to_batch_by_length(shifted_targets,
"shifted_targets")
extra_losses = []
# Create targets content and position embeddings.
targets_vocab_size = 256 * hparams.num_channels
targets_vocab_dim = mtf.Dimension("vocab", targets_vocab_size)
outputs_vocab_dim = mtf.Dimension("output_vocab", 256)
# Create embedding var for targets and positions and do a gather.
targets_embedding_var = mtf.get_variable(
mesh,
"targets_embedding",
mtf.Shape([targets_vocab_dim, model_dim]),
initializer=tf.random_normal_initializer(),
activation_dtype=activation_dtype)
x = mtf.gather(targets_embedding_var, shifted_targets,
targets_vocab_dim)
# Add positional embeddings
x += mtf.reshape(
self.create_positional_emb_2d(targets, max_length_dim, model_dim),
[length_dim, model_dim])
# If conditional and input is given, add the input embedding to the target.
# TODO(nikip): Verify conditional.
if self.has_input and not hparams.unconditional:
vocab_size = hparams.num_classes
inputs_vocab_dim = mtf.Dimension("vocab", vocab_size)
inputs = tf.squeeze(tf.to_int32(features["inputs"]), [2, 3])
inputs = import_to_batch_by_length(inputs, "inputs")
# Input embeddings
inputs_embedding_var = mtf_layers.embedding(
mesh,
"input_embedding",
mtf.Shape([inputs_vocab_dim, model_dim]),
activation_dtype=activation_dtype)
inputs_emb = mtf.gather(inputs_embedding_var, inputs,
inputs_vocab_dim)
x += inputs_emb
# Image Transformer Decoder
# [ self attention - ffn - residual + dropout] x n
for layer in range(hparams.num_decoder_layers):
layer_name = "decoder_layer_%d" % layer
with tf.variable_scope(layer_name):
# Self attention layer
x += layer_prepostprocess_dropout(
mtf_layers.masked_local_attention_1d(
mtf_layers.layer_norm(x,
model_dim,
name="layer_norm_self_att"),
None,
kv_channels,
heads,
block_length=hparams.block_length,
name="self_att"))
# ffn layer
x += layer_prepostprocess_dropout(
mtf_layers.dense_relu_dense(
mtf_layers.layer_norm(x,
model_dim,
name="layer_norm_ffn"),
filter_dim,
hparams.dropout,
dropout_broadcast_dims=[length_dim]))
x = mtf_layers.layer_norm(x,
model_dim,
name="decoder_final_layer_norm")
# Calculate the logits and loss.
logits = mtf_layers.dense(x, outputs_vocab_dim, name="logits")
soft_targets = mtf.one_hot(targets,
outputs_vocab_dim,
dtype=activation_dtype)
loss = mtf_layers.softmax_cross_entropy_with_logits(
logits, soft_targets, outputs_vocab_dim)
loss = mtf.reduce_mean(loss)
for l in extra_losses:
loss += l
return logits, loss
